diff --git a/docs/release_notes.rst b/docs/release_notes.rst index 9100d752..5fd69f54 100644 --- a/docs/release_notes.rst +++ b/docs/release_notes.rst @@ -60,6 +60,8 @@ Upcoming Release * Updates ci.yaml such that it fails if the generated outputs are different than the ones committed (https://github.com/PyPSA/technology-data/pull/205) +* Add BF-BOF and separate natural gas- and hydrogen-based steelmaking (The technology previously called `direct iron reduction furnace` becomes `hydrogen direct iron reduction`, and `natural gas direct iron reduction furnace` represent the conventional direct iron reduction process), cement and ethanol production technologies (https://github.com/PyPSA/technology-data/pull/211) + * Add industrial plant CCS retrofit options (https://github.com/PyPSA/technology-data/pull/212) * Include further unit tests for compile_cost_assumptions.py (https://github.com/PyPSA/technology-data/pull/210) @@ -67,7 +69,7 @@ Upcoming Release `v0.11.0 `__ (24th January 2025) ======================================================================================= -* Country specific cost assumptions and added NREL/ATB data (https://github.com/PyPSA/technology-data/pull/160) +* Country-specific cost assumptions and added NREL/ATB data (https://github.com/PyPSA/technology-data/pull/160) * Add missing currency_year for FOM (https://github.com/PyPSA/technology-data/pull/163) diff --git a/inputs/manual_input.csv b/inputs/manual_input.csv index 4a2f6405..609911ce 100644 --- a/inputs/manual_input.csv +++ b/inputs/manual_input.csv @@ -309,17 +309,32 @@ dry bulk carrier Capesize,capacity,2020,180000,t,2020,-,"DWT; corresponds to siz dry bulk carrier Capesize,investment,2020,40000000,EUR,2020,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR." dry bulk carrier Capesize,FOM,2020,4,%/year,2020,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost." dry bulk carrier Capesize,lifetime,2020,25,years,2020,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime. -direct iron reduction furnace,investment,2020,4277858,EUR/t_HBI/h,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost." -direct iron reduction furnace,FOM,2020,11.3,%/year,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost." -direct iron reduction furnace,lifetime,2020,40,years,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime. -direct iron reduction furnace,electricity-input,2020,1.03,MWh_el/t_hbi,2020,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’. -direct iron reduction furnace,hydrogen-input,2020,2.1,MWh_H2/t_hbi,2020,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect)." -direct iron reduction furnace,ore-input,2020,1.59,t_ore/t_hbi,2020,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’. +hydrogen direct iron reduction furnace,investment,2020,4277858,EUR/t_HBI/h,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost." +hydrogen direct iron reduction furnace,FOM,2020,11.3,%/year,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost." +hydrogen direct iron reduction furnace,lifetime,2020,40,years,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime. +hydrogen direct iron reduction furnace,economic_lifetime,2020,20,years,2020,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).", +hydrogen direct iron reduction furnace,electricity-input,2020,1.03,MWh_el/t_hbi,2020,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’. +hydrogen direct iron reduction furnace,hydrogen-input,2020,2.1,MWh_H2/t_hbi,2020,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect)." +hydrogen direct iron reduction furnace,ore-input,2020,1.59,t_ore/t_hbi,2020,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’. +natural gas direct iron reduction furnace,investment,2020,4277858,EUR/t_HBI/h,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost." +natural gas direct iron reduction furnace,FOM,2020,11.3,%/year,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.", +natural gas direct iron reduction furnace,lifetime,2020,40,years,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.", +natural gas direct iron reduction furnace,economic_lifetime,2020,20,years,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime. +natural gas direct iron reduction furnace,gas-input,2020,2.78,MWh_NG/t_hbi,2020,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI. +natural gas direct iron reduction furnace,ore-input,2020,1.59,t_ore/t_hbi,,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ", electric arc furnace,investment,2020,1839600,EUR/t_steel/h,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’. electric arc furnace,FOM,2020,30,%/year,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion." electric arc furnace,lifetime,2020,40,years,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime. +electric arc furnace,economic_lifetime,2020,20,years,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.", electric arc furnace,electricity-input,2020,0.6395,MWh_el/t_steel,2020,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. electric arc furnace,hbi-input,2020,1,t_hbi/t_steel,2020,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower. +electric arc furnace with hbi and scrap,investment,2020,1839600,EUR/t_steel/h,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’. +electric arc furnace with hbi and scrap,FOM,2020,30,%/year,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion." +electric arc furnace with hbi and scrap,lifetime,2020,40,years,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime. +electric arc furnace with hbi and scrap,economic_lifetime,2020,20,years,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.", +electric arc furnace with hbi and scrap,electricity-input,2020,0.6395,MWh_el/t_steel,2020,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. +electric arc furnace with hbi and scrap,hbi-input,2020,0.37,t_hbi/t_steel,2020,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower. +electric arc furnace with hbi and scrap,scrap-input,2020,0.71,t_scrap/t_steel,2020,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.", shipping fuel methanol,fuel,2020,72,EUR/MWh_th,2020,"Based on (source 1) Hampp et al (2022), https://arxiv.org/abs/2107.01092, and (source 2): https://www.methanol.org/methanol-price-supply-demand/; both accessed: 2022-12-03.",400 EUR/t assuming range roughly in the long-term range for green methanol (source 1) and late 2020+beyond values for grey methanol (source 2). shipping fuel methanol,CO2 intensity,2020,0.2482,t_CO2/MWh_th,2020,-,Based on stochiometric composition. iron ore DRI-ready,commodity,2020,97.73,EUR/t,2020,"Model assumptions from MPP Steel Transition Tool: https://missionpossiblepartnership.org/action-sectors/steel/, accessed: 2022-12-03.","DRI ready assumes 65% iron content, requiring no additional benefication." @@ -371,6 +386,7 @@ bioethanol crops,fuel,2020,54.6434100368518,EUR/MWhth,2010,"JRC ENSPRESO ca avg bioethanol crops,fuel,2030,72.477665790641,EUR/MWhth,2010,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM", bioethanol crops,fuel,2040,75.7178710725453,EUR/MWhth,2010,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM", bioethanol crops,fuel,2050,78.995541440487,EUR/MWhth,2010,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM", +bioethanol crops,CO2 intensity,2020,0.12894,tCO2/MWh_th,,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg)." biodiesel crops,fuel,2020,84.585016773297,EUR/MWhth,2010,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM", biodiesel crops,fuel,2030,121.021431275337,EUR/MWhth,2010,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM", biodiesel crops,fuel,2040,120.926387801857,EUR/MWhth,2010,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM", @@ -404,6 +420,49 @@ iron-air battery discharge,efficiency,2030,0.6,per unit,2023,"Form Energy, docu/ iron-air battery discharge,efficiency,2035,0.62,per unit,2023,"Form Energy, docu/FormEnergy_Europe_modeling_recommendations_2023.03.pdf, p4", iron-air battery discharge,efficiency,2040,0.63,per unit,2023,"Form Energy, docu/FormEnergy_Europe_modeling_recommendations_2023.03.pdf, p4", iron-air battery,lifetime,2030,17.5,years,2023,"Form Energy, docu/FormEnergy_Europe_modeling_recommendations_2023.03.pdf, p4", +blast furnace-basic oxygen furnace,investment,2020,7637406,EUR/t_steel/h,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’. +blast furnace-basic oxygen furnace,FOM,2020,14.18,%/year,2020,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’. +blast furnace-basic oxygen furnace,lifetime,2020,40,years,2020,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime. +blast furnace-basic oxygen furnace,economic_lifetime,2020,20,years,2020,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).", +blast furnace-basic oxygen furnace,coal-input,2020,1.43,MWh_coal/t_steel,2020,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio." +blast furnace-basic oxygen furnace,ore-input,2020,1.539,t_ore/t_steel,2020,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF` +blast furnace-basic oxygen furnace,scrap-input,2020,0.051,t_scrap/t_steel,2020,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF` +cement dry clinker,investment,2006,1095000,EUR/t_clinker/h,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year +cement dry clinker,FOM,2006,4,%/year,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.", +cement dry clinker,VOM,2006,5,EUR/t_clinker,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.", +cement dry clinker,lifetime,2006,30,years,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.", +cement dry clinker,gas-input,2006,0.00016,MWh_NG/t_clinker,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker +cement dry clinker,electricity-input,2006,0.0694,MWh_el/t_clinker,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker +cement dry clinker,heat-input,2006,0.9444,MWh_th/t_CO2,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker +cement finishing,investment,2006,87600,EUR/t_cement/h,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year +cement finishing,FOM,2006,30,%/year,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.", +cement finishing,VOM,2006,3,EUR/t_cement,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.", +cement finishing,electricity-input,2006,0.1736,MWh_el/t_cement,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement. +cement finishing,clinker-input,2006,0.656,t_cl/t_cement,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) +cement finishing,slag-input,2006,0.194,t_slag/t_cement,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) +cement finishing,lifetime,2006,25,years,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) +ethanol from starch crop,investment,2010,819630,EUR/MW_eth,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW" +ethanol from starch crop,investment,2020,677090,EUR/MW_eth,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW" +ethanol from starch crop,investment,2025,614720,EUR/MW_eth,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW" +ethanol from starch crop,investment,2030,570180,EUR/MW_eth,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW" +ethanol from starch crop,FOM,2010,11.4,%/year,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year" +ethanol from starch crop,FOM,2020,13.8,%/year,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year" +ethanol from starch crop,FOM,2025,15.2,%/year,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year" +ethanol from starch crop,FOM,2030,16.4,%/year,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year" +ethanol from starch crop,VOM,2010,24.9,EUR/MWh_eth,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM" +ethanol from starch crop,lifetime,2010,20,years,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production +ethanol from starch crop,efficiency,2010,0.58,p.u.,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t" +ethanol from sugar crops,investment,2010,659330,EUR/MW_eth,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW" +ethanol from sugar crops,investment,2020,501090,EUR/MW_eth,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW" +ethanol from sugar crops,investment,2025,454930,EUR/MW_eth,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW" +ethanol from sugar crops,investment,2030,421970,EUR/MW_eth,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW" +ethanol from sugar crops,FOM,2010,13.57,%/year,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year" +ethanol from sugar crops,FOM,2020,16.43,%/year,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year" +ethanol