final_energy_system_model #60
|
@ -56,3 +56,5 @@ class Archetype:
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}
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}
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return content
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|
|
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@ -69,11 +69,4 @@ class Content:
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return content
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def __str__(self):
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"""Print content"""
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_archetypes = []
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for _archetype in self.archetypes:
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_archetypes.append(_archetype.to_dictionary())
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content = {'Archetypes': _archetypes}
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return str(content)
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|
|
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@ -14,8 +14,9 @@ class PerformanceCurves:
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Parameter function class
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"""
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def __init__(self, curve_type, parameters, coefficients):
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def __init__(self, curve_type, dependant_variable, parameters, coefficients):
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self._curve_type = curve_type
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self._dependant_variable = dependant_variable
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self._parameters = parameters
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self._coefficients = coefficients
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@ -35,11 +36,12 @@ class PerformanceCurves:
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return self._curve_type
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@property
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def function(self):
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def dependant_variable(self):
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"""
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y (e.g. COP in COP = a*source temperature**2... )
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y (e.g. COP in COP = a*source temperature**2 + b*source temperature + c*source temperature*supply temperature +
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d*supply temperature + e*supply temperature**2 + f)
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"""
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return self._function
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return self._dependant_variable
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@property
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def parameters(self):
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@ -62,7 +64,8 @@ class PerformanceCurves:
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"""Class content to dictionary"""
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content = {'Parameter Function': {
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'curve type': self.curve_type,
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'parameters': self.parameters,
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'dependant variable': self.dependant_variable,
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'parameter(s)': self.parameters,
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'coefficients': self.coefficients,
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}
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}
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@ -36,7 +36,7 @@ class System:
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self._emission_system = emission_system
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self._generation_systems = generation_systems
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self._energy_storage_systems = energy_storage_systems
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self._configuration = configuration
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# self._configuration = configuration
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@property
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def lod(self):
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@ -79,7 +79,7 @@ class System:
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return self._generation_systems
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@property
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def distribution_system(self) -> Union[None, DistributionSystem]:
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def distribution_system(self) -> Union[None, List[DistributionSystem]]:
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"""
