278 lines
12 KiB
Python
278 lines
12 KiB
Python
"""
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lca_carbon_workflow module
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Returns the summarize of envelope and energy systems
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SPDX - License - Identifier: LGPL - 3.0 - or -later
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Copyright © 2024 Concordia CERC group
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Project Designer and Developer: Alireza Adli
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alireza.adli@mail.concordia.ca
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Theoritical Support for LCA emissions:
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Mohammad Seyedabadi mohammad.seyedabadi@mail.concordia.ca
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"""
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from pathlib import Path
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from input_geojson_content import InputGeoJsonContent
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from hub.imports.geometry_factory import GeometryFactory
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from hub.imports.construction_factory import ConstructionFactory
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from hub.helpers.dictionaries import Dictionaries
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from city_model_structure.life_cycle_assessment.access_nrcan_catalogue \
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import AccessNrcanCatalog
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from city_model_structure.life_cycle_assessment.opening_emission \
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import OpeningEmission
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from city_model_structure.life_cycle_assessment.envelope_emission \
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import EnvelopeEmission
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from city_model_structure.life_cycle_assessment.lca_end_of_life_carbon \
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import EndOfLifeEmission
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class LCACarbonWorkflow:
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def __init__(
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self,
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city_path,
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archetypes_catalog_file_name,
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constructions_catalog_file,
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catalog='nrcan',
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building_parameters=('height', 'year_of_construction', 'function')):
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"""
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LCACarbonWorkflow takes a number of buildings and enrich the city object
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using cerc-hub GeometryFactory and ConstructionFactory. Then it
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calculates embodied and end of life carbon emission of each building.
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It puts out the results of opening and envelop emission for each
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mentioned cycle separately.
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Final results will be stored in the below attributes:
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building_envelope_emission: float
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building_opening_emission: float
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building_component_emission: float
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building_envelope_end_of_life_emission: float
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building_opening_end_of_life_emission: float
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building_component_end_of_life_emission: float
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The above attributes will be computed when the calculate_emission()
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method of a LCACarbonWorkflow object is called.
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:param city_path: Either a path to the buildings (GeoJson)
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file or the content of such a file.
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:param archetypes_catalog_file_name: Path to the buildings'
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archetypes (JSON).
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:param constructions_catalog_file: Path to the construction materials
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data.
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:param catalog: Type of the catalog (in this case 'nrcan', the default
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argument)
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:param building_parameters: Parameters used for using the catalog (in
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this case three default arguments)
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"""
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self.file_path = Path(__file__).parent / 'input_files' / InputGeoJsonContent(
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city_path).content
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self.catalogs_path = Path(__file__).parent / 'input_files'
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self.archetypes_catalog_file_name = archetypes_catalog_file_name
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self.constructions_catalog_file = constructions_catalog_file
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self.nrcan_catalogs = AccessNrcanCatalog(
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self.catalogs_path,
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archetypes=self.archetypes_catalog_file_name,
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constructions=self.constructions_catalog_file)
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self.out_path = (Path(__file__).parent / 'out_files')
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self.handler = catalog
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self.height, self.year_of_construction, self.function = \
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building_parameters
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print('[simulation start]')
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self.city = GeometryFactory(
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'geojson',
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path=self.file_path,
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height_field=self.height,
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year_of_construction_field=self.year_of_construction,
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function_field=self.function,
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function_to_hub=Dictionaries().montreal_function_to_hub_function).city
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print(f'city created from {self.file_path}')
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ConstructionFactory(self.handler, self.city).enrich()
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self.building_envelope_emission = []
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self.building_opening_emission = []
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self.building_component_emission = []
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self.building_envelope_end_of_life_emission = []
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self.building_opening_end_of_life_emission = []
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self.building_component_end_of_life_emission = []
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def calculate_building_component_emission(self, building):
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"""
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This method is the core of the whole class. It takes each building
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contained in the city object and calculates and returns the envelope
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and opening emission of the embodied and end of life cycles. The building
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comes from the calculate_emission() method which goes through every
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building of the city object (meaning the input of the LCACarbonWorkflow
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object.
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The calculate_building_component_emission() method goes through each
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surface of the given building then each boundary of that surface to
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calculate the embodied and end of life emission of openings and the
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envelope of the building. It is being carried out by utilizing to
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hidden methods of the current class (methods contain description.)
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At the end, a tuple will be returned, containing the emissions
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attributes. The tuple will be unpacked in the calculate_emission()
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method. The attributes and their types are explained in the constructor.
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The building parameter comes from the calculate_emission() method
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which iterates through the city object buildings.
