""" Idf exports one building to idf format SPDX - License - Identifier: LGPL - 3.0 - or -later Copyright © 2022 Concordia CERC group Project Coder Guille Guillermo.GutierrezMorote@concordia.ca Code contributors: Pilar Monsalvete Alvarez de Uribarri pilar.monsalvete@concordia.ca Oriol Gavalda Torrellas oriol.gavalda@concordia.ca """ import copy from pathlib import Path from geomeppy import IDF import hub.helpers.constants as cte from hub.city_model_structure.attributes.schedule import Schedule from hub.city_model_structure.building_demand.thermal_zone import ThermalZone from hub.helpers.configuration_helper import ConfigurationHelper class Idf: """ Exports city to IDF """ _BUILDING = 'BUILDING' _ZONE = 'ZONE' _LIGHTS = 'LIGHTS' _APPLIANCES = 'OTHEREQUIPMENT' _PEOPLE = 'PEOPLE' _DHW = 'WATERUSE:EQUIPMENT' _THERMOSTAT = 'HVACTEMPLATE:THERMOSTAT' _IDEAL_LOAD_AIR_SYSTEM = 'HVACTEMPLATE:ZONE:IDEALLOADSAIRSYSTEM' _SURFACE = 'BUILDINGSURFACE:DETAILED' _SHADING = 'SHADING:BUILDING:DETAILED' _SHADING_PROPERTY = 'SHADINGPROPERTY:REFLECTANCE' _BUILDING_SURFACE = 'BuildingSurfaceDetailed' _CONSTRUCTION = 'CONSTRUCTION' _MATERIAL = 'MATERIAL' _MATERIAL_NOMASS = 'MATERIAL:NOMASS' _MATERIAL_ROOFVEGETATION = 'MATERIAL:ROOFVEGETATION' _WINDOW = 'FENESTRATIONSURFACE:DETAILED' _WINDOW_MATERIAL_SIMPLE = 'WINDOWMATERIAL:SIMPLEGLAZINGSYSTEM' _ROUGHNESS = 'MediumRough' _INFILTRATION = 'ZONEINFILTRATION:DESIGNFLOWRATE' _VENTILATION = 'ZONEVENTILATION:DESIGNFLOWRATE' _HOURLY_SCHEDULE = 'SCHEDULE:DAY:HOURLY' _COMPACT_SCHEDULE = 'SCHEDULE:COMPACT' _FILE_SCHEDULE = 'SCHEDULE:FILE' _SCHEDULE_LIMIT = 'SCHEDULETYPELIMITS' _ON_OFF = 'On/Off' _FRACTION = 'Fraction' _ANY_NUMBER = 'Any Number' _CONTINUOUS = 'Continuous' _DISCRETE = 'Discrete' _SIZING_PERIODS = 'SIZINGPERIOD:DESIGNDAY' _LOCATION = 'SITE:LOCATION' _SIMPLE = 'Simple' _EQUIPMENT_CONNECTIONS = 'ZONEHVAC:EQUIPMENTCONNECTIONS' _NODE_LIST = 'NODELIST' _BASEBOARD ='ZONEHVAC:BASEBOARD:CONVECTIVE:ELECTRIC' _AIR_TERMINAL_NO_REHEAT= 'AIRTERMINAL:SINGLEDUCT:CONSTANTVOLUME:NOREHEAT' _AIR_DISTRIBUTION='ZONEHVAC:AIRDISTRIBUTIONUNIT' _EQUIPMENT_LIST='ZONEHVAC:EQUIPMENTLIST' idf_surfaces = { cte.WALL: 'wall', cte.GROUND: 'floor', cte.ROOF: 'roof' } idf_type_limits = { cte.ON_OFF: 'on/off', cte.FRACTION: 'Fraction', cte.ANY_NUMBER: 'Any Number', cte.CONTINUOUS: 'Continuous', cte.DISCRETE: 'Discrete' } idf_day_types = { cte.MONDAY: 'Monday', cte.TUESDAY: 'Tuesday', cte.WEDNESDAY: 'Wednesday', cte.THURSDAY: 'Thursday', cte.FRIDAY: 'Friday', cte.SATURDAY: 'Saturday', cte.SUNDAY: 'Sunday', cte.HOLIDAY: 'Holidays', cte.WINTER_DESIGN_DAY: 'WinterDesignDay', cte.SUMMER_DESIGN_DAY: 'SummerDesignDay' } def __init__(self, city, output_path, idf_file_path, idd_file_path, epw_file_path, export_type="Surfaces", target_buildings=None): self._city = city self._sanity_check() self._output_path = str(output_path.resolve()) self._output_file = str((output_path / f'{city.name}.idf').resolve()) self._export_type = export_type self._idd_file_path = str(idd_file_path) self._idf_file_path = str(idf_file_path) self._epw_file_path = str(epw_file_path) IDF.setiddname(self._idd_file_path) self._idf = IDF(self._idf_file_path, self._epw_file_path) self._idf.newidfobject(self._SCHEDULE_LIMIT, Name=self._ANY_NUMBER) self._idf.newidfobject(self._SCHEDULE_LIMIT, Name=self._FRACTION, Lower_Limit_Value=0.0, Upper_Limit_Value=1.0, Numeric_Type=self._CONTINUOUS) self._idf.newidfobject(self._SCHEDULE_LIMIT, Name=self._ON_OFF, Lower_Limit_Value=0, Upper_Limit_Value=1, Numeric_Type=self._DISCRETE) self._target_buildings = target_buildings self._adjacent_buildings = [] if target_buildings is None: self._target_buildings = [building.name for building in self._city.buildings] else: for building_name in target_buildings: building = city.city_object(building_name) if building.neighbours is not None: self._adjacent_buildings += building.neighbours self._export() def _sanity_check(self): levels_of_detail = self._city.level_of_detail if