adding peak loads partial
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090b2251f1
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@ -44,6 +44,8 @@ class Building(CityObject):
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self._lighting_electrical_demand = dict()
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self._lighting_electrical_demand = dict()
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self._appliances_electrical_demand = dict()
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self._appliances_electrical_demand = dict()
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self._domestic_hot_water_heat_demand = dict()
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self._domestic_hot_water_heat_demand = dict()
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self._heating_peak_load = dict()
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self._cooling_peak_load = dict()
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self._eave_height = None
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self._eave_height = None
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self._grounds = []
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self._grounds = []
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self._roofs = []
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self._roofs = []
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@ -362,6 +364,38 @@ class Building(CityObject):
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"""
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"""
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self._domestic_hot_water_heat_demand = value
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self._domestic_hot_water_heat_demand = value
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@property
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def heating_peak_load(self) -> dict:
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"""
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Get heating peak load in W
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:return: dict{DataFrame(float)}
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"""
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return self._heating_peak_load
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@heating_peak_load.setter
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def heating_peak_load(self, value):
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"""
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Set heating peak load in W
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:param value: dict{DataFrame(float)}
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"""
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self._heating_peak_load = value
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@property
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def cooling_peak_load(self) -> dict:
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"""
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Get cooling peak load in W
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:return: dict{DataFrame(float)}
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"""
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return self._cooling_peak_load
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@cooling_peak_load.setter
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def cooling_peak_load(self, value):
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"""
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Set peak load in W
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:param value: dict{DataFrame(float)}
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"""
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self._cooling_peak_load = value
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@property
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@property
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def eave_height(self):
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def eave_height(self):
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"""
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"""
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@ -110,6 +110,14 @@ class CityObject:
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"""
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"""
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return self._surfaces
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return self._surfaces
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@surfaces.setter
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def surfaces(self, value):
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"""
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Set city object surfaces
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:return: [Surface]
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"""
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self._surfaces = value
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def surface(self, name) -> Union[Surface, None]:
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def surface(self, name) -> Union[Surface, None]:
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"""
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"""
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Get the city object surface with a given name
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Get the city object surface with a given name
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@ -184,6 +184,7 @@ MIN_FLOAT = float('-inf')
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# Tools
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# Tools
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SRA = 'sra'
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SRA = 'sra'
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INSEL_MEB = 'insel meb'
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INSEL_MEB = 'insel meb'