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Get distribution system
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:return: DistributionSystem
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@ -87,7 +87,7 @@ class System:
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return self._distribution_system
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@property
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def emission_system(self) -> Union[None, EmissionSystem]:
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def emission_system(self) -> Union[None, List[EmissionSystem]]:
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"""
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Get emission system
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:return: EmissionSystem
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@ -107,12 +107,10 @@ class System:
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_generation_systems = []
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for _generation in self.generation_systems:
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_generation_systems.append(_generation.to_dictionary())
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_distribution_system = None
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if self.distribution_system is not None:
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_distribution_system = self.distribution_system.to_dictionary()
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_emission_system = None
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if self.emission_system is not None:
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_emission_system = self.emission_system.to_dictionary()
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_distribution_system = [_distribution.to_dictionary() for _distribution in
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self.distribution_system] if self.distribution_system is not None else None
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_emission_system = [_emission.to_dictionary() for _emission in
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self.emission_system] if self.emission_system is not None else None
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_storage_system = [_storage.to_dictionary() for _storage in
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self.energy_storage_system] if self.energy_storage_system is not None else None
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@ -120,10 +118,10 @@ class System:
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'name': self.name,
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'level of detail': self.lod,
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'demand types': self.demand_types,
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'Generation system(s)': _generation_systems,
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'distribution system': _distribution_system,
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'emission system': _emission_system,
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'energy storage system': _storage_system,
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'generation system(s)': _generation_systems,
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'distribution system(s)': _distribution_system,
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'emission system(s)': _emission_system,
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'energy storage system(s)': _storage_system,
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}
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}
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return content
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@ -6,14 +6,13 @@ Project Coder Saeed Ranjbar saeed.ranjbar@concordia.ca
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Code contributors: Pilar Monsalvete Alvarez de Uribarri pilar.monsalvete@concordia.ca
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"""
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import xmltodict
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from hub.catalog_factories.catalog import Catalog
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from hub.catalog_factories.data_models.energy_systems.system import System
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from hub.catalog_factories.data_models.energy_systems.content import Content
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from hub.catalog_factories.data_models.energy_systems.generation_system import GenerationSystem
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from hub.catalog_factories.data_models.energy_systems.pv_generation_system import PvGenerationSystem
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from hub.catalog_factories.data_models.energy_systems.energy_storage_system import EnergyStorageSystem
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from hub.catalog_factories.data_models.energy_systems.thermal_storage_system import ThermalStorageSystem