levels_of_detail.geometry is None: raise AttributeError('Level of detail of geometry not assigned') if levels_of_detail.geometry < 1: raise AttributeError(f'Level of detail of geometry = {levels_of_detail.geometry}. Required minimum level 1') if levels_of_detail.construction is None: raise AttributeError('Level of detail of construction not assigned') if levels_of_detail.construction < 2: raise AttributeError( f'Level of detail of construction = {levels_of_detail.construction}. Required minimum level 2') if levels_of_detail.usage is None: raise AttributeError('Level of detail of usage not assigned') if levels_of_detail.usage < 2: raise AttributeError(f'Level of detail of usage = {levels_of_detail.usage}. Required minimum level 2') if levels_of_detail.weather is None: raise AttributeError('Level of detail of weather not assigned') if levels_of_detail.weather < 2: raise AttributeError(f'Level of detail of weather = {levels_of_detail.weather}. Required minimum level 2') @staticmethod def _matrix_to_list(points, lower_corner): lower_x = lower_corner[0] lower_y = lower_corner[1] lower_z = lower_corner[2] points_list = [] for point in points: point_tuple = (point[0] - lower_x, point[1] - lower_y, point[2] - lower_z) points_list.append(point_tuple) return points_list @staticmethod def _matrix_to_2d_list(points): points_list = [] for point in points: point_tuple = (point[0], point[1]) points_list.append(point_tuple) return points_list def _add_material(self, layer): for material in self._idf.idfobjects[self._MATERIAL]: if material.Name == layer.material_name: return for material in self._idf.idfobjects[self._MATERIAL_NOMASS]: if material.Name == layer.material_name: return if layer.no_mass: self._idf.newidfobject(self._MATERIAL_NOMASS, Name=layer.material_name, Roughness=self._ROUGHNESS, Thermal_Resistance=layer.thermal_resistance ) else: self._idf.newidfobject(self._MATERIAL, Name=layer.material_name, Roughness=self._ROUGHNESS, Thickness=layer.thickness, Conductivity=layer.conductivity, Density=layer.density, Specific_Heat=layer.specific_heat, Thermal_Absorptance=layer.thermal_absorptance, Solar_Absorptance=layer.solar_absorptance, Visible_Absorptance=layer.visible_absorptance ) @staticmethod def _create_infiltration_schedules(thermal_zone): _infiltration_schedules = [] if thermal_zone.thermal_control is None: return [] for hvac_availability_schedule in thermal_zone.thermal_control.hvac_availability_schedules: _schedule = Schedule() _schedule.type = cte.INFILTRATION _schedule.data_type = cte.FRACTION _schedule.time_step = cte.HOUR _schedule.time_range = cte.DAY _schedule.day_types = copy.deepcopy(hvac_availability_schedule.day_types) _infiltration_values = [] for hvac_value in hvac_availability_schedule.values: if hvac_value == 0: _infiltration_values.append(1.0) else: if thermal_zone.infiltration_rate_system_off == 0: _infiltration_values.append(0.0) else: _infiltration_values.append( thermal_zone.infiltration_rate_system_on / thermal_zone.infiltration_rate_system_off) _schedule.values = _infiltration_values _infiltration_schedules.append(_schedule) return _infiltration_schedules @staticmethod def _create_ventilation_schedules(thermal_zone): _ventilation_schedules = [] if thermal_zone.thermal_control is None: return [] for hvac_availability_schedule in thermal_zone.thermal_control.hvac_availability_schedules: _schedule = Schedule() _schedule.type = cte.VENTILATION _schedule.data_type = cte.FRACTION _schedule.time_step = cte.HOUR _schedule.time_range = cte.DAY _schedule.day_types = copy.deepcopy(hvac_availability_schedule.day_types) _ventilation_schedules = thermal_zone.thermal_control.hvac_availability_schedules return _ventilation_schedules @staticmethod def _create_yearly_values_schedules(schedule_type, values): _schedule = Schedule() _schedule.type = schedule_type _schedule.data_type = cte.ANY_NUMBER _schedule.time_step = cte.HOUR _schedule.time_range = cte.YEAR _schedule.day_types = ['monday', 'tuesday', 'wednesday', 