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PEAK_LOAD = 'peak load'
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# Costs units
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# Costs units
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CURRENCY_PER_SQM = 'currency/m2'
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CURRENCY_PER_SQM = 'currency/m2'
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@ -71,8 +71,11 @@ class Geojson:
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polygon = Polygon(points)
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polygon = Polygon(points)
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polygon.area = igh.ground_area(points)
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polygon.area = igh.ground_area(points)
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surface = Surface(polygon, polygon)
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surface = Surface(polygon, polygon)
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surfaces.append(surface)
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if len(buildings) == 1:
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buildings.append(Building(f'{name}_zone_{zone}', surfaces, year_of_construction, function))
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buildings[0].surfaces.append(surface)
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else:
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surfaces.append(surface)
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buildings.append(Building(f'{name}', surfaces, year_of_construction, function))
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return buildings
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return buildings
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@staticmethod
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@staticmethod
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@ -82,9 +85,10 @@ class Geojson:
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buildings = []
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buildings = []
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for zone, lod0_building in enumerate(lod0_buildings):
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for zone, lod0_building in enumerate(lod0_buildings):
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# print(zone, lod0_building.name)
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volume = 0
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for surface in lod0_building.grounds:
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for surface in lod0_building.grounds:
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volume = volume + surface.solid_polygon.area * height
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volume = surface.solid_polygon.area * height
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surfaces.append(surface)
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surfaces.append(surface)
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roof_coordinates = []
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roof_coordinates = []
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# adding a roof means invert the polygon coordinates and change the Z value
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# adding a roof means invert the polygon coordinates and change the Z value
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@ -112,10 +116,9 @@ class Geojson:
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polygon = Polygon(wall_coordinates)
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polygon = Polygon(wall_coordinates)
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wall = Surface(polygon, polygon)
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wall = Surface(polygon, polygon)
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surfaces.append(wall)
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surfaces.append(wall)
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building = Building(f'{name}', surfaces, year_of_construction, function)
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building = Building(f'{name}_zone_{zone}', surfaces, year_of_construction, function)
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building.volume = volume
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building.volume = volume
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buildings.append(building)
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buildings.append(building)
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return buildings
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return buildings
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@ -218,7 +221,7 @@ class Geojson:
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polygons = self._get_polygons(polygons, coordinates)
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polygons = self._get_polygons(polygons, coordinates)
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for polygon in polygons:
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for polygon in polygons:
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if extrusion_height == 0:
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if extrusion_height == 0:
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buildings = buildings + Geojson._create_buildings_lod0(f'{building_name}_part_{part}',
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buildings = buildings + Geojson._create_buildings_lod0(f'{building_name}',
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year_of_construction,
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year_of_construction,
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function,
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function,
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[polygon])
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[polygon])
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@ -226,11 +229,22 @@ class Geojson:
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else:
