pypsa-eur/doc/configtables/sector.csv

1		Unit	Values	Description
2	transport	--	{true, false}	Flag to include transport sector.
3	heating	--	{true, false}	Flag to include heating sector.
4	biomass	--	{true, false}	Flag to include biomass sector.
5	industry	--	{true, false}	Flag to include industry sector.
6	agriculture	--	{true, false}	Flag to include agriculture sector.
7	fossil_fuels	--	{true, false}	Flag to include imports of fossil fuels ( ["coal", "gas", "oil", "lignite"])
8	district_heating	--		`prepare_sector_network.py <https://github.com/PyPSA/pypsa-eur-sec/blob/master/scripts/prepare_sector_network.py>`_
9	-- potential	--	float	maximum fraction of urban demand which can be supplied by district heating
10	-- progress	--	Dictionary with planning horizons as keys.	Increase of today's district heating demand to potential maximum district heating share. Progress = 0 means today's district heating share. Progress = 1 means maximum fraction of urban demand is supplied by district heating
11	-- district_heating_loss	--	float	Share increase in district heat demand in urban central due to heat losses
12	-- supply_temperature_approximation
13	-- -- max_forward_temperature	°C	Dictionary with country codes as keys. One key must be 'default'.	Max. forward temperature in district heating (if ambient temperature lower-or-equal `lower_threshold_ambient_temperature`)
14	-- -- min_forward_temperature	°C	Dictionary with country codes as keys. One key must be 'default'.	Min. forward temperature in district heating (if ambient temperature higher-or-equal `upper_threshold_ambient_temperature`)
15	-- -- return_temperature	°C	Dictionary with country codes as keys. One key must be 'default'.	Return temperature in district heating. Must be lower than forward temperature
16	-- -- lower_threshold_ambient_temperature	°C	float	Assume `max_forward_temperature` if ambient temperature is below this threshold
17	-- -- upper_threshold_ambient_temperature	°C	float	Assume `min_forward_temperature` if ambient temperature is above this threshold
18	-- -- rolling_window_ambient_temperature	h	int	Rolling window size for averaging ambient temperature when approximating supply temperature
19	-- heat_source_cooling	K	float	Cooling of heat source for heat pumps
20	-- heat_pump_cop_approximation
21	-- -- refrigerant	--	{ammonia, isobutane}	Heat pump refrigerant assumed for COP approximation
22	-- -- heat_exchanger_pinch_point_temperature_difference	K	float	Heat pump pinch point temperature difference in heat exchangers assumed for approximation.
23	-- -- isentropic_compressor_efficiency	--	float	Isentropic efficiency of heat pump compressor assumed for approximation. Must be between 0 and 1.
24	-- -- heat_loss	--	float	Heat pump heat loss assumed for approximation. Must be between 0 and 1.
25	-- heat_pump_sources	--
26	-- -- urban central	--	List of heat sources for heat pumps in urban central heating
27	-- -- urban decentral	--	List of heat sources for heat pumps in urban decentral heating
28	-- -- rural	--	List of heat sources for heat pumps in rural heating
29	cluster_heat_buses	--	{true, false}	Cluster residential and service heat buses in `prepare_sector_network.py <https://github.com/PyPSA/pypsa-eur-sec/blob/master/scripts/prepare_sector_network.py>`_ to one to save memory.
30
31	bev_dsm_restriction _value	--	float	Adds a lower state of charge (SOC) limit for battery electric vehicles (BEV) to manage its own energy demand (DSM). Located in `build_transport_demand.py <https://github.com/PyPSA/pypsa-eur-sec/blob/master/scripts/build_transport_demand.py>`_. Set to 0 for no restriction on BEV DSM
32	bev_dsm_restriction _time	--	float	Time at which SOC of BEV has to be dsm_restriction_value
33	transport_heating _deadband_upper	°C	float	The maximum temperature in the vehicle. At higher temperatures, the energy required for cooling in the vehicle increases.
34	transport_heating _deadband_lower	°C	float	The minimum temperature in the vehicle. At lower temperatures, the energy required for heating in the vehicle increases.
35
36	ICE_lower_degree_factor	--	float	Share increase in energy demand in internal combustion engine (ICE) for each degree difference between the cold environment and the minimum temperature.
37	ICE_upper_degree_factor	--	float	Share increase in energy demand in internal combustion engine (ICE) for each degree difference between the hot environment and the maximum temperature.
38	EV_lower_degree_factor	--	float	Share increase in energy demand in electric vehicles (EV) for each degree difference between the cold environment and the minimum temperature.
