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config.default.yaml
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config.default.yaml
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# SPDX-FileCopyrightText: PyPSA-Earth and PyPSA-Eur Authors
#
# SPDX-License-Identifier: CC0-1.0
version: 0.5.0
tutorial: false
logging:
level: INFO
format: "%(levelname)s:%(name)s:%(message)s"
results_dir: results/
summary_dir: results/
costs_dir: data/ # TODO change to the equivalent of technology data
foresight: overnight
countries: ["NG", "BJ"]
# Can be replaced by country ["NG", "BJ"], continent ["Africa"] or user-specific region, see more at https://pypsa-earth.readthedocs.io/en/latest/configuration.html#top-level-configuration
enable:
retrieve_databundle: true # Recommended 'true', for the first run. Otherwise data might be missing.
retrieve_databundle_sector: true
retrieve_cost_data: true # true: retrieves cost data from technology data and saves in resources/costs.csv, false: uses cost data in data/costs.csv
download_osm_data: true # If 'true', OpenStreetMap data will be downloaded for the above given countries
build_natura_raster: false # If True, then an exclusion raster will be build
build_cutout: false
# If "build_cutout" : true, then environmental data is extracted according to `snapshots` date range and `countries`
# requires cds API key https://cds.climate.copernicus.eu/api-how-to
# More information https://atlite.readthedocs.io/en/latest/introduction.html#datasets
progress_bar: true # show progress bar during downloading routines and other long-running tasks
custom_rules: [] # Default empty [] or link to custom rule file e.g. ["my_folder/my_rules.smk"] that add rules to Snakefile
run:
name: "" # use this to keep track of runs with different settings
sector_name: "" # use this to keep track of sector scenario runs
shared_cutouts: true # set to true to share the default cutout(s) across runs
# Note: value false requires build_cutout to be enabled
allow_scenario_failure: false # If True, the workflow will continue even if a scenario in run_scnenario fails
scenario:
simpl: [""]
ll: ["copt"]
clusters: [10]
opts: [Co2L-3H]
planning_horizons: # investment years for myopic and perfect; or costs year for overnight
- 2030
sopts:
- "144H"
demand:
- "AB"
snapshots:
start: "2013-01-01"
end: "2014-01-01"
inclusive: "left" # end is not inclusive
# definition of the Coordinate Reference Systems
crs:
geo_crs: EPSG:4326 # general geographic projection, not used for metric measures. "EPSG:4326" is the standard used by OSM and google maps
distance_crs: EPSG:3857 # projection for distance measurements only. Possible recommended values are "EPSG:3857" (used by OSM and Google Maps)
area_crs: ESRI:54009 # projection for area measurements only. Possible recommended values are Global Mollweide "ESRI:54009"
# download_osm_data_nprocesses: 10 # (optional) number of threads used to download osm data
augmented_line_connection:
add_to_snakefile: false # If True, includes this rule to the workflow
connectivity_upgrade: 2 # Min. lines connection per node,
# 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
new_line_type: ["HVAC"] # Expanded lines can be either ["HVAC"] or ["HVDC"] or both ["HVAC", "HVDC"]
min_expansion: 1 # [MW] New created line expands by float/int input
min_DC_length: 600 # [km] Minimum line length of DC line
cluster_options:
simplify_network:
to_substations: false # network is simplified to nodes with positive or negative power injection (i.e. substations or offwind connections)
algorithm: kmeans # choose from: [hac, kmeans]
feature: solar+onwind-time # only for hac. choose from: [solar+onwind-time, solar+onwind-cap, solar-time, solar-cap, solar+offwind-cap] etc.