from sugar crops,FOM,2025,18.09,%/year,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year" +ethanol from sugar crops,FOM,2030,19.51,%/year,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year" +ethanol from sugar crops,VOM,2010,21.9,EUR/MWh_eth,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM" +ethanol from sugar crops,lifetime,2010,20,years,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production +ethanol from sugar crops,efficiency,2010,0.45,p.u.,2015,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t" ethanol carbon capture retrofit,FOM,2030,7,%/year,2019,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16", ethanol carbon capture retrofit,capture_rate,2030,0.94,per unit,2019,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-16, accessed 2025-04-16", ethanol carbon capture retrofit,electricity-input,2030,0.12,MWh/tCO2,2019,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16", diff --git a/outputs/US/costs_2020.csv b/outputs/US/costs_2020.csv index fc805739..5985c383 100644 --- a/outputs/US/costs_2020.csv +++ b/outputs/US/costs_2020.csv @@ -3466,6 +3466,7 @@ biochar pyrolysis,investment,167272.82,EUR/kW_biochar,"Danish Energy Agency, inp biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0,, biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0,, biodiesel crops,fuel,96.2077,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0,, +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).",,, bioethanol crops,fuel,62.1519,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0,, biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",,,, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0,, @@ -3573,6 +3574,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0,, biomass-to-methanol,investment,5591.3924,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0,, biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0,, +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0,, +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,capture_rate,0.9,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,compression-electricity-input,0.1,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, @@ -3588,6 +3596,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, cement carbon capture retrofit,investment,2608428.9904,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0,, cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0,, +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0,, +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0,, +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0,, +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0,, +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0,, +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, central air-sourced heat pump,FOM,0.2102,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0,, central air-sourced heat pump,VOM,2.3175,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0,, central air-sourced heat pump,efficiency,3.1,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0,, @@ -3835,21 +3857,23 @@ direct firing solid fuels CC,VOM,0.3276,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0,, direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0,, direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0,, -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0,, dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0,, dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0,, dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0,, electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0,, electric boiler steam,FOM,1.3375,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0,, electric boiler steam,VOM,0.8711,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0,, electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0,, @@ -3891,6 +3915,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, ethanol carbon capture retrofit,investment,935988.2129,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0,, ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +ethanol from starch crop,FOM,13.8,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0,, +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from starch crop,investment,716511.2815,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0,, +ethanol from sugar crops,FOM,16.43,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0,, +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from sugar crops,investment,530264.2751,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0,, fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0,, fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0,, fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0,, @@ -3973,6 +4007,13 @@ hydro,investment,2574.0603,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?buc hydro,investment,2574.0603,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2020.0,R&D,Conservative hydro,investment,2574.0603,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2020.0,R&D,Moderate hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0,, +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, hydrogen storage compressor,FOM,4.0,%/year,ICCT IRA e-fuels assumptions ,,2022.0,, hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,,, hydrogen storage compressor,investment,1.9919,USD/kWh_H2,ICCT IRA e-fuels assumptions ,,2022.0,, @@ -4047,6 +4088,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.599,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0,, micro CHP,investment,10630.1681,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0,, micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0,, +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0,, +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",,,, nuclear,CF,0.937,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2020.0,Market,Moderate nuclear,CF,0.937,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2020.0,R&D,Moderate nuclear,FOM,1.96,%/year,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2020.0,Market,Moderate diff --git a/outputs/US/costs_2025.csv b/outputs/US/costs_2025.csv index f23e0d58..9ebdd0a1 100644 --- a/outputs/US/costs_2025.csv +++ b/outputs/US/costs_2025.csv @@ -3546,6 +3546,7 @@ biochar pyrolysis,investment,167272.82,EUR/kW_biochar,"Danish Energy Agency, inp biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0,, biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0,, biodiesel crops,fuel,116.9293,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0,, +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).",,, bioethanol crops,fuel,72.2943,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0,, biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",,,, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0,, @@ -3653,6 +3654,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0,, biomass-to-methanol,investment,4348.8608,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0,, biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0,, +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0,, +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,capture_rate,0.9,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,compression-electricity-input,0.1,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, @@ -3668,6 +3676,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, cement carbon capture retrofit,investment,2608428.9904,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0,, cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0,, +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0,, +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0,, +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0,, +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0,, +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0,, +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, central air-sourced heat pump,FOM,0.2102,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0,, central air-sourced heat pump,VOM,2.3175,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0,, central air-sourced heat pump,efficiency,3.15,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0,, @@ -3921,21 +3943,23 @@ direct firing solid fuels CC,VOM,0.3301,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0,, direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0,, direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0,, -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0,, dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0,, dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0,, dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0,, electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0,, electric boiler steam,FOM,1.3933,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0,, electric boiler steam,VOM,0.8761,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0,, electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0,, @@ -3977,6 +4001,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, ethanol carbon capture retrofit,investment,935988.2129,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0,, ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +ethanol from starch crop,FOM,15.2,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0,, +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from starch crop,investment,650509.9986,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0,, +ethanol from sugar crops,FOM,18.09,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0,, +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from sugar crops,investment,481416.7648,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0,, fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0,, fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0,, fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0,, @@ -4059,6 +4093,13 @@ hydro,investment,2831.8236,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?buc hydro,investment,2831.8236,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,R&D,Moderate hydro,investment,2831.8236,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,R&D,Conservative hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0,, +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, hydrogen storage compressor,FOM,4.0,%/year,ICCT IRA e-fuels assumptions ,,2022.0,, hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,,, hydrogen storage compressor,investment,1.9919,USD/kWh_H2,ICCT IRA e-fuels assumptions ,,2022.0,, @@ -4133,6 +4174,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.604,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0,, micro CHP,investment,9224.3988,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0,, micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0,, +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0,, +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",,,, nuclear,efficiency,0.326,p.u.,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","Based on heat rate of 10.45 MMBtu/MWh_e and 3.4095 MMBtu/MWh_th, i.e. 1/(10.45/3.4095) = 0.3260.",2023.0,, nuclear,lifetime,40.0,years,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.",,2023.0,, offwind,CF,0.4794,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Advanced diff --git a/outputs/US/costs_2030.csv b/outputs/US/costs_2030.csv index 7d4d17d6..0cce44bb 100644 --- a/outputs/US/costs_2030.csv +++ b/outputs/US/costs_2030.csv @@ -3702,6 +3702,7 @@ biochar pyrolysis,investment,154405.68,EUR/kW_biochar,"Danish Energy Agency, inp biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0,, biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0,, biodiesel crops,fuel,137.6508,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0,, +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).",,, bioethanol crops,fuel,82.4367,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0,, biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",,,, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0,, @@ -3809,6 +3810,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0,, biomass-to-methanol,investment,3106.3291,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0,, biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0,, +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0,, +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,capture_rate,0.9,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,compression-electricity-input,0.085,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, @@ -3824,6 +3832,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, cement carbon capture retrofit,investment,2608428.9904,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0,, cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0,, +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0,, +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0,, +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0,, +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0,, +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0,, +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, central air-sourced heat pump,FOM,0.2336,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0,, central air-sourced heat pump,VOM,2.6561,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0,, central air-sourced heat pump,efficiency,3.2,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0,, @@ -4077,21 +4099,23 @@ direct firing solid fuels CC,VOM,0.3326,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0,, direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0,, direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0,, -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0,, dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0,, dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0,, dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0,, electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0,, electric boiler steam,FOM,1.4571,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0,, electric boiler steam,VOM,0.8811,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0,, electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0,, @@ -4133,6 +4157,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, ethanol carbon capture retrofit,investment,935988.2129,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0,, ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +ethanol from starch crop,FOM,16.4,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0,, +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from starch crop,investment,603376.8073,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0,, +ethanol from sugar crops,FOM,19.51,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0,, +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from sugar crops,investment,446537.78,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0,, fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0,, fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0,, fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0,, @@ -4215,6 +4249,13 @@ hydro,investment,2690.4649,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?buc hydro,investment,2831.8236,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,R&D,Moderate hydro,investment,2831.8236,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,R&D,Conservative hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0,, +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, hydrogen storage compressor,FOM,4.0,%/year,ICCT IRA e-fuels assumptions ,,2022.0,, hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,,, hydrogen storage compressor,investment,1.9919,USD/kWh_H2,ICCT IRA e-fuels assumptions ,,2022.0,, @@ -4289,6 +4330,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.609,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0,, micro CHP,investment,7841.7127,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0,, micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0,, +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0,, +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",,,, nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Advanced nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Moderate nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Conservative diff --git a/outputs/US/costs_2035.csv b/outputs/US/costs_2035.csv index 6d036a16..6c8cc2a7 100644 --- a/outputs/US/costs_2035.csv +++ b/outputs/US/costs_2035.csv @@ -3726,6 +3726,7 @@ biochar pyrolysis,investment,147972.11,EUR/kW_biochar,"Danish Energy Agency, inp biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0,, biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0,, biodiesel crops,fuel,137.5968,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0,, +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).",,, bioethanol crops,fuel,84.2795,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0,, biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",,,, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0,, @@ -3833,6 +3834,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0,, biomass-to-methanol,investment,2681.013,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0,, biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0,, +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0,, +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,capture_rate,0.925,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,compression-electricity-input,0.08,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, @@ -3848,6 +3856,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, cement carbon capture retrofit,investment,2608428.9904,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0,, cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0,, +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0,, +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0,, +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0,, +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0,, +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0,, +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, central air-sourced heat pump,FOM,0.2336,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0,, central air-sourced heat pump,VOM,2.4868,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0,, central air-sourced heat pump,efficiency,3.25,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0,, @@ -4101,21 +4123,23 @@ direct firing solid fuels CC,VOM,0.3339,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0,, direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0,, direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0,, -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0,, dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0,, dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0,, dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0,, electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0,, electric boiler steam,FOM,1.4214,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0,, electric boiler steam,VOM,0.8333,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0,, electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0,, @@ -4157,6 +4181,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, ethanol carbon capture retrofit,investment,935988.2129,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0,, ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +ethanol from starch crop,FOM,16.4,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0,, +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from starch crop,investment,603376.8073,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0,, +ethanol from sugar crops,FOM,19.51,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0,, +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from sugar crops,investment,446537.78,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0,, fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0,, fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0,, fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0,, @@ -4239,6 +4273,13 @@ hydro,investment,2568.6361,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?buc hydro,investment,2831.8236,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,R&D,Moderate hydro,investment,2831.8236,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,R&D,Conservative hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0,, +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, hydrogen storage compressor,FOM,4.0,%/year,ICCT IRA e-fuels assumptions ,,2022.0,, hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,,, hydrogen storage compressor,investment,1.9919,USD/kWh_H2,ICCT IRA e-fuels assumptions ,,2022.0,, @@ -4313,6 +4354,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.609,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0,, micro CHP,investment,7406.062,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0,, micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0,, +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0,, +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",,,, nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Advanced nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Moderate nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Conservative diff --git a/outputs/US/costs_2040.csv b/outputs/US/costs_2040.csv index 29e441e3..251128af 100644 --- a/outputs/US/costs_2040.csv +++ b/outputs/US/costs_2040.csv @@ -3726,6 +3726,7 @@ biochar pyrolysis,investment,141538.54,EUR/kW_biochar,"Danish Energy Agency, inp biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0,, biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0,, biodiesel crops,fuel,137.5427,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0,, +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).",,, bioethanol crops,fuel,86.1222,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0,, biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",,,, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0,, @@ -3833,6 +3834,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0,, biomass-to-methanol,investment,2255.697,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0,, biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0,, +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0,, +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,capture_rate,0.95,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,compression-electricity-input,0.075,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, @@ -3848,6 +3856,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, cement carbon capture retrofit,investment,2608428.9904,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0,, cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0,, +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0,, +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0,, +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0,, +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0,, +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0,, +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, central air-sourced heat pump,FOM,0.2336,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0,, central air-sourced heat pump,VOM,2.3175,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0,, central air-sourced heat pump,efficiency,3.3,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0,, @@ -4101,21 +4123,23 @@ direct firing solid fuels CC,VOM,0.3351,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0,, direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0,, direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0,, -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0,, dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0,, dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0,, dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0,, electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0,, electric boiler steam,FOM,1.3857,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0,, electric boiler steam,VOM,0.7855,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0,, electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0,, @@ -4157,6 +4181,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, ethanol carbon capture retrofit,investment,935988.2129,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0,, ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +ethanol from starch crop,FOM,16.4,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0,, +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from starch crop,investment,603376.8073,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0,, +ethanol from sugar crops,FOM,19.51,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0,, +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from sugar