Title: Finalizing the energy system data model and system factory

A new XML file named montreal_future_systems.xml is created where the elements of the file are the same as attributes of various classes. Therefore, the catalogue importer and energy system importer should have been updated accordingly. The catalog importer is organized in a general method so whenever someone wants to create a new catalogue they can use the created code as the blueprint.
This commit is contained in:
Saeed Ranjbar 2024-02-07 18:54:09 -05:00
parent 3e193f04a6
commit ebaec9bb7c
211 changed files with 2167 additions and 50 deletions

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@ -14,12 +14,12 @@ class ElectricalStorageSystem(EnergyStorageSystem):
Energy Storage System Class Energy Storage System Class
""" """
def __init__(self, storage_id, model_name=None, manufacturer=None, storage_type=None, def __init__(self, storage_id, type_energy_stored=None, model_name=None, manufacturer=None, storage_type=None,
nominal_capacity=None, losses_ratio=None, rated_output_power=None, nominal_efficiency=None, nominal_capacity=None, losses_ratio=None, rated_output_power=None, nominal_efficiency=None,
battery_voltage=None, depth_of_discharge=None, self_discharge_rate=None): battery_voltage=None, depth_of_discharge=None, self_discharge_rate=None):
super().__init__(storage_id, model_name, manufacturer, nominal_capacity, losses_ratio) super().__init__(storage_id, model_name, manufacturer, nominal_capacity, losses_ratio)
self._type_energy_stored = 'electrical' self._type_energy_stored = type_energy_stored
self._storage_type = storage_type self._storage_type = storage_type
self._rated_output_power = rated_output_power self._rated_output_power = rated_output_power
self._nominal_efficiency = nominal_efficiency self._nominal_efficiency = nominal_efficiency

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@ -14,7 +14,7 @@ class PvGenerationSystem(GenerationSystem):
Electricity Generation system class Electricity Generation system class
""" """
def __init__(self, system_id, name, model_name=None, manufacturer=None, electricity_efficiency=None, def __init__(self, system_id, name, system_type, model_name=None, manufacturer=None, electricity_efficiency=None,
nominal_electricity_output=None, nominal_ambient_temperature=None, nominal_cell_temperature=None, nominal_electricity_output=None, nominal_ambient_temperature=None, nominal_cell_temperature=None,
nominal_radiation=None, standard_test_condition_cell_temperature=None, nominal_radiation=None, standard_test_condition_cell_temperature=None,
standard_test_condition_maximum_power=None, cell_temperature_coefficient=None, width=None, height=None, standard_test_condition_maximum_power=None, cell_temperature_coefficient=None, width=None, height=None,
@ -22,7 +22,7 @@ class PvGenerationSystem(GenerationSystem):
super().__init__(system_id=system_id, name=name, model_name=model_name, super().__init__(system_id=system_id, name=name, model_name=model_name,
manufacturer=manufacturer, fuel_type='renewable', distribution_systems=distribution_systems, manufacturer=manufacturer, fuel_type='renewable', distribution_systems=distribution_systems,
energy_storage_systems=energy_storage_systems) energy_storage_systems=energy_storage_systems)
self._system_type = 'PV system' self._system_type = system_type
self._electricity_efficiency = electricity_efficiency self._electricity_efficiency = electricity_efficiency
self._nominal_electricity_output = nominal_electricity_output self._nominal_electricity_output = nominal_electricity_output
self._nominal_ambient_temperature = nominal_ambient_temperature self._nominal_ambient_temperature = nominal_ambient_temperature

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@ -15,12 +15,12 @@ class ThermalStorageSystem(EnergyStorageSystem):
Energy Storage System Class Energy Storage System Class
""" """
def __init__(self, storage_id, model_name=None, manufacturer=None, storage_type=None, def __init__(self, storage_id, type_energy_stored=None, model_name=None, manufacturer=None, storage_type=None,
nominal_capacity=None, losses_ratio=None, volume=None, height=None, layers=None, nominal_capacity=None, losses_ratio=None, volume=None, height=None, layers=None,
maximum_operating_temperature=None, storage_medium=None): maximum_operating_temperature=None, storage_medium=None):
super().__init__(storage_id, model_name, manufacturer, nominal_capacity, losses_ratio) super().__init__(storage_id, model_name, manufacturer, nominal_capacity, losses_ratio)