exclude_carriers: []
remove_stubs: true
remove_stubs_across_borders: true
p_threshold_drop_isolated: 20 # [MW] isolated buses are being discarded if bus mean power is below the specified threshold
p_threshold_merge_isolated: 300 # [MW] isolated buses are being merged into a single isolated bus if a bus mean power is below the specified threshold
s_threshold_fetch_isolated: 0.05 # [-] a share of the national load for merging an isolated network into a backbone network
cluster_network:
algorithm: kmeans
feature: solar+onwind-time
exclude_carriers: []
alternative_clustering: false # "False" use Voronoi shapes, "True" use GADM shapes
distribute_cluster: ["load"] # Distributes cluster nodes per country according to ['load'],['pop'] or ['gdp']
out_logging: true # When "True", logging is printed to console
aggregation_strategies:
generators: # use "min" for more conservative assumptions
p_nom: sum
p_nom_max: sum
p_nom_min: sum
p_min_pu: mean
marginal_cost: mean
committable: any
ramp_limit_up: max
ramp_limit_down: max
efficiency: mean
build_shape_options:
gadm_layer_id: 1 # GADM level area used for the gadm_shapes. Codes are country-dependent but roughly: 0: country, 1: region/county-like, 2: municipality-like
simplify_gadm: true # When true, shape polygons are simplified else no
update_file: false # When true, all the input files are downloaded again and replace the existing files
out_logging: true # When true, logging is printed to console
year: 2020 # reference year used to derive shapes, info on population and info on GDP
nprocesses: 3 # number of processes to be used in build_shapes
worldpop_method: "standard" # "standard" pulls from web 1kmx1km raster, "api" pulls from API 100mx100m raster,
# false (not "false") no pop addition to shape which is useful when generating only cutout
gdp_method: "standard" # "standard" pulls from web 1x1km raster, false (not "false") no gdp addition to shape which useful when generating only cutout
contended_flag: "set_by_country" # "set_by_country" assigns the contended areas to the countries according to the GADM database, "drop" drops these contended areas from the model
clean_osm_data_options: # osm = OpenStreetMap
names_by_shapes: true # Set the country name based on the extended country shapes
threshold_voltage: 51000 # [V] minimum voltage threshold to keep the asset (cable, line, generator, etc.) [V]
tag_substation: "transmission" # Filters only substations with 'transmission' tag, ('distribution' also available)
add_line_endings: true # When "True", then line endings are added to the dataset of the substations
generator_name_method: OSM # Methodology to specify the name to the generator. Options: OSM (name as by OSM dataset), closest_city (name by the closest city)
use_custom_lines: "OSM_only" # Use OSM (OSM_only), customized (custom_only), or both data sets (add_custom)
path_custom_lines: false # If exists, provide the specific absolute path of the custom file e.g. (...\data\custom_lines.geojson)
use_custom_substations: "OSM_only" # Use OSM (OSM_only), customized (custom_only), or both data sets (add_custom)
path_custom_substations: false # If exists, provide the specific absolute path of the custom file e.g. (...\data\custom_substations.geojson)
use_custom_cables: "OSM_only" # Use OSM (OSM_only), customized (custom_only), or both data sets (add_custom)
path_custom_cables: false # If exists, provide the specific absolute path of the custom file e.g. (...\data\custom_cables.geojson)
build_osm_network: # Options of the build_osm_network script; osm = OpenStreetMap
group_close_buses: true # When "True", close buses are merged and guarantee the voltage matching among line endings
group_tolerance_buses: 5000 # [m] (default 5000) Tolerance in meters of the close buses to merge
split_overpassing_lines: true # When True, lines overpassing buses are splitted and connected to the bueses
overpassing_lines_tolerance: 1 # [m] (default 1) Tolerance to identify lines overpassing buses
force_ac: false # When true, it forces all components (lines and substation) to be AC-only. To be used if DC assets create problem.
base_network:
min_voltage_substation_offshore: 51000 # [V] minimum voltage of the offshore substations
min_voltage_rebase_voltage: 51000 # [V] minimum voltage in base network
load_options:
ssp: "ssp2-2.6" # shared socio-economic pathway (GDP and population growth) scenario to consider
weather_year: 2013 # Load scenarios available with different weather year (different renewable potentials)
prediction_year: 2030 # Load scenarios available with different prediction year (GDP, population)
scale: 1 # scales all load time-series, i.e. 2 = doubles load
electricity:
base_voltage: 380.
voltages: [132., 220., 300., 380., 500., 750.]
co2limit: 7.75e+7 # European default, 0.05 * 3.1e9*0.5, needs to be adjusted for Africa
co2base: 1.487e+9 # European default, adjustment to Africa necessary
agg_p_nom_limits: data/agg_p_nom_minmax.csv
hvdc_as_lines: false # should HVDC lines be modeled as `Line` or as `Link` component?
automatic_emission: false
automatic_emission_base_year: 1990 # 1990 is taken as default. Any year from 1970 to 2018 can be selected.
operational_reserve: # like https://genxproject.github.io/GenX/dev/core/#Reserves
activate: false
epsilon_load: 0.02 # share of total load
epsilon_vres: 0.02 # share of total renewable supply
contingency: 0 # fixed capacity in MW
max_hours:
battery: 6
H2: 168
extendable_carriers:
Generator: [solar, onwind, offwind-ac, offwind-dc, OCGT]
StorageUnit: [] # battery, H2
Store: [battery, H2]
Link: [] # H2 pipeline
powerplants_filter: (DateOut >= 2022 or DateOut != DateOut)
custom_powerplants: false # "false" use only powerplantmatching (ppm) data, "merge" combines ppm and custom powerplants, "replace" use only custom powerplants
conventional_carriers: [nuclear, oil, OCGT, CCGT, coal, lignite, geothermal, biomass]
renewable_carriers: [solar, onwind, offwind-ac, offwind-dc, hydro]
estimate_renewable_capacities:
stats: "irena" # False, = greenfield expansion, 'irena' uses IRENA stats to add expansion limits
year: 2023 # Reference year, available years for IRENA stats are 2000 to 2023
p_nom_min: 1 # any float, scales the minimum expansion acquired from stats, i.e. 110% of <years>'s capacities => p_nom_min: 1.1
p_nom_max: false # sets the expansion constraint, False to deactivate this option and use estimated renewable potentials determine by the workflow, float scales the p_nom_min factor accordingly
technology_mapping:
# Wind is the Fueltype in ppm.data.Capacity_stats, onwind, offwind-{ac,dc} the carrier in PyPSA-Earth
Offshore: [offwind-ac, offwind-dc]
Onshore: [onwind]
PV: [solar]
lines:
ac_types:
132.: "243-AL1/39-ST1A 20.0"
220.: "Al/St 240/40 2-bundle 220.0"
300.: "Al/St 240/40 3-bundle 300.0"
380.: "Al/St 240/40 4-bundle 380.0"
500.: "Al/St 240/40 4-bundle 380.0"
750.: "Al/St 560/50 4-bundle 750.0"
dc_types:
500.: "HVDC XLPE 1000"
s_max_pu: 0.7
s_nom_max: .inf
length_factor: 1.25
under_construction: "zero" # 'zero': set capacity to zero, 'remove': remove, 'keep': with full capacity
links:
p_max_pu: 1.0
p_nom_max: .inf
under_construction: "zero" # 'zero': set capacity to zero, 'remove': remove, 'keep': with full capacity
transformers:
x: 0.1
s_nom: 2000.