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else:
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if self._max_z < extrusion_height:
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if self._max_z < extrusion_height:
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self._max_z = extrusion_height
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self._max_z = extrusion_height
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buildings = buildings + Geojson._create_buildings_lod1(f'{building_name}_part_{part}',
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if part == 0:
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year_of_construction,
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buildings = buildings + Geojson._create_buildings_lod1(f'{building_name}',
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function,
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year_of_construction,
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extrusion_height,
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function,
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[polygon])
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extrusion_height,
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[polygon])
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else:
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new_part = Geojson._create_buildings_lod1(f'{building_name}',
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year_of_construction,
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function,
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extrusion_height,
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[polygon])
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surfaces = buildings[len(buildings) - 1].surfaces + new_part[0].surfaces
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volume = buildings[len(buildings) - 1].volume + new_part[0].volume
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buildings[len(buildings) - 1] = Building(f'{building_name}', surfaces, year_of_construction, function)
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buildings[len(buildings) - 1].volume = volume
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self._city = City([self._min_x, self._min_y, 0.0], [self._max_x, self._max_y, self._max_z], 'epsg:26911')
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self._city = City([self._min_x, self._min_y, 0.0], [self._max_x, self._max_y, self._max_z], 'epsg:26911')
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for building in buildings:
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for building in buildings:
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@ -107,6 +107,9 @@ class GeometryFactory:
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Enrich the city given to the class using the class given handler
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Enrich the city given to the class using the class given handler
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:return: City
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:return: City
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"""
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"""
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if self._data_frame is None:
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return Geojson(self._path,
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self._data_frame = geopandas.read_file(self._path)
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self._name_field,
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return GPandas(self._data_frame).city
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self._height_field,
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self._year_of_construction_field,
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self._function_field,
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self._function_to_hub).city
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@ -4,7 +4,6 @@ SPDX - License - Identifier: LGPL - 3.0 - or -later
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Copyright © 2022 Concordia CERC group
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Copyright © 2022 Concordia CERC group
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Project Coder Guillermo.GutierrezMorote@concordia.ca
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Project Coder Guillermo.GutierrezMorote@concordia.ca
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"""
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"""
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from pathlib import Path
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from pathlib import Path
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import pandas as pd
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import pandas as pd
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import csv
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import csv
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@ -40,60 +39,55 @@ class InselMonthlyEnergyBalance:
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monthly_cooling = pd.DataFrame(cooling, columns=[cte.INSEL_MEB]).astype(float)
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monthly_cooling = pd.DataFrame(cooling, columns=[cte.INSEL_MEB]).astype(float)
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return monthly_heating, monthly_cooling
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return monthly_heating, monthly_cooling
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def _dhw_demand(self):
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def _dhw_and_electric_demand(self):
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for building in self._city.buildings:
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for building in self._city.buildings:
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domestic_hot_water_demand = []
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domestic_hot_water_demand = []
