2023-03-23 13:31:36 -04:00
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from pathlib import Path
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import pandas as pd
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import hub.helpers.constants as cte
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class Results:
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def __init__(self, city, path):
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self._city = city
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self._path = path
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def print(self):
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print_results = None
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file = 'city name: ' + self._city.name + '\n'
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2023-05-02 12:39:51 -04:00
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array = [None] * 12
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2023-03-23 13:31:36 -04:00
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for building in self._city.buildings:
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2023-06-07 14:48:21 -04:00
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if cte.MONTH in building.heating_demand.keys():
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heating_results = building.heating_demand[cte.MONTH].rename(columns={cte.INSEL_MEB: f'{building.name} heating Wh'})
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2023-05-02 12:39:51 -04:00
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else:
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2023-05-18 11:33:14 -04:00
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heating_results = pd.DataFrame(array, columns=[f'{building.name} heating demand Wh'])
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2023-06-07 14:48:21 -04:00
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if cte.MONTH in building.cooling_demand.keys():
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cooling_results = building.cooling_demand[cte.MONTH].rename(columns={cte.INSEL_MEB: f'{building.name} cooling Wh'})
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2023-05-02 12:39:51 -04:00
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else:
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2023-05-18 11:33:14 -04:00
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cooling_results = pd.DataFrame(array, columns=[f'{building.name} cooling demand Wh'])
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2023-05-02 12:39:51 -04:00
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if cte.MONTH in building.lighting_electrical_demand.keys():
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2023-03-24 11:47:09 -04:00
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lighting_results = building.lighting_electrical_demand[cte.MONTH]\
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.rename(columns={cte.INSEL_MEB: f'{building.name} lighting electrical demand Wh'})
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2023-05-02 12:39:51 -04:00
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else:
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lighting_results = pd.DataFrame(array, columns=[f'{building.name} lighting electrical demand Wh'])
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if cte.MONTH in building.appliances_electrical_demand.keys():
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2023-05-18 11:36:45 -04:00
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appliances_results = building.appliances_electrical_demand[cte.MONTH]\
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2023-03-24 11:47:09 -04:00
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.rename(columns={cte.INSEL_MEB: f'{building.name} appliances electrical demand Wh'})
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2023-05-02 12:39:51 -04:00
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else:
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appliances_results = pd.DataFrame(array, columns=[f'{building.name} appliances electrical demand Wh'])
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if cte.MONTH in building.domestic_hot_water_heat_demand.keys():
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2023-03-24 11:47:09 -04:00
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dhw_results = building.domestic_hot_water_heat_demand[cte.MONTH]\
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.rename(columns={cte.INSEL_MEB: f'{building.name} domestic hot water demand Wh'})
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else:
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dhw_results = pd.DataFrame(array, columns=[f'{building.name} domestic hot water demand Wh'])
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2023-05-18 11:33:14 -04:00
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if cte.MONTH in building.heating_consumption.keys():
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2023-05-18 11:36:45 -04:00
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heating_consumption_results = pd.DataFrame(building.heating_consumption[cte.MONTH],
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columns=[f'{building.name} heating consumption Wh'])
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2023-05-18 11:33:14 -04:00
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else:
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heating_consumption_results = pd.DataFrame(array, columns=[f'{building.name} heating consumption Wh'])
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if cte.MONTH in building.cooling_consumption.keys():
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2023-05-18 11:36:45 -04:00
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cooling_consumption_results = pd.DataFrame(building.cooling_consumption[cte.MONTH],
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columns=[f'{building.name} cooling consumption Wh'])
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2023-05-18 11:33:14 -04:00
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else:
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cooling_consumption_results = pd.DataFrame(array, columns=[f'{building.name} cooling consumption Wh'])
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if cte.MONTH in building.domestic_hot_water_consumption.keys():
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2023-05-18 11:36:45 -04:00
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dhw_consumption_results = pd.DataFrame(building.domestic_hot_water_consumption[cte.MONTH],
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columns=[f'{building.name} domestic hot water consumption Wh'])
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2023-05-18 11:33:14 -04:00
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else:
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dhw_consumption_results = pd.DataFrame(array, columns=[f'{building.name} domestic hot water consumption Wh'])
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if cte.MONTH in building.heating_peak_load.keys():
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2023-06-07 14:48:21 -04:00
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heating_peak_load_results = pd.DataFrame(building.heating_peak_load[cte.MONTH],
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columns=[f'{building.name} heating peak load W'])
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2023-05-18 11:33:14 -04:00
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else:
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heating_peak_load_results = pd.DataFrame(array, columns=[f'{building.name} heating peak load W'])
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if cte.MONTH in building.cooling_peak_load.keys():
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2023-06-07 14:48:21 -04:00
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cooling_peak_load_results = pd.DataFrame(building.cooling_peak_load[cte.MONTH],
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columns=[f'{building.name} cooling peak load W'])
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2023-05-18 11:33:14 -04:00
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else:
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cooling_peak_load_results = pd.DataFrame(array, columns=[f'{building.name} cooling peak load W'])
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2023-05-29 14:58:51 -04:00
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if cte.MONTH in building.onsite_electrical_production.keys():
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monthly_onsite_electrical_production = building.onsite_electrical_production[cte.MONTH]
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onsite_electrical_production = pd.DataFrame(monthly_onsite_electrical_production,
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columns=[f'{building.name} onsite electrical production Wh'])
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else:
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onsite_electrical_production = pd.DataFrame(array, columns=[f'{building.name} onsite electrical production Wh'])
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heating = 0
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cooling = 0
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for system in building.energy_systems:
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for demand_type in system.demand_types:
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if demand_type == cte.HEATING:
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heating = 1
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if demand_type == cte.COOLING:
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cooling = 1
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if cte.MONTH in building.heating_peak_load.keys() and cte.MONTH in building.cooling_peak_load.keys():
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peak_lighting = 0
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peak_appliances = 0
