def building_test2(prj): """ building which is hardcoded for testing """ bldg = Building(parent = prj) '''Set some building parameters''' bldg.name = "UnitTestBuilding" bldg.street_name = "Unit Street 42" bldg.city = "46325 Testing Town" bldg.year_of_construction = 1988 bldg.number_of_floors = 1 bldg.height_of_floors = 3.5 '''Instantiate a ThermalZone class, with building as parent and set some parameters of the thermal zone''' tz = ThermalZone(parent = bldg) tz.name = "Living Room" tz.area = 140.0 tz.volume = tz.area * bldg.number_of_floors * bldg.height_of_floors tz.infiltration_rate = 0.5 tz.use_conditions = BoundaryConditions(tz) tz.use_conditions.usage = "Living" tz.use_conditions.cooling_time = [5,18] tz.use_conditions.heating_time = [5,18] tz.use_conditions.set_temp_heat = 288.15 tz.use_conditions.set_temp_cool = 298.15 tz.use_conditions.temp_set_back= 4.0 tz.use_conditions.min_air_exchange= 0.0 tz.use_conditions.min_ahu= 0.0 tz.use_conditions.max_ahu = 2.6 tz.use_conditions.with_ahu = True tz.use_conditions.persons = 3 tz.use_conditions.machines = 3 tz.use_conditions.lighting_power = 3 tz.use_conditions.activity_type_machines = 2 tz.use_conditions.ratio_conv_rad_machines = 0.5 tz.use_conditions.profile_machines = [0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.2, 0.4, 0.6, 0.8, 0.8, 0.4, 0.6, 0.8, 0.8, 0.4, 0.2, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0] tz.use_conditions.profile_persons = [0.1, 0.1, 0.1, 0.1, 0.1, 0.1, 0.1, 0.2, 0.4, 0.6, 0.8, 0.8, 0.4, 0.6, 0.8, 0.8, 0.4, 0.2, 0.1, 0.1, 0.1, 0.1, 0.1, 0.1] tz.use_conditions.profile_lighting = [0.1, 0.1, 0.1, 0.1, 0.1, 0.1, 0.1, 0.2, 0.4, 0.6, 0.8, 0.8, 0.4, 0.6, 0.8, 0.8, 0.4, 0.2, 0.1, 0.1, 0.1, 0.1, 0.1, 0.1] tz.use_conditions.use_constant_ach_rate = False tz.use_conditions.base_ach = 0.2 tz.use_conditions.max_user_ach = 1.0 tz.use_conditions.max_overheating_ach = [3.0, 2.0] tz.use_conditions.max_summer_ach = [1.0, 273.15 + 10, 273.15 + 17] tz.use_conditions.winter_reduction = [0.2, 273.15, 273.15 + 10] out_wall_dict = [["Outer Wall 1", [bldg.year_of_construction, 'heavy', 10.0, 90.0, 0.0]], ["Outer Wall 2", [bldg.year_of_construction, 'heavy', 14.0, 90.0, 90.0]], ["Outer Wall 3", [bldg.year_of_construction, 'heavy', 10.0, 90.0, 180.0]], ["Outer Wall 4", [bldg.year_of_construction, 'heavy', 14.0, 90.0, 270.0]]] #import collections #out_wall_dict = collections.OrderedDict(sorted(out_wall_dict.items(), key=lambda t: t[0])) for value in out_wall_dict: '''instantiate OuterWall class''' out_wall = OuterWall(parent = tz) out_wall.name = value[0] out_wall.year_of_construction = value[1][0] out_wall.construction_type = value[1][1] out_wall.area = value[1][2] out_wall.tilt = value[1][3] out_wall.orientation = value[1][4] out_wall.building_age_group = [1994, 1998] out_wall.inner_radiation = 5.0 out_wall.inner_convection = 2.7 out_wall.outer_radiation = 5.0 out_wall.outer_convection = 20.0 out_wall_layer1 = Layer(out_wall) out_wall_layer1.id = 1 out_wall_layer1.thickness = 5.0 out_wall_material = Material(out_wall_layer1) out_wall_material.name = "material1" out_wall_material.density = 5.0 out_wall_material.thermal_conduc = 4.0 out_wall_material.heat_capac = 0.48 out_wall_material.transmittance = 0.0 out_wall_layer2 = Layer(out_wall) out_wall_layer2.id = 2 out_wall_layer2.thickness = 2.0 out_wall_material = Material(out_wall_layer2) out_wall_material.name = "material" out_wall_material.density = 2.0 out_wall_material.thermal_conduc = 2.0 out_wall_material.heat_capac = 0.84 out_wall_material.transmittance = 0.0 in_wall_dict = [["Inner Wall 1", [bldg.year_of_construction, 'light', 10.0]], ["Inner Wall 2", [bldg.year_of_construction, 'heavy', 14.0]], ["Inner Wall 3", [bldg.year_of_construction, 'light', 10.0]]] for value in in_wall_dict: '''instantiate OuterWall class''' in_wall = InnerWall(parent = tz) in_wall.name = value[0] in_wall.year_of_construction = value[1][0] in_wall.construction_type = value[1][1] in_wall.area = value[1][2] in_wall.building_age_group = [1994, 1998] in_wall.inner_radiation = 5.0 in_wall.inner_convection = 2.7 in_wall_layer1 = Layer(in_wall) in_wall_layer1.id = 1 in_wall_layer1.thickness = 5.0 in_wall_material = Material(in_wall_layer1) in_wall_material.name = "material1" in_wall_material.density = 5.0 in_wall_material.thermal_conduc = 4.0 in_wall_material.heat_capac = 0.48 in_wall_layer2 = Layer(in_wall) in_wall_layer2.id = 2 in_wall_layer2.thickness = 2.0 in_wall_material = Material(in_wall_layer2) in_wall_material.name = "material" in_wall_material.density = 2.0 in_wall_material.thermal_conduc = 2.0 in_wall_material.heat_capac = 0.84 win_dict = [["Window 1", [bldg.year_of_construction, 5.0, 90.0, 90.0]], ["Window 2", [bldg.year_of_construction, 8.0, 90.0, 180.0]], ["Window 3", [bldg.year_of_construction, 5.0, 90.0, 270.0]]] for value in win_dict: win = Window(parent = tz) win.construction_type = "Window" win.name = value[0] win.area = value[1][1] win.tilt = value[1][2] win.orientation = value[1][3] win.building_age_group = [1994, 1998] win.inner_convection = 1.7 win.inner_radiation = 5.0 win.outer_convection = 20.0 win.outer_radiation = 5.0 win.g_value = 0.789 win.a_conv = 0.03 win.shading_g_total = 1.0 win.shading_max_irr = 180.0 win_layer = Layer(parent = win) win_layer.id = 1 win_layer.thickness = 0.024 win_material = Material(win_layer) win_material.name = "GlasWindow" win_material.thermal_conduc = 0.067 win_material.transmittance = 0.9 roof = Rooftop(parent = tz) roof.name = "Roof" roof.year_of_construction = bldg.year_of_construction roof.construction_type = "heavy" roof.area = 140.0 roof_layer1 = Layer(roof) roof_layer1.id = 1 roof_layer1.thickness = 5.0 roof_material = Material(roof_layer1) roof_material.name = "material1" roof_material.density = 5.0 roof_material.thermal_conduc = 4.0 roof_material.heat_capac = 0.48 roof_layer2 = Layer(roof) roof_layer2.id = 2 roof_layer2.thickness = 2.0 roof_material = Material(roof_layer2) roof_material.name = "material" roof_material.density = 2.0 roof_material.thermal_conduc = 2.0 roof_material.heat_capac = 0.84 ground = GroundFloor(parent = tz) ground.name = "ground" ground.year_of_construction = bldg.year_of_construction ground.construction_type = "heavy" ground.area = 140.0 ground_layer1 = Layer(ground) ground_layer1.id = 1 ground_layer1.thickness = 5.0 ground_material = Material(ground_layer1) ground_material.name = "material1" ground_material.density = 5.0 ground_material.thermal_conduc = 4.0 ground_material.heat_capac = 0.48 ground_layer2 = Layer(ground) ground_layer2.id = 2 ground_layer2.thickness = 2.0 ground_material = Material(ground_layer2) ground_material.name = "material" ground_material.density = 2.0 ground_material.thermal_conduc = 2.0 ground_material.heat_capac = 0.84 return bldg
def building_test2(prj): """ building which is hardcoded for testing """ bldg = Building(parent=prj) '''Set some building parameters''' bldg.name = "UnitTestBuilding" bldg.street_name = "Unit Street 42" bldg.city = "46325 Testing Town" bldg.year_of_construction = 1988 bldg.number_of_floors = 1 bldg.height_of_floors = 3.5 '''Instantiate a ThermalZone class, with building as parent and set some parameters of the thermal zone''' tz = ThermalZone(parent=bldg) tz.name = "Living Room" tz.area = 140.0 tz.volume = tz.area * bldg.number_of_floors * bldg.height_of_floors tz.infiltration_rate = 0.5 tz.use_conditions = BoundaryConditions(tz) tz.use_conditions.usage = "Living" tz.use_conditions.cooling_time = [5, 18] tz.use_conditions.heating_time = [5, 18] tz.use_conditions.set_temp_heat = 288.15 tz.use_conditions.set_temp_cool = 298.15 tz.use_conditions.temp_set_back = 4.0 tz.use_conditions.min_air_exchange = 0.0 tz.use_conditions.min_ahu = 0.0 tz.use_conditions.max_ahu = 2.6 tz.use_conditions.with_ahu = True tz.use_conditions.persons = 3 tz.use_conditions.machines = 3 tz.use_conditions.lighting_power = 3 tz.use_conditions.activity_type_machines = 2 tz.use_conditions.ratio_conv_rad_machines = 0.5 tz.use_conditions.profile_machines = [0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0, 0.2, 0.4, 0.6, 0.8, 0.8, 0.4, 0.6, 0.8, 0.8, 0.4, 0.2, 0.0, 0.0, 0.0, 0.0, 0.0, 0.0] tz.use_conditions.profile_persons = [0.1, 0.1, 0.1, 0.1, 0.1, 0.1, 0.1, 0.2, 0.4, 0.6, 0.8, 0.8, 0.4, 0.6, 0.8, 0.8, 0.4, 0.2, 0.1, 0.1, 0.1, 0.1, 0.1, 0.1] tz.use_conditions.profile_lighting = [0.1, 0.1, 0.1, 0.1, 0.1, 0.1, 0.1, 0.2, 0.4, 0.6, 0.8, 0.8, 0.4, 0.6, 0.8, 0.8, 0.4, 0.2, 0.1, 0.1, 0.1, 0.1, 0.1, 0.1] tz.use_conditions.use_constant_ach_rate = False tz.use_conditions.base_ach = 0.2 tz.use_conditions.max_user_ach = 1.0 tz.use_conditions.max_overheating_ach = [3.0, 2.0] tz.use_conditions.max_summer_ach = [1.0, 273.15 + 10, 273.15 + 17] tz.use_conditions.winter_reduction = [0.2, 273.15, 273.15 + 10] out_wall_dict = [["Outer Wall 1", [bldg.year_of_construction, 'heavy', 10.0, 90.0, 0.0]], ["Outer Wall 2", [bldg.year_of_construction, 'heavy', 14.0, 90.0, 90.0]], ["Outer Wall 3", [bldg.year_of_construction, 'heavy', 10.0, 90.0, 180.0]], ["Outer Wall 4", [bldg.year_of_construction, 'heavy', 14.0, 90.0, 270.0]]] #import collections #out_wall_dict = collections.OrderedDict(sorted(out_wall_dict.items(), key=lambda t: t[0])) for value in out_wall_dict: '''instantiate OuterWall class''' out_wall = OuterWall(parent=tz) out_wall.name = value[0] out_wall.year_of_construction = value[1][0] out_wall.construction_type = value[1][1] out_wall.area = value[1][2] out_wall.tilt = value[1][3] out_wall.orientation = value[1][4] out_wall.building_age_group = [1994, 1998] out_wall.inner_radiation = 5.0 out_wall.inner_convection = 2.7 out_wall.outer_radiation = 5.0 out_wall.outer_convection = 20.0 out_wall_layer1 = Layer(out_wall) out_wall_layer1.id = 1 out_wall_layer1.thickness = 5.0 out_wall_material = Material(out_wall_layer1) out_wall_material.name = "material1" out_wall_material.density = 5.0 out_wall_material.thermal_conduc = 4.0 out_wall_material.heat_capac = 0.48 out_wall_material.transmittance = 0.0 out_wall_layer2 = Layer(out_wall) out_wall_layer2.id = 2 out_wall_layer2.thickness = 2.0 out_wall_material = Material(out_wall_layer2) out_wall_material.name = "material" out_wall_material.density = 2.0 out_wall_material.thermal_conduc = 2.0 out_wall_material.heat_capac = 0.84 out_wall_material.transmittance = 0.0 in_wall_dict = [["Inner Wall 1", [bldg.year_of_construction, 'light', 10.0]], ["Inner Wall 2", [bldg.year_of_construction, 'heavy', 14.0]], ["Inner Wall 3", [bldg.year_of_construction, 'light', 10.0]]] for value in in_wall_dict: '''instantiate OuterWall class''' in_wall = InnerWall(parent=tz) in_wall.name = value[0] in_wall.year_of_construction = value[1][0] in_wall.construction_type = value[1][1] in_wall.area = value[1][2] in_wall.building_age_group = [1994, 1998] in_wall.inner_radiation = 5.0 in_wall.inner_convection = 2.7 in_wall_layer1 = Layer(in_wall) in_wall_layer1.id = 1 in_wall_layer1.thickness = 5.0 in_wall_material = Material(in_wall_layer1) in_wall_material.name = "material1" in_wall_material.density = 5.0 in_wall_material.thermal_conduc = 4.0 in_wall_material.heat_capac = 0.48 in_wall_layer2 = Layer(in_wall) in_wall_layer2.id = 2 in_wall_layer2.thickness = 2.0 in_wall_material = Material(in_wall_layer2) in_wall_material.name = "material" in_wall_material.density = 2.0 in_wall_material.thermal_conduc = 2.0 in_wall_material.heat_capac = 0.84 win_dict = [["Window 1", [bldg.year_of_construction, 5.0, 