self._type_energy_stored = 'thermal' self._type_energy_stored = type_energy_stored
self._storage_type = storage_type self._storage_type = storage_type
self._volume = volume self._volume = volume
self._height = height self._height = height

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@ -0,0 +1,539 @@
"""
Montreal future energy system catalog
SPDX - License - Identifier: LGPL - 3.0 - or -later
Copyright © 2022 Concordia CERC group
Project Coder Saeed Ranjbar saeed.ranjbar@concordia.ca
"""
import xmltodict
from pathlib import Path
from hub.catalog_factories.catalog import Catalog
from hub.catalog_factories.data_models.energy_systems.distribution_system import DistributionSystem
from hub.catalog_factories.data_models.energy_systems.emission_system import EmissionSystem
from hub.catalog_factories.data_models.energy_systems.system import System
from hub.catalog_factories.data_models.energy_systems.content import Content
from hub.catalog_factories.data_models.energy_systems.non_pv_generation_system import NonPvGenerationSystem
from hub.catalog_factories.data_models.energy_systems.pv_generation_system import PvGenerationSystem
from hub.catalog_factories.data_models.energy_systems.thermal_storage_system import ThermalStorageSystem
from hub.catalog_factories.data_models.energy_systems.performance_curves import PerformanceCurves
from hub.catalog_factories.data_models.energy_systems.archetype import Archetype
from hub.catalog_factories.data_models.construction.material import Material
from hub.catalog_factories.data_models.construction.layer import Layer
class MontrealFutureSystemCatalogue(Catalog):
"""
North america energy system catalog class
"""
def __init__(self, path):
path = str(path / 'montreal_future_systems.xml')
with open(path, 'r', encoding='utf-8') as xml:
self._archetypes = xmltodict.parse(xml.read(),
force_list=['pv_generation_component', 'templateStorages', 'demand'])
self._storage_components = self._load_storage_components()
self._generation_components = self._load_generation_components()
self._energy_emission_components = self._load_emission_equipments()
self._distribution_components = self._load_distribution_equipments()
self._systems = self._load_systems()
self._system_archetypes = self._load_archetypes()
self._content = Content(self._system_archetypes,
self._systems,
generations=self._generation_components,
distributions=self._distribution_components)
def _load_generation_components(self):
generation_components = []
non_pv_generation_components = self._archetypes['EnergySystemCatalog']['energy_generation_components'][
'non_pv_generation_component']
if non_pv_generation_components is not None:
for non_pv in non_pv_generation_components:
system_id = non_pv['system_id']
name = non_pv['name']
system_type = non_pv['system_type']
model_name = non_pv['model_name']
manufacturer = non_pv['manufacturer']
fuel_type = non_pv['fuel_type']
distribution_systems = non_pv['distribution_systems']
energy_storage_systems = None
if non_pv['energy_storage_systems'] is not None:
storage_component = non_pv['energy_storage_systems']['storage_id']
storage_systems = self._search_storage_equipment(self._load_storage_components(), storage_component)
energy_storage_systems = storage_systems
nominal_heat_output = non_pv['nominal_heat_output']
maximum_heat_output = non_pv['maximum_heat_output']
minimum_heat_output = non_pv['minimum_heat_output']
source_medium = non_pv['source_medium']
supply_medium = non_pv['supply_medium']
heat_efficiency = non_pv['heat_efficiency']
nominal_cooling_output = non_pv['nominal_cooling_output']
maximum_cooling_output = non_pv['maximum_cooling_output']
minimum_cooling_output = non_pv['minimum_cooling_output']
cooling_efficiency = non_pv['cooling_efficiency']
electricity_efficiency = non_pv['electricity_efficiency']
source_temperature = non_pv['source_temperature']
source_mass_flow = non_pv['source_mass_flow']
nominal_electricity_output = non_pv['nominal_electricity_output']
maximum_heat_supply_temperature = non_pv['maximum_heat_supply_temperature']
minimum_heat_supply_temperature = non_pv['minimum_heat_supply_temperature']
maximum_cooling_supply_temperature = non_pv['maximum_cooling_supply_temperature']
minimum_cooling_supply_temperature = non_pv['minimum_cooling_supply_temperature']
heat_output_curve = None
heat_fuel_consumption_curve = None
heat_efficiency_curve = None
cooling_output_curve = None
cooling_fuel_consumption_curve = None
cooling_efficiency_curve = None
if non_pv['heat_output_curve'] is not None:
curve_type = non_pv['heat_output_curve']['curve_type']