'thursday', 'friday', 'saturday', 'sunday', 'holiday', 'winter_design_day', 'summer_design_day'] _schedule.values = values return [_schedule] @staticmethod def _create_constant_value_schedules(schedule_type, value): _schedule = Schedule() _schedule.type = schedule_type _schedule.data_type = cte.ANY_NUMBER _schedule.time_step = cte.HOUR _schedule.time_range = cte.DAY _schedule.day_types = ['monday', 'tuesday', 'wednesday', 'thursday', 'friday', 'saturday', 'sunday', 'holiday', 'winter_design_day', 'summer_design_day'] _schedule.values = [value for _ in range(0, 24)] return [_schedule] def _add_standard_compact_hourly_schedule(self, usage, schedule_type, schedules): for schedule in self._idf.idfobjects[self._COMPACT_SCHEDULE]: if schedule.Name == f'{schedule_type} schedules {usage}': return _kwargs = {'Name': f'{schedule_type} schedules {usage}', 'Schedule_Type_Limits_Name': self.idf_type_limits[schedules[0].data_type], 'Field_1': 'Through: 12/31'} counter = 1 for j, schedule in enumerate(schedules): _val = schedule.values _new_field = '' for day_type in schedule.day_types: _new_field += f' {self.idf_day_types[day_type]}' _kwargs[f'Field_{j * 25 + 2}'] = f'For:{_new_field}' counter += 1 for i, _ in enumerate(_val): _kwargs[f'Field_{j * 25 + 3 + i}'] = f'Until: {i + 1:02d}:00,{_val[i]}' counter += 1 _kwargs[f'Field_{counter + 1}'] = 'For AllOtherDays' _kwargs[f'Field_{counter + 2}'] = 'Until: 24:00,0.0' self._idf.newidfobject(self._COMPACT_SCHEDULE, **_kwargs) def _write_schedules_file(self, usage, schedule): file_name = str((Path(self._output_path) / f'{schedule.type} schedules {usage}.dat').resolve()) with open(file_name, 'w', encoding='utf8') as file: for value in schedule.values: file.write(f'{str(value)},\n') return file_name def _add_file_schedule(self, usage, schedule, file_name): _schedule = self._idf.newidfobject(self._FILE_SCHEDULE, Name=f'{schedule.type} schedules {usage}') _schedule.Schedule_Type_Limits_Name = self.idf_type_limits[schedule.data_type] _schedule.File_Name = file_name _schedule.Column_Number = 1 _schedule.Rows_to_Skip_at_Top = 0 _schedule.Number_of_Hours_of_Data = 8760 _schedule.Column_Separator = 'Comma' _schedule.Interpolate_to_Timestep = 'No' _schedule.Minutes_per_Item = 60 def _add_schedules(self, usage, schedule_type, new_schedules): if len(new_schedules) < 1: return schedule_from_file = False for schedule in new_schedules: if len(schedule.values) > 168: # Hours in one week schedule_from_file = True if schedule_from_file: for schedule in self._idf.idfobjects[self._FILE_SCHEDULE]: if schedule.Name == f'{schedule_type} schedules {usage}': return file_name = self._write_schedules_file(usage, new_schedules[0]) self._add_file_schedule(usage, new_schedules[0], file_name) return for schedule in self._idf.idfobjects[self._HOURLY_SCHEDULE]: if schedule.Name == f'{schedule_type} schedules {usage}': return self._add_standard_compact_hourly_schedule(usage, schedule_type, new_schedules) return def _add_construction(self, thermal_boundary): for construction in self._idf.idfobjects[self._CONSTRUCTION]: if thermal_boundary.parent_surface.vegetation is not None: vegetation_name = f'{thermal_boundary.construction_name}_{thermal_boundary.parent_surface.vegetation.name}' if construction.Name == vegetation_name: return else: if construction.Name == thermal_boundary.construction_name: return if thermal_boundary.layers is None: for material in self._idf.idfobjects[self._MATERIAL]: if material.Name == "DefaultMaterial": return self._idf.set_default_constructions() return for layer in thermal_boundary.layers: self._add_material(layer) layers = thermal_boundary.layers # The constructions should have at least one layer if thermal_boundary.parent_surface.vegetation is not None: vegetation_name = f'{thermal_boundary.construction_name}_{thermal_boundary.parent_surface.vegetation.name}' _kwargs = {'Name': vegetation_name, 'Outside_Layer': thermal_boundary.parent_surface.vegetation.name} for i in range(0, len(layers) - 