39	EV_upper_degree_factor	--	float	Share increase in energy demand in electric vehicles (EV) for each degree difference between the hot environment and the maximum temperature.
40	bev_dsm	--	{true, false}	Add the option for battery electric vehicles (BEV) to participate in demand-side management (DSM)
41
42	bev_availability	--	float	The share for battery electric vehicles (BEV) that are able to do demand side management (DSM)
43	bev_energy	--	float	The average size of battery electric vehicles (BEV) in MWh
44	bev_charge_efficiency	--	float	Battery electric vehicles (BEV) charge and discharge efficiency
45	bev_charge_rate	MWh	float	The power consumption for one electric vehicle (EV) in MWh. Value derived from 3-phase charger with 11 kW.
46	bev_avail_max	--	float	The maximum share plugged-in availability for passenger electric vehicles.
47	bev_avail_mean	--	float	The average share plugged-in availability for passenger electric vehicles.
48	v2g	--	{true, false}	Allows feed-in to grid from EV battery
49	land_transport_fuel_cell _share	--	Dictionary with planning horizons as keys.	The share of vehicles that uses fuel cells in a given year
50	land_transport_electric _share	--	Dictionary with planning horizons as keys.	The share of vehicles that uses electric vehicles (EV) in a given year
51	land_transport_ice _share	--	Dictionary with planning horizons as keys.	The share of vehicles that uses internal combustion engines (ICE) in a given year. What is not EV or FCEV is oil-fuelled ICE.
52	transport_electric_efficiency	MWh/100km	float	The conversion efficiencies of electric vehicles in transport
53	transport_fuel_cell_efficiency	MWh/100km	float	The H2 conversion efficiencies of fuel cells in transport
54	transport_ice_efficiency	MWh/100km	float	The oil conversion efficiencies of internal combustion engine (ICE) in transport
55	agriculture_machinery _electric_share	--	float	The share for agricultural machinery that uses electricity
56	agriculture_machinery _oil_share	--	float	The share for agricultural machinery that uses oil
57	agriculture_machinery _fuel_efficiency	--	float	The efficiency of electric-powered machinery in the conversion of electricity to meet agricultural needs.
58	agriculture_machinery _electric_efficiency	--	float	The efficiency of oil-powered machinery in the conversion of oil to meet agricultural needs.
59	Mwh_MeOH_per_MWh_H2	LHV	float	The energy amount of the produced methanol per energy amount of hydrogen. From `DECHEMA (2017) <https://dechema.de/dechema_media/Downloads/Positionspapiere/Technology_study_Low_carbon_energy_and_feedstock_for_the_European_chemical_industry-p-20002750.pdf>`_, page 64.
60	MWh_MeOH_per_tCO2	LHV	float	The energy amount of the produced methanol per ton of CO2. From `DECHEMA (2017) <https://dechema.de/dechema_media/Downloads/Positionspapiere/Technology_study_Low_carbon_energy_and_feedstock_for_the_European_chemical_industry-p-20002750.pdf>`_, page 66.
61	MWh_MeOH_per_MWh_e	LHV	float	The energy amount of the produced methanol per energy amount of electricity. From `DECHEMA (2017) <https://dechema.de/dechema_media/Downloads/Positionspapiere/Technology_study_Low_carbon_energy_and_feedstock_for_the_European_chemical_industry-p-20002750.pdf>`_, page 64.
62	shipping_hydrogen _liquefaction	--	{true, false}	Whether to include liquefaction costs for hydrogen demand in shipping.
63
64	shipping_hydrogen_share	--	Dictionary with planning horizons as keys.	The share of ships powered by hydrogen in a given year
65	shipping_methanol_share	--	Dictionary with planning horizons as keys.	The share of ships powered by methanol in a given year
66	shipping_oil_share	--	Dictionary with planning horizons as keys.	The share of ships powered by oil in a given year
67	shipping_methanol _efficiency	--	float	The efficiency of methanol-powered ships in the conversion of methanol to meet shipping needs (propulsion). The efficiency increase from oil can be 10-15% higher according to the `IEA <https://www.iea-amf.org/app/webroot/files/file/Annex%20Reports/AMF_Annex_56.pdf>`_
68
69	shipping_oil_efficiency	--	float	The efficiency of oil-powered ships in the conversion of oil to meet shipping needs (propulsion). Base value derived from 2011
70	aviation_demand_factor	--	float	The proportion of demand for aviation compared to today's consumption
71	HVC_demand_factor	--	float	The proportion of demand for high-value chemicals compared to today's consumption
72
73	time_dep_hp_cop	--	{true, false}	Consider the time dependent coefficient of performance (COP) of the heat pump
74	heat_pump_sink_T	°C	float	The temperature heat sink used in heat pumps based on DTU / large area radiators. The value is conservatively high to cover hot water and space heating in poorly-insulated buildings
75	reduce_space_heat _exogenously	--	{true, false}	Influence on space heating demand by a certain factor (applied before losses in district heating).