dependant_variable = non_pv['heat_output_curve']['dependant_variable']
parameters = non_pv['heat_output_curve']['parameters']
coefficients = list(non_pv['heat_output_curve']['coefficients'].values())
heat_output_curve = PerformanceCurves(curve_type, dependant_variable, parameters, coefficients)
if non_pv['heat_fuel_consumption_curve'] is not None:
curve_type = non_pv['heat_fuel_consumption_curve']['curve_type']
dependant_variable = non_pv['heat_fuel_consumption_curve']['dependant_variable']
parameters = non_pv['heat_fuel_consumption_curve']['parameters']
coefficients = list(non_pv['heat_fuel_consumption_curve']['coefficients'].values())
heat_fuel_consumption_curve = PerformanceCurves(curve_type, dependant_variable, parameters, coefficients)
if non_pv['heat_efficiency_curve'] is not None:
curve_type = non_pv['heat_efficiency_curve']['curve_type']
dependant_variable = non_pv['heat_efficiency_curve']['dependant_variable']
parameters = non_pv['heat_efficiency_curve']['parameters']
coefficients = list(non_pv['heat_efficiency_curve']['coefficients'].values())
heat_efficiency_curve = PerformanceCurves(curve_type, dependant_variable, parameters, coefficients)
if non_pv['cooling_output_curve'] is not None:
curve_type = non_pv['cooling_output_curve']['curve_type']
dependant_variable = non_pv['cooling_output_curve']['dependant_variable']
parameters = non_pv['cooling_output_curve']['parameters']
coefficients = list(non_pv['cooling_output_curve']['coefficients'].values())
cooling_output_curve = PerformanceCurves(curve_type, dependant_variable, parameters, coefficients)
if non_pv['cooling_fuel_consumption_curve'] is not None:
curve_type = non_pv['cooling_fuel_consumption_curve']['curve_type']
dependant_variable = non_pv['cooling_fuel_consumption_curve']['dependant_variable']
parameters = non_pv['cooling_fuel_consumption_curve']['parameters']
coefficients = list(non_pv['cooling_fuel_consumption_curve']['coefficients'].values())
cooling_fuel_consumption_curve = PerformanceCurves(curve_type, dependant_variable, parameters, coefficients)
if non_pv['cooling_efficiency_curve'] is not None:
curve_type = non_pv['cooling_efficiency_curve']['curve_type']
dependant_variable = non_pv['cooling_efficiency_curve']['dependant_variable']
parameters = non_pv['cooling_efficiency_curve']['parameters']
coefficients = list(non_pv['cooling_efficiency_curve']['coefficients'].values())
cooling_efficiency_curve = PerformanceCurves(curve_type, dependant_variable, parameters, coefficients)
dual_supply_capability = None
if non_pv['dual_supply_capability'] is not None:
if non_pv['dual_supply_capability'] == 'True':
dual_supply_capability = True
else:
dual_supply_capability = False
non_pv_component = NonPvGenerationSystem(system_id=system_id,
name=name,
system_type=system_type,
model_name=model_name,
manufacturer=manufacturer,
fuel_type=fuel_type,
nominal_heat_output=nominal_heat_output,
maximum_heat_output=maximum_heat_output,
minimum_heat_output=minimum_heat_output,
source_medium=source_medium,
supply_medium=supply_medium,
heat_efficiency=heat_efficiency,
nominal_cooling_output=nominal_cooling_output,
maximum_cooling_output=maximum_cooling_output,
minimum_cooling_output=minimum_cooling_output,
cooling_efficiency=cooling_efficiency,
electricity_efficiency=electricity_efficiency,
source_temperature=source_temperature,
source_mass_flow=source_mass_flow,
nominal_electricity_output=nominal_electricity_output,
maximum_heat_supply_temperature=maximum_heat_supply_temperature,
minimum_heat_supply_temperature=minimum_heat_supply_temperature,
maximum_cooling_supply_temperature=maximum_cooling_supply_temperature,
minimum_cooling_supply_temperature=minimum_cooling_supply_temperature,
heat_output_curve=heat_output_curve,
heat_fuel_consumption_curve=heat_fuel_consumption_curve,
heat_efficiency_curve=heat_efficiency_curve,
cooling_output_curve=cooling_output_curve,
cooling_fuel_consumption_curve=cooling_fuel_consumption_curve,
cooling_efficiency_curve=cooling_efficiency_curve,
distribution_systems=distribution_systems,
energy_storage_systems=energy_storage_systems,
dual_supply_capability=dual_supply_capability)
generation_components.append(non_pv_component)
pv_generation_components = self._archetypes['EnergySystemCatalog']['energy_generation_components'][
'pv_generation_component']
if pv_generation_components is not None:
for pv in pv_generation_components:
system_id = pv['system_id']
name = pv['name']
system_type = pv['system_type']
model_name = pv['model_name']
manufacturer = pv['manufacturer']
electricity_efficiency = pv['electricity_efficiency']