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if building.internal_zones[0].thermal_zones is None:
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domestic_hot_water_demand = [0] * 12
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else:
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thermal_zone = building.internal_zones[0].thermal_zones[0]
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area = thermal_zone.total_floor_area
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cold_water = building.cold_water_temperature[cte.MONTH]['epw']
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for month in range(0, 12):
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total_dhw_demand = 0
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for schedule in thermal_zone.domestic_hot_water.schedules:
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total_day = 0
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for value in schedule.values:
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total_day += value
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for day_type in schedule.day_types:
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demand = thermal_zone.domestic_hot_water.peak_flow * cte.WATER_DENSITY * cte.WATER_HEAT_CAPACITY \
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* (thermal_zone.domestic_hot_water.service_temperature - cold_water[month])
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total_dhw_demand += total_day * cte.DAYS_A_MONTH[day_type][month] * demand
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domestic_hot_water_demand.append(total_dhw_demand * area)
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building.domestic_hot_water_heat_demand[cte.MONTH] = \
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pd.DataFrame(domestic_hot_water_demand, columns=[cte.INSEL_MEB])
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def _electrical_demand(self):
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for building in self._city.buildings:
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lighting_demand = []
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lighting_demand = []
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appliances_demand = []
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appliances_demand = []
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if building.internal_zones[0].thermal_zones is None:
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if building.internal_zones[0].thermal_zones is None:
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domestic_hot_water_demand = [0] * 12
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lighting_demand = [0] * 12
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lighting_demand = [0] * 12
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appliances_demand = [0] * 12
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appliances_demand = [0] * 12
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else:
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else:
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thermal_zone = building.internal_zones[0].thermal_zones[0]
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thermal_zone = building.internal_zones[0].thermal_zones[0]
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area = thermal_zone.total_floor_area
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area = thermal_zone.total_floor_area
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cold_water = building.cold_water_temperature[cte.MONTH]['epw']
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peak_flow = thermal_zone.domestic_hot_water.peak_flow
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service_temperature = thermal_zone.domestic_hot_water.service_temperature
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lighting_density = thermal_zone.lighting.density
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appliances_density = thermal_zone.appliances.density
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for month in range(0, 12):
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for month in range(0, 12):
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total_dhw_demand = 0
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total_lighting = 0
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total_lighting = 0
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total_appliances = 0
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for schedule in thermal_zone.lighting.schedules:
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for schedule in thermal_zone.lighting.schedules:
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total_day = 0
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total_day = 0
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for value in schedule.values:
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for value in schedule.values:
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total_day += value
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total_day += value
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for day_type in schedule.day_types:
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for day_type in schedule.day_types:
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total_lighting += total_day * cte.DAYS_A_MONTH[day_type][month] * thermal_zone.lighting.density
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total_lighting += total_day * cte.DAYS_A_MONTH[day_type][month] * lighting_density
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lighting_demand.append(total_lighting * area)
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lighting_demand.append(total_lighting * area)
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total_appliances = 0
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for schedule in thermal_zone.appliances.schedules:
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for schedule in thermal_zone.appliances.schedules:
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total_day = 0