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from hub.catalog_factories.data_models.energy_systems.performance_curves import PerformanceCurves
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from hub.catalog_factories.data_models.energy_systems.archetype import Archetype
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from hub.catalog_factories.data_models.construction.material import Material
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@ -40,7 +39,6 @@ class NorthAmericaEnergySystemCatalog(Catalog):
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None,
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self._storage_components)
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print(self._content)
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def _load_generation_components(self):
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generation_components = []
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boilers = self._archetypes['EnergySystemCatalog']['energy_generation_components']['boilers']
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@ -55,7 +53,8 @@ class NorthAmericaEnergySystemCatalog(Catalog):
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system_type = 'boiler'
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boiler_fuel_type = boiler['@fuel']
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boiler_nominal_thermal_output = float(boiler['@installedThermalPower'])
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boiler_maximum_heat_output = float(boiler['@modulationRange'])
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boiler_maximum_heat_output = float(boiler['@maximumHeatOutput'])
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boiler_minimum_heat_output = float(boiler['@minimumHeatOutput'])
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boiler_heat_efficiency = float(boiler['@nominalEfficiency'])
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boiler_component = GenerationSystem(boiler_id,
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@ -65,8 +64,8 @@ class NorthAmericaEnergySystemCatalog(Catalog):
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system_type,
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boiler_fuel_type,
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boiler_nominal_thermal_output,
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None,
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None,
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boiler_maximum_heat_output,
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boiler_minimum_heat_output,
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None,
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None,
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boiler_heat_efficiency,
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@ -99,18 +98,20 @@ class NorthAmericaEnergySystemCatalog(Catalog):
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system_type = 'heat pump'
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heat_pump_fuel_type = heat_pump['@fuel']
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heat_pump_nominal_thermal_output = float(heat_pump['@installedThermalPower'])
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heat_pump_modulation_range = float(heat_pump['@modulationRange'])
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heat_pump_source_type = heat_pump['@heatSource']
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heat_pump_maximum_heat_output = float(heat_pump['@maximumHeatOutput'])
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heat_pump_minimum_heat_output = float(heat_pump['@minimumHeatOutput'])
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heat_pump_source_medium = heat_pump['@heatSource']
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heat_pump_supply_medium = heat_pump['@supply_medium']
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heat_pump_nominal_cop = float(heat_pump['@nominalCOP'])
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heat_pump_maximum_heating_temperature = float(heat_pump['@maxHeatingSupTemperature'])
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heat_pump_minimum_heating_temperature = float(heat_pump['@minHeatingSupTemperature'])
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heat_pump_maximum_cooling_temperature = float(heat_pump['@maxCoolingSupTemperature'])
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heat_pump_minimum_cooling_temperature = float(heat_pump['@minCoolingSupTemperature'])
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heat_pump_maximum_heat_supply_temperature = float(heat_pump['@maxHeatingSupTemperature'])
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heat_pump_minimum_heat_supply_temperature = float(heat_pump['@minHeatingSupTemperature'])
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heat_pump_maximum_cooling_supply_temperature = float(heat_pump['@maxCoolingSupTemperature'])