crops,investment,446537.78,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0,, fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0,, fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0,, fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0,, @@ -4239,6 +4273,13 @@ hydro,investment,2446.8072,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?buc hydro,investment,2831.8236,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,R&D,Moderate hydro,investment,2718.3647,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,R&D,Conservative hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0,, +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, hydrogen storage compressor,FOM,4.0,%/year,ICCT IRA e-fuels assumptions ,,2022.0,, hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,,, hydrogen storage compressor,investment,1.9919,USD/kWh_H2,ICCT IRA e-fuels assumptions ,,2022.0,, @@ -4313,6 +4354,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.609,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0,, micro CHP,investment,6970.4113,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0,, micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0,, +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0,, +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",,,, nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Advanced nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Moderate nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Conservative diff --git a/outputs/US/costs_2045.csv b/outputs/US/costs_2045.csv index 96e7bec0..e2bc0b4b 100644 --- a/outputs/US/costs_2045.csv +++ b/outputs/US/costs_2045.csv @@ -3726,6 +3726,7 @@ biochar pyrolysis,investment,135104.97,EUR/kW_biochar,"Danish Energy Agency, inp biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0,, biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0,, biodiesel crops,fuel,134.6872,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0,, +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).",,, bioethanol crops,fuel,87.9862,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0,, biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",,,, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0,, @@ -3833,6 +3834,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0,, biomass-to-methanol,investment,1904.4308,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0,, biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0,, +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0,, +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,capture_rate,0.95,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,compression-electricity-input,0.075,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, @@ -3848,6 +3856,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, cement carbon capture retrofit,investment,2608428.9904,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0,, cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0,, +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0,, +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0,, +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0,, +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0,, +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0,, +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, central air-sourced heat pump,FOM,0.2336,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0,, central air-sourced heat pump,VOM,2.5715,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0,, central air-sourced heat pump,efficiency,3.35,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0,, @@ -4101,21 +4123,23 @@ direct firing solid fuels CC,VOM,0.3351,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0,, direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0,, direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0,, -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0,, dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0,, dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0,, dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0,, electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0,, electric boiler steam,FOM,1.35,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0,, electric boiler steam,VOM,0.7855,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0,, electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0,, @@ -4157,6 +4181,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, ethanol carbon capture retrofit,investment,935988.2129,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0,, ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +ethanol from starch crop,FOM,16.4,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0,, +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from starch crop,investment,603376.8073,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0,, +ethanol from sugar crops,FOM,19.51,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0,, +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from sugar crops,investment,446537.78,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0,, fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0,, fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0,, fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0,, @@ -4239,6 +4273,13 @@ hydro,investment,2446.8072,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?buc hydro,investment,2831.8236,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,R&D,Moderate hydro,investment,2718.3647,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,R&D,Conservative hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0,, +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, hydrogen storage compressor,FOM,4.0,%/year,ICCT IRA e-fuels assumptions ,,2022.0,, hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,,, hydrogen storage compressor,investment,1.9919,USD/kWh_H2,ICCT IRA e-fuels assumptions ,,2022.0,, @@ -4313,6 +4354,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.609,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0,, micro CHP,investment,6534.7606,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0,, micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0,, +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0,, +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",,,, nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Advanced nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Moderate nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Conservative diff --git a/outputs/US/costs_2050.csv b/outputs/US/costs_2050.csv index 22298c84..d82c0070 100644 --- a/outputs/US/costs_2050.csv +++ b/outputs/US/costs_2050.csv @@ -3726,6 +3726,7 @@ biochar pyrolysis,investment,128671.4,EUR/kW_biochar,"Danish Energy Agency, inpu biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0,, biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0,, biodiesel crops,fuel,131.8317,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0,, +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).",,, bioethanol crops,fuel,89.8502,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0,, biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",,,, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0,, @@ -3833,6 +3834,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0,, biomass-to-methanol,investment,1553.1646,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0,, biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0,, +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0,, +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0,, +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0,, cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,capture_rate,0.95,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, cement capture,compression-electricity-input,0.075,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0,, @@ -3848,6 +3856,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, cement carbon capture retrofit,investment,2608428.9904,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0,, cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0,, +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0,, +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0,, +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0,, +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0,, +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0,, +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0,, +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0,, central air-sourced heat pump,FOM,0.2336,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0,, central air-sourced heat pump,VOM,2.8255,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0,, central air-sourced heat pump,efficiency,3.4,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0,, @@ -4101,21 +4123,23 @@ direct firing solid fuels CC,VOM,0.3351,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0,, direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0,, direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0,, -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0,, dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0,, dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0,, dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0,, electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0,, +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0,, +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0,, +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0,, +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0,, +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0,, electric boiler steam,FOM,1.3143,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0,, electric boiler steam,VOM,0.7855,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0,, electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0,, @@ -4157,6 +4181,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0,, ethanol carbon capture retrofit,investment,935988.2129,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0,, ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0,, +ethanol from starch crop,FOM,16.4,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0,, +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from starch crop,investment,603376.8073,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0,, +ethanol from sugar crops,FOM,19.51,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0,, +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0,, +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0,, +ethanol from sugar crops,investment,446537.78,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0,, +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0,, fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0,, fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0,, fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0,, @@ -4239,6 +4273,13 @@ hydro,investment,2446.8072,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?buc hydro,investment,2831.8236,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,R&D,Moderate hydro,investment,2718.3647,USD/kW,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,R&D,Conservative hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0,, +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0,, +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0,, +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0,, +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0,, hydrogen storage compressor,FOM,4.0,%/year,ICCT IRA e-fuels assumptions ,,2022.0,, hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,,, hydrogen storage compressor,investment,1.9919,USD/kWh_H2,ICCT IRA e-fuels assumptions ,,2022.0,, @@ -4313,6 +4354,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.609,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0,, micro CHP,investment,6099.1099,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0,, micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0,, +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0,, +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0,, +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0,, +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0,, +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",,,, nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Advanced nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Moderate nuclear,CF,0.93,per