type: ""
atlite:
nprocesses: 4
cutouts:
cutout-2013-era5:
module: era5
dx: 0.3 # cutout resolution
dy: 0.3 # cutout resolution
# The cutout time is automatically set by the snapshot range. See `snapshot:` option above and 'build_cutout.py'.
# time: ["2013-01-01", "2014-01-01"] # to manually specify a different weather year (~70 years available)
# The cutout spatial extent [x,y] is automatically set by country selection. See `countires:` option above and 'build_cutout.py'.
# x: [-12., 35.] # set cutout range manual, instead of automatic by boundaries of country
# y: [33., 72] # manual set cutout range
renewable:
onwind:
cutout: cutout-2013-era5
resource:
method: wind
turbine: Vestas_V112_3MW
capacity_per_sqkm: 3 # conservative, ScholzPhd Tab 4.3.1: 10MW/km^2
# correction_factor: 0.93
copernicus:
# Scholz, Y. (2012). Renewable energy based electricity supply at low costs:
# development of the REMix model and application for Europe. ( p.42 / p.28)
# CLC grid codes:
# 11X/12X - Various forest types
# 20 - Shrubs
# 30 - Herbaceus vegetation
# 40 - Cropland
# 50 - Urban
# 60 - Bare / Sparse vegetation
# 80 - Permanent water bodies
# 100 - Moss and lichen
# 200 - Open sea
grid_codes: [20, 30, 40, 60, 100, 111, 112, 113, 114, 115, 116, 121, 122, 123, 124, 125, 126]
distance: 1000
distance_grid_codes: [50]
natura: true
potential: simple # or conservative
clip_p_max_pu: 1.e-2
extendable: true
offwind-ac:
cutout: cutout-2013-era5
resource:
method: wind
turbine: NREL_ReferenceTurbine_5MW_offshore
capacity_per_sqkm: 2
# correction_factor: 0.8855
# proxy for wake losses
# from 10.1016/j.energy.2018.08.153
# until done more rigorously in #153
copernicus:
grid_codes: [80, 200]
natura: true
max_depth: 50
max_shore_distance: 30000
potential: simple # or conservative
clip_p_max_pu: 1.e-2
extendable: true
offwind-dc:
cutout: cutout-2013-era5
resource:
method: wind
turbine: NREL_ReferenceTurbine_5MW_offshore
# ScholzPhd Tab 4.3.1: 10MW/km^2
capacity_per_sqkm: 3
# correction_factor: 0.8855
# proxy for wake losses
# from 10.1016/j.energy.2018.08.153
# until done more rigorously in #153
copernicus:
grid_codes: [80, 200]
natura: true
max_depth: 50
min_shore_distance: 30000
potential: simple # or conservative
clip_p_max_pu: 1.e-2
extendable: true
solar:
cutout: cutout-2013-era5
resource:
method: pv
panel: CSi
orientation: latitude_optimal # will lead into optimal design
# slope: 0. # slope: 0 represent a flat panel
# azimuth: 180. # azimuth: 180 south orientation
capacity_per_sqkm: 4.6 # From 1.7 to 4.6 addresses issue #361
# Determined by comparing uncorrected area-weighted full-load hours to those
# published in Supplementary Data to
# Pietzcker, Robert Carl, et al. "Using the sun to decarbonize the power
# sector: The economic potential of photovoltaics and concentrating solar
# power." Applied Energy 135 (2014): 704-720.
correction_factor: 0.854337
copernicus:
grid_codes: [20, 30, 40, 50, 60, 90, 100]
natura: true
potential: simple # or conservative
clip_p_max_pu: 1.e-2
extendable: true
hydro:
cutout: cutout-2013-era5
hydrobasins_level: 6
resource:
method: hydro
hydrobasins: data/hydrobasins/hybas_world.shp
flowspeed: 1.0 # m/s
# weight_with_height: false
# show_progress: true
carriers: [ror, PHS, hydro]
PHS_max_hours: 6
hydro_max_hours: "energy_capacity_totals_by_country" # not active
hydro_max_hours_default: 6.0 # (optional, default 6) Default value of max_hours for hydro when NaN values are found
clip_min_inflow: 1.0
extendable: true
normalization:
method: hydro_capacities # 'hydro_capacities' to rescale country hydro production by using hydro_capacities, 'eia' to rescale by eia data, false for no rescaling
year: 2013 # (optional) year of statistics used to rescale the runoff time series. When not provided, the cutout weather year is used
multiplier: 1.1 # multiplier applied after the normalization of the hydro production; default 1.0
csp:
cutout: cutout-2013-era5
resource:
method: csp
installation: SAM_solar_tower
capacity_per_sqkm: 2.392 # From 1.7 to 4.6 addresses issue #361
# Determined by comparing uncorrected area-weighted full-load hours to those
# published in Supplementary Data to
# Pietzcker, Robert Carl, et al. "Using the sun to decarbonize the power
# sector: The economic potential of photovoltaics and concentrating solar
# power." Applied Energy 135 (2014): 704-720.
copernicus:
grid_codes: [20, 30, 40, 60, 90]
distancing_codes: [50]
distance_to_codes: 3000
natura: true
potential: simple # or conservative
clip_p_max_pu: 1.e-2
extendable: true
csp_model: advanced # simple or advanced
# TODO: Needs to be adjusted for Africa.
costs:
year: 2030
version: v0.6.2
discountrate: [0.071] #, 0.086, 0.111]
# [EUR/USD] ECB: https://www.ecb.europa.eu/stats/exchange/eurofxref/html/eurofxref-graph-usd.en.html # noqa: E501
USD2013_to_EUR2013: 0.7532 # [EUR/USD] ECB: https://www.ecb.europa.eu/stats/exchange/eurofxref/html/eurofxref-graph-usd.en.html
rooftop_share: 0.14 # based on the potentials, assuming (0.1 kW/m2 and 10 m2/person)
fill_values:
FOM: 0
VOM: 0
efficiency: 1
fuel: 0
investment: 0
lifetime: 25
CO2 intensity: 0
discount rate: 0.07
marginal_cost: # EUR/MWh
solar: 0.01
onwind: 0.015
offwind: 0.015
hydro: 0.
H2: 0.
electrolysis: 0.
fuel cell: 0.
battery: 0.
battery inverter: 0.
emission_prices: # in currency per tonne emission, only used with the option Ep
co2: 0.
# investment: # EUR/MW
# CCGT: 830000
# FOM: # %/year
# CCGT: 3.35
# VOM: # EUR/MWh
# CCGT: 4.2
# fuel: # EUR/MWh
# gas: 10.1
# lifetime: # years
# CCGT: 25.0
# efficiency: # per unit
# CCGT: 0.58
lines:
length_factor: 1.25 #to estimate offwind connection costs
monte_carlo:
# Description: Specify Monte Carlo sampling options for uncertainty analysis.
# Define the option list for Monte Carlo sampling.
# Make sure add_to_snakefile is set to true to enable Monte-Carlo
options:
add_to_snakefile: false # When set to true, enables Monte Carlo sampling
samples: 9 # number of optimizations. Note that number of samples when using scipy has to be the square of a prime number
sampling_strategy: "chaospy" # "pydoe2", "chaospy", "scipy", packages that are supported
seed: 42 # set seedling for reproducibilty
# Uncertanties on any PyPSA object are specified by declaring the specific PyPSA object under the key 'uncertainties'.
# For each PyPSA object, the 'type' and 'args' keys represent the type of distribution and its argument, respectively.
# Supported distributions types are uniform, normal, lognormal, triangle, beta and gamma.
# The arguments of the distribution are passed using the key 'args' as follows, tailored by distribution type
# normal: [mean, std], lognormal: [mean, std], uniform: [lower_bound, upper_bound],
# triangle: [mid_point (between 0 - 1)], beta: [alpha, beta], gamma: [shape, scale]
# More info on the distributions are documented in the Chaospy reference guide...
# https://chaospy.readthedocs.io/en/master/reference/distribution/index.html
# An abstract example is as follows:
# {pypsa network object, e.g. "loads_t.p_set"}:
# type: {any supported distribution among the previous: "uniform", "normal", ...}
# args: {arguments passed as a list depending on the distribution, see the above and more at https://pypsa.readthedocs.io/}
uncertainties:
loads_t.p_set:
type: uniform
args: [0, 1]
generators_t.p_max_pu.loc[:, n.generators.carrier == "onwind"]:
type: lognormal
args: [1.5]
generators_t.p_max_pu.loc[:, n.generators.carrier == "solar"]:
type: beta
args: [0.5, 2]
# ------------------- SECTOR OPTIONS -------------------
policy_config:
hydrogen:
temporal_matching: "no_res_matching" # either "h2_yearly_matching", "h2_monthly_matching", "no_res_matching"
spatial_matching: false
additionality: false # RE electricity is equal to the amount required for additional hydrogen export compared to the 0 export case ("reference_case")
allowed_excess: 1.0
is_reference: false # Whether or not this network is a reference case network, relevant only if additionality is _true_
remove_h2_load: false #Whether or not to remove the h2 load from the network, relevant only if is_reference is _true_
path_to_ref: "" # Path to the reference case network for additionality calculation, relevant only if additionality is _true_ and is_reference is _false_
re_country_load: false # Set to "True" to force the RE electricity to be equal to the electricity required for hydrogen export and the country electricity load. "False" excludes the country electricity load from the constraint.
