|
|
Line 6: |
Line 6: |
| |contact_persons=Behrang Shirizadeh | | |contact_persons=Behrang Shirizadeh |
| |contact_email=mailto:shirizadeh@centre-cired.fr | | |contact_email=mailto:shirizadeh@centre-cired.fr |
| + | |website=http://www.centre-cired.fr/fr/behrang-shirizadeh/ |
| |text_description=The EOLES family of models optimizes the investment and operation of an energy system | | |text_description=The EOLES family of models optimizes the investment and operation of an energy system |
| in order to minimize the total cost while satisfying energy demand. EOLES_elec is the | | in order to minimize the total cost while satisfying energy demand. EOLES_elec is the |
Line 15: |
Line 16: |
| generation technologies burn methane which can come from three sources: fossil natural | | generation technologies burn methane which can come from three sources: fossil natural |
| gas, biogas from anaerobic digestion and renewable gas from power-to-gas technology | | gas, biogas from anaerobic digestion and renewable gas from power-to-gas technology |
− | (methanation). EOLES_elec also includes four energy storage technologies: pumpedhydro storage (PHS), Li-Ion batteries and two types of methanation. | + | (methanation). EOLES_elec also includes four energy storage technologies: pumped hydro storage (PHS), Li-Ion batteries and two types of methanation (with and without CCS). |
| |Primary outputs=Annualized cost, Installed capacities and generation and storage profiles | | |Primary outputs=Annualized cost, Installed capacities and generation and storage profiles |
| |User documentation=http://www2.centre-cired.fr/IMG/pdf/cired_wp_2020_79_shirizadeh_quirion.pdf | | |User documentation=http://www2.centre-cired.fr/IMG/pdf/cired_wp_2020_79_shirizadeh_quirion.pdf |
Line 24: |
Line 25: |
| |Link to source=https://github.com/BehrangShirizadeh/EOLES_elec | | |Link to source=https://github.com/BehrangShirizadeh/EOLES_elec |
| |data_availability=all | | |data_availability=all |
− | |open_future=Yes | + | |open_future=No |
| |modelling_software=GAMS | | |modelling_software=GAMS |
| |GUI=No | | |GUI=No |
Line 39: |
Line 40: |
| |Storage (Gas)=Yes | | |Storage (Gas)=Yes |
| |Storage (Heat)=No | | |Storage (Heat)=No |
| + | |User behaviour=Inelastic demand |
| |Market models=Electricity and carbon markets | | |Market models=Electricity and carbon markets |
| |decisions=dispatch, investment | | |decisions=dispatch, investment |
| + | |Changes in efficiency=fixed |
| + | |georesolution=Country level |
| |timeresolution=Hour | | |timeresolution=Hour |
| |network_coverage=transmission | | |network_coverage=transmission |
| |Observation period=More than one year | | |Observation period=More than one year |
| |Additional dimensions (Ecological)=CO2 emissions, CO2 storage need | | |Additional dimensions (Ecological)=CO2 emissions, CO2 storage need |
− | |Additional dimensions (Economical)=system-wide LCOE, technology specific LCOE, hourly spot price and carbon and energy market revenues | + | |Additional dimensions (Economical)=system-wide LCOE, technology specific LCOE, hourly spot price, Social cost, Technical cost and Carbon and Energy market revenues |
| + | |Additional dimensions (Social)=Social cost of Carbon, Social cost of System |
| |Additional dimensions (Other)=load curtailment, storage loss and etc. | | |Additional dimensions (Other)=load curtailment, storage loss and etc. |
| |math_modeltype=Optimization, Simulation | | |math_modeltype=Optimization, Simulation |
− | |math_modeltype_shortdesc=linear optimization of dispatch and investment, solved in CPLEX solver of GAMS | + | |math_modeltype_shortdesc=Simultaneous optimization of dispatch and investment (linear programming), solved in CPLEX solver of GAMS |
| |math_objective=investment cost and operational costs (fixed and variable) minimization | | |math_objective=investment cost and operational costs (fixed and variable) minimization |
| |deterministic=Deterministic; Perfect foresight; Sensitivity analysis ; | | |deterministic=Deterministic; Perfect foresight; Sensitivity analysis ; |
| |is_suited_for_many_scenarios=No | | |is_suited_for_many_scenarios=No |
| |montecarlo=No | | |montecarlo=No |
| + | |citation_references=Shirizadeh, B. & Quirion, P. (2020). Low-carbon options for French power sector: What role for renewables, nuclear energy and carbon capture and storage? Energy Economics, 105004. |
| + | |citation_doi=https://doi.org/10.1016/j.eneco.2020.105004 |
| |Model input file format=No | | |Model input file format=No |
| |Model file format=No | | |Model file format=No |
| |Model output file format=No | | |Model output file format=No |
| }} | | }} |