nominal_electricity_output = pv['nominal_electricity_output']
nominal_ambient_temperature = pv['nominal_ambient_temperature']
nominal_cell_temperature = pv['nominal_cell_temperature']
nominal_radiation = pv['nominal_radiation']
standard_test_condition_cell_temperature = pv['standard_test_condition_cell_temperature']
standard_test_condition_maximum_power = pv['standard_test_condition_maximum_power']
cell_temperature_coefficient = pv['cell_temperature_coefficient']
width = pv['width']
height = pv['height']
distribution_systems = pv['distribution_systems']
energy_storage_systems = None
if pv['energy_storage_systems'] is not None:
storage_component = pv['energy_storage_systems']['storage_id']
storage_systems = self._search_storage_equipment(self._load_storage_components(), storage_component)
energy_storage_systems = storage_systems
pv_component = PvGenerationSystem(system_id=system_id,
name=name,
system_type=system_type,
model_name=model_name,
manufacturer=manufacturer,
electricity_efficiency=electricity_efficiency,
nominal_electricity_output=nominal_electricity_output,
nominal_ambient_temperature=nominal_ambient_temperature,
nominal_cell_temperature=nominal_cell_temperature,
nominal_radiation=nominal_radiation,
standard_test_condition_cell_temperature=
standard_test_condition_cell_temperature,
standard_test_condition_maximum_power=standard_test_condition_maximum_power,
cell_temperature_coefficient=cell_temperature_coefficient,
width=width,
height=height,
distribution_systems=distribution_systems,
energy_storage_systems=energy_storage_systems)
generation_components.append(pv_component)
return generation_components
def _load_distribution_equipments(self):
_equipments = []
distribution_systems = self._archetypes['EnergySystemCatalog']['distribution_systems']['distribution_system']
if distribution_systems is not None:
for distribution_system in distribution_systems:
system_id = None
model_name = None
system_type = None
supply_temperature = None
distribution_consumption_fix_flow = None
distribution_consumption_variable_flow = None
heat_losses = None
generation_systems = None
energy_storage_systems = None
emission_systems = None
distribution_equipment = DistributionSystem(system_id=system_id,
model_name=model_name,
system_type=system_type,
supply_temperature=supply_temperature,
distribution_consumption_fix_flow=distribution_consumption_fix_flow,
distribution_consumption_variable_flow=
distribution_consumption_variable_flow,
heat_losses=heat_losses,
generation_systems=generation_systems,
energy_storage_systems=energy_storage_systems,
emission_systems=emission_systems
)
_equipments.append(distribution_equipment)
return _equipments
def _load_emission_equipments(self):
_equipments = []
dissipation_systems = self._archetypes['EnergySystemCatalog']['dissipation_systems']['dissipation_system']
if dissipation_systems is not None:
for dissipation_system in dissipation_systems:
system_id = None
model_name = None
system_type = None
parasitic_energy_consumption = None
emission_system = EmissionSystem(system_id=system_id,
model_name=model_name,
system_type=system_type,
parasitic_energy_consumption=parasitic_energy_consumption)
_equipments.append(emission_system)
return _equipments
def _load_storage_components(self):
storage_components = []
thermal_storages = self._archetypes['EnergySystemCatalog']['energy_storage_components']['thermalStorages']
template_storages = self._archetypes['EnergySystemCatalog']['energy_storage_components']['templateStorages']
for tes in thermal_storages:
storage_id = tes['storage_id']
type_energy_stored = tes['type_energy_stored']
model_name = tes['model_name']
manufacturer = tes['manufacturer']
storage_type = tes['storage_type']
volume = tes['physical_characteristics']['volume']
height = tes['physical_characteristics']['height']
maximum_operating_temperature = tes['maximum_operating_temperature']
materials = self._load_materials()
insulation_material_id = tes['insulation']['material_id']
insulation_material = self._search_material(materials, insulation_material_id)
material_id = tes['physical_characteristics']['material_id']
tank_material = self._search_material(materials, material_id)
thickness = float(tes['insulation']['insulationThickness']) / 100 # from cm to m
insulation_layer = Layer(None, 'insulation', insulation_material, thickness)
thickness = float(tes['physical_characteristics']['tankThickness']) / 100 # from cm to m
tank_layer = Layer(None, 'tank', tank_material, thickness)
media = self._load_media()
media_id = tes['storage_medium']['medium_id']
medium = self._search_media(media, media_id)