90.0, 90.0]], ["Window 2", [bldg.year_of_construction, 8.0, 90.0, 180.0]], ["Window 3", [bldg.year_of_construction, 5.0, 90.0, 270.0]]] for value in win_dict: win = Window(parent=tz) win.construction_type = "Window" win.name = value[0] win.area = value[1][1] win.tilt = value[1][2] win.orientation = value[1][3] win.building_age_group = [1994, 1998] win.inner_convection = 1.7 win.inner_radiation = 5.0 win.outer_convection = 20.0 win.outer_radiation = 5.0 win.g_value = 0.789 win.a_conv = 0.03 win.shading_g_total = 1.0 win.shading_max_irr = 180.0 win_layer = Layer(parent=win) win_layer.id = 1 win_layer.thickness = 0.024 win_material = Material(win_layer) win_material.name = "GlasWindow" win_material.thermal_conduc = 0.067 win_material.transmittance = 0.9 roof = Rooftop(parent=tz) roof.name = "Roof" roof.year_of_construction = bldg.year_of_construction roof.construction_type = "heavy" roof.area = 140.0 roof_layer1 = Layer(roof) roof_layer1.id = 1 roof_layer1.thickness = 5.0 roof_material = Material(roof_layer1) roof_material.name = "material1" roof_material.density = 5.0 roof_material.thermal_conduc = 4.0 roof_material.heat_capac = 0.48 roof_layer2 = Layer(roof) roof_layer2.id = 2 roof_layer2.thickness = 2.0 roof_material = Material(roof_layer2) roof_material.name = "material" roof_material.density = 2.0 roof_material.thermal_conduc = 2.0 roof_material.heat_capac = 0.84 ground = GroundFloor(parent=tz) ground.name = "ground" ground.year_of_construction = bldg.year_of_construction ground.construction_type = "heavy" ground.area = 140.0 ground_layer1 = Layer(ground) ground_layer1.id = 1 ground_layer1.thickness = 5.0 ground_material = Material(ground_layer1) ground_material.name = "material1" ground_material.density = 5.0 ground_material.thermal_conduc = 4.0 ground_material.heat_capac = 0.48 ground_layer2 = Layer(ground) ground_layer2.id = 2 ground_layer2.thickness = 2.0 ground_material = Material(ground_layer2) ground_material.name = "material" ground_material.density = 2.0 ground_material.thermal_conduc = 2.0 ground_material.heat_capac = 0.84 return bldg
def _load_building(prj, pyxb_bld, type, project_bind): if type == "Building": bldg = Building(prj) elif type == "Office": bldg = Office(prj) elif type == "Institute": bldg = Institute(prj) elif type == "Institute4": bldg = Institute4(prj) elif type == "Institute8": bldg = Institute8(prj) elif type == "Residential": bldg = SingleFamilyDwelling(prj) bldg.name = pyxb_bld.name bldg.street_name = pyxb_bld.street_name bldg.city = pyxb_bld.city bldg.type_of_building = pyxb_bld.type_of_building bldg.year_of_construction = pyxb_bld.year_of_construction bldg.year_of_retrofit = pyxb_bld.year_of_retrofit bldg.number_of_floors = pyxb_bld.number_of_floors bldg.height_of_floors = pyxb_bld.height_of_floors if not pyxb_bld.ThermalZone: bldg.net_leased_area = pyxb_bld.net_leased_area if pyxb_bld.CentralAHU: pyxb_ahu = pyxb_bld.CentralAHU bldg.central_ahu = BuildingAHU(bldg) bldg.central_ahu.heating = pyxb_ahu.heating bldg.central_ahu.cooling = pyxb_ahu.cooling bldg.central_ahu.dehumidification = pyxb_ahu.dehumidification bldg.central_ahu.humidification = pyxb_ahu.humidification bldg.central_ahu.heat_recovery = pyxb_ahu.heat_recovery bldg.central_ahu.by_pass_dehumidification = \ pyxb_ahu.by_pass_dehumidification bldg.central_ahu.efficiency_recovery = pyxb_ahu.efficiency_recovery try: if float(project_bind.version) >= 0.5: bldg.central_ahu.efficiency_recovery_false = \ pyxb_ahu.efficiency_recovery_false else: bldg.central_ahu.efficiency_recovery_false = \ pyxb_ahu.efficiency_revocery_false except AttributeError: bldg.central_ahu.efficiency_recovery_false = \ pyxb_ahu.efficiency_revocery_false bldg.central_ahu.profile_min_relative_humidity = \ pyxb_ahu.profile_min_relative_humidity bldg.central_ahu.profile_max_relative_humidity = \ pyxb_ahu.profile_max_relative_humidity bldg.central_ahu.profile_v_flow = \ pyxb_ahu.profile_v_flow bldg.central_ahu.profile_temperature = \ pyxb_ahu.profile_temperature for pyxb_zone in pyxb_bld.ThermalZone: zone = ThermalZone(bldg) zone.name = pyxb_zone.name zone.area = pyxb_zone.area zone.volume = pyxb_zone.volume zone.infiltration_rate = pyxb_zone.infiltration_rate zone.use_conditions = BoundaryConditions(zone) pyxb_use = pyxb_zone.UseCondition.BoundaryConditions zone.use_conditions.typical_length = pyxb_zone.typical_length zone.use_conditions.typical_width = pyxb_zone.typical_width zone.use_conditions.usage = \ pyxb_use.usage zone.use_conditions.usage_time = \ pyxb_use.UsageOperationTime.usage_time zone.use_conditions.daily_usage_hours = \ pyxb_use.UsageOperationTime.daily_usage_hours zone.use_conditions.yearly_usage_days = \ pyxb_use.UsageOperationTime.yearly_usage_days zone.use_conditions.yearly_usage_hours_day = \ pyxb_use.UsageOperationTime.yearly_usage_hours_day zone.use_conditions.yearly_usage_hours_night = \ pyxb_use.UsageOperationTime.yearly_usage_hours_night zone.use_conditions.daily_operation_ahu_cooling = \ pyxb_use.UsageOperationTime.daily_operation_ahu_cooling zone.use_conditions.yearly_heating_days = \ pyxb_use.UsageOperationTime.yearly_heating_days zone.use_conditions.yearly_ahu_days = \ pyxb_use.UsageOperationTime.yearly_ahu_days zone.use_conditions.yearly_cooling_days = \ pyxb_use.UsageOperationTime.yearly_cooling_days zone.use_conditions.daily_operation_heating = \ pyxb_use.UsageOperationTime.daily_operation_heating try: if float(project_bind.version) >= 0.4: zone.use_conditions.maintained_illuminance = \ pyxb_use.Lighting.maintained_illuminance else: zone.use_conditions.maintained_illuminance = \ pyxb_use.Lighting.maintained_illuminace except AttributeError: zone.use_conditions.maintained_illuminance = \ pyxb_use.Lighting.maintained_illuminace