add generation and config

hub/catalog_factories/data_models/energy_systems/pv_generation_system.py

@@ -17,8 +17,9 @@ class PvGenerationSystem(GenerationSystem):
   """
 
   def __init__(self, nominal_ambient_temperature, nominal_cell_temperature, nominal_radiation,
-               standard_test_condition_cell_temperature, standard_test_condition_maximum_power, width, height,
+               standard_test_condition_cell_temperature, standard_test_condition_maximum_power,
-               model_name, manufacturer, electricity_efficiency, nominal_electricity_output):
+               cell_temperature_coefficient, width, height, model_name, manufacturer, electricity_efficiency,
+               nominal_electricity_output):
     super(GenerationSystem, self).__init__(model_name=model_name, manufacturer=manufacturer, system_type='pv',
                                            fuel_type='renewable', nominal_thermal_output=None, modulation_range=None,
                                            source_types=None, heat_efficiency=None, cooling_efficiency=None,
@@ -29,6 +30,7 @@ class PvGenerationSystem(GenerationSystem):
     self._nominal_radiation = nominal_radiation
     self._standard_test_condition_cell_temperature = standard_test_condition_cell_temperature
     self._standard_test_condition_maximum_power = standard_test_condition_maximum_power
+    self._cell_temperature_coefficient = cell_temperature_coefficient
     self._width = width
     self._height = height
 
@@ -72,6 +74,14 @@ class PvGenerationSystem(GenerationSystem):
     """
     return self._standard_test_condition_maximum_power
 
+  @property
+  def cell_temperature_coefficient(self):
+    """
+    Get cell temperature coefficient of PV module
+    :return: float
+    """
+    return self._cell_temperature_coefficient
+
   @property
   def width(self):
     """
@@ -102,6 +112,7 @@ class PvGenerationSystem(GenerationSystem):
       'nominal radiation [W/m2]': self.nominal_radiation,
       'standard test condition cell temperature [Celsius]': self.standard_test_condition_cell_temperature,
       'standard test condition maximum power [kW]': self.standard_test_condition_maximum_power,
+      'cell temperature coefficient':self.cell_temperature_coefficient,
       'width': self.width,
       'height': self.height,
     }

hub/catalog_factories/energy_systems/north_america_energy_system_catalog.py

@@ -12,6 +12,7 @@ from hub.catalog_factories.catalog import Catalog
 from hub.catalog_factories.data_models.energy_systems.system import System
 from hub.catalog_factories.data_models.energy_systems.content import Content
 from hub.catalog_factories.data_models.energy_systems.generation_system import GenerationSystem
+from hub.catalog_factories.data_models.energy_systems.pv_generation_system import PvGenerationSystem
 from hub.catalog_factories.data_models.energy_systems.distribution_system import DistributionSystem
 from hub.catalog_factories.data_models.energy_systems.energy_emission_system import EnergyEmissionSystem
 from hub.catalog_factories.data_models.energy_systems.energy_storage_system import EnergyStorageSystem
@@ -25,23 +26,129 @@ class NorthAmericaEnergySystemCatalog(Catalog):
   """
   North america energy system catalog class
   """
+
   def __init__(self, path):
     path = str(path / 'Tools4CitiesESMF.xml')
     with open(path, 'r', encoding='utf-8') as xml:
       self._archetypes = xmltodict.parse(xml.read())
-#    self._systems = self._load_systems()
+    self._systems = self._load_systems()
-#    self._generation_components = self._load_generation_components()
+    print(self._load_systems())
+    self._generation_components = self._load_generation_components()
+    print(self._generation_components)
     self._storage_components = self._load_storage_components()
     print(self._storage_components)
-#    self._system_archetypes = self._load_system_archetypes()
 