76	reduce_space_heat _exogenously_factor	--	Dictionary with planning horizons as keys.	A positive factor can mean renovation or demolition of a building. If the factor is negative, it can mean an increase in floor area, increased thermal comfort, population growth. The default factors are determined by the `Eurocalc Homes and buildings decarbonization scenario <http://tool.european-calculator.eu/app/buildings/building-types-area/?levers=1ddd4444421213bdbbbddd44444ffffff11f411111221111211l212221>`_
77	retrofitting
78	-- retro_endogen	--	{true, false}	Add retrofitting as an endogenous system which co-optimise space heat savings.
79	-- cost_factor	--	float	Weight costs for building renovation
80	-- interest_rate	--	float	The interest rate for investment in building components
81	-- annualise_cost	--	{true, false}	Annualise the investment costs of retrofitting
82	-- tax_weighting	--	{true, false}	Weight the costs of retrofitting depending on taxes in countries
83	-- construction_index	--	{true, false}	Weight the costs of retrofitting depending on labour/material costs per country
84	tes	--	{true, false}	Add option for storing thermal energy in large water pits associated with district heating systems and individual thermal energy storage (TES)
85	tes_tau			The time constant used to calculate the decay of thermal energy in thermal energy storage (TES): 1- :math:`e^{-1/24τ}`.
86	-- decentral	days	float	The time constant in decentralized thermal energy storage (TES)
87	-- central	days	float	The time constant in centralized thermal energy storage (TES)
88	boilers	--	{true, false}	Add option for transforming gas into heat using gas boilers
89	resistive_heaters	--	{true, false}	Add option for transforming electricity into heat using resistive heaters (independently from gas boilers)
90	oil_boilers	--	{true, false}	Add option for transforming oil into heat using boilers
91	biomass_boiler	--	{true, false}	Add option for transforming biomass into heat using boilers
92	overdimension_heat_generators			Add option for overdimensioning heating systems by a certain factor. This allows them to cover heat demand peaks e.g. 10% higher than those in the data with a setting of 1.1.
93	-- decentral	--	float	The factor for overdimensioning (increasing CAPEX) decentral heating systems
94	-- central	--	float	The factor for overdimensioning (increasing CAPEX) central heating systems
95	chp	--	{true, false}	Add option for using Combined Heat and Power (CHP)
96	micro_chp	--	{true, false}	Add option for using Combined Heat and Power (CHP) for decentral areas.
97	solar_thermal	--	{true, false}	Add option for using solar thermal to generate heat.
98	solar_cf_correction	--	float	The correction factor for the value provided by the solar thermal profile calculations
99	marginal_cost_storage	currency/MWh	float	The marginal cost of discharging batteries in distributed grids
100	methanation	--	{true, false}	Add option for transforming hydrogen and CO2 into methane using methanation.
101	coal_cc	--	{true, false}	Add option for coal CHPs with carbon capture
102	dac	--	{true, false}	Add option for Direct Air Capture (DAC)
103	co2_vent	--	{true, false}	Add option for vent out CO2 from storages to the atmosphere.
104	allam_cycle_gas	--	{true, false}	Add option to include `Allam cycle gas power plants <https://en.wikipedia.org/wiki/Allam_power_cycle>`_
105	hydrogen_fuel_cell	--	{true, false}	Add option to include hydrogen fuel cell for re-electrification. Assuming OCGT technology costs
106	hydrogen_turbine	--	{true, false}	Add option to include hydrogen turbine for re-electrification. Assuming OCGT technology costs
107	SMR	--	{true, false}	Add option for transforming natural gas into hydrogen and CO2 using Steam Methane Reforming (SMR)
108	SMR CC	--	{true, false}	Add option for transforming natural gas into hydrogen and CO2 using Steam Methane Reforming (SMR) and Carbon Capture (CC)
109	regional_oil_demand	--	{true, false}	Spatially resolve oil demand. Set to true if regional CO2 constraints needed.
110	regional_co2 _sequestration_potential
111	-- enable	--	{true, false}	Add option for regionally-resolved geological carbon dioxide sequestration potentials based on `CO2StoP <https://setis.ec.europa.eu/european-co2-storage-database_en>`_.