demand_data:
update_data: true # if true, the workflow downloads the energy balances data saved in data/demand/unsd/data again. Turn on for the first run.
base_year: 2019
other_industries: false # Whether or not to include industries that are not specified. some countries have has exaggerated numbers, check carefully.
aluminium_year: 2019 # Year of the aluminium demand data specified in `data/AL_production.csv`
fossil_reserves:
oil: 100 #TWh Maybe redundant
export:
endogenous: false # If true, the export demand is endogenously determined by the model
endogenous_price: 400 # EUR/MWh # Market price, for wich the hydrogen for endogenous exports is sold. Only considered, if ["export"]["endogenous"] is set to true.
store: true # [True, False] # specifies whether an export store to balance demand is implemented
store_capital_costs: "no_costs" # ["standard_costs", "no_costs"] # specifies the costs of the export store. "standard_costs" takes CAPEX of "hydrogen storage tank type 1 including compressor"
h2export: [10] # Yearly export demand in TWh. Only considered, if ["export"]["endogenous"] is set to false
export_profile: "ship" # use "ship" or "constant". Only considered, if ["export"]["endogenous"] is set to false
ship:
ship_capacity: 0.4 # TWh # 0.05 TWh for new ones, 0.003 TWh for Susio Frontier, 0.4 TWh according to Hampp2021: "Corresponds to 11360 t H2 (l) with LHV of 33.3333 Mwh/t_H2. Cihlar et al 2020 based on IEA 2019, Table 3-B"
travel_time: 288 # hours # From Agadir to Rotterdam and back (12*24)
fill_time: 24 # hours, for 48h see Hampp2021
unload_time: 24 # hours for 48h see Hampp2021
custom_data:
renewables: [] # ['csp', 'rooftop-solar', 'solar']
elec_demand: false
heat_demand: false
industry_demand: false
industry_database: false
transport_demand: false
water_costs: false
h2_underground: false
add_existing: false
custom_sectors: false
gas_network: false # If "True" then a custom .csv file must be placed in "resources/custom_data/pipelines.csv" , If "False" the user can choose btw "greenfield" or Model built-in datasets. Please refer to ["sector"] below.
export_ports: false # If "True" then a custom .csv file must be placed in "data/custom/export_ports.csv"
airports: false # If "True" then a custom .csv file must be placed in "data/custom/airports.csv". Data format for aiports must be in the format of the airports.csv file in the data folder.
industry:
reference_year: 2015
solar_thermal:
clearsky_model: simple
orientation:
slope: 45.
azimuth: 180.
existing_capacities:
grouping_years_power: [1960, 1965, 1970, 1975, 1980, 1985, 1990, 1995, 2000, 2005, 2010, 2015, 2020, 2025, 2030]
grouping_years_heat: [1980, 1985, 1990, 1995, 2000, 2005, 2010, 2015, 2019] # these should not extend 2020
threshold_capacity: 10
default_heating_lifetime: 20
conventional_carriers:
- lignite
- coal
- oil
- uranium
sector:
gas:
spatial_gas: true # ALWAYS TRUE
network: false # ALWAYS FALSE for now (NOT USED)
network_data: GGIT # Global dataset -> 'GGIT' , European dataset -> 'IGGIELGN'
network_data_GGIT_status: ["Construction", "Operating", "Idle", "Shelved", "Mothballed", "Proposed"]
hydrogen:
network: true
H2_retrofit_capacity_per_CH4: 0.6
network_limit: 2000 #GWkm
network_routes: gas # "gas or "greenfield". If "gas" -> the network data are fetched from ["sector"]["gas"]["network_data"]. If "greenfield" -> the network follows the topology of electrical transmission lines
gas_network_repurposing: true # If true -> ["sector"]["gas"]["network"] is automatically false
underground_storage: false
hydrogen_colors: false
set_color_shares: false
blue_share: 0.40
pink_share: 0.05
coal:
spatial_coal: true
shift_to_elec: true # If true, residential and services demand of coal is shifted to electricity. If false, the final energy demand of coal is disregarded
lignite:
spatial_lignite: false
international_bunkers: false #Whether or not to count the emissions of international aviation and navigation
oil:
spatial_oil: true
district_heating:
potential: 0.3 #maximum fraction of urban demand which can be supplied by district heating
#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
progress: 1
# 2020: 0.0
# 2030: 0.3
# 2040: 0.6
# 2050: 1.0
district_heating_loss: 0.15
reduce_space_heat_exogenously: true # reduces space heat demand by a given factor (applied before losses in DH)
# this can represent e.g. building renovation, building demolition, or if
# the factor is negative: increasing floor area, increased thermal comfort, population growth
reduce_space_heat_exogenously_factor: 0.29 # per unit reduction in space heat demand