zone.use_conditions.usage_level_height = \ pyxb_use.Lighting.usage_level_height zone.use_conditions.red_factor_visual = \ pyxb_use.Lighting.red_factor_visual zone.use_conditions.rel_absence = \ pyxb_use.Lighting.rel_absence zone.use_conditions.room_index = \ pyxb_use.Lighting.room_index zone.use_conditions.part_load_factor_lighting = \ pyxb_use.Lighting.part_load_factor_lighting zone.use_conditions.ratio_conv_rad_lighting = \ pyxb_use.Lighting.ratio_conv_rad_lighting zone.use_conditions.set_temp_heat = \ pyxb_use.RoomClimate.set_temp_heat zone.use_conditions.set_temp_cool = \ pyxb_use.RoomClimate.set_temp_cool zone.use_conditions.temp_set_back = \ pyxb_use.RoomClimate.temp_set_back zone.use_conditions.min_temp_heat = \ pyxb_use.RoomClimate.min_temp_heat zone.use_conditions.max_temp_cool = \ pyxb_use.RoomClimate.max_temp_cool zone.use_conditions.rel_humidity = \ pyxb_use.RoomClimate.rel_humidity zone.use_conditions.cooling_time = \ pyxb_use.RoomClimate.cooling_time zone.use_conditions.heating_time = \ pyxb_use.RoomClimate.heating_time zone.use_conditions.min_air_exchange = \ pyxb_use.RoomClimate.min_air_exchange zone.use_conditions.rel_absence_ahu = \ pyxb_use.RoomClimate.rel_absence_ahu zone.use_conditions.part_load_factor_ahu = \ pyxb_use.RoomClimate.part_load_factor_ahu zone.use_conditions.persons = \ pyxb_use.InternalGains.persons zone.use_conditions.profile_persons = \ pyxb_use.InternalGains.profile_persons zone.use_conditions.machines = \ pyxb_use.InternalGains.machines zone.use_conditions.profile_machines = \ pyxb_use.InternalGains.profile_machines zone.use_conditions.lighting_power = \ pyxb_use.InternalGains.lighting_power zone.use_conditions.profile_lighting = \ pyxb_use.InternalGains.profile_lighting zone.use_conditions.min_ahu = \ pyxb_use.AHU.min_ahu zone.use_conditions.max_ahu = \ pyxb_use.AHU.max_ahu zone.use_conditions.with_ahu = \ pyxb_use.AHU.with_ahu zone.use_constant_ach_rate = \ pyxb_use.AHU.use_constant_ach_rate zone.base_ach = \ pyxb_use.AHU.base_ach zone.max_user_ach = \ pyxb_use.AHU.max_user_ach zone.max_overheating_ach = \ pyxb_use.AHU.max_overheating_ach zone.max_summer_ach = \ pyxb_use.AHU.max_summer_ach zone.winter_reduction = \ pyxb_use.AHU.winter_reduction for pyxb_wall in pyxb_zone.OuterWall: out_wall = OuterWall(zone) set_basic_data_teaser(pyxb_wall, out_wall) set_layer_data_teaser(pyxb_wall, out_wall) try: if float(project_bind.version) >= 0.6: for pyxb_wall in pyxb_zone.Door: out_wall = Door(zone) set_basic_data_teaser(pyxb_wall, out_wall) set_layer_data_teaser(pyxb_wall, out_wall) except AttributeError: pass for pyxb_wall in pyxb_zone.Rooftop: roof = Rooftop(zone) set_basic_data_teaser(pyxb_wall, roof) set_layer_data_teaser(pyxb_wall, roof) # zone.outer_walls.append(roof) for pyxb_wall in pyxb_zone.GroundFloor: gr_floor = GroundFloor(zone) set_basic_data_teaser(pyxb_wall, gr_floor) set_layer_data_teaser(pyxb_wall, gr_floor) # zone.outer_walls.append(gr_floor) for pyxb_wall in pyxb_zone.InnerWall: in_wall = InnerWall(zone) set_basic_data_teaser(pyxb_wall, in_wall) set_layer_data_teaser(pyxb_wall, in_wall) # zone.inner_walls.append(in_wall) for pyxb_wall in pyxb_zone.Ceiling: ceiling = Ceiling(zone) set_basic_data_teaser(pyxb_wall, ceiling) set_layer_data_teaser(pyxb_wall, ceiling) # zone.inner_walls.append(ceiling) for pyxb_wall in pyxb_zone.Floor: floor = Floor(zone) set_basic_data_teaser(pyxb_wall, floor) set_layer_data_teaser(pyxb_wall, floor) # zone.inner_walls.append(floor) for pyxb_win in pyxb_zone.Window: win = Window(zone) set_basic_data_teaser(pyxb_win, win) set_layer_data_teaser(pyxb_win, win)
def example_create_building(): ''' Instantiate a Project class (with load_data set to true), instantiate a Building class, with the project as a parent. This automatically adds the specific building and all its future changes to the project. ''' prj = Project(load_data=True) bldg = Building(parent=prj) '''Set some building parameters''' bldg.name = "SuperExampleBuilding" bldg.street_name = "Awesome Avenue 42" bldg.city = "46325 Fantastic Town" bldg.year_of_construction = 1988 bldg.number_of_floors = 1 bldg.height_of_floors = 3.5 '''Instantiate a ThermalZone class, with building as parent and set some parameters of the thermal zone''' tz = ThermalZone(parent=bldg) tz.name = "Living Room" tz.area = 140.0 tz.volume = tz.area * bldg.number_of_floors * bldg.height_of_floors tz.infiltration_rate = 0.5 '''Instantiate UseConditions18599 class with thermal zone as parent, and load the use conditions for the usage 'Living' ''' tz.use_conditions = BoundaryConditions(parent=tz) tz.use_conditions.load_use_conditions("Living") '''Define two elements representing a pitched roof and define Layers and Materials explicitly''' roof_south = Rooftop(parent=tz) roof_south.name = "Roof_South" roof_north = Rooftop(parent=tz) roof_north.name = "Roof_North" '''Set area, orientation and tilt of South Roof''' roof_south.area = 75.0 roof_south.orientation = 180.0 roof_south.tilt = 55.0 '''Set coefficient of heat transfer''' roof_south.inner_convection = 1.7 roof_south.outer_convection = 5.0 roof_south.inner_radiation = 20.0 roof_south.outer_radiation = 5.0 '''Set layer and material''' layer_1s = Layer(parent=roof_south, id=0) # id indicates the order of # layer from inside to outside layer_1s.thickness = 0.15 material_1_2 = Material(layer_1s) material_1_2.name = "Insulation" material_1_2.density = 120.0 material_1_2.heat_capac = 0.04 material_1_2.thermal_conduc = 1.0 layer_2s = Layer(parent=roof_south, id=1) layer_2s.thickness = 0.15 material_1_1 = Material(layer_2s) material_1_1.name = "Tile" material_1_1.density = 1400.0 material_1_1.heat_capac = 0.6 material_1_1.thermal_conduc = 