214 lines
12 KiB
Python
214 lines
12 KiB
Python
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import math
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import csv
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import hub.helpers.constants as cte
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from pv_assessment.electricity_demand_calculator import HourlyElectricityDemand
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from hub.catalog_factories.energy_systems_catalog_factory import EnergySystemsCatalogFactory
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from hub.helpers.monthly_values import MonthlyValues
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class PvSystemProduction:
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def __init__(self, building=None, pv_system=None, battery=None, tilt_angle=None,
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solar_angles=None, pv_installation_type=None, simulation_model_type=None, module_model_name=None,
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inverter_efficiency=None, system_catalogue_handler=None, roof_percentage_coverage=None,
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facade_coverage_percentage=None, csv_output=False, output_path=None):
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"""
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:param building:
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:param tilt_angle:
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:param solar_angles:
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:param simulation_model_type:
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:param module_model_name:
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:param inverter_efficiency:
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:param system_catalogue_handler:
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:param roof_percentage_coverage:
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:param facade_coverage_percentage:
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"""
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self.building = building
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self.tilt_angle = tilt_angle
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self.solar_angles = solar_angles
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self.pv_installation_type = pv_installation_type
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self.simulation_model_type = simulation_model_type
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self.module_model_name = module_model_name
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self.inverter_efficiency = inverter_efficiency
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self.system_catalogue_handler = system_catalogue_handler
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self.roof_percentage_coverage = roof_percentage_coverage
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self.facade_coverage_percentage = facade_coverage_percentage
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self.pv_hourly_generation = None
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self.t_cell = None
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self.results = {}
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self.csv_output = csv_output
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self.output_path = output_path
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if pv_system is not None:
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self.pv_system = pv_system
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else:
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for energy_system in self.building.energy_systems:
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for generation_system in energy_system.generation_systems:
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if generation_system.system_type == cte.PHOTOVOLTAIC:
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self.pv_system = generation_system
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if battery is not None:
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self.battery = battery
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else:
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for energy_system in self.building.energy_systems:
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for generation_system in energy_system.generation_systems:
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if generation_system.system_type == cte.PHOTOVOLTAIC and generation_system.energy_storage_systems is not None:
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for storage_system in generation_system.energy_storage_systems:
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if storage_system.type_energy_stored == cte.ELECTRICAL:
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self.battery = storage_system
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@staticmethod
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def explicit_model(pv_system, inverter_efficiency, number_of_panels, irradiance, outdoor_temperature):
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inverter_efficiency = inverter_efficiency
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stc_power = float(pv_system.standard_test_condition_maximum_power)
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stc_irradiance = float(pv_system.standard_test_condition_radiation)
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cell_temperature_coefficient = float(pv_system.cell_temperature_coefficient) / 100 if (
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pv_system.cell_temperature_coefficient is not None) else None
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stc_t_cell = float(pv_system.standard_test_condition_cell_temperature)
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nominal_condition_irradiance = float(pv_system.nominal_radiation)
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nominal_condition_cell_temperature = float(pv_system.nominal_cell_temperature)
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nominal_t_out = float(pv_system.nominal_ambient_temperature)
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g_i = irradiance
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t_out = outdoor_temperature
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t_cell = []
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pv_output = []
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for i in range(len(g_i)):
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t_cell.append((t_out[i] + (g_i[i] / nominal_condition_irradiance) *
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(nominal_condition_cell_temperature - nominal_t_out)))
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pv_output.append((inverter_efficiency * number_of_panels * (stc_power * (g_i[i] / stc_irradiance) *
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(1 - cell_temperature_coefficient *
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(t_cell[i] - stc_t_cell)))))
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return pv_output
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def rooftop_sizing(self, roof):
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pv_system = self.pv_system
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if self.module_model_name is not None:
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self.system_assignation()
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# System Sizing
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module_width = float(pv_system.width)
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module_height = float(pv_system.height)
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roof_area = roof.perimeter_area
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pv_module_area = module_width * module_height
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available_roof = (self.roof_percentage_coverage * roof_area)
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# Inter-Row Spacing
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winter_solstice = self.solar_angles[(self.solar_angles['AST'].dt.month == 12) &
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(self.solar_angles['AST'].dt.day == 21) &
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(self.solar_angles['AST'].dt.hour == 12)]
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solar_altitude = winter_solstice['solar altitude'].values[0]
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solar_azimuth = winter_solstice['solar azimuth'].values[0]
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distance = ((module_height * math.sin(math.radians(self.tilt_angle)) * abs(
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math.cos(math.radians(solar_azimuth)))) / math.tan(math.radians(solar_altitude)))
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distance = float(format(distance, '.2f'))
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# Calculation of the number of panels
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space_dimension = math.sqrt(available_roof)
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space_dimension = float(format(space_dimension, '.2f'))
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panels_per_row = math.ceil(space_dimension / module_width)
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number_of_rows = math.ceil(space_dimension / distance)
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total_number_of_panels = panels_per_row * number_of_rows
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total_pv_area = total_number_of_panels * pv_module_area
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roof.installed_solar_collector_area = total_pv_area
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return panels_per_row, number_of_rows
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def system_assignation(self):
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generation_units_catalogue = EnergySystemsCatalogFactory(self.system_catalogue_handler).catalog