unit,NREL/ATB-https://data.openei.org/s3_viewer?bucket=oedi-data-lake&prefix=ATB%2Felectricity%2Fcsv%2F2022%2F,Meaning of scenario and financial case: https://atb.nrel.gov/electricity/2024/definitions#scenarios,2022.0,Market,Conservative diff --git a/outputs/costs_2020.csv b/outputs/costs_2020.csv index bab27cef..707fc3f8 100644 --- a/outputs/costs_2020.csv +++ b/outputs/costs_2020.csv @@ -560,6 +560,7 @@ biochar pyrolysis,investment,167272.82,EUR/kW_biochar,"Danish Energy Agency, inp biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0 biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0 biodiesel crops,fuel,96.2077,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0 +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).", bioethanol crops,fuel,62.1519,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0 biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0 @@ -634,6 +635,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0 biomass-to-methanol,investment,5591.3924,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0 biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0 +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0 +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,capture_rate,0.9,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,compression-electricity-input,0.1,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 @@ -649,6 +657,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 cement carbon capture retrofit,investment,2587727.173,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0 cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0 +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0 +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0 +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0 +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0 +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0 +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 central air-sourced heat pump,FOM,0.2102,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0 central air-sourced heat pump,VOM,2.3175,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0 central air-sourced heat pump,efficiency,3.1,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0 @@ -842,21 +864,23 @@ direct firing solid fuels CC,VOM,0.3276,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0 direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0 direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0 -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0 dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0 dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0 dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0 electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0 electric boiler steam,FOM,1.3375,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0 electric boiler steam,VOM,0.8711,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0 electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0 @@ -898,6 +922,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 ethanol carbon capture retrofit,investment,928559.735,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0 ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +ethanol from starch crop,FOM,13.8,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0 +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from starch crop,investment,716511.2815,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0 +ethanol from sugar crops,FOM,16.43,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0 +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from sugar crops,investment,530264.2751,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0 fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0 fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0 fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0 @@ -935,6 +969,13 @@ hydro,FOM,1.0,%/year,DIW DataDoc http://hdl.handle.net/10419/80348, from old pyp hydro,efficiency,0.9,per unit,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2015.0 hydro,investment,2274.8177,EUR/kWel,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2010.0 hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0 +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 hydrogen storage compressor,FOM,4.0,%/year,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",-,2020.0 hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,2020.0 hydrogen storage compressor,investment,87.69,EUR/kW_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.","2923 EUR/kg_H2. For a 206 kg/h compressor. Base CAPEX 40 528 EUR/kW_el with scale factor 0.4603. kg_H2 converted to MWh using LHV. Pressure range: 30 bar in, 250 bar out.",2020.0 @@ -1009,6 +1050,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.599,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0 micro CHP,investment,10630.1681,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0 micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0 +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0 +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",, nuclear,FOM,1.27,%/year,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (131.5+152.75)/2 USD/kW_e / (1.09 USD/EUR) relative to investment costs.",2023.0 nuclear,VOM,3.5464,EUR/MWh_e,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (4.25+5)/2 USD/kW_e / (1.09 USD/EUR) .",2023.0 nuclear,efficiency,0.326,p.u.,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","Based on heat rate of 10.45 MMBtu/MWh_e and 3.4095 MMBtu/MWh_th, i.e. 1/(10.45/3.4095) = 0.3260.",2023.0 diff --git a/outputs/costs_2025.csv b/outputs/costs_2025.csv index 4d2fbcd8..376ac6e1 100644 --- a/outputs/costs_2025.csv +++ b/outputs/costs_2025.csv @@ -560,6 +560,7 @@ biochar pyrolysis,investment,167272.82,EUR/kW_biochar,"Danish Energy Agency, inp biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0 biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0 biodiesel crops,fuel,116.9293,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0 +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).", bioethanol crops,fuel,72.2943,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0 biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0 @@ -634,6 +635,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0 biomass-to-methanol,investment,4348.8608,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0 biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0 +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0 +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,capture_rate,0.9,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,compression-electricity-input,0.1,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 @@ -649,6 +657,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 cement carbon capture retrofit,investment,2587727.173,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0 cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0 +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0 +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0 +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0 +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0 +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0 +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 central air-sourced heat pump,FOM,0.2102,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0 central air-sourced heat pump,VOM,2.3175,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0 central air-sourced heat pump,efficiency,3.15,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0 @@ -842,21 +864,23 @@ direct firing solid fuels CC,VOM,0.3301,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0 direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0 direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0 -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0 dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0 dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0 dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0 electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0 electric boiler steam,FOM,1.3933,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0 electric boiler steam,VOM,0.8761,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0 electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0 @@ -898,6 +922,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 ethanol carbon capture retrofit,investment,928559.735,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0 ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +ethanol from starch crop,FOM,15.2,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0 +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from starch crop,investment,650509.9986,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0 +ethanol from sugar crops,FOM,18.09,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0 +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from sugar crops,investment,481416.7648,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0 fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0 fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0 fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0 @@ -935,6 +969,13 @@ hydro,FOM,1.0,%/year,DIW DataDoc http://hdl.handle.net/10419/80348, from old pyp hydro,efficiency,0.9,per unit,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2015.0 hydro,investment,2274.8177,EUR/kWel,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2010.0 hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0 +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 hydrogen storage compressor,FOM,4.0,%/year,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",-,2020.0 hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,2020.0 hydrogen storage compressor,investment,87.69,EUR/kW_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.","2923 EUR/kg_H2. For a 206 kg/h compressor. Base CAPEX 40 528 EUR/kW_el with scale factor 0.4603. kg_H2 converted to MWh using LHV. Pressure range: 30 bar in, 250 bar out.",2020.0 @@ -1009,6 +1050,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.604,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0 micro CHP,investment,9224.3988,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0 micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0 +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0 +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",, nuclear,FOM,1.27,%/year,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (131.5+152.75)/2 USD/kW_e / (1.09 USD/EUR) relative to investment costs.",2023.0 nuclear,VOM,3.5464,EUR/MWh_e,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (4.25+5)/2 USD/kW_e / (1.09 USD/EUR) .",2023.0 nuclear,efficiency,0.326,p.u.,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","Based on heat rate of 10.45 MMBtu/MWh_e and 3.4095 MMBtu/MWh_th, i.e. 1/(10.45/3.4095) = 0.3260.",2023.0 diff --git a/outputs/costs_2030.csv b/outputs/costs_2030.csv index 0cdbdaf3..63727a1a 100644 --- a/outputs/costs_2030.csv +++ b/outputs/costs_2030.csv @@ -560,6 +560,7 @@ biochar pyrolysis,investment,154405.68,EUR/kW_biochar,"Danish Energy Agency, inp biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0 biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0 biodiesel crops,fuel,137.6508,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0 +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).", bioethanol crops,fuel,82.4367,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0 biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0 @@ -634,6 +635,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0 biomass-to-methanol,investment,3106.3291,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0 biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0 +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0 +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,capture_rate,0.9,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,compression-electricity-input,0.085,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 @@ -649,6 +657,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 cement carbon capture retrofit,investment,2587727.173,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0 cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0 +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0 +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0 +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0 +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0 +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0 +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 central air-sourced heat pump,FOM,0.2336,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0 central air-sourced heat pump,VOM,2.6561,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0 central air-sourced heat pump,efficiency,3.2,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0 @@ -842,21 +864,23 @@ direct firing solid fuels CC,VOM,0.3326,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0 direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0 direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0 -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0 dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0 dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0 dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0 electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0 electric boiler steam,FOM,1.4571,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0 electric boiler steam,VOM,0.8811,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0 electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0 @@ -898,6 +922,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 ethanol carbon capture retrofit,investment,928559.735,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0 ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +ethanol from starch crop,FOM,16.4,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0 +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from starch crop,investment,603376.8073,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0 +ethanol from sugar crops,FOM,19.51,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0 +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from sugar crops,investment,446537.78,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0 fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0 fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0 fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0 @@ -935,6 +969,13 @@ hydro,FOM,1.0,%/year,DIW DataDoc http://hdl.handle.net/10419/80348, from old pyp hydro,efficiency,0.9,per unit,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2015.0 hydro,investment,2274.8177,EUR/kWel,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2010.0 hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0 +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 hydrogen storage compressor,FOM,4.0,%/year,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",-,2020.0 hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,2020.0 hydrogen storage compressor,investment,87.69,EUR/kW_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.","2923 EUR/kg_H2. For a 206 kg/h compressor. Base CAPEX 40 528 EUR/kW_el with scale factor 0.4603. kg_H2 converted to MWh using LHV. Pressure range: 30 bar in, 250 bar out.",2020.0 @@ -1009,6 +1050,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.609,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0 micro CHP,investment,7841.7127,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0 micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0 +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0 +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",, nuclear,FOM,1.27,%/year,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (131.5+152.75)/2 USD/kW_e / (1.09 USD/EUR) relative to investment costs.",2023.0 nuclear,VOM,3.5464,EUR/MWh_e,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (4.25+5)/2 USD/kW_e / (1.09 USD/EUR) .",2023.0 nuclear,efficiency,0.326,p.u.,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","Based on heat rate of 10.45 MMBtu/MWh_e and 3.4095 MMBtu/MWh_th, i.e. 1/(10.45/3.4095) = 0.3260.",2023.0 diff --git a/outputs/costs_2035.csv b/outputs/costs_2035.csv index 3d015bb2..fff783c4 100644 --- a/outputs/costs_2035.csv +++ b/outputs/costs_2035.csv @@ -560,6 +560,7 @@ biochar pyrolysis,investment,147972.11,EUR/kW_biochar,"Danish Energy Agency, inp biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0 biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0 biodiesel crops,fuel,137.5968,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0 +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).", bioethanol crops,fuel,84.2795,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0 biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0 @@ -634,6 +635,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0 biomass-to-methanol,investment,2681.013,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0 biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0 +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0 +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,capture_rate,0.925,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,compression-electricity-input,0.08,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 @@ -649,6 +657,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 cement carbon capture retrofit,investment,2587727.173,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0 cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0 +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0 +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0 +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0 +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0 +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0 +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 central air-sourced heat pump,FOM,0.2336,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0 central air-sourced heat pump,VOM,2.4868,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0 central air-sourced heat pump,efficiency,3.25,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0 @@ -842,21 +864,23 @@ direct firing solid fuels CC,VOM,0.3339,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0 direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0 direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0 -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0 dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0 dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0 dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0 electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0 electric boiler steam,FOM,1.4214,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0 electric boiler steam,VOM,0.8333,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0 electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0 @@ -898,6 +922,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 ethanol carbon capture retrofit,investment,928559.735,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0 ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +ethanol from starch crop,FOM,16.4,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0 +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from starch crop,investment,603376.8073,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0 +ethanol from sugar crops,FOM,19.51,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0 +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from sugar crops,investment,446537.78,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0 fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0 fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0 fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0 @@ -935,6 +969,13 @@ hydro,FOM,1.0,%/year,DIW DataDoc http://hdl.handle.net/10419/80348, from old pyp hydro,efficiency,0.9,per unit,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2015.0 hydro,investment,2274.8177,EUR/kWel,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2010.0 hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0 +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 hydrogen storage compressor,FOM,4.0,%/year,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",-,2020.0 hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,2020.0 hydrogen storage compressor,investment,87.69,EUR/kW_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.","2923 EUR/kg_H2. For a 206 kg/h compressor. Base CAPEX 40 528 EUR/kW_el with scale factor 0.4603. kg_H2 converted to MWh using LHV. Pressure range: 30 bar in, 250 bar out.",2020.0 @@ -1009,6 +1050,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.609,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0 micro CHP,investment,7406.062,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0 micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0 +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0 +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",, nuclear,FOM,1.27,%/year,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (131.5+152.75)/2 USD/kW_e / (1.09 USD/EUR) relative to investment costs.",2023.0 nuclear,VOM,3.5464,EUR/MWh_e,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (4.25+5)/2 USD/kW_e / (1.09 USD/EUR) .",2023.0 nuclear,efficiency,0.326,p.u.,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","Based on heat rate of 10.45 MMBtu/MWh_e and 3.4095 MMBtu/MWh_th, i.e. 1/(10.45/3.4095) = 0.3260.",2023.0 diff --git a/outputs/costs_2040.csv b/outputs/costs_2040.csv index a6c46d6a..0a551f84 100644 --- a/outputs/costs_2040.csv +++ b/outputs/costs_2040.csv @@ -560,6 +560,7 @@ biochar pyrolysis,investment,141538.54,EUR/kW_biochar,"Danish Energy Agency, inp biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0 biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0 biodiesel crops,fuel,137.5427,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0 +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).", bioethanol crops,fuel,86.1222,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0 biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0 @@ -634,6 +635,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0 biomass-to-methanol,investment,2255.697,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0 biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0 +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0 +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,capture_rate,0.95,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,compression-electricity-input,0.075,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 @@ -649,6 +657,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 cement carbon capture retrofit,investment,2587727.173,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0 cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0 +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0 +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0 +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0 +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0 +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0 +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 central air-sourced heat pump,FOM,0.2336,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0 central air-sourced heat pump,VOM,2.3175,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0 central air-sourced heat pump,efficiency,3.3,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0 @@ -842,21 +864,23 @@ direct firing solid fuels CC,VOM,0.3351,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0 direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0 direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0 -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0 dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0 dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0 dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0 electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0 electric boiler steam,FOM,1.3857,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0 electric boiler steam,VOM,0.7855,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0 electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0 @@ -898,6 +922,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 ethanol carbon capture retrofit,investment,928559.735,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0 ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +ethanol from starch crop,FOM,16.4,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0 +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from starch crop,investment,603376.8073,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0 +ethanol from sugar crops,FOM,19.51,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0 +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from sugar crops,investment,446537.78,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0 fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0 fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0 fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0 @@ -935,6 +969,13 @@ hydro,FOM,1.0,%/year,DIW DataDoc http://hdl.handle.net/10419/80348, from old pyp hydro,efficiency,0.9,per unit,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2015.0 hydro,investment,2274.8177,EUR/kWel,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2010.0 hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0 +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 hydrogen storage compressor,FOM,4.0,%/year,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",-,2020.0 hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,2020.0 hydrogen storage compressor,investment,87.69,EUR/kW_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.","2923 EUR/kg_H2. For a 206 kg/h compressor. Base CAPEX 40 528 EUR/kW_el with scale factor 0.4603. kg_H2 converted to MWh using LHV. Pressure range: 30 bar in, 250 bar out.",2020.0 @@ -1009,6 +1050,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.609,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0 micro CHP,investment,6970.4113,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0 micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0 +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0 +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",, nuclear,FOM,1.27,%/year,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (131.5+152.75)/2 USD/kW_e / (1.09 USD/EUR) relative to investment costs.",2023.0 nuclear,VOM,3.5464,EUR/MWh_e,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (4.25+5)/2 USD/kW_e / (1.09 USD/EUR) .",2023.0 nuclear,efficiency,0.326,p.u.,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","Based on heat rate of 10.45 MMBtu/MWh_e and 3.4095 MMBtu/MWh_th, i.e. 1/(10.45/3.4095) = 0.3260.",2023.0 diff --git a/outputs/costs_2045.csv b/outputs/costs_2045.csv index 36644699..7e1f729c 100644 --- a/outputs/costs_2045.csv +++ b/outputs/costs_2045.csv @@ -560,6 +560,7 @@ biochar pyrolysis,investment,135104.97,EUR/kW_biochar,"Danish Energy Agency, inp biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0 biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0 biodiesel crops,fuel,134.6872,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0 +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).", bioethanol crops,fuel,87.9862,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0 biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0 @@ -634,6 +635,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0 biomass-to-methanol,investment,1904.4308,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0 biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0 +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0 +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,capture_rate,0.95,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,compression-electricity-input,0.075,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 @@ -649,6 +657,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 cement carbon capture retrofit,investment,2587727.173,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0 cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0 +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0 +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0 +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0 +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0 +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0 +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 central air-sourced heat pump,FOM,0.2336,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0 central air-sourced heat pump,VOM,2.5715,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0 central air-sourced heat pump,efficiency,3.35,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0 @@ -842,21 +864,23 @@ direct firing solid fuels CC,VOM,0.3351,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0 direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0 direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0 -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0 dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0 dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0 dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0 electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0 electric boiler steam,FOM,1.35,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0 electric boiler steam,VOM,0.7855,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0 electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0 @@ -898,6 +922,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 ethanol carbon capture retrofit,investment,928559.735,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0 ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +ethanol from starch crop,FOM,16.4,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0 +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from starch crop,investment,603376.8073,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0 +ethanol from sugar crops,FOM,19.51,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0 +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from sugar crops,investment,446537.78,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0 fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0 fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0 fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0 @@ -935,6 +969,13 @@ hydro,FOM,1.0,%/year,DIW DataDoc http://hdl.handle.net/10419/80348, from old pyp hydro,efficiency,0.9,per unit,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2015.0 hydro,investment,2274.8177,EUR/kWel,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2010.0 hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0 +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 hydrogen storage compressor,FOM,4.0,%/year,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",-,2020.0 hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,2020.0 hydrogen storage compressor,investment,87.69,EUR/kW_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.","2923 EUR/kg_H2. For a 206 kg/h compressor. Base CAPEX 40 528 EUR/kW_el with scale factor 0.4603. kg_H2 converted to MWh using LHV. Pressure range: 30 bar in, 250 bar out.",2020.0 @@ -1009,6 +1050,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.609,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0 micro CHP,investment,6534.7606,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0 micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0 +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0 +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",, nuclear,FOM,1.27,%/year,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (131.5+152.75)/2 USD/kW_e / (1.09 USD/EUR) relative to investment costs.",2023.0 nuclear,VOM,3.5464,EUR/MWh_e,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (4.25+5)/2 USD/kW_e / (1.09 USD/EUR) .",2023.0 nuclear,efficiency,0.326,p.u.,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","Based on heat rate of 10.45 MMBtu/MWh_e and 3.4095 MMBtu/MWh_th, i.e. 1/(10.45/3.4095) = 0.3260.",2023.0 diff --git a/outputs/costs_2050.csv b/outputs/costs_2050.csv index 1d15fb46..b5956fb9 100644 --- a/outputs/costs_2050.csv +++ b/outputs/costs_2050.csv @@ -560,6 +560,7 @@ biochar pyrolysis,investment,128671.4,EUR/kW_biochar,"Danish Energy Agency, inpu biochar pyrolysis,lifetime,25.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: Technical lifetime",2020.0 biochar pyrolysis,yield-biochar,0.0582,ton biochar/MWh_feedstock,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","105 Slow pyrolysis, Straw: yield biochar",2020.0 biodiesel crops,fuel,131.8317,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIORPS1 (rape seed), ENS_BaU_GFTM",,2010.0 +bioethanol crops,CO2 intensity,0.1289,tCO2/MWh_th,,"CO2 released during fermentation of bioethanol crops, based on stochiometric composition: C6H12O6 -> 2 C2H5OH + 2 CO2 , i.e. 1 kg ethanol → ~0.956 kg CO₂ (from fermentation) → 0.1289 tCO₂/MWh (with LHV = 26.7 MJ/kg).", bioethanol crops,fuel,89.8502,EUR/MWhth,"JRC ENSPRESO ca avg for MINBIOCRP11 (Bioethanol barley, wheat, grain maize, oats, other cereals and rye), ENS_BaU_GFTM",,2010.0 biogas,CO2 stored,0.0868,tCO2/MWh_th,"Stoichiometric calculation, doi:10.1016/j.apenergy.2022.120016",, biogas,FOM,7.7769,%/year,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","81 Biogas, Basic plant, small: Total O&M",2020.0 @@ -634,6 +635,13 @@ biomass-to-methanol,efficiency-electricity,0.02,MWh_e/MWh_th,"Danish Energy Agen biomass-to-methanol,efficiency-heat,0.22,per unit,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx","97 Methanol from biomass gasif.: District heat Output,",2020.0 biomass-to-methanol,investment,1553.1646,EUR/kW_MeOH,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Specific investment,2020.0 biomass-to-methanol,lifetime,20.0,years,"Danish Energy Agency, inputs/data_sheets_for_renewable_fuels.xlsx",97 Methanol from biomass gasif.: Technical lifetime,2020.0 +blast furnace-basic oxygen furnace,FOM,14.18,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",123.67 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,coal-input,1.43,MWh_coal/t_steel,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ","Based on process ‘Avg BF-BOF` using 195 kg_PCI/t_HM (PCI = Pulverized Coal Injected; HM = Hot Metal) as substitute for coke, 24 MJ/kg as LHV for coal and 1 : 1.1 as HM-to-steel ratio.",2020.0 +blast furnace-basic oxygen furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +blast furnace-basic oxygen furnace,investment,7637406.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",871.85 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘Avg BF-BOF’.,2020.0 +blast furnace-basic oxygen furnace,lifetime,40.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +blast furnace-basic oxygen furnace,ore-input,1.539,t_ore/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 +blast furnace-basic oxygen furnace,scrap-input,0.051,t_scrap/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",Based on process ‘Avg BF-BOF`,2020.0 cement capture,FOM,3.0,%/year,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,capture_rate,0.95,per unit,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 cement capture,compression-electricity-input,0.075,MWh/tCO2,"Danish Energy Agency, inputs/technology_data_for_carbon_capture_transport_storage.xlsx",401.c Post comb - Cement kiln,2020.0 @@ -649,6 +657,20 @@ cement carbon capture retrofit,electricity-input,0.16,MWh/tCO2,"National Petrole cement carbon capture retrofit,gas-input,0.76,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 cement carbon capture retrofit,investment,2587727.173,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 247 million USD, CO2 Volume captured 842000 t/year",2019.0 cement carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +cement dry clinker,FOM,4.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,VOM,5.2911,EUR/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement dry clinker,electricity-input,0.0694,MWh_el/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.25 PJ per Mt clinker,2015.0 +cement dry clinker,gas-input,0.0002,MWh_NG/t_clinker,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 0.0058 PJ per Mt clinker,2015.0 +cement dry clinker,heat-input,0.9444,MWh_th/t_CO2,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original values 3.4 PJ per Mt clinker,2015.0 +cement dry clinker,investment,1158752.6816,EUR/t_clinker/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 125 EUR/t/year,2015.0 +cement dry clinker,lifetime,30.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `IND` (ICMDRYPRD01, ICM.Dry Process Production.01) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,FOM,30.0,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,VOM,3.1747,EUR/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",,2015.0 +cement finishing,clinker-input,0.656,t_cl/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,electricity-input,0.1736,MWh_el/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer) with original value 0.6251 PJ per Mt cement.,2015.0 +cement finishing,investment,92700.2145,EUR/t_cement/h,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Original value 10 EUR/t/year,2015.0 +cement finishing,lifetime,25.