# the default factors are determined by the LTS scenario from http://tool.european-calculator.eu/app/buildings/building-types-area/?levers=1ddd4444421213bdbbbddd44444ffffff11f411111221111211l212221
# 2020: 0.10 # this results in a space heat demand reduction of 10%
# 2025: 0.09 # first heat demand increases compared to 2020 because of larger floor area per capita
# 2030: 0.09
# 2035: 0.11
# 2040: 0.16
# 2045: 0.21
# 2050: 0.29
tes: true
tes_tau: # 180 day time constant for centralised, 3 day for decentralised
decentral: 3
central: 180
boilers: true
oil_boilers: false
chp: true
micro_chp: false
solar_thermal: true
heat_pump_sink_T: 55 #Celsius, based on DTU / large area radiators; used un build_cop_profiles.py
time_dep_hp_cop: true #time dependent heat pump coefficient of performance
solar_cf_correction: 0.788457 # = >>>1/1.2683
bev_plug_to_wheel_efficiency: 0.2 #kWh/km from EPA https://www.fueleconomy.gov/feg/ for Tesla Model S
bev_charge_efficiency: 0.9 #BEV (dis-)charging efficiency
transport_heating_deadband_upper: 20.
transport_heating_deadband_lower: 15.
ICE_lower_degree_factor: 0.375 #in per cent increase in fuel consumption per degree above deadband
ICE_upper_degree_factor: 1.6
EV_lower_degree_factor: 0.98
EV_upper_degree_factor: 0.63
bev_avail_max: 0.95
bev_avail_mean: 0.8
bev_dsm_restriction_value: 0.75 #Set to 0 for no restriction on BEV DSM
bev_dsm_restriction_time: 7 #Time at which SOC of BEV has to be dsm_restriction_value
v2g: true #allows feed-in to grid from EV battery
bev_dsm: true #turns on EV battery
bev_energy: 0.05 #average battery size in MWh
bev_availability: 0.5 #How many cars do smart charging
transport_fuel_cell_efficiency: 0.5
transport_internal_combustion_efficiency: 0.3
industry_util_factor: 0.7
biomass_transport: true # biomass transport between nodes
biomass_transport_default_cost: 0.1 #EUR/km/MWh
solid_biomass_potential: 40 # TWh/a, Potential of whole modelled area
biogas_potential: 0.5 # TWh/a, Potential of whole modelled area
efficiency_heat_oil_to_elec: 0.9
efficiency_heat_biomass_to_elec: 0.9
efficiency_heat_gas_to_elec: 0.9
electricity_distribution_grid: true # adds low voltage buses and shifts AC loads, BEVs, heat pumps, and resistive heaters, micro CHPs to low voltage buses if technologies are present
solar_rooftop: true # adds distribution side customer rooftop PV (only work if electricity_distribution_grid: true)
home_battery: true # adds home batteries to low voltage buses ((only work if electricity_distribution_grid: true)
transmission_efficiency:
electricity distribution grid:
efficiency_static: 0.97 # efficiency of distribution grid (i.e. 3% loses)
dynamic_transport:
enable: false # If "True", then the BEV and FCEV shares are obtained depending on the "Co2L"-wildcard (e.g. "Co2L0.70: 0.10"). If "False", then the shares are obtained depending on the "demand" wildcard and "planning_horizons" wildcard as listed below (e.g. "DF_2050: 0.08")
land_transport_electric_share:
Co2L2.0: 0.00
Co2L1.0: 0.01
Co2L0.90: 0.03
Co2L0.80: 0.06
Co2L0.70: 0.10
Co2L0.60: 0.17
Co2L0.50: 0.27
Co2L0.40: 0.40
Co2L0.30: 0.55
Co2L0.20: 0.69
Co2L0.10: 0.80
Co2L0.00: 0.88
land_transport_fuel_cell_share:
Co2L2.0: 0.01
Co2L1.0: 0.01
Co2L0.90: 0.01
Co2L0.80: 0.01
Co2L0.70: 0.01
Co2L0.60: 0.01
Co2L0.50: 0.01
Co2L0.40: 0.01
Co2L0.30: 0.01
Co2L0.20: 0.01
Co2L0.10: 0.01
Co2L0.00: 0.01
land_transport_fuel_cell_share: # 1 means all FCEVs HERE
BU_2030: 0.00
AP_2030: 0.004
NZ_2030: 0.02
DF_2030: 0.01
AB_2030: 0.01
BU_2050: 0.00
AP_2050: 0.06
NZ_2050: 0.28
DF_2050: 0.08
land_transport_electric_share: # 1 means all EVs # This leads to problems when non-zero HERE
BU_2030: 0.00
AP_2030: 0.075
NZ_2030: 0.13
DF_2030: 0.01
AB_2030: 0.01
BU_2050: 0.00
AP_2050: 0.42
NZ_2050: 0.68
DF_2050: 0.011
co2_network: true
co2_sequestration_potential: 200 #MtCO2/a sequestration potential for Europe
co2_sequestration_cost: 10 #EUR/tCO2 for sequestration of CO2
hydrogen_underground_storage: true
shipping_hydrogen_liquefaction: false
shipping_average_efficiency: 0.4 #For conversion of fuel oil to propulsion in 2011
shipping_hydrogen_share: #1.0
BU_2030: 0.00
AP_2030: 0.00
NZ_2030: 0.10
DF_2030: 0.05
AB_2030: 0.05
BU_2050: 0.00
AP_2050: 0.25
NZ_2050: 0.36
DF_2050: 0.12
gadm_level: 1
h2_cavern: true
marginal_cost_storage: 0
methanation: true
helmeth: true
dac: true
SMR: true
SMR CC: true
cc_fraction: 0.9
cc: true
space_heat_share: 0.6 # the share of space heating from all heating. Remainder goes to water heating.