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heat_pump_minimum_cooling_supply_temperature = float(heat_pump['@minCoolingSupTemperature'])
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cop_curve_type = heat_pump['performance_curve']['@curve_type']
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dependant_variable = heat_pump['performance_curve']['dependant_variable']
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parameters = heat_pump['performance_curve']['parameters']
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coefficients = list(heat_pump['performance_curve']['coefficients'].values())
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cop_curve = PerformanceCurves(cop_curve_type, parameters, coefficients)
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cop_curve = PerformanceCurves(cop_curve_type, dependant_variable, parameters, coefficients)
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heat_pump_component = GenerationSystem(heat_pump_id,
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heat_pump_name,
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@ -119,9 +120,9 @@ class NorthAmericaEnergySystemCatalog(Catalog):
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system_type,
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heat_pump_fuel_type,
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heat_pump_nominal_thermal_output,
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None,
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None,
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heat_pump_source_type,
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heat_pump_maximum_heat_output,
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heat_pump_minimum_heat_output,
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heat_pump_source_medium,
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heat_pump_supply_medium,
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heat_pump_nominal_cop,
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None,
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@ -132,10 +133,10 @@ class NorthAmericaEnergySystemCatalog(Catalog):
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None,
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None,
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None,
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heat_pump_maximum_heating_temperature,
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heat_pump_minimum_heating_temperature,
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heat_pump_maximum_cooling_temperature,
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heat_pump_minimum_cooling_temperature,
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heat_pump_maximum_heat_supply_temperature,
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heat_pump_minimum_heat_supply_temperature,
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heat_pump_maximum_cooling_supply_temperature,
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heat_pump_minimum_cooling_supply_temperature,
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None,
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None,
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cop_curve,
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@ -288,65 +289,58 @@ class NorthAmericaEnergySystemCatalog(Catalog):
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name = tes['@name']
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model_name = tes['@modelName']
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manufacturer = tes['@manufacturer']
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volume = tes['@volume']
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height = tes['@height']
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storage_type = 'sensible'
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volume = tes['physical_characteristics']['@volume']
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height = tes['physical_characteristics']['@height']
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maximum_operating_temperature = tes['@maxTemp']
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materials = self._load_materials()
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insulation_material_name = tes['@insulationMaterial']
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insulation_material = self._search_material(materials, insulation_material_name)
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material_name = tes['@tankMaterial']
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tank_material = self._search_material(materials, material_name)
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thickness = float(tes['@insulationThickness']) / 100 # from cm to m
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insulation_material_id = tes['insulation']['@material_id']
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insulation_material = self._search_material(materials, insulation_material_id)
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material_id = tes['physical_characteristics']['@material_id']