1): _kwargs[f'Layer_{i + 2}'] = layers[i].material_name else: _kwargs = {'Name': thermal_boundary.construction_name, 'Outside_Layer': layers[0].material_name} for i in range(1, len(layers) - 1): _kwargs[f'Layer_{i + 1}'] = layers[i].material_name self._idf.newidfobject(self._CONSTRUCTION, **_kwargs) def _add_window_construction_and_material(self, thermal_opening): for window_material in self._idf.idfobjects[self._WINDOW_MATERIAL_SIMPLE]: if window_material['UFactor'] == thermal_opening.overall_u_value and \ window_material['Solar_Heat_Gain_Coefficient'] == thermal_opening.g_value: return order = str(len(self._idf.idfobjects[self._WINDOW_MATERIAL_SIMPLE]) + 1) material_name = 'glazing_' + order _kwargs = {'Name': material_name, 'UFactor': thermal_opening.overall_u_value, 'Solar_Heat_Gain_Coefficient': thermal_opening.g_value} self._idf.newidfobject(self._WINDOW_MATERIAL_SIMPLE, **_kwargs) window_construction_name = 'window_construction_' + order _kwargs = {'Name': window_construction_name, 'Outside_Layer': material_name} self._idf.newidfobject(self._CONSTRUCTION, **_kwargs) def _add_zone(self, thermal_zone, name): for zone in self._idf.idfobjects['ZONE']: if zone.Name == name: return self._idf.newidfobject(self._ZONE, Name=name, Volume=thermal_zone.volume) self._add_heating_system(thermal_zone, name) def _add_thermostat(self, thermal_zone): thermostat_name = f'Thermostat {thermal_zone.usage_name}' for thermostat in self._idf.idfobjects[self._THERMOSTAT]: if thermostat.Name == thermostat_name: return thermostat return self._idf.newidfobject( self._THERMOSTAT, Name=thermostat_name, Heating_Setpoint_Schedule_Name=f'Heating thermostat schedules {thermal_zone.usage_name}', Cooling_Setpoint_Schedule_Name=f'Cooling thermostat schedules {thermal_zone.usage_name}' ) def _add_heating_system(self, thermal_zone, zone_name): for air_system in self._idf.idfobjects[self._EQUIPMENT_CONNECTIONS]: if air_system.Zone_Name == zone_name: return thermostat = self._add_thermostat(thermal_zone) self._idf.newidfobject(self._EQUIPMENT_CONNECTIONS, Zone_Name=zone_name, Zone_Conditioning_Equipment_List_Name=f'{zone_name} Equipment List', Zone_Air_Inlet_Node_or_NodeList_Name=f'{zone_name} Inlet Node List', Zone_Air_Node_Name=f'Node 1', Zone_Return_Air_Node_or_NodeList_Name=f'{zone_name} Return Node List') def _add_nodelist_system(self, thermal_zone, zone_name): self._idf.newidfobject(self._NODE_LIST, Name=f'{zone_name} Inlet Node List',Node_1_Name='Node 1') self._idf.newidfobject(self._NODE_LIST, Name=f'{zone_name} Return Node List', Node_1_Name='Node 3') def _add_baseboard_system(self, thermal_zone, zone_name): for baseboard in self._idf.idfobjects[self._BASEBOARD]: if baseboard.Zone_Name == zone_name: return self._idf.newidfobject(self._BASEBOARD, Name=f'Elec Baseboard',Availability_Schedule_Name='HVAC AVAIL') def _add_air_terminal_system(self, thermal_zone, zone_name): """for air_terminal in self._idf.idfobjects[self._AIR_TERMINAL_NO_REHEAT]: if air_terminal.Zone_Name == zone_name: return""" self._idf.newidfobject(self._AIR_TERMINAL_NO_REHEAT, Name=f'Diffuser', Availability_Schedule_Name='HVAC AVAIL', Air_Inlet_Node_Name='Node 4', Air_Outlet_Node_Name='Node 2') def _add_air_distribution_system(self, thermal_zone, zone_name): for air_distribution in self._idf.idfobjects[self._AIR_DISTRIBUTION]: if air_distribution.Zone_Name == zone_name: return self._idf.newidfobject(self._AIR_DISTRIBUTION, Name='ADU Diffuser', Air_Distribution_Unit_Outlet_Node_Name='Node 2', Air_Terminal_Object_Type='AirTerminal:SingleDuct:ConstantVolume:NoReheat', Air_Terminal_Name='Diffuser') def _add_equipment_list_system(self, thermal_zone, zone_name): for air_distribution in self._idf.idfobjects[self._EQUIPMENT_LIST]: if air_distribution.Zone_Name == zone_name: return self._idf.newidfobject(self._EQUIPMENT_LIST, Name=f'{zone_name} Equipment List', Load_Distribution_Scheme='SequentialLoad', Zone_Equipment_1_Object_Type='ZoneHVAC:Baseboard:Convective:Electric', Zone_Equipment_1_Name='Elec