airport_sizing_factor: 3
min_part_load_fischer_tropsch: 0.9
conventional_generation: # generator : carrier
OCGT: gas
oil: oil
coal: coal
lignite: lignite
biomass: biomass
keep_existing_capacities: true
solving:
options:
formulation: kirchhoff
load_shedding: true
noisy_costs: true
min_iterations: 4
max_iterations: 6
clip_p_max_pu: 0.01
skip_iterations: true
track_iterations: false
# nhours: 10
solver:
name: gurobi
options: gurobi-default
solver_options:
highs-default:
# refer to https://ergo-code.github.io/HiGHS/dev/options/definitions/
threads: 4
solver: "ipm"
run_crossover: "off"
small_matrix_value: 1e-6
large_matrix_value: 1e9
primal_feasibility_tolerance: 1e-5
dual_feasibility_tolerance: 1e-5
ipm_optimality_tolerance: 1e-4
parallel: "on"
random_seed: 123
gurobi-default:
threads: 4
method: 2 # barrier
crossover: 0
BarConvTol: 1.e-6
Seed: 123
AggFill: 0
PreDual: 0
GURO_PAR_BARDENSETHRESH: 200
gurobi-numeric-focus:
NumericFocus: 3 # Favour numeric stability over speed
method: 2 # barrier
crossover: 0 # do not use crossover
BarHomogeneous: 1 # Use homogeneous barrier if standard does not converge
BarConvTol: 1.e-5
FeasibilityTol: 1.e-4
OptimalityTol: 1.e-4
ObjScale: -0.5
threads: 8
Seed: 123
gurobi-fallback: # Use gurobi defaults
crossover: 0
method: 2 # barrier
BarHomogeneous: 1 # Use homogeneous barrier if standard does not converge
BarConvTol: 1.e-5
FeasibilityTol: 1.e-5
OptimalityTol: 1.e-5
Seed: 123
threads: 8
cplex-default:
threads: 4
lpmethod: 4 # barrier
solutiontype: 2 # non basic solution, ie no crossover
barrier.convergetol: 1.e-5
feasopt.tolerance: 1.e-6
copt-default:
Threads: 8
LpMethod: 2
Crossover: 0
cbc-default: {} # Used in CI
glpk-default: {} # Used in CI
mem: 30000 #memory in MB; 20 GB enough for 50+B+I+H2; 100 GB for 181+B+I+H2
plotting:
map:
figsize: [7, 7]
boundaries: [-10.2, 29, 35, 72]
p_nom:
bus_size_factor: 5.e+4
linewidth_factor: 3.e+3
color_geomap:
ocean: white
land: whitesmoke
costs_max: 10
costs_threshold: 0.2
energy_max: 20000
energy_min: -20000
energy_threshold: 15
vre_techs:
- onwind
- offwind-ac
- offwind-dc
- solar
- ror
conv_techs:
- OCGT
- CCGT
- nuclear
- Nuclear
- coal
- oil
storage_techs:
- hydro+PHS
- battery
- H2
renewable_storage_techs:
- PHS
- hydro
load_carriers:
- AC load
AC_carriers:
- AC line
- AC transformer
link_carriers:
- DC line
- Converter AC-DC
heat_links:
- heat pump
- resistive heater
- CHP heat
- CHP electric
- gas boiler
- central heat pump
- central resistive heater
- central CHP heat
- central CHP electric
- central gas boiler
heat_generators:
- gas boiler
- central gas boiler
- solar thermal collector
- central solar thermal collector
tech_colors:
onwind: "#235ebc"
onshore wind: "#235ebc"
offwind: "#6895dd"
offwind-ac: "#6895dd"
offshore wind: "#6895dd"
offshore wind ac: "#6895dd"
offshore wind (AC): "#6895dd"
offwind-dc: "#74c6f2"
offshore wind dc: "#74c6f2"
offshore wind (DC): "#74c6f2"
wave: "#004444"
hydro: "#08ad97"
hydro+PHS: "#08ad97"
PHS: "#08ad97"
hydro reservoir: "#08ad97"
hydroelectricity: "#08ad97"
ror: "#4adbc8"
run of river: "#4adbc8"
solar: "#f9d002"
solar PV: "#f9d002"
solar thermal: "#ffef60"
solar rooftop: "#ffef60"
biomass: "#0c6013"
solid biomass: "#06540d"
solid biomass for industry co2 from atmosphere: "#654321"