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total_day = 0
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for value in schedule.values:
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for value in schedule.values:
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total_day += value
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total_day += value
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for day_type in schedule.day_types:
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for day_type in schedule.day_types:
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total_appliances += total_day * cte.DAYS_A_MONTH[day_type][month] * thermal_zone.appliances.density
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total_appliances += total_day * cte.DAYS_A_MONTH[day_type][month] * appliances_density
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appliances_demand.append(total_appliances * area)
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appliances_demand.append(total_appliances * area)
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for schedule in thermal_zone.domestic_hot_water.schedules:
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total_day = 0
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for value in schedule.values:
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total_day += value
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for day_type in schedule.day_types:
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demand = peak_flow * cte.WATER_DENSITY * cte.WATER_HEAT_CAPACITY * (service_temperature - cold_water[month])
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total_dhw_demand += total_day * cte.DAYS_A_MONTH[day_type][month] * demand
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domestic_hot_water_demand.append(total_dhw_demand * area)
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building.domestic_hot_water_heat_demand[cte.MONTH] = pd.DataFrame(domestic_hot_water_demand, columns=[cte.INSEL_MEB])
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building.lighting_electrical_demand[cte.MONTH] = pd.DataFrame(lighting_demand, columns=[cte.INSEL_MEB])
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building.lighting_electrical_demand[cte.MONTH] = pd.DataFrame(lighting_demand, columns=[cte.INSEL_MEB])
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building.appliances_electrical_demand[cte.MONTH] = pd.DataFrame(appliances_demand, columns=[cte.INSEL_MEB])
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building.appliances_electrical_demand[cte.MONTH] = pd.DataFrame(appliances_demand, columns=[cte.INSEL_MEB])
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@ -109,5 +103,4 @@ class InselMonthlyEnergyBalance:
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building.cooling[cte.YEAR] = pd.DataFrame(
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building.cooling[cte.YEAR] = pd.DataFrame(
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[building.cooling[cte.MONTH][cte.INSEL_MEB].astype(float).sum()], columns=[cte.INSEL_MEB]
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[building.cooling[cte.MONTH][cte.INSEL_MEB].astype(float).sum()], columns=[cte.INSEL_MEB]
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)
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)
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self._dhw_demand()
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self._dhw_and_electric_demand()
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self._electrical_demand()
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0
hub/imports/results/peak_calculation/__init__.py
Normal file
0
hub/imports/results/peak_calculation/__init__.py
Normal file
118
hub/imports/results/peak_calculation/loads_calculation.py
Normal file
118
hub/imports/results/peak_calculation/loads_calculation.py
Normal file
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@ -0,0 +1,118 @@
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"""
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Calculation of loads for peak heating and cooling
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SPDX - License - Identifier: LGPL - 3.0 - or -later
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Copyright © 2022 Concordia CERC group
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Project Coder Pilar Monsalvete Alvarez de Uribarri pilar.monsalvete@concordia.ca
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"""
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import hub.helpers.constants as cte
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class LoadsCalculation:
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"""
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LoadsCalculation class
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"""
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def __init__(self, building):
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self._building = building
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@staticmethod
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def _get_load_transmitted(thermal_zone, internal_temperature, ambient_temperature, ground_temperature):
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load_transmitted_opaque = 0
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load_transmitted_transparent = 0
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for thermal_boundary in thermal_zone.thermal_boundaries:
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if thermal_boundary.type == cte.GROUND:
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external_temperature = ground_temperature
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elif thermal_boundary.type == cte.INTERIOR_WALL:
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external_temperature = internal_temperature
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else:
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external_temperature = ambient_temperature
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load_transmitted_opaque += thermal_boundary.u_value * thermal_boundary.opaque_area \