2.5 '''Set area, orientation and tilt of North Roof''' roof_north.area = 75.0 roof_north.orientation = 0.0 roof_north.tilt = 55.0 '''Set coefficient of heat transfer''' roof_north.inner_convection = 1.7 roof_north.outer_convection = 5.0 roof_north.inner_radiation = 20.0 roof_north.outer_radiation = 5.0 '''Set layer and material''' layer_1n = Layer(parent=roof_north, id=0) layer_1n.thickness = 0.15 material_1_2 = Material(layer_1n) material_1_2.name = "Insulation" material_1_2.density = 120.0 material_1_2.heat_capac = 0.04 material_1_2.thermal_conduc = 1.0 layer_2n = Layer(parent=roof_north, id=1) layer_2n.thickness = 0.15 layer_2n.position = 1 material_1_1 = Material(layer_2n) material_1_1.name = "Tile" material_1_1.density = 1400.0 material_1_1.heat_capac = 0.6 material_1_1.thermal_conduc = 2.5 '''We save information of the Outer and Inner walls as well as Windows in dicts, the key is the name, while the value is a list (if applicable) [year of construciton, construction type, area, tilt, orientation] ''' out_wall_dict = {"Outer Wall 1": [bldg.year_of_construction, 'heavy', 10.0, 90.0, 0.0], "Outer Wall 2": [bldg.year_of_construction, 'heavy', 14.0, 90.0, 90.0], "Outer Wall 3": [bldg.year_of_construction, 'heavy', 10.0, 90.0, 180.0], "Outer Wall 4": [bldg.year_of_construction, 'heavy', 14.0, 90.0, 270.0]} in_wall_dict = {"Inner Wall 1": [bldg.year_of_construction, 'light', 10.0], "Inner Wall 2": [bldg.year_of_construction, 'heavy', 14.0], "Inner Wall 3": [bldg.year_of_construction, 'light', 10.0]} win_dict = {"Window 1": [bldg.year_of_construction, 5.0, 90.0, 90.0], "Window 2": [bldg.year_of_construction, 8.0, 90.0, 180.0], "Window 3": [bldg.year_of_construction, 5.0, 90.0, 270.0]} for key, value in out_wall_dict.items(): '''instantiate OuterWall class''' out_wall = OuterWall(parent = tz) out_wall.name = key '''load typical construction, based on year of construction and construction type''' out_wall.load_type_element(year=value[0], construction=value[1]) out_wall.area = value[2] out_wall.tilt = value[3] out_wall.orientation = value[4] for key, value in in_wall_dict.items(): '''instantiate InnerWall class''' in_wall = InnerWall(parent = tz) in_wall.name = key '''load typical construction, based on year of construction and construction type''' in_wall.load_type_element(year=value[0], construction=value[1]) in_wall.area = value[2] for key, value in win_dict.items(): '''instantiate Window class''' win = Window(parent = tz) win.name = key win.area = value[1] win.tilt = value[2] win.orientation = value[3] ''' We know the exact properties of the window, thus we set them instead of loading a typical construction ''' win.inner_convection = 1.7 win.inner_radiation = 5.0 win.outer_convection = 20.0 win.outer_radiation = 5.0 win.g_value = 0.789 win.a_conv = 0.03 win.shading_g_total = 1.0 win.shading_max_irr = 180.0 '''Instantiate a Layer class, with window as parent, set attributes''' win_layer = Layer(parent = win) win_layer.id = 1 win_layer.thickness = 0.024 '''Instantiate a Material class, with window layer as parent, set attributes''' win_material = Material(win_layer) win_material.name = "GlasWindow" win_material.thermal_conduc = 0.067 win_material.transmittance = 0.9 '''For a GroundFloor we are using the load_type_element function, which needs the year of construction and the construction type ('heavy' or 'light') ''' ground = GroundFloor(parent=tz) ground.name = "Ground floor" ground.load_type_element(bldg.year_of_construction, 'heavy') ground.area = 140.0 ''' We calculate the RC Values according to AixLib procedure ''' prj.used_library_calc = 'AixLib' prj.number_of_elements_calc = 2 prj.merge_windows_calc = False prj.calc_all_buildings() ''' Export the Modelica Record ''' prj.export_aixlib(building_model="MultizoneEquipped", zone_model="ThermalZoneEquipped", corG=True, internal_id=None, path=None) '''Or we use Annex60 method with for elements''' #prj.calc_all_buildings(number_of_elements=4, # merge_windows=False, # used_library='Annex60') #prj.export_annex() ''' Save new TEASER XML and cityGML ''' prj.save_project("ExampleProject") prj.save_citygml("ExampleCityGML")
def example_create_building(): """"This function demonstrates generating a building adding all information separately""" # First step: Import the TEASER API (called Project) into your Python module from teaser.project import Project # To use the API instantiate the Project class and rename the Project. The # parameter load_data=True indicates that we load data into our # Project (e.g. for Material properties and typical wall constructions. # This can take a few seconds, depending on the size of the used data base. prj = Project(load_data=True) prj.name = "BuildingExample" # Instantiate a Building class and set the Project API as a parent to # this building. This will automatically add this building and all its # future changes to the project. This is helpful as we can use the data # base and API functions (like explained in e2 - e5). We also set some # building parameters. Be careful: Dymola does not like whitespaces in # names and filenames, thus we will delete them anyway in TEASER. from teaser.logic.buildingobjects.building import Building bldg = Building(parent=prj) bldg.name = "SuperExampleBuilding" bldg.street_name = "AwesomeAvenue42" bldg.city = "46325FantasticTown" bldg.year_of_construction = 2015 bldg.number_of_floors = 1 bldg.height_of_floors = 3.5 # Instantiate a ThermalZone class and set the Building as a parent of it. # Set some parameters of the thermal zone. Be careful: Dymola does not # like whitespaces in names and filenames, thus we will delete them # anyway in TEASER. from teaser.logic.buildingobjects.thermalzone import