solid biomass for industry co2 to stored: "#654321"
solid biomass for industry CC: "#654321"
biogas: "#23932d"
waste: "#68896b"
geothermal: "#ba91b1"
OCGT: "#d35050"
OCGT marginal: "sandybrown"
OCGT-heat: "#ee8340"
CCGT: "#b80404"
gas: "#d35050"
natural gas: "#d35050"
gas boiler: "#ee8340"
gas boilers: "#ee8340"
gas boiler marginal: "#ee8340"
gas-to-power/heat: "brown"
SMR: "#4F4F2F"
SMR CC: "darkblue"
oil: "#262626"
oil boiler: "#B5A642"
oil emissions: "#666666"
gas for industry: "#333333"
gas for industry CC: "brown"
gas for industry co2 to atmosphere: "#654321"
gas for industry co2 to stored: "#654321"
nuclear: "#ff9000"
Nuclear: "r"
Nuclear marginal: "r"
uranium: "r"
coal: "#707070"
Coal: "k"
Coal marginal: "k"
lignite: "#9e5a01"
Lignite: "grey"
Lignite marginal: "grey"
H2: "#ea048a"
H2 for industry: "#222222"
H2 for shipping: "#6495ED"
H2 liquefaction: "m"
hydrogen storage: "#ea048a"
battery: "slategray"
battery discharger: "slategray"
battery charger: "slategray"
battery storage: "slategray"
home battery: "#614700"
home battery storage: "#614700"
lines: "#70af1d"
transmission lines: "#70af1d"
AC: "#70af1d"
AC-AC: "#70af1d"
AC line: "#70af1d"
links: "#8a1caf"
HVDC links: "#8a1caf"
DC: "#8a1caf"
DC-DC: "#8a1caf"
DC link: "#8a1caf"
load: "#ff0000"
load shedding: "#ff0000"
Electric load: "b"
electricity: "k"
electric demand: "k"
electricity distribution grid: "y"
heat: "darkred"
Heat load: "r"
heat pumps: "#76EE00"
heat pump: "#76EE00"
air heat pump: "#76EE00"
ground heat pump: "#40AA00"
CHP: "r"
CHP heat: "r"
CHP electric: "r"
heat demand: "darkred"
rural heat: "#880000"
central heat: "#b22222"
decentral heat: "#800000"
low-temperature heat for industry: "#991111"
process heat: "#FF3333"
power-to-heat: "red"
resistive heater: "pink"
Sabatier: "#FF1493"
methanation: "#FF1493"
power-to-gas: "purple"
power-to-liquid: "darkgreen"
helmeth: "#7D0552"
DAC: "deeppink"
co2 stored: "#123456"
CO2 pipeline: "gray"
CO2 sequestration: "#123456"
co2: "#123456"
co2 vent: "#654321"
process emissions: "#222222"
process emissions CC: "gray"
process emissions to stored: "#444444"
process emissions to atmosphere: "#888888"
agriculture heat: "#D07A7A"
agriculture machinery oil: "#1e1e1e"
agriculture machinery oil emissions: "#111111"
agriculture electricity: "#222222"
Fischer-Tropsch: "#44DD33"
kerosene for aviation: "#44BB11"
naphtha for industry: "#44FF55"
land transport oil: "#44DD33"
land transport oil emissions: "#666666"
land transport fuel cell: "#AAAAAA"
land transport EV: "grey"
V2G: "grey"
BEV charger: "grey"
shipping: "#6495ED"
shipping oil: "#6495ED"
shipping oil emissions: "#6495ED"
water tanks: "#BBBBBB"
hot water storage: "#BBBBBB"
hot water charging: "#BBBBBB"
hot water discharging: "#999999"
Li ion: "grey"
district heating: "#CC4E5C"
retrofitting: "purple"
building retrofitting: "purple"
solid biomass transport: "green"
biomass EOP: "green"
high-temp electrolysis: "magenta"
today: "#D2691E"
Ambient: "k"
nice_names:
OCGT: Open-Cycle Gas
CCGT: Combined-Cycle Gas
offwind-ac: Offshore Wind (AC)
offwind-dc: Offshore Wind (DC)
onwind: Onshore Wind
solar: Solar
PHS: Pumped Hydro Storage
hydro: Reservoir & Dam
battery: Battery Storage
H2: Hydrogen Storage
lines: Transmission Lines
ror: Run of River