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* (internal_temperature - external_temperature)
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for thermal_opening in thermal_boundary.thermal_openings:
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load_transmitted_transparent += thermal_opening.overall_u_value \
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* (internal_temperature - external_temperature)
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load_transmitted_opaque += thermal_zone.additional_thermal_bridge_u_value * thermal_zone.footprint_area \
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* (internal_temperature - ambient_temperature)
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load_transmitted = load_transmitted_opaque + load_transmitted_transparent
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return load_transmitted
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@staticmethod
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def _get_load_ventilation(thermal_zone, internal_temperature, ambient_temperature):
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load_renovation_sensible = 0
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for usage in thermal_zone.usages:
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load_renovation_sensible += cte.AIR_DENSITY * cte.AIR_HEAT_CAPACITY * usage.mechanical_air_change \
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* thermal_zone.volume / cte.HOUR_TO_MINUTES / cte.MINUTES_TO_SECONDS \
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* (internal_temperature - ambient_temperature)
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load_infiltration_sensible = cte.AIR_DENSITY * cte.AIR_HEAT_CAPACITY * thermal_zone.infiltration_rate_system_off \
|
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|
* thermal_zone.volume / cte.HOUR_TO_MINUTES / cte.MINUTES_TO_SECONDS \
|
||||||
|
* (internal_temperature - ambient_temperature)
|
||||||
|
|
||||||
|
load_ventilation = load_renovation_sensible + load_infiltration_sensible
|
||||||
|
|
||||||
|
return load_ventilation
|
||||||
|
|
||||||
|
def get_heating_transmitted_load(self, ambient_temperature, ground_temperature):
|
||||||
|
heating_load_transmitted = 0
|
||||||
|
for internal_zone in self._building.internal_zones:
|
||||||
|
for thermal_zone in internal_zone.thermal_zones:
|
||||||
|
internal_temperature = thermal_zone.thermal_control.mean_heating_set_point
|
||||||
|
heating_load_transmitted += self._get_load_transmitted(thermal_zone, internal_temperature, ambient_temperature,
|
||||||
|
ground_temperature)
|
||||||
|
return heating_load_transmitted
|
||||||
|
|
||||||
|
def get_cooling_transmitted_load(self, ambient_temperature, ground_temperature):
|
||||||
|
cooling_load_transmitted = 0
|
||||||
|
for internal_zone in self._building.internal_zones:
|
||||||
|
for thermal_zone in internal_zone.thermal_zones:
|
||||||
|
internal_temperature = thermal_zone.thermal_control.mean_cooling_set_point
|
||||||
|
cooling_load_transmitted += self._get_load_transmitted(thermal_zone, internal_temperature, ambient_temperature,
|
||||||
|
ground_temperature)
|
||||||
|
return cooling_load_transmitted
|
||||||
|
|
||||||
|
def get_heating_ventilation_load_sensible(self, ambient_temperature):
|
||||||
|
heating_ventilation_load = 0
|
||||||
|
for internal_zone in self._building.internal_zones:
|
||||||
|
for thermal_zone in internal_zone.thermal_zones:
|
||||||
|
internal_temperature = thermal_zone.thermal_control.mean_heating_set_point
|
||||||
|
heating_ventilation_load += self._get_load_ventilation(thermal_zone, internal_temperature, ambient_temperature)
|
||||||
|
return heating_ventilation_load
|
||||||
|
|
||||||
|
def get_cooling_ventilation_load_sensible(self, ambient_temperature):
|
||||||
|
cooling_ventilation_load = 0
|
||||||
|
for internal_zone in self._building.internal_zones:
|
||||||
|
for thermal_zone in internal_zone.thermal_zones:
|
||||||
|
internal_temperature = thermal_zone.thermal_control.mean_cooling_set_point
|
||||||
|
cooling_ventilation_load += self._get_load_ventilation(thermal_zone, internal_temperature, ambient_temperature)
|
||||||
|
return cooling_ventilation_load
|
||||||
|
|
||||||
|
def get_internal_load_sensible(self):
|
||||||
|
cooling_load_occupancy_sensible = 0
|
||||||
|
cooling_load_lighting = 0
|
||||||
|
cooling_load_equipment_sensible = 0
|
||||||
|
for internal_zone in self._building.internal_zones:
|
||||||
|
for thermal_zone in internal_zone.thermal_zones:
|
||||||
|
cooling_load_occupancy_sensible += (thermal_zone.occupancy.sensible_convective_internal_gain
|
||||||
|
+ thermal_zone.occupancy.sensible_radiative_internal_gain) \
|
||||||
|
* thermal_zone.footprint_area
|
||||||
|
cooling_load_lighting += (thermal_zone.lighting.density * thermal_zone.lighting.convective_fraction
|
||||||
|
+ thermal_zone.lighting.density * thermal_zone.lighting.radiative_fraction) \
|
||||||
|
* thermal_zone.footprint_area
|
||||||
|
cooling_load_equipment_sensible += (thermal_zone.appliances.density * thermal_zone.appliances.convective_fraction
|
||||||
|
+ thermal_zone.appliances.density * thermal_zone.appliances.radiative_fraction) \
|
||||||
|
* thermal_zone.footprint_area
|
||||||
|
internal_load = cooling_load_occupancy_sensible + cooling_load_lighting + cooling_load_equipment_sensible
|
||||||
|
return internal_load
|
||||||
|
|
||||||
|
def get_radiation_load(self, irradiance_format, hour):
|
||||||
|
cooling_load_radiation = 0
|
||||||
|
for internal_zone in self._building.internal_zones:
|
||||||
|
for thermal_zone in internal_zone.thermal_zones:
|
||||||
|
for thermal_boundary in thermal_zone.thermal_boundaries:
|
||||||
|
for thermal_opening in thermal_boundary.thermal_openings:
|
||||||
|
radiation = thermal_boundary.parent_surface.global_irradiance[cte.HOUR][irradiance_format][hour]
|
||||||
|
cooling_load_radiation += thermal_opening.area * (1 - thermal_opening.frame_ratio) * thermal_opening.g_value \
|
||||||
|
* radiation
|
||||||
|
return cooling_load_radiation
|
61
hub/imports/results/peak_load.py