ThermalZone tz = ThermalZone(parent=bldg) tz.name = "LivingRoom" tz.area = 140.0 tz.volume = tz.area * bldg.number_of_floors * bldg.height_of_floors tz.infiltration_rate = 0.5 # Instantiate BoundaryConditions and load conditions for `Living`. from teaser.logic.buildingobjects.boundaryconditions.boundaryconditions \ import BoundaryConditions tz.use_conditions = BoundaryConditions(parent=tz) tz.use_conditions.load_use_conditions("Living", prj.data) # Define two building elements reflecting a pitched roof (south = 180° and # north = 0°). Setting the the ThermalZone as a parent will automatically # assign this element to the thermal zone. We also set names, tilt and # coefficients for heat transfer on the inner and outer side of the # roofs. If the building has a flat roof, please use -1 as # orientation. Please read the docs to get more information on these # parameters. from teaser.logic.buildingobjects.buildingphysics.rooftop import Rooftop roof_south = Rooftop(parent=tz) roof_south.name = "Roof_South" roof_south.area = 75.0 roof_south.orientation = 180.0 roof_south.tilt = 55.0 roof_south.inner_convection = 1.7 roof_south.outer_convection = 20.0 roof_south.inner_radiation = 5.0 roof_south.outer_radiation = 5.0 roof_north = Rooftop(parent=tz) roof_north.name = "Roof_North" roof_north.area = 75.0 roof_north.orientation = 0.0 roof_north.tilt = 55.0 roof_north.inner_convection = 1.7 roof_north.outer_convection = 20.0 roof_north.inner_radiation = 5.0 roof_north.outer_radiation = 5.0 # To define the wall constructions we need to instantiate Layer and # Material objects and set attributes. id indicates the order of wall # construction from inside to outside (so 0 is on the inner surface). You # need to set this value! from teaser.logic.buildingobjects.buildingphysics.layer import Layer # First layer south layer_s1 = Layer(parent=roof_south, id=0) layer_s1.thickness = 0.3 from teaser.logic.buildingobjects.buildingphysics.material import Material material_s1 = Material(layer_s1) material_s1.name = "Insulation" material_s1.density = 120.0 material_s1.heat_capac = 0.04 material_s1.thermal_conduc = 1.0 # Second layer south layer_s2 = Layer(parent=roof_south, id=1) layer_s2.thickness = 0.15 material_s2 = Material(layer_s2) material_s2.name = "Tile" material_s2.density = 1400.0 material_s2.heat_capac = 0.6 material_s2.thermal_conduc = 2.5 # First layer north layer_n1 = Layer(parent=roof_north, id=0) layer_n1.thickness = 0.3 from teaser.logic.buildingobjects.buildingphysics.material import Material material_n1 = Material(layer_n1) material_n1.name = "Insulation" material_n1.density = 120.0 material_n1.heat_capac = 0.04 material_n1.thermal_conduc = 1.0 # Second layer north layer_n2 = Layer(parent=roof_north, id=1) layer_n2.thickness = 0.15 material_n2 = Material(layer_n2) material_n2.name = "Tile" material_n2.density = 1400.0 material_n2.heat_capac = 0.6 material_n2.thermal_conduc = 2.5 # Another option is to use the database for typical wall constructions, # but set area, tilt, orientation individually. To simplify code, # we save individual information for exterior walls, interior walls into # dictionaries. # outer walls # {'name_of_wall': [area, tilt, orientation]} # interior walls # {'name_of_wall': [area, tilt, orientation]} from teaser.logic.buildingobjects.buildingphysics.outerwall import OuterWall out_wall_dict = {"OuterWall_north": [10.0, 90.0, 0.0], "OuterWall_east": [14.0, 90.0, 90.0], "OuterWall_south": [10.0, 90.0, 180.0], "OuterWall_west": [14.0, 90.0, 270.0]} # For ground floors the orientation is always -2 ground_floor_dict = {"GroundFloor": [100.0, 0.0, -2]} from teaser.logic.buildingobjects.buildingphysics.innerwall import InnerWall in_wall_dict = {"InnerWall1": [10.0], "InnerWall2": [14.0], "InnerWall3": [10.0]} for key, value in out_wall_dict.items(): # Instantiate class, key is the name out_wall = OuterWall(parent=tz) out_wall.name = key # Use load_type_element() function of the building element, and pass # over the year of construction of the building and the type of # construction (in this case `heavy`). out_wall.load_type_element( year=bldg.year_of_construction, construction='heavy') # area, tilt and orientation need to be set individually. out_wall.area = value[0] out_wall.tilt = value[1] out_wall.orientation = value[2] # Repeat the procedure for inner walls and ground floors for key, value in in_wall_dict.items(): in_wall = InnerWall(parent=tz) in_wall.name = key in_wall.load_type_element( year=bldg.year_of_construction, construction='heavy') in_wall.area = value[0] from teaser.logic.buildingobjects.buildingphysics.groundfloor import \ GroundFloor for key, value in ground_floor_dict.items(): ground = GroundFloor(parent=tz) ground.name = key ground.load_type_element( year=bldg.year_of_construction, construction='heavy') ground.area = value[0] ground.tilt = value[1] ground.orientation = value[2] from teaser.logic.buildingobjects.buildingphysics.window import Window win_dict = {"Window_east": [5.0, 90.0, 90.0], "Window_south": [8.0, 90.0, 180.0], "Window_west": [5.0, 90.0, 270.0]} for key, value in win_dict.items(): win = Window(parent=tz) win.name = key win.area = value[0] win.tilt = value[1] win.orientation = value[2] # Additional to the already known attributes the window has # additional attributes. Window.g_value describes the solar gain # through windows, a_conv the convective heat transmission due to # absorption of the window on the inner side. shading_g_total and # shading_max_irr refers to the shading (solar gain reduction of the # shading and shading_max_irr the threshold of irradiance to # automatically apply shading). win.inner_convection = 1.7 win.inner_radiation = 5.0 win.outer_convection = 20.0 win.outer_radiation = 5.0 win.g_value = 0.789 win.a_conv = 0.03 win.shading_g_total = 0.0 win.shading_max_irr = 180.0 # One equivalent layer for windows win_layer = Layer(parent=win) win_layer.id = 1 win_layer.thickness = 0.024 # Material for glass win_material = Material(win_layer) win_material.name = "GlasWindow" win_material.thermal_conduc = 0.067 win_material.transmittance = 0.9