112	-- attribute	--	string or list	Name (or list of names) of the attribute(s) for the sequestration potential
113	-- include_onshore	--	{true, false}	Add options for including onshore sequestration potentials
114	-- min_size	Gt	float	Any sites with lower potential than this value will be excluded
115	-- max_size	Gt	float	The maximum sequestration potential for any one site.
116	-- years_of_storage	years	float	The years until potential exhausted at optimised annual rate
117	co2_sequestration_potential	--	Dictionary with planning horizons as keys.	The potential of sequestering CO2 in Europe per year and investment period
118	co2_sequestration_cost	currency/tCO2	float	The cost of sequestering a ton of CO2
119	co2_sequestration_lifetime	years	int	The lifetime of a CO2 sequestration site
120	co2_spatial	--	{true, false}	Add option to spatially resolve carrier representing stored carbon dioxide. This allows for more detailed modelling of CCUTS, e.g. regarding the capturing of industrial process emissions, usage as feedstock for electrofuels, transport of carbon dioxide, and geological sequestration sites.
121
122	co2network	--	{true, false}	Add option for planning a new carbon dioxide transmission network
123	co2_network_cost_factor	p.u.	float	The cost factor for the capital cost of the carbon dioxide transmission network
124
125	cc_fraction	--	float	The default fraction of CO2 captured with post-combustion capture
126	hydrogen_underground _storage	--	{true, false}	Add options for storing hydrogen underground. Storage potential depends regionally.
127	hydrogen_underground _storage_locations		{onshore, nearshore, offshore}	The location where hydrogen underground storage can be located. Onshore, nearshore, offshore means it must be located more than 50 km away from the sea, within 50 km of the sea, or within the sea itself respectively.
128
129	methanol	--	--	Add methanol as carrrier and add enabled methnol technologies
130	-- regional_methanol_demand	--	{true, false}	Spatially resolve methanol demand. Set to true if regional CO2 constraints needed.
131	-- methanol_reforming	--	{true, false}	Add methanol reforming
132	-- methanol_reforming_cc	--	{true, false}	Add methanol reforming with carbon capture
133	-- methanol_to_kerosene	--	{true, false}	Add methanol to kerosene
134	-- methanol_to_power	--	--	Add different methanol to power technologies
135	-- -- ccgt	--	{true, false}	Add combined cycle gas turbine (CCGT) using methanol
136	-- -- ccgt_cc	--	{true, false}	Add combined cycle gas turbine (CCGT) with carbon capture using methanol
137	-- -- ocgt	--	{true, false}	Add open cycle gas turbine (OCGT) using methanol
138	-- -- allam	--	{true, false}	Add Allam cycle gas power plants using methanol
139
140	ammonia	--	{true, false, regional}	Add ammonia as a carrrier. It can be either true (copperplated NH3), false (no NH3 carrier) or "regional" (regionalised NH3 without network)
141	min_part_load_fischer _tropsch	per unit of p_nom	float	The minimum unit dispatch (``p_min_pu``) for the Fischer-Tropsch process
142	min_part_load _methanolisation	per unit of p_nom	float	The minimum unit dispatch (``p_min_pu``) for the methanolisation process
143
144	use_fischer_tropsch _waste_heat	--	{true, false}	Add option for using waste heat of Fischer Tropsch in district heating networks
145	use_fuel_cell_waste_heat	--	{true, false}	Add option for using waste heat of fuel cells in district heating networks
146	use_electrolysis_waste _heat	--	{true, false}	Add option for using waste heat of electrolysis in district heating networks
147	electricity_transmission _grid	--	{true, false}	Switch for enabling/disabling the electricity transmission grid.
148	electricity_distribution _grid	--	{true, false}	Add a simplified representation of the exchange capacity between transmission and distribution grid level through a link.
149	electricity_distribution _grid_cost_factor			Multiplies the investment cost of the electricity distribution grid
150
151	electricity_grid _connection	--	{true, false}	Add the cost of electricity grid connection for onshore wind and solar
152	transmission_efficiency			Section to specify transmission losses or compression energy demands of bidirectional links. Splits them into two capacity-linked unidirectional links.
153	-- {carrier}	--	str	The carrier of the link.
154	-- -- efficiency_static	p.u.	float	Length-independent transmission efficiency.
155	-- -- efficiency_per_1000km	p.u. per 1000 km	float	Length-dependent transmission efficiency ($\eta^{\text{length}}$)
156	-- -- compression_per_1000km	p.u. per 1000 km	float	Length-dependent electricity demand for compression ($\eta \cdot \text{length}$) implemented as multi-link to local electricity bus.