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:param building: hub.city_model_structure.building.Building
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:return: tuple
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"""
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surface_envelope_emission = []
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surface_opening_emission = []
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surface_envelope_end_of_life_emission = []
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surface_opening_end_of_life_emission = []
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opaque_surface_code = self.nrcan_catalogs.find_opaque_surface(
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self.nrcan_catalogs.hub_to_nrcan_function(building.function),
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self.nrcan_catalogs.year_to_period_of_construction(
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building.year_of_construction),
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'6')
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for surface in building.surfaces:
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boundary_envelope_emission = []
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boundary_opening_emission = []
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boundary_envelope_end_of_life_emission = []
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boundary_opening_end_of_life_emission = []
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for boundary in surface.associated_thermal_boundaries:
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opening_emission = None
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opening_end_of_life_emission = None
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layer_emission, layer_end_of_life_emission = \
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self._calculate_envelope_emission(boundary)
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boundary_envelope_emission += layer_emission
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boundary_envelope_end_of_life_emission += layer_end_of_life_emission
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if boundary.window_ratio:
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opening_emission, opening_end_of_life_emission = \
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self._calculate_opening_emission(
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building, surface, boundary, opaque_surface_code)
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if opening_emission:
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boundary_opening_emission += opening_emission
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boundary_opening_end_of_life_emission += opening_end_of_life_emission
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if boundary_opening_emission:
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surface_opening_emission += boundary_opening_emission
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surface_opening_end_of_life_emission += \
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boundary_opening_end_of_life_emission
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surface_envelope_emission += boundary_envelope_emission
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surface_envelope_end_of_life_emission += \
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boundary_envelope_end_of_life_emission
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building_envelope_emission = sum(surface_envelope_emission)
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building_envelope_workload = sum(surface_envelope_end_of_life_emission)
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building_opening_emission = sum(surface_opening_emission)
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building_opening_workload = sum(surface_opening_end_of_life_emission)
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building_component_emission = \
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building_envelope_emission + building_opening_emission
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building_component_workload = \
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building_envelope_workload + building_opening_workload
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return building_envelope_emission, building_opening_emission, \
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building_component_emission, building_envelope_workload, \
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building_opening_workload, building_component_workload
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def _calculate_envelope_emission(self, boundary):
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"""
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The method calculates embodied and end of life emission of the building's
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envelope by iterating through each building boundary's layers. The
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argument corresponding to the boundary parameter comes from the
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calculate_building_component_emission() method. The output also is used
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in the calculate_building_component_emission() method. So the current
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method is hidden to the user.
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The method utilizes the EnvelopeEmission and EndOfLifeEmission classes of
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(currently named) life_cycle_assessment series of class.
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:param boundary:
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hub.city_model_structure.building_demand.thermal_boundary.ThermalBoundary
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:return: tuple
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"""
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layer_emission = []
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layer_end_of_life_emission = []
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for layer in boundary.layers:
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if not layer.no_mass:
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layer_material = \
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self.nrcan_catalogs.search_material(layer.material_name)
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layer_emission.append(EnvelopeEmission(
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layer_material['embodied_carbon'],
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boundary.opaque_area,
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layer.thickness, layer.density).calculate_envelope_emission())
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boundary_workload = \
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boundary.opaque_area * \
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layer.thickness * \
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layer.density
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layer_end_of_life_emission.append(EndOfLifeEmission(
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layer_material['recycling_ratio'],
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layer_material['onsite_recycling_ratio'],
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layer_material['company_recycling_ratio'],
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layer_material['landfilling_ratio'],
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boundary_workload).calculate_end_of_life_emission())
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return layer_emission, layer_end_of_life_emission
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def _calculate_opening_emission(
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self,
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building, surface, boundary, opaque_surface_code,
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density=2579):
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"""
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This calculates the opening emission by iterating through each thermal
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opening of each building's boundary. It is done based on the mentioned
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parameters.
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The arguments come from the calculate_building_component_emission()
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method and the output is used in the same method. So the current method
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is hidden to the user.
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Windows have the assumed density of 2579 kg/m3
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Window's thickness assumed the same as wall's thickness
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These two values are being used to calculate window's workload for
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the End of Life emission evaluation.
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The method utilizes the OpeningEmission and EndOfLifeEmission classes of
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(currently named) life_cycle_assessment series of class.
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:param building: hub.city_model_structure.building.Building
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:param surface:
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hub.city_model_structure.building_demand.surface.Surface
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:param boundary:
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hub.city_model_structure.building_demand.thermal_boundary.ThermalBoundary
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:param opaque_surface_code: str
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:param density: int
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:return: tuple
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"""
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opening_emission = []
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opening_end_of_life_emission = []
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for opening in boundary.thermal_openings:
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transparent_surface_type = 'Window'
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if building.year_of_construction >= 2020 and \
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surface.type == 'Roof':
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transparent_surface_type = 'Skylight'
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opening_material = self.nrcan_catalogs.search_transparent_surfaces(
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transparent_surface_type, opaque_surface_code)
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opening_emission.append(
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OpeningEmission(opening_material['embodied_carbon'],
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opening.area).calculate_opening_emission())
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window_workload = opening.area * boundary.thickness * density
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opening_end_of_life_emission.append(EndOfLifeEmission(
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opening_material['recycling_ratio'],
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opening_material['onsite_recycling_ratio'],
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opening_material['company_recycling_ratio'],
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opening_material['landfilling_ratio'],
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window_workload).calculate_end_of_life_emission())
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return opening_emission, opening_end_of_life_emission
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def calculate_emission(self):
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"""
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It iterates through the city object and gives each building to the
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calculate_building_component_emission() method. Then it unpack the results
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of the mentioned method to the (currently six) attributes which hold the
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final results. These attributes are mentioned in the constructor method
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description.
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"""
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for building in self.city.buildings:
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envelope_emission, opening_emission, component_emission, \
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envelope_end_of_life_emission, \
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opening_end_of_life_emission, \
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component_end_of_life_emission = \
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self.calculate_building_component_emission(building)
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self.building_envelope_emission.append(envelope_emission)
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self.building_opening_emission.append(opening_emission)
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self.building_component_emission.append(component_emission)
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self.building_envelope_end_of_life_emission.append(
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envelope_end_of_life_emission)
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self.building_opening_end_of_life_emission.append(
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opening_end_of_life_emission)
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self.building_component_end_of_life_emission.append(
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component_end_of_life_emission)
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