Normal file
61
hub/imports/results/peak_load.py
Normal file
|
@ -0,0 +1,61 @@
|
||||||
|
import hub.helpers.constants as cte
|
||||||
|
from hub.imports.results.peak_calculation.loads_calculation import LoadsCalculation
|
||||||
|
|
||||||
|
|
||||||
|
class PeakLoad:
|
||||||
|
|
||||||
|
_MONTH_STARTING_HOUR = [0, 744, 1416, 2160, 2880, 3624, 4344, 5088, 5832, 6552, 7296, 8016]
|
||||||
|
|
||||||
|
def __init__(self, city):
|
||||||
|
self._city = city
|
||||||
|
self._weather_format = 'epw'
|
||||||
|
|
||||||
|
def enrich(self):
|
||||||
|
for building in self._city.buildings:
|
||||||
|
monthly_heating_loads = []
|
||||||
|
monthly_cooling_loads = []
|
||||||
|
ambient_temperature = building.external_temperature[cte.HOUR][self._weather_format]
|
||||||
|
for month in range(0, 12):
|
||||||
|
ground_temperature = building.ground_temperature[cte.MONTH]['2'][month]
|
||||||
|
heating_ambient_temperature = 100
|
||||||
|
cooling_ambient_temperature = -100
|
||||||
|
heating_calculation_hour = -1
|
||||||
|
cooling_calculation_hour = -1
|
||||||
|
start_hour = self._MONTH_STARTING_HOUR[month]
|
||||||
|
end_hour = 8760
|
||||||
|
if month < 11:
|
||||||
|
end_hour = self._MONTH_STARTING_HOUR[month + 1]
|
||||||
|
for hour in range(start_hour, end_hour):
|
||||||
|
temperature = ambient_temperature[hour]
|
||||||
|
if temperature < heating_ambient_temperature:
|
||||||
|
heating_ambient_temperature = temperature
|
||||||
|
heating_calculation_hour = hour
|
||||||
|
if temperature > cooling_ambient_temperature:
|
||||||
|
cooling_ambient_temperature = temperature
|
||||||
|
cooling_calculation_hour = hour
|
||||||
|
|
||||||
|
loads = LoadsCalculation(building)
|
||||||
|
heating_load_transmitted = loads.get_heating_transmitted_load(heating_ambient_temperature, ground_temperature)
|
||||||
|
heating_load_ventilation_sensible = loads.get_heating_ventilation_load_sensible(heating_ambient_temperature)
|
||||||
|
heating_load_ventilation_latent = 0
|
||||||
|
heating_load = heating_load_transmitted + heating_load_ventilation_sensible + heating_load_ventilation_latent
|
||||||
|
|
||||||
|
cooling_load_transmitted = loads.get_cooling_transmitted_load(cooling_ambient_temperature, ground_temperature)
|
||||||
|
cooling_load_renovation_sensible = loads.get_cooling_ventilation_load_sensible(cooling_ambient_temperature)
|
||||||
|
cooling_load_internal_gains_sensible = loads.get_internal_load_sensible()
|
||||||
|
cooling_load_radiation = loads.get_radiation_load(self._irradiance_format, cooling_calculation_hour)
|
||||||
|
cooling_load_sensible = cooling_load_transmitted + cooling_load_renovation_sensible - cooling_load_radiation \
|
||||||
|
- cooling_load_internal_gains_sensible
|
||||||
|
|
||||||
|
cooling_load_latent = 0
|
||||||
|
cooling_load = cooling_load_sensible + cooling_load_latent
|
||||||
|
if heating_load < 0:
|
||||||
|
heating_load = 0
|
||||||
|
if cooling_load > 0:
|
||||||
|
cooling_load = 0
|
||||||
|
monthly_heating_loads.append(heating_load)
|
||||||
|
monthly_cooling_loads.append(cooling_load)
|
||||||
|
|
||||||
|
self._results[building.name] = {'monthly heating peak load': monthly_heating_loads,
|
||||||
|
'monthly cooling peak load': monthly_cooling_loads}
|
||||||
|
self._print_results()
|
|
@ -9,6 +9,7 @@ from pathlib import Path
|
||||||
|
|
||||||
from hub.helpers.utils import validate_import_export_type
|
from hub.helpers.utils import validate_import_export_type
|
||||||
from hub.hub_logger import logger
|
from hub.hub_logger import logger
|
||||||
|
from hub.imports.results.peak_load import PeakLoad
|
||||||
from hub.imports.results.simplified_radiosity_algorithm import SimplifiedRadiosityAlgorithm
|
from hub.imports.results.simplified_radiosity_algorithm import SimplifiedRadiosityAlgorithm
|
||||||
from hub.imports.results.insel_monthly_energry_balance import InselMonthlyEnergyBalance
|
from hub.imports.results.insel_monthly_energry_balance import InselMonthlyEnergyBalance
|
||||||
from hub.imports.results.insel_heatpump_energy_demand import InselHeatPumpEnergyDemand
|
from hub.imports.results.insel_heatpump_energy_demand import InselHeatPumpEnergyDemand
|
||||||
|
@ -59,6 +60,12 @@ class ResultFactory:
|
||||||
"""
|
"""
|
||||||
InselMonthlyEnergyBalance(self._city, self._base_path).enrich()
|
InselMonthlyEnergyBalance(self._city, self._base_path).enrich()
|
||||||
|
|
||||||
|
def _peak_load(self):
|
||||||
|
"""
|
||||||
|
Enrich the city with peak load results
|
||||||
|
"""
|
||||||
|
PeakLoad(self._city).enrich()
|
||||||
|
|
||||||
def enrich(self):
|
def enrich(self):
|
||||||
"""
|
"""
|
||||||
Enrich the city given to the class using the usage factory given handler
|
Enrich the city given to the class using the usage factory given handler
|
||||||
|
|
|
@ -24,4 +24,5 @@ geopandas
|
||||||
triangle
|
triangle
|
||||||
psycopg2-binary
|
psycopg2-binary
|
||||||
Pillow
|
Pillow
|
||||||
pathlib
|
pathlib
|
||||||
|
pickle5
|
1
setup.py
1
setup.py
|
@ -87,6 +87,7 @@ setup(
|
||||||
('hub/catalog_factories/greenery/ecore_greenery', glob.glob('hub/catalog_factories/greenery/ecore_greenery/*.ecore')),
|
('hub/catalog_factories/greenery/ecore_greenery', glob.glob('hub/catalog_factories/greenery/ecore_greenery/*.ecore')),
|
||||||
('hub/data/construction.', glob.glob('hub/data/construction/*')),
|
('hub/data/construction.', glob.glob('hub/data/construction/*')),
|
||||||
('hub/data/customized_imports', glob.glob('hub/data/customized_imports/*.xml')),
|
('hub/data/customized_imports', glob.glob('hub/data/customized_imports/*.xml')),
|
||||||
|
('data/geolocation', glob.glob('hub/data/geolocation/*.txt')),
|
||||||
('hub/data/energy_systems', glob.glob('hub/data/energy_systems/*.xml')),
|
('hub/data/energy_systems', glob.glob('hub/data/energy_systems/*.xml')),
|
||||||
('hub/data/energy_systems', glob.glob('hub/data/energy_systems/*.insel')),
|
('hub/data/energy_systems', glob.glob('hub/data/energy_systems/*.insel')),
|
||||||
('hub/data/energy_systems', glob.glob('hub/data/energy_systems/*.xlsx')),
|
('hub/data/energy_systems', glob.glob('hub/data/energy_systems/*.xlsx')),
|
||||||
|
|
Loading…
Reference in New Issue
Block a user