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tank_material = self._search_material(materials, material_id)
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thickness = float(tes['insulation']['@insulationThickness']) / 100 # from cm to m
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insulation_layer = Layer(None, 'insulation', insulation_material, thickness)
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thickness = float(tes['@tankThickness']) / 100 # from cm to m
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tank_layer = Layer(None, 'insulation', tank_material, thickness)
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# the convention is from outside to inside
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thickness = float(tes['physical_characteristics']['@tankThickness']) / 100 # from cm to m
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tank_layer = Layer(None, 'tank', tank_material, thickness)
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# the convention is from outside to inside
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layers = [insulation_layer, tank_layer]
|
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storage_component = EnergyStorageSystem(storage_id,
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||||
name,
|
||||
model_name,
|
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manufacturer,
|
||||
'thermal',
|
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volume,
|
||||
None,
|
||||
None,
|
||||
None,
|
||||
None,
|
||||
None,
|
||||
height,
|
||||
layers,
|
||||
maximum_operating_temperature)
|
||||
storage_component = ThermalStorageSystem(storage_id,
|
||||
name,
|
||||
model_name,
|
||||
manufacturer,
|
||||
storage_type,
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volume,
|
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height,
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layers,
|
||||
maximum_operating_temperature)
|
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storage_components.append(storage_component)
|
||||
|
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for template in template_storages:
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storage_id = template['@storage_id']
|
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name = template['@name']
|
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storage_type = 'sensible'
|
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maximum_temperature = template['@maxTemp']
|
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height = template['physical_characteristics']['@height']
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materials = self._load_materials()
|
||||
insulation_material_name = template['@insulationMaterial']
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insulation_material = self._search_material(materials, insulation_material_name)
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material_name = template['@tankMaterial']
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tank_material = self._search_material(materials, material_name)
|
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thickness = float(template['@insulationThickness']) / 100 # from cm to m
|
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insulation_material_id = template['insulation']['@material_id']
|
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insulation_material = self._search_material(materials, insulation_material_id)
|
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material_id = template['physical_characteristics']['@material_id']
|
||||
tank_material = self._search_material(materials, material_id)
|
||||
thickness = float(template['insulation']['@insulationThickness']) / 100 # from cm to m
|
||||
insulation_layer = Layer(None, 'insulation', insulation_material, thickness)
|
||||
thickness = float(template['@tankThickness']) / 100 # from cm to m
|
||||
tank_layer = Layer(None, 'insulation', tank_material, thickness)
|
||||
# the convention is from outside to inside
|
||||
thickness = float(template['physical_characteristics']['@tankThickness']) / 100 # from cm to m
|
||||
tank_layer = Layer(None, 'tank', tank_material, thickness)
|
||||
# the convention is from outside to inside
|
||||
layers = [insulation_layer, tank_layer]
|
||||
storage_component = EnergyStorageSystem(storage_id,
|
||||
name,
|
||||
None,
|
||||
None,
|
||||
'thermal',
|
||||
None,
|
||||
None,
|
||||
None,
|
||||
None,
|
||||
None,
|
||||
None,
|
||||
None,
|
||||
layers,
|
||||
maximum_temperature)
|
||||
storage_component = ThermalStorageSystem(storage_id,
|
||||
name,
|
||||
None,
|
||||
None,
|
||||
storage_type,
|
||||
None,
|
||||
height,
|
||||
layers,
|
||||
maximum_temperature)
|
||||
storage_components.append(storage_component)
|
||||
return storage_components
|
||||
|
||||
|
@ -393,9 +387,10 @@ class NorthAmericaEnergySystemCatalog(Catalog):
|
|||
materials = []
|
||||
_materials = self._archetypes['EnergySystemCatalog']['materials']['material']
|
||||