Baseboard', Zone_Equipment_1_Heating_or_NoLoad_Sequence='1', Zone_Equipment_2_Object_Type='ZoneHVAC:AirDistributionUnit', Zone_Equipment_2_Name ='ADU Diffuser') def _add_occupancy(self, thermal_zone, zone_name): number_of_people = thermal_zone.occupancy.occupancy_density * thermal_zone.total_floor_area fraction_radiant = 0 total_sensible = ( thermal_zone.occupancy.sensible_radiative_internal_gain + thermal_zone.occupancy.sensible_convective_internal_gain ) if total_sensible != 0: fraction_radiant = thermal_zone.occupancy.sensible_radiative_internal_gain / total_sensible self._idf.newidfobject(self._PEOPLE, Name=f'{zone_name}_occupancy', Zone_or_ZoneList_Name=zone_name, Number_of_People_Schedule_Name=f'Occupancy schedules {thermal_zone.usage_name}', Number_of_People_Calculation_Method="People", Number_of_People=number_of_people, Fraction_Radiant=fraction_radiant, Activity_Level_Schedule_Name=f'Activity Level schedules {thermal_zone.usage_name}' ) def _add_lighting(self, thermal_zone: ThermalZone, zone_name: str): fraction_radiant = thermal_zone.lighting.radiative_fraction method = 'Watts/Area' storeys_number = int(thermal_zone.total_floor_area / thermal_zone.footprint_area) watts_per_zone_floor_area = thermal_zone.lighting.density * storeys_number subcategory = f'ELECTRIC EQUIPMENT#{zone_name}#GeneralLights' self._idf.newidfobject(self._LIGHTS, Name=f'{zone_name}_lights', Zone_or_ZoneList_Name=zone_name, Schedule_Name=f'Lighting schedules {thermal_zone.usage_name}', Design_Level_Calculation_Method=method, Watts_per_Zone_Floor_Area=watts_per_zone_floor_area, Fraction_Radiant=fraction_radiant, EndUse_Subcategory=subcategory ) def _add_appliances(self, thermal_zone, zone_name): fuel_type = 'Electricity' fraction_radiant = thermal_zone.appliances.radiative_fraction fraction_latent = thermal_zone.appliances.latent_fraction method = 'Watts/Area' storeys_number = int(thermal_zone.total_floor_area / thermal_zone.footprint_area) watts_per_zone_floor_area = thermal_zone.appliances.density * storeys_number subcategory = f'ELECTRIC EQUIPMENT#{zone_name}#InteriorEquipment' self._idf.newidfobject(self._APPLIANCES, Fuel_Type=fuel_type, Name=f'{zone_name}_appliance', Zone_or_ZoneList_Name=zone_name, Schedule_Name=f'Appliance schedules {thermal_zone.usage_name}', Design_Level_Calculation_Method=method, Power_per_Zone_Floor_Area=watts_per_zone_floor_area, Fraction_Latent=fraction_latent, Fraction_Radiant=fraction_radiant, EndUse_Subcategory=subcategory ) def _add_infiltration(self, thermal_zone, zone_name): schedule = f'Infiltration schedules {thermal_zone.usage_name}' _infiltration = thermal_zone.infiltration_rate_system_off * cte.HOUR_TO_SECONDS self._idf.newidfobject(self._INFILTRATION, Name=f'{zone_name}_infiltration', Zone_or_ZoneList_Name=zone_name, Schedule_Name=schedule, Design_Flow_Rate_Calculation_Method='AirChanges/Hour', Air_Changes_per_Hour=_infiltration ) def _add_ventilation(self, thermal_zone, zone_name): schedule = f'Ventilation schedules {thermal_zone.usage_name}' _air_change = thermal_zone.mechanical_air_change * cte.HOUR_TO_SECONDS self._idf.newidfobject(self._VENTILATION, Name=f'{zone_name}_ventilation', Zone_or_ZoneList_Name=zone_name, Schedule_Name=schedule, Design_Flow_Rate_Calculation_Method='AirChanges/Hour', Air_Changes_per_Hour=_air_change ) def _add_dhw(self, thermal_zone, zone_name): peak_flow_rate = thermal_zone.domestic_hot_water.peak_flow * thermal_zone.total_floor_area self._idf.newidfobject(self._DHW, Name=f'DHW {zone_name}', Peak_Flow_Rate=peak_flow_rate, Flow_Rate_Fraction_Schedule_Name=f'DHW_prof schedules {thermal_zone.usage_name}', Target_Temperature_Schedule_Name=f'DHW_temp schedules {thermal_zone.usage_name}', Hot_Water_Supply_Temperature_Schedule_Name=f'DHW_temp schedules {thermal_zone.usage_name}', Cold_Water_Supply_Temperature_Schedule_Name=f'cold_temp schedules {zone_name}', EndUse_Subcategory=f'DHW {zone_name}', Zone_Name=zone_name ) def _rename_building(self, city_name): name = str(str(city_name.encode("utf-8"))) for building in self._idf.idfobjects[self._BUILDING]: building.Name = f'Buildings in {name}' building['Solar_Distribution'] = 'FullExterior' def _remove_sizing_periods(self): while len(self._idf.idfobjects[self._SIZING_PERIODS]) > 0: self._idf.popidfobject(self._SIZING_PERIODS, 0) def _remove_location(self): self._idf.popidfobject(self._LOCATION, 0) def _export(self): """ Export the idf file into the given path. If buildings to calculate are provided, only those will appear in the output variables, otherwise all the city buildings will be calculated. If adjacent buildings are provided those buildings will be calculated, but will not appear in the output variables. export type = "Surfaces|Block" """ self._remove_location() self._remove_sizing_periods() self._rename_building(self._city.name) self._lod = self._city.level_of_detail.geometry for building in self._city.buildings: for internal_zone in building.internal_zones: if internal_zone.thermal_zones_from_internal_zones is None: continue for thermal_zone in internal_zone.thermal_zones_from_internal_zones: for thermal_boundary in thermal_zone.thermal_boundaries: self._add_construction(thermal_boundary) if thermal_boundary.parent_surface.vegetation is not None: self._add_vegetation_material(thermal_boundary.parent_surface.vegetation) for thermal_opening in thermal_boundary.thermal_openings: self._add_window_construction_and_material(thermal_opening) usage = thermal_zone.usage_name if building.name in self._target_buildings or building.name in self._adjacent_buildings: _new_schedules = self._create_infiltration_schedules(thermal_zone) self._add_schedules(usage, 'Infiltration', _new_schedules) _new_schedules = self._create_ventilation_schedules(thermal_zone) self._add_schedules(usage, 'Ventilation', _new_schedules) self._add_schedules(usage, 'Occupancy', thermal_zone.occupancy.occupancy_schedules) self._add_schedules(usage, 'HVAC AVAIL', thermal_zone.thermal_control.hvac_availability_schedules) self._add_schedules(usage, 'Heating thermostat', thermal_zone.thermal_control.heating_set_point_schedules) self._add_schedules(usage, 'Cooling thermostat', thermal_zone.thermal_control.cooling_set_point_schedules) self._add_schedules(usage, 'Lighting', thermal_zone.lighting.schedules) self._add_schedules(usage, 'Appliance', thermal_zone.appliances.schedules) self._add_schedules(usage, 'DHW_prof', thermal_zone.domestic_hot_water.schedules) _new_schedules = self._create_yearly_values_schedules('cold_temp', building.cold_water_temperature[cte.HOUR]) self._add_schedules(building.name, 'cold_temp', _new_schedules) value = thermal_zone.domestic_hot_water.service_temperature _new_schedules = self._create_constant_value_schedules('DHW_temp', value) self._add_schedules(usage, 'DHW_temp', _new_schedules) _occ = thermal_zone.occupancy if _occ.occupancy_density == 0: _total_heat = 0 else: _total_heat = (_occ.sensible_convective_internal_gain + _occ.sensible_radiative_internal_gain + _occ.latent_internal_gain) / _occ.occupancy_density _new_schedules = self._create_constant_value_schedules('Activity Level', _total_heat) self._add_schedules(usage, 'Activity Level', _new_schedules) self._add_zone(thermal_zone, building.name) self._add_heating_system(thermal_zone, building.name) self._add_nodelist_system(thermal_zone,building.name) self._add_baseboard_system(thermal_zone, building.name) self._add_air_terminal_system(thermal_zone, building.name) self._add_air_distribution_system(thermal_zone, building.name) self._add_equipment_list_system(thermal_zone, building.name) self._add_infiltration(thermal_zone, building.name) self._add_ventilation(thermal_zone, building.name) self._add_occupancy(thermal_zone, building.name) self._add_lighting(thermal_zone, building.name) self._add_appliances(thermal_zone, building.name) self._add_dhw(thermal_zone, building.name) if self._export_type == "Surfaces": if building.name in