157	H2_network	--	{true, false}	Add option for new hydrogen pipelines
158	gas_network	--	{true, false}	Add existing natural gas infrastructure, incl. LNG terminals, production and entry-points. The existing gas network is added with a lossless transport model. A length-weighted `k-edge augmentation algorithm <https://networkx.org/documentation/stable/reference/algorithms/generated/networkx.algorithms.connectivity.edge_augmentation.k_edge_augmentation.html#networkx.algorithms.connectivity.edge_augmentation.k_edge_augmentation>`_ can be run to add new candidate gas pipelines such that all regions of the model can be connected to the gas network. When activated, all the gas demands are regionally disaggregated as well.
159	H2_retrofit	--	{true, false}	Add option for retrofiting existing pipelines to transport hydrogen.
160	H2_retrofit_capacity _per_CH4	--	float	The ratio for H2 capacity per original CH4 capacity of retrofitted pipelines. The `European Hydrogen Backbone (April, 2020) p.15 <https://gasforclimate2050.eu/wp-content/uploads/2020/07/2020_European-Hydrogen-Backbone_Report.pdf>`_ 60% of original natural gas capacity could be used in cost-optimal case as H2 capacity.
161	gas_network_connectivity _upgrade	--	float	The number of desired edge connectivity (k) in the length-weighted `k-edge augmentation algorithm <https://networkx.org/documentation/stable/reference/algorithms/generated/networkx.algorithms.connectivity.edge_augmentation.k_edge_augmentation.html#networkx.algorithms.connectivity.edge_augmentation.k_edge_augmentation>`_ used for the gas network
162	gas_distribution_grid	--	{true, false}	Add a gas distribution grid
163	gas_distribution_grid _cost_factor			Multiplier for the investment cost of the gas distribution grid
164
165	biomass_spatial	--	{true, false}	Add option for resolving biomass demand regionally
166	biomass_transport	--	{true, false}	Add option for transporting solid biomass between nodes
167	biogas_upgrading_cc	--	{true, false}	Add option to capture CO2 from biomass upgrading
168	conventional_generation			Add a more detailed description of conventional carriers. Any power generation requires the consumption of fuel from nodes representing that fuel.
169	biomass_to_liquid	--	{true, false}	Add option for transforming solid biomass into liquid fuel with the same properties as oil
170	biomass_to_liquid_cc	--	{true, false}	Add option for transforming solid biomass into liquid fuel with the same properties as oil with carbon capture
171	biosng	--	{true, false}	Add option for transforming solid biomass into synthesis gas with the same properties as natural gas
172	biosng_cc	--	{true, false}	Add option for transforming solid biomass into synthesis gas with the same properties as natural gas with carbon capture
173	bioH2	--	{true, false}	Add option for transforming solid biomass into hydrogen with carbon capture
174	municipal_solid_waste	--	{true, false}	Add option for municipal solid waste
175	limit_max_growth
176	-- enable	--	{true, false}	Add option to limit the maximum growth of a carrier
177	-- factor	p.u.	float	The maximum growth factor of a carrier (e.g. 1.3 allows 30% larger than max historic growth)
178	-- max_growth
179	-- -- {carrier}	GW	float	The historic maximum growth of a carrier
180	-- max_relative_growth
181	-- -- {carrier}	p.u.	float	The historic maximum relative growth of a carrier
182
183	enhanced_geothermal
184	-- enable	--	{true, false}	Add option to include Enhanced Geothermal Systems
185	-- flexible	--	{true, false}	Add option for flexible operation (see Ricks et al. 2024)
186	-- max_hours	--	int	The maximum hours the reservoir can be charged under flexible operation
187	-- max_boost	--	float	The maximum boost in power output under flexible operation
188	-- var_cf	--	{true, false}	Add option for variable capacity factor (see Ricks et al. 2024)
189	-- sustainability_factor	--	float	Share of sourced heat that is replenished by the earth's core (see details in `build_egs_potentials.py <https://github.com/PyPSA/pypsa-eur-sec/blob/master/scripts/build_egs_potentials.py>`_)
190	solid_biomass_import
191	-- enable	--	{true, false}	Add option to include solid biomass imports
192	-- price	currency/MWh	float	Price for importing solid biomass
193	-- max_amount	Twh	float	Maximum solid biomass import potential
194	-- upstream_emissions_factor	p.u.	float	Upstream emissions of solid biomass imports