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catalog_pv_generation_equipments = [component for component in
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generation_units_catalogue.entries('generation_equipments') if
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component.system_type == 'photovoltaic']
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selected_pv_module = None
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for pv_module in catalog_pv_generation_equipments:
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if self.module_model_name == pv_module.model_name:
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selected_pv_module = pv_module
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if selected_pv_module is None:
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raise ValueError("No PV module with the provided model name exists in the catalogue")
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for energy_system in self.building.energy_systems:
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for idx, generation_system in enumerate(energy_system.generation_systems):
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if generation_system.system_type == cte.PHOTOVOLTAIC:
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new_system = selected_pv_module
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# Preserve attributes that exist in the original but not in the new system
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for attr in dir(generation_system):
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# Skip private attributes and methods
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if not attr.startswith('__') and not callable(getattr(generation_system, attr)):
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if not hasattr(new_system, attr):
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setattr(new_system, attr, getattr(generation_system, attr))
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# Replace the old generation system with the new one
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energy_system.generation_systems[idx] = new_system
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def grid_tied_system(self):
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rooftops_pv_output = [0] * 8760
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facades_pv_output = [0] * 8760
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rooftop_number_of_panels = 0
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if 'rooftop' in self.pv_installation_type.lower():
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for roof in self.building.roofs:
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if roof.perimeter_area > 40:
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np, ns = self.rooftop_sizing(roof)
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single_roof_number_of_panels = np * ns
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rooftop_number_of_panels += single_roof_number_of_panels
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if self.simulation_model_type == 'explicit':
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single_roof_pv_output = self.explicit_model(pv_system=self.pv_system,
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inverter_efficiency=self.inverter_efficiency,
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number_of_panels=single_roof_number_of_panels,
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irradiance=roof.global_irradiance_tilted[cte.HOUR],
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outdoor_temperature=self.building.external_temperature[
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cte.HOUR])
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for i in range(len(rooftops_pv_output)):
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rooftops_pv_output[i] += single_roof_pv_output[i]
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total_hourly_pv_output = [rooftops_pv_output[i] + facades_pv_output[i] for i in range(8760)]
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results = {'building_name': self.building.name,
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'total_floor_area_m2': self.building.thermal_zones_from_internal_zones[0].total_floor_area,
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'roof_area_m2': self.building.roofs[0].perimeter_area, 'rooftop_panels': rooftop_number_of_panels,
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'rooftop_panels_area_m2': self.building.roofs[0].installed_solar_collector_area,
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'yearly_rooftop_ghi_kW/m2': self.building.roofs[0].global_irradiance[cte.YEAR][0] / 1000,
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f'yearly_rooftop_tilted_radiation_{self.tilt_angle}_degree_kW/m2':
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self.building.roofs[0].global_irradiance_tilted[cte.YEAR][0] / 1000,
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'yearly_rooftop_pv_production_kWh': sum(rooftops_pv_output) / 1000,
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'yearly_total_pv_production_kWh': sum(total_hourly_pv_output) / 1000,
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'specific_pv_production_kWh/kWp': sum(rooftops_pv_output) / (
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float(self.pv_system.standard_test_condition_maximum_power) * rooftop_number_of_panels),
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'hourly_rooftop_poa_irradiance_W/m2': self.building.roofs[0].global_irradiance_tilted[cte.HOUR],
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'hourly_rooftop_pv_output_W': rooftops_pv_output, 'T_out': self.building.external_temperature[cte.HOUR],
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'total_hourly_pv_system_output_W': total_hourly_pv_output}
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return results
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def enrich(self):
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system_archetype_name = self.building.energy_systems_archetype_name
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archetype_name = '_'.join(system_archetype_name.lower().split())
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if 'grid_tied' in archetype_name:
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self.results = self.grid_tied_system()
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for energy_system in self.building.energy_systems:
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for generation_system in energy_system.generation_systems:
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if generation_system.system_type == cte.PHOTOVOLTAIC:
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generation_system.installed_capacity = (self.results['rooftop_panels'] *
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float(generation_system.standard_test_condition_maximum_power))
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hourly_pv_output = self.results['total_hourly_pv_system_output_W']
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self.building.pv_generation[cte.HOUR] = hourly_pv_output
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self.building.pv_generation[cte.MONTH] = MonthlyValues.get_total_month(hourly_pv_output)
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self.building.pv_generation[cte.YEAR] = [sum(hourly_pv_output)]
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if self.csv_output:
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self.save_to_csv(self.results, self.output_path, f'{self.building.name}_pv_system_analysis.csv')
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@staticmethod
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def save_to_csv(data, output_path, filename='rooftop_system_results.csv'):
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# Separate keys based on whether their values are single values or lists
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single_value_keys = [key for key, value in data.items() if not isinstance(value, list)]
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list_value_keys = [key for key, value in data.items() if isinstance(value, list)]
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# Check if all lists have the same length
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list_lengths = [len(data[key]) for key in list_value_keys]
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if not all(length == list_lengths[0] for length in list_lengths):
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raise ValueError("All lists in the dictionary must have the same length")
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# Get the length of list values (assuming all lists are of the same length, e.g., 8760 for hourly data)
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num_rows = list_lengths[0] if list_value_keys else 1
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# Open the CSV file for writing
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with open(output_path / filename, mode='w', newline='') as csv_file:
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writer = csv.writer(csv_file)
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# Write single-value data as a header section
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for key in single_value_keys:
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writer.writerow([key, data[key]])
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# Write an empty row for separation
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writer.writerow([])
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# Write the header for the list values
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writer.writerow(list_value_keys)
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# Write each row for the lists
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for i in range(num_rows):
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row = [data[key][i] for key in list_value_keys]
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writer.writerow(row)
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