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 +cement finishing,slag-input,0.194,t_slag/t_cement,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND_Trans.xlsx`, Sheet `IND_Trans` (ICMFINPRO01, Cement finishing) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Based on inputs for DE (major EU producer),2015.0 central air-sourced heat pump,FOM,0.2336,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Fixed O&M",2015.0 central air-sourced heat pump,VOM,2.8255,EUR/MWh_th,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Variable O&M",2015.0 central air-sourced heat pump,efficiency,3.4,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","40 Comp. hp, airsource 3 MW: Total efficiency, net, name plate",2015.0 @@ -842,21 +864,23 @@ direct firing solid fuels CC,VOM,0.3351,EUR/MWh,"Danish Energy Agency, inputs/te direct firing solid fuels CC,efficiency,1.0,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","312.b Direct firing Sold Fuels: Total efficiency, net, annual average",2019.0 direct firing solid fuels CC,investment,221.54,EUR/kW,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Nominal investment,2019.0 direct firing solid fuels CC,lifetime,15.0,years,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",312.b Direct firing Sold Fuels: Technical lifetime,2019.0 -direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 -direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 -direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 -direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 -direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 dry bulk carrier Capesize,FOM,4.0,%/year,"Based on https://www.hellenicshippingnews.com/capesize-freight-returns-below-operating-expense-levels-but-shipowners-reject-lay-ups/, accessed: 2022-12-03.","5000 USD/d OPEX, exchange rate: 1.15 USD = 1 EUR; absolute value calculate relative to investment cost.",2020.0 dry bulk carrier Capesize,capacity,180000.0,t,-,"DWT; corresponds to size of Capesize bulk carriers which have previously docked at the habour in Hamburg, Germany. Short of 200 kt limit for VLBCs.",2020.0 dry bulk carrier Capesize,investment,40000000.0,EUR,"Based on https://www.hellenicshippingnews.com/dry-bulk-carriers-in-high-demand-as-rates-keep-rallying/, accessed: 2022-12-03.","See figure for ‘Dry Bulk Newbuild Prices’, Capesize at end of 2020. Exchange rate: 1.15 USD = 1 EUR.",2020.0 dry bulk carrier Capesize,lifetime,25.0,years,"Based on https://mfame.guru/fall-life-expectancy-bulk-carriers/, accessed: 2022-12-03.",Expected lifetime.,2020.0 electric arc furnace,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 electric arc furnace,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 electric arc furnace,hbi-input,1.0,t_hbi/t_steel,-,Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 electric arc furnace,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 electric arc furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,FOM,30.0,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","EAF has high OPEX of 62.99 EUR/year/t_steel, presumably because of electrode corrosion.",2020.0 +electric arc furnace with hbi and scrap,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",,2020.0 +electric arc furnace with hbi and scrap,electricity-input,0.6395,MWh_el/t_steel,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘EAF’. ,2020.0 +electric arc furnace with hbi and scrap,hbi-input,0.37,t_hbi/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",Assume HBI instead of scrap as input.Scrap would require higher input (in tonnes) as steel content is lower.,2020.0 +electric arc furnace with hbi and scrap,investment,1839600.0,EUR/t_steel/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",210 EUR/t_steel output/a. MPP steel tool uses CAPEX/OPEX for technology ‘EAF’.,2020.0 +electric arc furnace with hbi and scrap,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +electric arc furnace with hbi and scrap,scrap-input,0.71,t_scrap/t_steel,"World Steel Association, Fact Sheet – Steel and raw materials: https://worldsteel.org/wp-content/uploads/Fact-sheet-raw-materials-2023-1.pdf, Accessed 2024-04-17.",,2020.0 electric boiler steam,FOM,1.3143,%/year,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Fixed O&M,2019.0 electric boiler steam,VOM,0.7855,EUR/MWh,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx",310.1 Electric boiler steam : Variable O&M,2019.0 electric boiler steam,efficiency,0.99,per unit,"Danish Energy Agency, inputs/technology_data_for_industrial_process_heat.xlsx","310.1 Electric boiler steam : Total efficiency, net, annual average",2019.0 @@ -898,6 +922,16 @@ ethanol carbon capture retrofit,capture_rate,0.94,per unit,"National Petroleum C ethanol carbon capture retrofit,electricity-input,0.12,MWh/tCO2,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-20, accessed 2025-04-16",,2019.0 ethanol carbon capture retrofit,investment,928559.735,USD/(tCO2/h),"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-18, accessed 2025-04-16","Capital cost 36 million USD, CO2 Volume captured 342000 t/year",2019.0 ethanol carbon capture retrofit,lifetime,20.0,years,"National Petroleum Council, Meeting the Dual Challenge - A Roadmap to At-Scale Deployment of Carbon Capture, Use, and Storage: https://dualchallenge.npc.org/files/CCUS-Chap_2-030521.pdf, p2-21, accessed 2025-04-16",,2019.0 +ethanol from starch crop,FOM,16.4,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from starch crop,VOM,26.3497,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value 6.93 MEUR/PJ VAROM",2015.0 +ethanol from starch crop,efficiency,0.58,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production. Converted from 0.35 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from starch crop,investment,603376.8073,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from starch crop,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH101, Ethanol production from starch crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for USA and European production,2015.0 +ethanol from sugar crops,FOM,19.51,%/year,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original values FIXOM in MEUR/GW divided by INVCOST for the corresponding year",2015.0 +ethanol from sugar crops,VOM,23.1751,EUR/MWh_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production, original value 6.09 MEUR/PJ VAROM",2015.0 +ethanol from sugar crops,efficiency,0.45,p.u.,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for Brazilian production. Converted from 0.292 t_crop/t_eth, LHV_crop = 16.1 GJ/t, LHV_ethanol = 26.7 GJ/t",2015.0 +ethanol from sugar crops,investment,446537.78,EUR/MW_eth,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.","Suited for USA and European production, original value INVCOST in MEUR/GW",2015.0 +ethanol from sugar crops,lifetime,20.0,years,"JRC, 01_JRC-EU-TIMES Full model, https://zenodo.org/records/3544900, file `SubRES_10_TECHS_CHP_SUP_IND.xlsx`, Sheet `SUP` (BCRPETH201, Ethanol production from sugar crops ) and currency year from file `SysSettings.xls`, sheet `Constants`, Attribute `G_Dyear` = 2015.",Suited for Brazilian production,2015.0 fuel cell,FOM,5.0,%/year,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Fixed O&M,2015.0 fuel cell,c_b,1.25,50oC/100oC,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx",12 LT-PEMFC CHP: Cb coefficient,2015.0 fuel cell,efficiency,0.5,per unit,"Danish Energy Agency, inputs/technology_data_for_el_and_dh.xlsx","12 LT-PEMFC CHP: Electricity efficiency, annual average",2015.0 @@ -935,6 +969,13 @@ hydro,FOM,1.0,%/year,DIW DataDoc http://hdl.handle.net/10419/80348, from old pyp hydro,efficiency,0.9,per unit,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2015.0 hydro,investment,2274.8177,EUR/kWel,DIW DataDoc http://hdl.handle.net/10419/80348, from old pypsa cost assumptions,2010.0 hydro,lifetime,80.0,years,IEA2010, from old pypsa cost assumptions,2015.0 +hydrogen direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","55.28 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ OPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,economic_lifetime,20.0,years,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15).",,2020.0 +hydrogen direct iron reduction furnace,electricity-input,1.03,MWh_el/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03).",Based on process ‘DRI-EAF_100% green H2’ reduced by electricity demand of process ‘EAF’.,2020.0 +hydrogen direct iron reduction furnace,hydrogen-input,2.1,MWh_H2/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2022-12-05). ","63 kg H2/t steel for process ‘DRI-EAF_100% green H2’ according to documentation (raw input files for MPP model list 73 kg H2 / t steel, which seems to high and is probably incorrect).",2020.0 +hydrogen direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +hydrogen direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +hydrogen direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2022-12-03). ",Based on process ‘DRI-EAF_100% green H2’.,2020.0 hydrogen storage compressor,FOM,4.0,%/year,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",-,2020.0 hydrogen storage compressor,compression-electricity-input,0.05,MWh_el/MWh_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.",1.707 kWh/kg.,2020.0 hydrogen storage compressor,investment,87.69,EUR/kW_H2,"Based on Stöckl et al (2021): https://doi.org/10.48550/arXiv.2005.03464, table SI.4.","2923 EUR/kg_H2. For a 206 kg/h compressor. Base CAPEX 40 528 EUR/kW_el with scale factor 0.4603. kg_H2 converted to MWh using LHV. Pressure range: 30 bar in, 250 bar out.",2020.0 @@ -1009,6 +1050,12 @@ micro CHP,efficiency,0.351,per unit,"Danish Energy Agency, inputs/technologydata micro CHP,efficiency-heat,0.609,per unit,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx","219 LT-PEMFC mCHP - natural gas: Heat efficiency, annual average, net",2015.0 micro CHP,investment,6099.1099,EUR/kW_th,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Specific investment,2015.0 micro CHP,lifetime,20.0,years,"Danish Energy Agency, inputs/technologydatafor_heating_installations_marts_2018.xlsx",219 LT-PEMFC mCHP - natural gas: Technical lifetime,2015.0 +natural gas direct iron reduction furnace,FOM,11.3,%/year,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,economic_lifetime,20.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2022-12-05.",MPP steel model distinguishes between plant lifetime (40 years) and investment cycle (20 years). Choose plant lifetime.,2020.0 +natural gas direct iron reduction furnace,gas-input,2.78,MWh_NG/t_hbi,"Mission Possible Partnership (2022): Steel Model Documentation (https://mpp.gitbook.io/mpp-steel-model/model-overview/model-components/technologies, accessed: 2025-04-15). ",Original value 10 GJ/t_DRI.,2020.0 +natural gas direct iron reduction furnace,investment,4277858.0,EUR/t_HBI/h,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.","488.34 EUR/t_HBI output/a. MPP steel tool uses CAPEX/OPEX for technology ‘DRI-EAF_100% green H2’, substract ‘EAF’ CAPEX here to estimate DRI furnace cost.",2020.0 +natural gas direct iron reduction furnace,lifetime,40.0,years,"Model assumptions from MPP Steel Transition Tool: https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/CAPEX%20OPEX%20Per%20Technology.xlsx, accessed: 2025-04-15.",,2020.0 +natural gas direct iron reduction furnace,ore-input,1.59,t_ore/t_hbi,"Mission Possible Partnership (2022): Steel Model (https://github.com/missionpossiblepartnership/mpp-steel-model/blob/9eca52db92bd2d9715f30e98ccaaf36677fdb516/mppsteel/data/import_data/Technology%20Business%20Cases.csv, accessed: 2025-04-15). ",, nuclear,FOM,1.27,%/year,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (131.5+152.75)/2 USD/kW_e / (1.09 USD/EUR) relative to investment costs.",2023.0 nuclear,VOM,3.5464,EUR/MWh_e,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","U.S. specific costs including newly commissioned Vogtle plant, average of range and currency converted, i.e. (4.25+5)/2 USD/kW_e / (1.09 USD/EUR) .",2023.0 nuclear,efficiency,0.326,p.u.,"Lazard's levelized cost of energy analysis - version 16.0 (2023): https://www.lazard.com/media/typdgxmm/lazards-lcoeplus-april-2023.pdf , pg. 49 (Levelized Cost of Energy - Key Assumptions), accessed: 2023-12-14.","Based on heat rate of 10.45 MMBtu/MWh_e and 3.4095 MMBtu/MWh_th, i.e. 1/(10.45/3.4095) = 0.3260.",2023.0