layers = [insulation_layer, tank_layer]
nominal_capacity = tes['nominal_capacity']
losses_ratio = tes['losses_ratio']
storage_component = ThermalStorageSystem(storage_id=storage_id,
model_name=model_name,
type_energy_stored=type_energy_stored,
manufacturer=manufacturer,
storage_type=storage_type,
nominal_capacity=nominal_capacity,
losses_ratio=losses_ratio,
volume=volume,
height=height,
layers=layers,
maximum_operating_temperature=maximum_operating_temperature,
storage_medium=medium)
storage_components.append(storage_component)
for template in template_storages:
storage_id = template['storage_id']
storage_type = template['storage_type']
type_energy_stored = template['type_energy_stored']
maximum_operating_temperature = template['maximum_operating_temperature']
height = template['physical_characteristics']['height']
materials = self._load_materials()
insulation_material_id = template['insulation']['material_id']
insulation_material = self._search_material(materials, insulation_material_id)
material_id = template['physical_characteristics']['material_id']
tank_material = self._search_material(materials, material_id)
thickness = float(template['insulation']['insulationThickness']) / 100 # from cm to m
insulation_layer = Layer(None, 'insulation', insulation_material, thickness)
thickness = float(template['physical_characteristics']['tankThickness']) / 100 # from cm to m
tank_layer = Layer(None, 'tank', tank_material, thickness)
layers = [insulation_layer, tank_layer]
media = self._load_media()
media_id = template['storage_medium']['medium_id']
medium = self._search_media(media, media_id)
model_name = template['model_name']
manufacturer = template['manufacturer']
nominal_capacity = template['nominal_capacity']
losses_ratio = template['losses_ratio']
volume = template['physical_characteristics']['volume']
storage_component = ThermalStorageSystem(storage_id=storage_id,
model_name=model_name,
type_energy_stored=type_energy_stored,
manufacturer=manufacturer,
storage_type=storage_type,
nominal_capacity=nominal_capacity,
losses_ratio=losses_ratio,
volume=volume,
height=height,
layers=layers,
maximum_operating_temperature=maximum_operating_temperature,
storage_medium=medium)
storage_components.append(storage_component)
return storage_components
def _load_systems(self):
base_path = Path(Path(__file__).parent.parent.parent / 'data/energy_systems')
_catalog_systems = []
systems = self._archetypes['EnergySystemCatalog']['systems']['system']
for system in systems:
system_id = system['id']
name = system['name']
demands = system['demands']['demand']
generation_components = system['components']['generation_id']
generation_systems = self._search_generation_equipment(self._load_generation_components(), generation_components)
configuration_schema = Path(base_path / system['schema'])
energy_system = System(system_id=system_id,
name=name,
demand_types=demands,
generation_systems=generation_systems,
distribution_systems=None,
configuration_schema=configuration_schema)
_catalog_systems.append(energy_system)
return _catalog_systems
def _load_archetypes(self):
_system_archetypes = []
system_clusters = self._archetypes['EnergySystemCatalog']['system_archetypes']['system_archetype']
for system_cluster in system_clusters:
name = system_cluster['name']
systems = system_cluster['systems']['system_id']
integer_system_ids = [int(item) for item in systems]
_systems = []
for system_archetype in self._systems:
if int(system_archetype.id) in integer_system_ids:
_systems.append(system_archetype)
_system_archetypes.append(Archetype(name=name, systems=_systems))
return _system_archetypes
def _load_materials(self):
materials = []
_materials = self._archetypes['EnergySystemCatalog']['materials']['material']
for _material in _materials:
material_id = _material['material_id']
name = _material['name']
conductivity = _material['conductivity']
solar_absorptance = _material['solar_absorptance']
thermal_absorptance = _material['thermal_absorptance']
density = _material['density']
specific_heat = _material['specific_heat']
no_mass = _material['no_mass']
visible_absorptance = _material['visible_absorptance']
thermal_resistance = _material['thermal_resistance']
material = Material(material_id,
name,
solar_absorptance=solar_absorptance,
thermal_absorptance=thermal_absorptance,
density=density,
conductivity=conductivity,
thermal_resistance=thermal_resistance,
visible_absorptance=visible_absorptance,
no_mass=no_mass,
specific_heat=specific_heat)
materials.append(material)
return materials
@staticmethod
def _search_material(materials, material_id):