self._target_buildings or building.name in self._adjacent_buildings: if building.thermal_zones_from_internal_zones is not None: self._add_surfaces(building, building.name) else: self._add_pure_geometry(building, building.name) else: self._add_shading(building) else: self._add_block(building) self._idf.newidfobject( "OUTPUT:VARIABLE", Variable_Name="Zone Ideal Loads Supply Air Total Heating Energy", Reporting_Frequency="Hourly", ) self._idf.newidfobject( "OUTPUT:VARIABLE", Variable_Name="Zone Ideal Loads Supply Air Total Cooling Energy", Reporting_Frequency="Hourly", ) self._idf.newidfobject( "OUTPUT:VARIABLE", Variable_Name="Water Use Equipment Heating Rate", Reporting_Frequency="Hourly", ) # post-process to erase windows associated to adiabatic walls windows_list = [] for window in self._idf.idfobjects[self._WINDOW]: found = False for surface in self._idf.idfobjects[self._SURFACE]: if window.Building_Surface_Name == surface.Name: found = True if not found: windows_list.append(window) for window in windows_list: self._idf.removeidfobject(window) self._idf.saveas(str(self._output_file)) return self._idf def run(self): """ Start the energy plus simulation """ self._idf.run(expandobjects=False, readvars=True, output_directory=self._output_path, output_prefix=f'{self._city.name}_') def _add_block(self, building): _points = self._matrix_to_2d_list(building.foot_print.coordinates) self._idf.add_block(name=building.name, coordinates=_points, height=building.max_height, num_stories=int(building.storeys_above_ground)) for surface in self._idf.idfobjects[self._SURFACE]: for thermal_zone in building.thermal_zones_from_internal_zones: for boundary in thermal_zone.thermal_boundaries: if surface.Type == self.idf_surfaces[boundary.surface.type]: surface.Construction_Name = boundary.construction_name break for usage in thermal_zone.usages: surface.Zone_Name = usage.id break break self._idf.intersect_match() def _add_shading(self, building): for surface in building.surfaces: shading = self._idf.newidfobject(self._SHADING, Name=f'{surface.name}') coordinates = self._matrix_to_list(surface.solid_polygon.coordinates, self._city.lower_corner) shading.setcoords(coordinates) solar_reflectance = surface.short_wave_reflectance if solar_reflectance is None: solar_reflectance = ConfigurationHelper().short_wave_reflectance self._idf.newidfobject(self._SHADING_PROPERTY, Shading_Surface_Name=f'{surface.name}', Diffuse_Solar_Reflectance_of_Unglazed_Part_of_Shading_Surface=solar_reflectance, Fraction_of_Shading_Surface_That_Is_Glazed=0) def _add_pure_geometry(self, building, zone_name): for surface in building.surfaces: outside_boundary_condition = 'Outdoors' sun_exposure = 'SunExposed' wind_exposure = 'WindExposed' idf_surface_type = self.idf_surfaces[surface.type] _kwargs = {'Name': f'{surface.name}', 'Surface_Type': idf_surface_type, 'Zone_Name': zone_name} if surface.type == cte.GROUND: outside_boundary_condition = 'Ground' sun_exposure = 'NoSun' wind_exposure = 'NoWind' if surface.percentage_shared is not None and surface.percentage_shared > 0.5: outside_boundary_condition = 'Surface' outside_boundary_condition_object = surface.name sun_exposure = 'NoSun' wind_exposure = 'NoWind' _kwargs['Outside_Boundary_Condition_Object'] = outside_boundary_condition_object _kwargs['Outside_Boundary_Condition'] = outside_boundary_condition _kwargs['Sun_Exposure'] = sun_exposure _kwargs['Wind_Exposure'] = wind_exposure idf_surface = self._idf.newidfobject(self._SURFACE, **_kwargs) coordinates = self._matrix_to_list(surface.solid_polygon.coordinates, self._city.lower_corner) idf_surface.setcoords(coordinates) if self._lod >= 3: for internal_zone in building.internal_zones: for thermal_zone in internal_zone.thermal_zones_from_internal_zones: for boundary in thermal_zone.thermal_boundaries: self._add_windows_by_vertices(boundary) else: # idf only allows setting wwr for external walls wwr = 0 self._idf.set_wwr(wwr) def _add_surfaces(self, building, zone_name): for