for _material in _materials:
|
||||
material_id = _material['@material_id']
|
||||
name = _material['@name']
|
||||
thermal_conductivity = _material['@thermalConductivity']
|
||||
material = Material(None,
|
||||
material = Material(material_id,
|
||||
name,
|
||||
None,
|
||||
None,
|
||||
|
@ -409,15 +404,15 @@ class NorthAmericaEnergySystemCatalog(Catalog):
|
|||
return materials
|
||||
|
||||
@staticmethod
|
||||
def _search_material(materials, material_name):
|
||||
def _search_material(materials, material_id):
|
||||
_material = None
|
||||
for material in materials:
|
||||
if material.name == material_name:
|
||||
if int(material.id) == int(material_id):
|
||||
_material = material
|
||||
return _material
|
||||
|
||||
if _material is None:
|
||||
raise ValueError(f'Material not found in catalog [{material_name}]')
|
||||
raise ValueError(f'Material with the id = [{material_id}] not found in catalog ')
|
||||
|
||||
@staticmethod
|
||||
def _search_generation_equipment(generation_systems, generation_id):
|
||||
|
|
|
@ -5,37 +5,37 @@
|
|||
<media media_id="1" media_name="Water" density="981.0" heatCapacity="4180.0" evaporationTemperature="100.0"/>
|
||||
</medias>
|
||||
<energy_generation_components>
|
||||
<boilers generation_id="1" name="Natural-Gas Boiler" modelName="ALP080B" manufacturer="Alpine" installedThermalPower="21.0" modulationRange="0.88" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="2" name="Natural-Gas Boiler" modelName="ALP105B" manufacturer="Alpine" installedThermalPower="28.0" modulationRange="0.88" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="3" name="Natural-Gas Boiler" modelName="ALP150B" manufacturer="Alpine" installedThermalPower="40.0" modulationRange="0.88" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="4" name="Natural-Gas Boiler" modelName="ALP210B" manufacturer="Alpine" installedThermalPower="57.0" modulationRange="0.87" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="5" name="Natural-Gas Boiler" modelName="ALTAC-136" manufacturer="Alta" installedThermalPower="33.0" modulationRange="0.95" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="6" name="Natural-Gas Boiler" modelName="ALTA-120" manufacturer="Alta" installedThermalPower="33.0" modulationRange="0.95" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="7" name="Natural-Gas Boiler" modelName="ASPN-085" manufacturer="Aspen" installedThermalPower="23.15" modulationRange="0.97" nominalEfficiency="0.96" fuel="natural gas"/>
|
||||
<boilers generation_id="8" name="Natural-Gas Boiler" modelName="ASPN-110" manufacturer="Aspen" installedThermalPower="30.19" modulationRange="0.96" nominalEfficiency="0.96" fuel="natural gas"/>
|
||||
<boilers generation_id="9" name="Natural-Gas Boiler" modelName="ASPNC-155" manufacturer="Aspen" installedThermalPower="42.5" modulationRange="0.96" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="10" name="Natural-Gas Boiler" modelName="K2WTC-135B" manufacturer="K2" installedThermalPower="32.8" modulationRange="0.96" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="11" name="Natural-Gas Boiler" modelName="K2WTC-180B" manufacturer="K2" installedThermalPower="49.5" modulationRange="0.96" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="1" name="Natural-Gas Boiler" modelName="ALP080B" manufacturer="Alpine" installedThermalPower="21.0" minimumHeatOutput="4.7" maximumHeatOutput="23.5" modulationRange="0.88" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="2" name="Natural-Gas Boiler" modelName="ALP105B" manufacturer="Alpine" installedThermalPower="28.0" minimumHeatOutput="6.15" maximumHeatOutput="30.8" modulationRange="0.88" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="3" name="Natural-Gas Boiler" modelName="ALP150B" manufacturer="Alpine" installedThermalPower="40.0" minimumHeatOutput="8.8" maximumHeatOutput="44" modulationRange="0.88" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="4" name="Natural-Gas Boiler" modelName="ALP210B" manufacturer="Alpine" installedThermalPower="57.0" minimumHeatOutput="12.3" maximumHeatOutput="61.5" modulationRange="0.87" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="5" name="Natural-Gas Boiler" modelName="ALTAC-136" manufacturer="Alta" installedThermalPower="33.0" minimumHeatOutput="4.0" maximumHeatOutput="35.2" modulationRange="0.95" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="6" name="Natural-Gas Boiler" modelName="ALTA-120" manufacturer="Alta" installedThermalPower="33.0" minimumHeatOutput="4.0" maximumHeatOutput="35.2" modulationRange="0.95" nominalEfficiency="0.95" combi="false" fuel="natural gas"/>
|
||||
<boilers generation_id="7" name="Natural-Gas Boiler" modelName="ASPN-085" manufacturer="Aspen" installedThermalPower="23.15" minimumHeatOutput="2.5" maximumHeatOutput="25.0" modulationRange="0.97" nominalEfficiency="0.96" fuel="natural gas"/>
|
||||
<boilers generation_id="8" name="Natural-Gas Boiler" modelName="ASPN-110" manufacturer="Aspen" installedThermalPower="30.19" minimumHeatOutput="3.2" maximumHeatOutput="32.0" modulationRange="0.96" nominalEfficiency="0.96" fuel="natural gas"/>
|
||||