def example_create_building(): ''' Instantiate a Project class (with load_data set to true), instantiate a Building class, with the project as a parent. This automatically adds the specific building and all its future changes to the project. ''' prj = Project(load_data = True) bldg = Building(parent = prj) '''Set some building parameters''' bldg.name = "SuperExampleBuilding" bldg.street_name = "Awesome Avenue 42" bldg.city = "46325 Fantastic Town" bldg.year_of_construction = 1988 bldg.number_of_floors = 1 bldg.height_of_floors = 3.5 '''Instantiate a ThermalZone class, with building as parent and set some parameters of the thermal zone''' tz = ThermalZone(parent = bldg) tz.name = "Living Room" tz.area = 140.0 tz.volume = tz.area * bldg.number_of_floors * bldg.height_of_floors tz.infiltration_rate = 0.5 '''Instantiate UseConditions18599 class with thermal zone as parent, and load the use conditions for the usage 'Living' ''' tz.use_conditions = BoundaryConditions(parent = tz) tz.use_conditions.load_use_conditions("Living") '''We save information of the Outer and Inner walls as well as Windows in dicts, the key is the name, while the value is a list (if applicable) [year of construciton, construction type, area, tilt, orientation]''' out_wall_dict = {"Outer Wall 1": [bldg.year_of_construction, 'heavy', 10.0, 90.0, 0.0], "Outer Wall 2": [bldg.year_of_construction, 'heavy', 14.0, 90.0, 90.0], "Outer Wall 3": [bldg.year_of_construction, 'heavy', 10.0, 90.0, 180.0], "Outer Wall 4": [bldg.year_of_construction, 'heavy', 14.0, 90.0, 270.0]} in_wall_dict = {"Inner Wall 1": [bldg.year_of_construction, 'light', 10.0], "Inner Wall 2": [bldg.year_of_construction, 'heavy', 14.0], "Inner Wall 3": [bldg.year_of_construction, 'light', 10.0]} win_dict = {"Window 1": [bldg.year_of_construction, 5.0, 90.0, 90.0], "Window 2": [bldg.year_of_construction, 8.0, 90.0, 180.0], "Window 3": [bldg.year_of_construction, 5.0, 90.0, 270.0]} for key, value in out_wall_dict.items(): '''instantiate OuterWall class''' out_wall = OuterWall(parent = tz) out_wall.name = key '''load typical construction, based on year of construction and construction type''' out_wall.load_type_element(year = value[0], construction = value[1]) out_wall.area = value[2] out_wall.tilt = value[3] out_wall.orientation = value[4] for key, value in in_wall_dict.items(): '''instantiate InnerWall class''' in_wall = InnerWall(parent = tz) in_wall.name = key '''load typical construction, based on year of construction and construction type''' in_wall.load_type_element(year = value[0], construction = value[1]) in_wall.area = value[2] for key, value in win_dict.items(): '''instantiate Window class''' win = Window(parent = tz) win.name = key win.area = value[1] win.tilt = value[2] win.orientation = value[3] ''' We know the exact properties of the window, thus we set them instead of loading a typical construction ''' win.inner_convection = 1.7 win.inner_radiation = 5.0 win.outer_convection = 20.0 win.outer_radiation = 5.0 win.g_value = 0.789 win.a_conv = 0.03 win.shading_g_total = 1.0 win.shading_max_irr = 180.0 '''Instantiate a Layer class, with window as parent, set attributes''' win_layer = Layer(parent = win) win_layer.id = 1 win_layer.thickness = 0.024 '''Instantiate a Material class, with window layer as parent, set attributes''' win_material = Material(win_layer) win_material.name = "GlasWindow" win_material.thermal_conduc = 0.067 win_material.transmittance = 0.9 '''Define a Rooftop and a Groundfloor, we don't need to set tilt and orientation because we take the default values''' roof = Rooftop(parent = tz) roof.name = "Roof" roof.load_type_element(bldg.year_of_construction, 'heavy') roof.area = 140.0 ground = GroundFloor(parent = tz) ground.name = "Ground floor" ground.load_type_element(bldg.year_of_construction, 'heavy') ground.area = 140.0 ''' We calculate the RC Values according to AixLib procedure ''' prj.used_library_calc = 'AixLib' prj.number_of_elements_calc = 2 prj.merge_windows_calc = False prj.calc_all_buildings() ''' Export the Modelica Record ''' prj.export_aixlib(building_model="MultizoneEquipped", zone_model="ThermalZoneEquipped", corG=True, internal_id=None, path=None) '''Or we use Annex60 method with for elements''' #prj.calc_all_buildings(number_of_elements=4, # merge_windows=False, # used_library='Annex60') #prj.export_annex() ''' Save new TEASER XML ''' prj.save_gml("ExampleProject") prj.save_citygml("Easypeasy")
def _load_building(prj, pyxb_bld, type): if type == "Building": bldg = Building(prj) elif type == "Office": bldg = Office(prj) elif type == "Institute": bldg = Institute(prj) elif type == "Institute4": bldg = Institute4(prj) elif type == "Institute8": bldg = Institute8(prj) elif type == "Residential": bldg = SingleFamilyDwelling(prj) bldg.name = pyxb_bld.name bldg.street_name = pyxb_bld.street_name bldg.city = pyxb_bld.city bldg.type_of_building = pyxb_bld.type_of_building bldg.year_of_construction = pyxb_bld.year_of_construction bldg.year_of_retrofit = pyxb_bld.year_of_retrofit bldg.number_of_floors = pyxb_bld.number_of_floors bldg.height_of_floors = pyxb_bld.height_of_floors if not pyxb_bld.ThermalZone: bldg.net_leased_area = pyxb_bld.net_leased_area if pyxb_bld.CentralAHU: pyxb_ahu = pyxb_bld.CentralAHU bldg.central_ahu = BuildingAHU(bldg) bldg.central_ahu.heating = pyxb_ahu.heating bldg.central_ahu.cooling = pyxb_ahu.cooling bldg.central_ahu.dehumidification = pyxb_ahu.dehumidification bldg.central_ahu.humidification = pyxb_ahu.humidification bldg.central_ahu.heat_recovery = pyxb_ahu.heat_recovery bldg.central_ahu.by_pass_dehumidification = \ pyxb_ahu.by_pass_dehumidification bldg.central_ahu.efficiency_recovery =pyxb_ahu.efficiency_recovery bldg.central_ahu.efficiency_revocery_false = \ pyxb_ahu.efficiency_revocery_false bldg.central_ahu.profile_min_relative_humidity = \ pyxb_ahu.profile_min_relative_humidity bldg.central_ahu.profile_max_relative_humidity = \ pyxb_ahu.profile_max_relative_humidity bldg.central_ahu.profile_v_flow = \ pyxb_ahu.profile_v_flow bldg.central_ahu.profile_temperature = \ pyxb_ahu.profile_temperature for pyxb_zone in pyxb_bld.ThermalZone: zone = ThermalZone(bldg) zone.name = pyxb_zone.name zone.area = pyxb_zone.area zone.volume = pyxb_zone.volume zone.infiltration_rate = pyxb_zone.infiltration_rate # zone.use_conditions.typical_length = pyxb_zone.typical_length # zone.use_conditions.typical_width = pyxb_zone.typical_width zone.use_conditions = BoundaryConditions(zone) pyxb_use = pyxb_zone.UseCondition.BoundaryConditions zone.use_conditions.usage = \ pyxb_use.usage zone.use_conditions.usage_time = \ pyxb_use.UsageOperationTime.usage_time zone.use_conditions.daily_usage_hours = \ pyxb_use.UsageOperationTime.daily_usage_hours zone.use_conditions.yearly_usage_days = \ pyxb_use.UsageOperationTime.yearly_usage_days zone.use_conditions.yearly_usage_hours_day = \ pyxb_use.UsageOperationTime.yearly_usage_hours_day zone.use_conditions.yearly_usage_hours_night = \ pyxb_use.UsageOperationTime.yearly_usage_hours_night zone.use_conditions.daily_operation_ahu_cooling = \ pyxb_use.UsageOperationTime.daily_operation_ahu_cooling zone.use_conditions.yearly_heating_days = \ pyxb_use.UsageOperationTime.yearly_heating_days zone.use_conditions.yearly_ahu_days = \ pyxb_use.UsageOperationTime.yearly_ahu_days zone.use_conditions.yearly_cooling_days = \ pyxb_use.UsageOperationTime.yearly_cooling_days zone.use_conditions.daily_operation_heating = \ pyxb_use.UsageOperationTime.daily_operation_heating zone.use_conditions.maintained_illuminace = \ pyxb_use.Lighting.maintained_illuminace zone.use_conditions.usage_level_height = \ pyxb_use.Lighting.usage_level_height zone.use_conditions.red_factor_visual = \ pyxb_use.Lighting.red_factor_visual zone.use_conditions.rel_absence = \ pyxb_use.Lighting.rel_absence zone.use_conditions.room_index = \ pyxb_use.Lighting.room_index zone.use_conditions.part_load_factor_lighting = \ pyxb_use.Lighting.part_load_factor_lighting zone.use_conditions.ratio_conv_rad_lighting = \ pyxb_use.Lighting.ratio_conv_rad_lighting zone.use_conditions.set_temp_heat = \ pyxb_use.RoomClimate.set_temp_heat zone.use_conditions.set_temp_cool = \ pyxb_use.RoomClimate.set_temp_cool zone.use_conditions.temp_set_back = \ pyxb_use.RoomClimate.temp_set_back zone.use_conditions.min_temp_heat = \ pyxb_use.RoomClimate.min_temp_heat zone.use_conditions.max_temp_cool = \ pyxb_use.RoomClimate.max_temp_cool zone.use_conditions.rel_humidity = \ pyxb_use.RoomClimate.rel_humidity zone.use_conditions.cooling_time = \ pyxb_use.RoomClimate.cooling_time zone.use_conditions.heating_time = \ pyxb_use.RoomClimate.heating_time zone.use_conditions.min_air_exchange = \ pyxb_use.RoomClimate.min_air_exchange zone.use_conditions.rel_absence_ahu = \ pyxb_use.RoomClimate.rel_absence_ahu zone.use_conditions.part_load_factor_ahu = \ pyxb_use.RoomClimate.part_load_factor_ahu zone.use_conditions.persons = \ pyxb_use.InternalGains.persons zone.use_conditions.profile_persons = \ pyxb_use.InternalGains.profile_persons zone.use_conditions.machines = \ pyxb_use.InternalGains.machines zone.use_conditions.profile_machines = \ pyxb_use.InternalGains.profile_machines zone.use_conditions.lighting_power = \ pyxb_use.InternalGains.lighting_power zone.use_conditions.profile_lighting = \ pyxb_use.InternalGains.profile_lighting zone.use_conditions.min_ahu = \ pyxb_use.AHU.min_ahu zone.use_conditions.max_ahu = \ pyxb_use.AHU.max_ahu zone.use_conditions.with_ahu = \ pyxb_use.AHU.with_ahu zone.use_constant_ach_rate = \ pyxb_use.AHU.use_constant_ach_rate zone.base_ach = \ pyxb_use.AHU.base_ach zone.max_user_ach = \ pyxb_use.AHU.max_user_ach zone.max_overheating_ach = \ pyxb_use.AHU.max_overheating_ach zone.max_summer_ach = \ pyxb_use.AHU.max_summer_ach zone.winter_reduction = \ pyxb_use.AHU.winter_reduction for pyxb_wall in pyxb_zone.OuterWall: out_wall = OuterWall(zone) set_basic_data_teaser(pyxb_wall, out_wall) set_layer_data_teaser(pyxb_wall, out_wall) # zone.outer_walls.append(out_wall) for pyxb_wall in pyxb_zone.Rooftop: roof = Rooftop(zone) set_basic_data_teaser(pyxb_wall, roof) set_layer_data_teaser(pyxb_wall, roof) # zone.outer_walls.append(roof) for pyxb_wall in pyxb_zone.GroundFloor: gr_floor = GroundFloor(zone) set_basic_data_teaser(pyxb_wall, gr_floor) set_layer_data_teaser(pyxb_wall, gr_floor) # zone.outer_walls.append(gr_floor) for pyxb_wall in pyxb_zone.InnerWall: in_wall = InnerWall(zone) set_basic_data_teaser(pyxb_wall, in_wall) set_layer_data_teaser(pyxb_wall, in_wall) # zone.inner_walls.append(in_wall) for pyxb_wall in pyxb_zone.Ceiling: ceiling = Ceiling(zone) set_basic_data_teaser(pyxb_wall, ceiling) set_layer_data_teaser(pyxb_wall, ceiling) # zone.inner_walls.append(ceiling) for pyxb_wall in pyxb_zone.Floor: floor = Floor(zone) set_basic_data_teaser(pyxb_wall, floor) set_layer_data_teaser(pyxb_wall, floor) # zone.inner_walls.append(floor) for pyxb_win in pyxb_zone.Window: win = Window(zone) set_basic_data_teaser(pyxb_win, win) set_layer_data_teaser(pyxb_win, win)