_material = None
for material in materials:
if int(material.id) == int(material_id):
_material = material
break
if _material is None:
raise ValueError(f'Material with the id = [{material_id}] not found in catalog ')
return _material
def _load_media(self):
media = []
_media = [self._archetypes['EnergySystemCatalog']['media']['medium']]
for _medium in _media:
medium_id = _medium['medium_id']
density = _medium['density']
name = _medium['name']
conductivity = _medium['conductivity']
solar_absorptance = _medium['solar_absorptance']
thermal_absorptance = _medium['thermal_absorptance']
specific_heat = _medium['specific_heat']
no_mass = _medium['no_mass']
visible_absorptance = _medium['visible_absorptance']
thermal_resistance = _medium['thermal_resistance']
medium = Material(material_id=medium_id,
name=name,
solar_absorptance=solar_absorptance,
thermal_absorptance=thermal_absorptance,
visible_absorptance=visible_absorptance,
no_mass=no_mass,
thermal_resistance=thermal_resistance,
conductivity=conductivity,
density=density,
specific_heat=specific_heat)
media.append(medium)
return media
@staticmethod
def _search_media(media, medium_id):
_medium = None
for medium in media:
if int(medium.id) == int(medium_id):
_medium = medium
break
if _medium is None:
raise ValueError(f'media with the id = [{medium_id}] not found in catalog ')
return _medium
@staticmethod
def _search_generation_equipment(generation_systems, generation_id):
_generation_systems = []
if isinstance(generation_id, list):
integer_ids = [int(item) for item in generation_id]
for generation in generation_systems:
if int(generation.id) in integer_ids:
_generation_systems.append(generation)
else:
integer_id = int(generation_id)
for generation in generation_systems:
if int(generation.id) == integer_id:
_generation_systems.append(generation)
if len(_generation_systems) == 0:
_generation_systems = None
raise ValueError(f'The system with the following id is not found in catalog [{generation_id}]')
return _generation_systems
@staticmethod
def _search_storage_equipment(storage_systems, storage_id):
_storage_systems = []
for storage in storage_systems:
if storage.id in storage_id:
_storage_systems.append(storage)
if len(_storage_systems) == 0:
_storage_systems = None
raise ValueError(f'The system with the following id is not found in catalog [{storage_id}]')
return _storage_systems
def names(self, category=None):
"""
Get the catalog elements names
:parm: optional category filter
"""
if category is None:
_names = {'archetypes': [], 'systems': [], 'generation_equipments': [], 'storage_equipments': []}
for archetype in self._content.archetypes:
_names['archetypes'].append(archetype.name)
for system in self._content.systems:
_names['systems'].append(system.name)
for equipment in self._content.generation_equipments:
_names['generation_equipments'].append(equipment.name)
else:
_names = {category: []}
if category.lower() == 'archetypes':
for archetype in self._content.archetypes:
_names[category].append(archetype.name)
elif category.lower() == 'systems':
for system in self._content.systems:
_names[category].append(system.name)
elif category.lower() == 'generation_equipments':
for system in self._content.generation_equipments:
_names[category].append(system.name)
else:
raise ValueError(f'Unknown category [{category}]')
return _names
def entries(self, category=None):
"""
Get the catalog elements
:parm: optional category filter
"""
if category is None:
return self._content
if category.lower() == 'archetypes':
return self._content.archetypes
if category.lower() == 'systems':
return self._content.systems
if category.lower() == 'generation_equipments':
return self._content.generation_equipments
raise ValueError(f'Unknown category [{category}]')
def get_entry(self, name):
"""
Get one catalog element by names
:parm: entry name
"""
for entry in self._content.archetypes:
if entry.name.lower() == name.lower():
return entry
for entry in self._content.systems:
if entry.name.lower() == name.lower():
return entry
for entry in self._content.generation_equipments:
if entry.name.lower() == name.lower():
return entry
raise IndexError(f"{name} doesn't exists in the catalog")

View File

@ -10,6 +10,7 @@ from typing import TypeVar
from hub.catalog_factories.energy_systems.montreal_custom_catalog import MontrealCustomCatalog from hub.catalog_factories.energy_systems.montreal_custom_catalog import MontrealCustomCatalog
from hub.catalog_factories.energy_systems.north_america_energy_system_catalog import NorthAmericaEnergySystemCatalog from hub.catalog_factories.energy_systems.north_america_energy_system_catalog import NorthAmericaEnergySystemCatalog