-    # store the full catalog data model in self._content
+  #    self._system_archetypes = self._load_system_archetypes()
-#    self._content = Content(self._system_archetypes,
+
-#                            self._systems,
+  # store the full catalog data model in self._content
-#                            self._generation_components,
+  #    self._content = Content(self._system_archetypes,
-#                            None,
+  #                            self._systems,
-#                            None,
+  #                            self._generation_components,
-#                            self._storage_components)
+  #                            None,
+  #                            None,
+  #                            self._storage_components)
+  def _load_systems(self):
+    system_configurations = []
+    configurations = self._archetypes['encomp:EnergySystemCatalog']['energysystemconfiguration']
+    for configuration in configurations:
+      system_configurations.append(configuration['@configurationName'])
+    return system_configurations
+
+  def _load_generation_components(self):
+    generation_components = []
+    boilers = self._archetypes['encomp:EnergySystemCatalog']['energycomponent']['boilers']
+    heat_pumps = self._archetypes['encomp:EnergySystemCatalog']['energycomponent']['heatPumps']
+    photovoltaics = self._archetypes['encomp:EnergySystemCatalog']['energycomponent']['photovoltaicModules']
+    print(photovoltaics.keys())
+    for boiler in boilers:
+      boiler_model_name = boiler['@modelName']
+      boiler_manufacturer = boiler['@manufacturer']
+      system_type = 'boiler'
+      boiler_fuel_type = boiler['@fuel']
+      boiler_nominal_thermal_output = float(boiler['@installedThermalPower'])
+      boiler_modulation_range = float(boiler['@modulationRange'])
+      boiler_heat_efficiency = float(boiler['@nominalEfficiency'])
+
+      boiler_component = GenerationSystem(boiler_model_name,
+                                          boiler_manufacturer,
+                                          system_type,
+                                          boiler_fuel_type,
+                                          boiler_nominal_thermal_output,
+                                          boiler_modulation_range,
+                                          None,
+                                          None,
+                                          boiler_heat_efficiency,
+                                          None,
+                                          None,
+                                          None,
+                                          None,
+                                          None,
+                                          None,
+                                          None,
+                                          None,
+                                          None)
+      generation_components.append(boiler_component)
+    for heat_pump in heat_pumps:
+      heat_pump_model_name = heat_pump['@modelName']
+      heat_pump_manufacturer = heat_pump['@manufacturer']
+      system_type = 'heat pump'
+      heat_pump_fuel_type = heat_pump['@fuel']
+      heat_pump_nominal_thermal_output = float(heat_pump['@installedThermalPower'])
+      heat_pump_modulation_range = float(heat_pump['@modulationRange'])
+      heat_pump_source_type = heat_pump['@heatSource']
+      heat_pump_supply_medium = heat_pump['@supply_medium']
+      heat_pump_nominal_cop = float(heat_pump['@nominalCOP'])
+      heat_pump_maximum_heating_temperature = float(heat_pump['@maxHeatingSupTemperature'])
+      heat_pump_minimum_heating_temperature = float(heat_pump['@minHeatingSupTemperature'])
+      heat_pump_maximum_cooling_temperature = float(heat_pump['@maxCoolingSupTemperature'])
+      heat_pump_minimum_cooling_temperature = float(heat_pump['@minCoolingSupTemperature'])
+
+      heat_pump_component = GenerationSystem(heat_pump_model_name,
+                                             heat_pump_manufacturer,
+                                             system_type,
+                                             heat_pump_fuel_type,
+                                             heat_pump_nominal_thermal_output,
+                                             heat_pump_modulation_range,
+                                             heat_pump_source_type,
+                                             heat_pump_supply_medium,
+                                             heat_pump_nominal_cop,
+                                             None,
+                                             None,
+                                             None,
+                                             None,
+                                             None,
+                                             heat_pump_maximum_heating_temperature,
+                                             heat_pump_minimum_heating_temperature,
+                                             heat_pump_maximum_cooling_temperature,
+                                             heat_pump_minimum_cooling_temperature)
+      generation_components.append(heat_pump_component)
+    for pv in photovoltaics:
+      nominal_ambient_temperature = float(pv['@nominalAmbientTemperature'])
+      nominal_cell_temperature = float(pv['@nominalCellTemperature'])
+      nominal_radiation = float(pv['@nominalRadiation'])
+      standard_test_condition_cell_temperature = float(pv['@STCCellTemperature'])
+      standard_test_condition_maximum_power = float(pv['@STCMaxPower'])
+      cell_temperature_coefficient = float(pv['@CellTemperatureCoefficient'])
+      width = float(pv['@width'])
+      height = float(pv['@height'])
+      pv_model_name = pv['@modelName']
+      pv_manufacturer = pv['@manufacturer']
+      pv_electricity_efficiency = pv['@nominalEfficiency']
+      pv_nominal_electricity_output = pv['@nominalPower']
+      pv_component = PvGenerationSystem(nominal_ambient_temperature,
+                                        nominal_cell_temperature,
+                                        nominal_radiation,
+                                        standard_test_condition_cell_temperature,
+                                        standard_test_condition_maximum_power,
+                                        cell_temperature_coefficient,
+                                        width,
+                                        height,
+                                        pv_model_name,
+                                        pv_manufacturer,
+                                        pv_electricity_efficiency,
+                                        pv_nominal_electricity_output)
+      generation_components.append(pv_component)
+    return generation_components
 