thermal_zone in building.thermal_zones_from_internal_zones: for boundary in thermal_zone.thermal_boundaries: idf_surface_type = self.idf_surfaces[boundary.parent_surface.type] outside_boundary_condition = 'Outdoors' sun_exposure = 'SunExposed' wind_exposure = 'WindExposed' _kwargs = {'Name': f'{boundary.parent_surface.name}', 'Surface_Type': idf_surface_type, 'Zone_Name': zone_name} if boundary.parent_surface.type == cte.GROUND: outside_boundary_condition = 'Ground' sun_exposure = 'NoSun' wind_exposure = 'NoWind' if boundary.parent_surface.percentage_shared is not None and boundary.parent_surface.percentage_shared > 0.5: outside_boundary_condition = 'Surface' outside_boundary_condition_object = boundary.parent_surface.name sun_exposure = 'NoSun' wind_exposure = 'NoWind' _kwargs['Outside_Boundary_Condition_Object'] = outside_boundary_condition_object _kwargs['Outside_Boundary_Condition'] = outside_boundary_condition _kwargs['Sun_Exposure'] = sun_exposure _kwargs['Wind_Exposure'] = wind_exposure if boundary.parent_surface.vegetation is not None: construction_name = f'{boundary.construction_name}_{boundary.parent_surface.vegetation.name}' else: construction_name = boundary.construction_name _kwargs['Construction_Name'] = construction_name surface = self._idf.newidfobject(self._SURFACE, **_kwargs) coordinates = self._matrix_to_list(boundary.parent_surface.solid_polygon.coordinates, self._city.lower_corner) surface.setcoords(coordinates) if self._lod >= 3: for internal_zone in building.internal_zones: for thermal_zone in internal_zone.thermal_zones_from_internal_zones: for boundary in thermal_zone.thermal_boundaries: self._add_windows_by_vertices(boundary) else: # idf only allows setting wwr for external walls wwr = 0 for surface in building.surfaces: if surface.type == cte.WALL: wwr = surface.associated_thermal_boundaries[0].window_ratio self._idf.set_wwr(wwr, construction='window_construction_1') def _add_windows_by_vertices(self, boundary): raise NotImplementedError def _compare_window_constructions(self, window_construction, opening): glazing = window_construction['Outside_Layer'] for material in self._idf.idfobjects[self._WINDOW_MATERIAL_SIMPLE]: if material['Name'] == glazing: if material['UFactor'] == opening.overall_u_value and material[ 'Solar_Heat_Gain_Coefficient'] == opening.g_value: return True return False def _add_vegetation_material(self, vegetation): for vegetation_material in self._idf.idfobjects[self._MATERIAL_ROOFVEGETATION]: if vegetation_material.Name == vegetation.name: return soil = vegetation.soil height = 0 leaf_area_index = 0 leaf_reflectivity = 0 leaf_emissivity = 0 minimal_stomatal_resistance = 0 for plant in vegetation.plants: height += plant.percentage * plant.height leaf_area_index += plant.percentage * plant.leaf_area_index leaf_reflectivity += plant.percentage * plant.leaf_reflectivity leaf_emissivity += plant.percentage * plant.leaf_emissivity minimal_stomatal_resistance += plant.percentage * plant.minimal_stomatal_resistance self._idf.newidfobject( self._MATERIAL_ROOFVEGETATION, Name=vegetation.name, Height_of_Plants=height, Leaf_Area_Index=leaf_area_index, Leaf_Reflectivity=leaf_reflectivity, Leaf_Emissivity=leaf_emissivity, Minimum_Stomatal_Resistance=minimal_stomatal_resistance, Soil_Layer_Name=soil.name, Roughness=soil.roughness, Thickness=vegetation.soil_thickness, Conductivity_of_Dry_Soil=soil.dry_conductivity, Density_of_Dry_Soil=soil.dry_density, Specific_Heat_of_Dry_Soil=soil.dry_specific_heat, Thermal_Absorptance=soil.thermal_absorptance, Solar_Absorptance=soil.solar_absorptance, Visible_Absorptance=soil.visible_absorptance, Saturation_Volumetric_Moisture_Content_of_the_Soil_Layer=soil.saturation_volumetric_moisture_content, Residual_Volumetric_Moisture_Content_of_the_Soil_Layer=soil.residual_volumetric_moisture_content, Initial_Volumetric_Moisture_Content_of_the_Soil_Layer=soil.initial_volumetric_moisture_content, Moisture_Diffusion_Calculation_Method=self._SIMPLE )