from hub.catalog_factories.energy_systems.montreal_future_system_catalogue import MontrealFutureSystemCatalogue
from hub.helpers.utils import validate_import_export_type from hub.helpers.utils import validate_import_export_type
Catalog = TypeVar('Catalog') Catalog = TypeVar('Catalog')
@ -40,6 +41,13 @@ class EnergySystemsCatalogFactory:
""" """
return NorthAmericaEnergySystemCatalog(self._path) return NorthAmericaEnergySystemCatalog(self._path)
@property
def _montreal_future(self):
"""
Retrieve North American catalog
"""
return MontrealFutureSystemCatalogue(self._path)
@property @property
def catalog(self) -> Catalog: def catalog(self) -> Catalog:
""" """

View File

@ -90,6 +90,7 @@ class Building(CityObject):
self._interior_slabs.append(surface) self._interior_slabs.append(surface)
else: else:
logging.error('Building %s [%s] has an unexpected surface type %s.', self.name, self.aliases, surface.type) logging.error('Building %s [%s] has an unexpected surface type %s.', self.name, self.aliases, surface.type)
self._heating_consumption_disaggregated = {}
@property @property
def shell(self) -> Polyhedron: def shell(self) -> Polyhedron:
@ -702,6 +703,7 @@ class Building(CityObject):
Get total electricity consumption for distribution and emission systems in J Get total electricity consumption for distribution and emission systems in J
return: dict return: dict
""" """
_distribution_systems_electrical_consumption = {}
if len(self._distribution_systems_electrical_consumption) != 0: if len(self._distribution_systems_electrical_consumption) != 0:
return self._distribution_systems_electrical_consumption return self._distribution_systems_electrical_consumption
_peak_load = self.heating_peak_load[cte.YEAR][0] _peak_load = self.heating_peak_load[cte.YEAR][0]
@ -715,31 +717,33 @@ class Building(CityObject):
if self.energy_systems is None: if self.energy_systems is None:
return self._distribution_systems_electrical_consumption return self._distribution_systems_electrical_consumption
for energy_system in self.energy_systems: for energy_system in self.energy_systems:
emission_system = energy_system.emission_systems.generic_emission_system distribution_systems = energy_system.distribution_systems
parasitic_energy_consumption = 0 for distribution_system in distribution_systems:
if emission_system is not None: emission_systems = distribution_system.emission_systems
parasitic_energy_consumption = emission_system.parasitic_energy_consumption parasitic_energy_consumption = 0
distribution_system = energy_system.distribution_systems.generic_distribution_system if emission_systems is not None:
consumption_variable_flow = distribution_system.distribution_consumption_variable_flow for emission_system in emission_systems:
for demand_type in energy_system.demand_types: parasitic_energy_consumption += emission_system.parasitic_energy_consumption
if demand_type.lower() == cte.HEATING.lower(): consumption_variable_flow = distribution_system.distribution_consumption_variable_flow
if _peak_load_type == cte.HEATING.lower(): for demand_type in energy_system.demand_types:
_consumption_fix_flow = distribution_system.distribution_consumption_fix_flow if demand_type.lower() == cte.HEATING.lower():
for heating_demand_key in self.heating_demand: if _peak_load_type == cte.HEATING.lower():
_consumption = [0]*len(self.heating_demand[heating_demand_key]) _consumption_fix_flow = distribution_system.distribution_consumption_fix_flow
_demand = self.heating_demand[heating_demand_key] for heating_demand_key in self.heating_demand:
for i, _ in enumerate(_consumption): _consumption = [0]*len(self.heating_demand[heating_demand_key])
_consumption[i] += (parasitic_energy_consumption + consumption_variable_flow) * _demand[i] _demand = self.heating_demand[heating_demand_key]
self._distribution_systems_electrical_consumption[heating_demand_key] = _consumption for i, _ in enumerate(_consumption):
if demand_type.lower() == cte.COOLING.lower(): _consumption[i] += (parasitic_energy_consumption + consumption_variable_flow) * _demand[i]
if _peak_load_type == cte.COOLING.lower(): self._distribution_systems_electrical_consumption[heating_demand_key] = _consumption
_consumption_fix_flow = distribution_system.distribution_consumption_fix_flow if demand_type.lower() == cte.COOLING.lower():
for demand_key in self.cooling_demand: if _peak_load_type == cte.COOLING.lower():
_consumption = self._distribution_systems_electrical_consumption[demand_key] _consumption_fix_flow = distribution_system.distribution_consumption_fix_flow