<boilers generation_id="9" name="Natural-Gas Boiler" modelName="ASPNC-155" manufacturer="Aspen" installedThermalPower="42.5" minimumHeatOutput="4.5" maximumHeatOutput="45.0" modulationRange="0.96" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="10" name="Natural-Gas Boiler" modelName="K2WTC-135B" manufacturer="K2" installedThermalPower="32.8" minimumHeatOutput="3.5" maximumHeatOutput="35.0" modulationRange="0.96" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<boilers generation_id="11" name="Natural-Gas Boiler" modelName="K2WTC-180B" manufacturer="K2" installedThermalPower="49.5" minimumHeatOutput="5.3" maximumHeatOutput="53.0" modulationRange="0.96" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
|
||||
<photovoltaicModules generation_id="12" name="Photovoltaic Module" modelName="445MS" manufacturer="Canadian Solar" nominalPower="334.0" nominalEfficiency="0.201" nominalRadiation="800.0" STCRadiation="1000.0" nominalCellTemperature="41.0" STCCellTemperature="26.0" nominalAmbientTemperature="20.0" STCMaxPower="445.0" CellTemperatureCoefficient="-0.0034" height="1.048" width="2.01"/>
|
||||
<heatPumps generation_id="13" name="Air-to-Water Heat Pump" modelName="CMAA 012" description="A second degree equation is used in form of A*T_source^2 + B*T_source + C*T_source*T_sup + D*T_sup + E*T_sup^2 + F" manufacturer="TRANE" installedThermalPower="51.7" modulationRange="0.0" fuel="Electricity" heatSource="Air" nominalCOP="3.32" maxHeatingSupTemperature="55.0" minHeatingSupTemperature="6.0" maxCoolingSupTemperature="30.0" minCoolingSupTemperature="11.0" supply_medium="water">
|
||||
<heatPumps generation_id="13" name="Air-to-Water Heat Pump" modelName="CMAA 012" description="A second degree equation is used in form of A*T_source^2 + B*T_source + C*T_source*T_sup + D*T_sup + E*T_sup^2 + F" manufacturer="TRANE" installedThermalPower="51.7" minimumHeatOutput="0" maximumHeatOutput="51.7" modulationRange="0.0" fuel="Electricity" heatSource="Air" nominalCOP="3.32" maxHeatingSupTemperature="55.0" minHeatingSupTemperature="6.0" maxCoolingSupTemperature="30.0" minCoolingSupTemperature="11.0" supply_medium="water">
|
||||
<performance_curve curve_type="second degree multivariable function">
|
||||
<parameters>COP</parameters>
|
||||
<dependant_variable>COP</dependant_variable>
|
||||
<parameters>source_temperature</parameters>
|
||||
<parameters>supply_temperature</parameters>
|
||||
<coefficients a="9.5E-4" b="0.177" c="-0.00242" d="-0.155" e="9.3E-4" f="8.044"/>
|
||||
</performance_curve>
|
||||
</heatPumps>
|
||||
<heatPumps generation_id="14" name="Air-to-Water Heat Pump" modelName="CMAA 70" description="A second degree equation is used in form of A*T_source^2 + B*T_source + C*T_source*T_sup + D*T_sup + E*T_sup^2 + F" manufacturer="TRANE" installedThermalPower="279.3" modulationRange="0.0" fuel="Electricity" heatSource="Air" nominalCOP="3.07" maxHeatingSupTemperature="55.0" minHeatingSupTemperature="6.0" maxCoolingSupTemperature="30.0" minCoolingSupTemperature="11.0" supply_medium="water">
|
||||
<heatPumps generation_id="14" name="Air-to-Water Heat Pump" modelName="CMAA 70" description="A second degree equation is used in form of A*T_source^2 + B*T_source + C*T_source*T_sup + D*T_sup + E*T_sup^2 + F" manufacturer="TRANE" installedThermalPower="279.3" minimumHeatOutput="0" maximumHeatOutput="279.3" modulationRange="0.0" fuel="Electricity" heatSource="Air" nominalCOP="3.07" maxHeatingSupTemperature="55.0" minHeatingSupTemperature="6.0" maxCoolingSupTemperature="30.0" minCoolingSupTemperature="11.0" supply_medium="water">
|
||||
<performance_curve curve_type="second degree multivariable function">
|
||||
<parameters>COP</parameters>
|
||||
<dependant_variable>COP</dependant_variable>
|
||||
<parameters>source_temperature</parameters>
|
||||
<parameters>supply_temperature</parameters>
|
||||
<coefficients a="0.0011" b="0.207" c="-0.00292" d="-0.187" e="0.00121" f="8.95"/>
|
||||
</performance_curve>
|
||||
</heatPumps>
|
||||
<heatPumps generation_id="15" name="Air-to-Water Heat Pump" modelName="CMAA 140" description="A second degree equation is used in form of A*T_source^2 + B*T_source + C*T_source*T_sup + D*T_sup + E*T_sup^2 + F" manufacturer="TRANE" installedThermalPower="279.3" modulationRange="0.0" fuel="Electricity" heatSource="Air" nominalCOP="3.46" maxHeatingSupTemperature="55.0" minHeatingSupTemperature="6.0" maxCoolingSupTemperature="30.0" minCoolingSupTemperature="11.0" supply_medium="water">
|
||||
<heatPumps generation_id="15" name="Air-to-Water Heat Pump" modelName="CMAA 140" description="A second degree equation is used in form of A*T_source^2 + B*T_source + C*T_source*T_sup + D*T_sup + E*T_sup^2 + F" manufacturer="TRANE" installedThermalPower="557" minimumHeatOutput="0" maximumHeatOutput="557" modulationRange="0.0" fuel="Electricity" heatSource="Air" nominalCOP="3.46" maxHeatingSupTemperature="55.0" minHeatingSupTemperature="6.0" maxCoolingSupTemperature="30.0" minCoolingSupTemperature="11.0" supply_medium="water">
|
||||
<performance_curve curve_type="second degree multivariable function">
|
||||
<parameters>COP</parameters>
|