   def _load_storage_components(self):
     storage_components = []

hub/data/energy_systems/Tools4CitiesESMF.xml

@@ -2,18 +2,18 @@
 <encomp:EnergySystemCatalog xmi:version="2.0" xmlns:xmi="http://www.omg.org/XMI" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xmlns:encomp="https://www.hft-stuttgart.de/energycomponents">
   <energycomponent>
     <media name="Water" density="981.0" heatCapacity="4180.0" evaporationTemperature="100.0"/>
-    <boilers modelName="ALP080B" manufacturer="Alpine" installedThermalPower="21.0" modulationRange="0.88" nominalEfficiency="0.95" combi="true"/>
+    <boilers modelName="ALP080B" manufacturer="Alpine" installedThermalPower="21.0" modulationRange="0.88" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
-    <boilers modelName="ALP105B" manufacturer="Alpine" installedThermalPower="28.0" modulationRange="0.88" nominalEfficiency="0.95" combi="true"/>
+    <boilers modelName="ALP105B" manufacturer="Alpine" installedThermalPower="28.0" modulationRange="0.88" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
-    <boilers modelName="ALP150B" manufacturer="Alpine" installedThermalPower="40.0" modulationRange="0.88" nominalEfficiency="0.95" combi="true"/>
+    <boilers modelName="ALP150B" manufacturer="Alpine" installedThermalPower="40.0" modulationRange="0.88" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
-    <boilers modelName="ALP210B" manufacturer="Alpine" installedThermalPower="57.0" modulationRange="0.87" nominalEfficiency="0.95" combi="true"/>
+    <boilers modelName="ALP210B" manufacturer="Alpine" installedThermalPower="57.0" modulationRange="0.87" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
-    <boilers modelName="ALTAC-136" manufacturer="Alta" installedThermalPower="33.0" modulationRange="0.95" nominalEfficiency="0.95" combi="true"/>
+    <boilers modelName="ALTAC-136" manufacturer="Alta" installedThermalPower="33.0" modulationRange="0.95" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
-    <boilers modelName="ALTA-120" manufacturer="Alta" installedThermalPower="33.0" modulationRange="0.95" nominalEfficiency="0.95" combi="true"/>
+    <boilers modelName="ALTA-120" manufacturer="Alta" installedThermalPower="33.0" modulationRange="0.95" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
-    <boilers modelName="ASPN-085" manufacturer="Aspen" installedThermalPower="23.15" modulationRange="0.97" nominalEfficiency="0.96"/>
+    <boilers modelName="ASPN-085" manufacturer="Aspen" installedThermalPower="23.15" modulationRange="0.97" nominalEfficiency="0.96" fuel="natural gas"/>
-    <boilers modelName="ASPN-110" manufacturer="Aspen" installedThermalPower="30.19" modulationRange="0.96" nominalEfficiency="0.96"/>
+    <boilers modelName="ASPN-110" manufacturer="Aspen" installedThermalPower="30.19" modulationRange="0.96" nominalEfficiency="0.96" fuel="natural gas"/>
-    <boilers modelName="ASPNC-155" manufacturer="Aspen" installedThermalPower="42.5" modulationRange="0.96" nominalEfficiency="0.95" combi="true"/>
+    <boilers modelName="ASPNC-155" manufacturer="Aspen" installedThermalPower="42.5" modulationRange="0.96" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
-    <boilers modelName="K2WTC-135B" manufacturer="K2" installedThermalPower="32.8" modulationRange="0.96" nominalEfficiency="0.95" combi="true"/>
+    <boilers modelName="K2WTC-135B" manufacturer="K2" installedThermalPower="32.8" modulationRange="0.96" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
-    <boilers modelName="K2WTC-180B" manufacturer="K2" installedThermalPower="49.5" modulationRange="0.96" nominalEfficiency="0.95" combi="true"/>
+    <boilers modelName="K2WTC-180B" manufacturer="K2" installedThermalPower="49.5" modulationRange="0.96" nominalEfficiency="0.95" combi="true" fuel="natural gas"/>
-    <photovoltaicModules 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"/>
+    <photovoltaicModules 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 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">
       <coefficientOfPerformance xsi:type="encomp:SecondDegreePolynomialFunction" parameter="COP" parameterA="9.5E-4" parameterB="0.177" parameterC="-0.00242" parameterD="-0.155" parameterE="9.3E-4" parameterF="8.044"/>
     </heatPumps>