_demand = self.cooling_demand[demand_key] for demand_key in self.cooling_demand:
for i, _ in enumerate(_consumption): _consumption = self._distribution_systems_electrical_consumption[demand_key]
_consumption[i] += (parasitic_energy_consumption + consumption_variable_flow) * _demand[i] _demand = self.cooling_demand[demand_key]
self._distribution_systems_electrical_consumption[demand_key] = _consumption for i, _ in enumerate(_consumption):
_consumption[i] += (parasitic_energy_consumption + consumption_variable_flow) * _demand[i]
self._distribution_systems_electrical_consumption[demand_key] = _consumption
for key, item in self._distribution_systems_electrical_consumption.items(): for key, item in self._distribution_systems_electrical_consumption.items():
for i in range(0, len(item)): for i in range(0, len(item)):
@ -758,13 +762,16 @@ class Building(CityObject):
if demand_type.lower() == consumption_type.lower(): if demand_type.lower() == consumption_type.lower():
if consumption_type in (cte.HEATING, cte.DOMESTIC_HOT_WATER): if consumption_type in (cte.HEATING, cte.DOMESTIC_HOT_WATER):
for generation_system in generation_systems: for generation_system in generation_systems:
coefficient_of_performance = generation_system.heat_efficiency if generation_system.heat_efficiency is not None:
coefficient_of_performance = float(generation_system.heat_efficiency)
elif consumption_type == cte.COOLING: elif consumption_type == cte.COOLING:
for generation_system in generation_systems: for generation_system in generation_systems:
coefficient_of_performance = generation_system.cooling_efficiency if generation_system.cooling_efficiency is not None:
coefficient_of_performance = float(generation_system.cooling_efficiency)
elif consumption_type == cte.ELECTRICITY: elif consumption_type == cte.ELECTRICITY:
for generation_system in generation_systems: for generation_system in generation_systems:
coefficient_of_performance = generation_system.electricity_efficiency if generation_system.electricity_efficiency is not None:
coefficient_of_performance = float(generation_system.electricity_efficiency)
if coefficient_of_performance == 0: if coefficient_of_performance == 0:
values = [0]*len(demand) values = [0]*len(demand)
final_energy_consumed = values final_energy_consumed = values
@ -795,16 +802,37 @@ class Building(CityObject):
if self.energy_systems is None: if self.energy_systems is None:
return self._onsite_electrical_production return self._onsite_electrical_production
for energy_system in self.energy_systems: for energy_system in self.energy_systems:
if energy_system.generation_systems[0].system_type == cte.PHOTOVOLTAIC: for generation_system in energy_system.generation_systems:
_efficiency = energy_system.generation_systems[0].electricity_efficiency if generation_system.system_type == cte.PHOTOVOLTAIC:
self._onsite_electrical_production = {} if generation_system.electricity_efficiency is not None:
for _key in self.roofs[0].global_irradiance.keys(): _efficiency = float(generation_system.electricity_efficiency)
_results = [0 for _ in range(0, len(self.roofs[0].global_irradiance[_key]))] else:
for surface in self.roofs: _efficiency = 0
if _key in orientation_losses_factor: self._onsite_electrical_production = {}
_results = [x + y * _efficiency * surface.perimeter_area for _key in self.roofs[0].global_irradiance.keys():
* surface.solar_collectors_area_reduction_factor * z _results = [0 for _ in range(0, len(self.roofs[0].global_irradiance[_key]))]
for x, y, z in zip(_results, surface.global_irradiance[_key], for surface in self.roofs:
orientation_losses_factor[_key]['south'])] if _key in orientation_losses_factor:
self._onsite_electrical_production[_key] = _results _results = [x + y * _efficiency * surface.perimeter_area
* surface.solar_collectors_area_reduction_factor * z
for x, y, z in zip(_results, surface.global_irradiance[_key],
orientation_losses_factor[_key]['south'])]
self._onsite_electrical_production[_key] = _results
return self._onsite_electrical_production return self._onsite_electrical_production
@property
def heating_consumption_disaggregated(self) -> dict:
"""
Get energy consumed for heating from different fuels in J
return: dict
"""
return self._heating_consumption_disaggregated
@heating_consumption_disaggregated.setter
def heating_consumption_disaggregated(self, value):
"""
Get energy consumed for heating from different fuels in J
return: dict
"""
self._heating_consumption_disaggregated = value

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