||||
<dependant_variable>COP</dependant_variable>
|
||||
<parameters>source_temperature</parameters>
|
||||
<parameters>supply_temperature</parameters>
|
||||
<coefficients a="0.00109" b="0.209" c="-0.00291" d="-0.172" e="0.00102" f="8.95"/>
|
||||
|
@ -55,13 +55,36 @@
|
|||
<manufacturers manufacturer_id="6" name="Canadian Solar" country="Canada" product="Photovoltaic Module"/>
|
||||
</energy_generation_components>
|
||||
<energy_storage_components>
|
||||
<thermalStorages storage_id="1" name="Hot Water Storage Tank" modelName="HF 200" manufacturer="reflex" volume="0.5" maxTemp="95.0" insulationThickness="90.0" tankThickness="0" usesMedium="Water" insulationMaterial="Polyurethane" height="1.5" tankMaterial="Steel"/>
|
||||
<thermalStorages storage_id="2" name="Hot Water Storage Tank" modelName="HF 300" manufacturer="reflex" volume="0.6" maxTemp="95.0" insulationThickness="90.0" tankThickness="0" usesMedium="Water" insulationMaterial="Polyurethane" height="1.3" tankMaterial="Steel"/>
|
||||
<thermalStorages storage_id="3" name="Hot Water Storage Tank" modelName="HF 500" manufacturer="reflex" volume="0.5" maxTemp="95.0" insulationThickness="90.0" tankThickness="0" usesMedium="Water" insulationMaterial="Polyurethane" height="1.5" tankMaterial="Steel"/>
|
||||
<thermalStorages storage_id="4" name="Hot Water Storage Tank" modelName="HF 200" manufacturer="reflex" volume="0.5" maxTemp="95.0" insulationThickness="90.0" tankThickness="0" usesMedium="Water" insulationMaterial="Polyurethane" height="1.5" tankMaterial="Steel"/>
|
||||
<thermalStorages storage_id="5" name="Hot Water Storage Tank" modelName="HF 200" manufacturer="reflex" volume="0.5" maxTemp="95.0" insulationThickness="90.0" tankThickness="0" usesMedium="Water" insulationMaterial="Polyurethane" height="1.5" tankMaterial="Steel"/>
|
||||
<templateStorages storage_id="6" name="template Hot Water Storage Tank" maxTemp="95.0" insulationThickness="90.0" tankThickness="0" usesMedium="Water" insulationMaterial="Polyurethane" tankMaterial="Steel"/>
|
||||
<powerStorages/>
|
||||
<thermalStorages storage_id="1" name="Hot Water Storage Tank" modelName="HF 200" manufacturer="reflex" maxTemp="95.0">
|
||||
<insulation material_id="1" insulationMaterial="Polyurethane" insulationThickness="90.0"/>
|
||||
<physical_characteristics material_id="2" tankThickness="0" height="1.5" tankMaterial="Steel" volume="0.5"/>
|
||||
<medium media_id="1" usesMedium="Water"/>
|
||||
</thermalStorages>
|
||||
<thermalStorages storage_id="2" name="Hot Water Storage Tank" modelName="HF 300" manufacturer="reflex" maxTemp="95.0">
|
||||
<insulation material_id="1" insulationMaterial="Polyurethane" insulationThickness="90.0"/>
|
||||
<physical_characteristics material_id="2" tankThickness="0" height="1.5" tankMaterial="Steel" volume="0.6"/>
|
||||
<medium media_id="1" usesMedium="Water"/>
|
||||
</thermalStorages>
|
||||
<thermalStorages storage_id="3" name="Hot Water Storage Tank" modelName="HF 500" manufacturer="reflex" maxTemp="95.0">
|
||||
<insulation material_id="1" insulationMaterial="Polyurethane" insulationThickness="90.0"/>
|
||||
<physical_characteristics material_id="2" tankThickness="0" height="1.5" tankMaterial="Steel" volume="0.5"/>
|
||||
<medium media_id="1" usesMedium="Water"/>
|
||||
</thermalStorages>
|
||||
<thermalStorages storage_id="4" name="Hot Water Storage Tank" modelName="HF 200" manufacturer="reflex" maxTemp="95.0">
|
||||
<insulation material_id="1" insulationMaterial="Polyurethane" insulationThickness="90.0"/>
|
||||
<physical_characteristics material_id="2" tankThickness="0" height="1.5" tankMaterial="Steel" volume="0.5"/>
|
||||
<medium media_id="1" usesMedium="Water"/>
|
||||
</thermalStorages>
|
||||
<thermalStorages storage_id="5" name="Hot Water Storage Tank" modelName="HF 200" manufacturer="reflex" maxTemp="95.0">
|
||||
<insulation material_id="1" insulationMaterial="Polyurethane" insulationThickness="90.0"/>
|
||||
<physical_characteristics material_id="2" tankThickness="0" height="1.5" tankMaterial="Steel" volume="0.5"/>
|
||||
<medium media_id="1" usesMedium="Water"/>
|
||||
</thermalStorages>
|
||||
<templateStorages storage_id="6" name="template Hot Water Storage Tank" maxTemp="95.0">
|
||||
<insulation material_id="1" insulationMaterial="Polyurethane" insulationThickness="90.0"/>
|
||||
<physical_characteristics material_id="2" tankThickness="0" height="1.5" tankMaterial="Steel"/>
|
||||
<medium media_id="1" usesMedium="Water"/>
|
||||
</templateStorages>
|
||||
<manufacturers manufacturer_id="1" name="reflex" product="Storage Tank"/>
|
||||
</energy_storage_components>
|
||||
<materials>
|
||||
|
|
|
@ -38,5 +38,7 @@ class TestSystemsCatalog(TestCase):
|
|||
def test_north_america_systems_catalog(self):
|
||||
catalog = EnergySystemsCatalogFactory('north_america').catalog
|
||||
|
||||
def test_montreal_catalog(self):
|
||||
catalog = EnergySystemsCatalogFactory('montreal_custom').catalog
|
||||
|
||||
|
||||
# def test_montreal_catalog(self):
|
||||
# catalog = EnergySystemsCatalogFactory('montreal_custom').catalog
|
||||
|
|
Loading…
Reference in New Issue
Block a user