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for thermal_zone in building.internal_zones[0].thermal_zones:
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lighting = thermal_zone.lighting
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for schedule in lighting.schedules:
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for value in schedule.values:
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if value * lighting.density * thermal_zone.total_floor_area > peak_lighting:
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peak_lighting = value * lighting.density * thermal_zone.total_floor_area
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appliances = thermal_zone.appliances
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for schedule in appliances.schedules:
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for value in schedule.values:
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if value * appliances.density * thermal_zone.total_floor_area > peak_appliances:
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peak_appliances = value * appliances.density * thermal_zone.total_floor_area
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2023-06-07 14:48:21 -04:00
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monthly_electricity_peak = [0.9 * peak_lighting + 0.7 * peak_appliances] * 12
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2023-05-29 14:58:51 -04:00
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conditioning_peak = []
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2023-06-07 14:48:21 -04:00
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for i, value in enumerate(building.heating_peak_load[cte.MONTH]):
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if cooling * building.cooling_peak_load[cte.MONTH][i] > heating * value:
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conditioning_peak.append(cooling * building.cooling_peak_load[cte.MONTH][i])
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2023-05-29 14:58:51 -04:00
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else:
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conditioning_peak.append(heating * value)
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monthly_electricity_peak[i] += 0.8 * conditioning_peak[i]
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electricity_peak_load_results = pd.DataFrame(monthly_electricity_peak
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, columns=[f'{building.name} electricity peak load W'])
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else:
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electricity_peak_load_results = pd.DataFrame(array, columns=[f'{building.name} electricity peak load W'])
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if cte.MONTH in building.distribution_systems_electrical_consumption.keys():
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extra_electrical_consumption = pd.DataFrame(building.distribution_systems_electrical_consumption[cte.MONTH],
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columns=[
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f'{building.name} electrical consumption for distribution Wh'])
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else:
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extra_electrical_consumption = pd.DataFrame(array,
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columns=[
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f'{building.name} electrical consumption for distribution Wh'])
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2023-03-23 13:31:36 -04:00
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if print_results is None:
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print_results = heating_results
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else:
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print_results = pd.concat([print_results, heating_results], axis='columns')
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2023-03-23 13:49:41 -04:00
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print_results = pd.concat([print_results,
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cooling_results,
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lighting_results,
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appliances_results,
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2023-05-18 11:33:14 -04:00
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dhw_results,
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heating_consumption_results,
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cooling_consumption_results,
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dhw_consumption_results,
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heating_peak_load_results,
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2023-05-29 14:58:51 -04:00
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cooling_peak_load_results,
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electricity_peak_load_results,
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onsite_electrical_production,
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extra_electrical_consumption], axis='columns')
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2023-03-23 13:31:36 -04:00
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file += '\n'
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2023-03-24 11:47:09 -04:00
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file += f'name: {building.name}\n'
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file += f'year of construction: {building.year_of_construction}\n'
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file += f'function: {building.function}\n'
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file += f'floor area: {building.floor_area}\n'
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if building.average_storey_height is not None and building.eave_height is not None:
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file += f'storeys: {int(building.eave_height / building.average_storey_height)}\n'
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else:
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file += f'storeys: n/a\n'
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file += f'volume: {building.volume}\n'
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2023-03-23 13:31:36 -04:00
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full_path_results = Path(self._path / 'demand.csv').resolve()
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print_results.to_csv(full_path_results, na_rep='null')
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full_path_metadata = Path(self._path / 'metadata.csv').resolve()
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with open(full_path_metadata, 'w') as metadata_file:
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metadata_file.write(file)
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2023-07-07 10:12:48 -04:00
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def outputsforgraph(self):
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file = 'city name: ' + self._city.name + '\n'
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array = [None] * 12
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for building in self._city.buildings:
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if cte.MONTH in building.heating_demand.keys():
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heating_results = building.heating_demand[cte.MONTH].rename(
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columns={cte.INSEL_MEB: f'{building.name} heating Wh'})
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else:
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heating_results = pd.DataFrame(array, columns=[f'{building.name} heating demand Wh'])
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if cte.MONTH in building.cooling_demand.keys():
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cooling_results = building.cooling_demand[cte.MONTH].rename(
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columns={cte.INSEL_MEB: f'{building.name} cooling Wh'})
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else:
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cooling_results = pd.DataFrame(array, columns=[f'{building.name} cooling demand Wh'])
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if cte.MONTH in building.lighting_electrical_demand.keys():
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lighting_results = building.lighting_electrical_demand[cte.MONTH] \
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.rename(columns={cte.INSEL_MEB: f'{building.name} lighting electrical demand Wh'})
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else:
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lighting_results = pd.DataFrame(array, columns=[f'{building.name} lighting electrical demand Wh'])
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if cte.MONTH in building.appliances_electrical_demand.keys():
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appliances_results = building.appliances_electrical_demand[cte.MONTH] \
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.rename(columns={cte.INSEL_MEB: f'{building.name} appliances electrical demand Wh'})
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else:
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appliances_results = pd.DataFrame(array, columns=[f'{building.name} appliances electrical demand Wh'])
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if cte.MONTH in building.domestic_hot_water_heat_demand.keys():
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dhw_results = building.domestic_hot_water_heat_demand[cte.MONTH] \
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.rename(columns={cte.INSEL_MEB: f'{building.name} domestic hot water demand Wh'})
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else:
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dhw_results = pd.DataFrame(array, columns=[f'{building.name} domestic hot water demand Wh'])
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if cte.MONTH in building.heating_consumption.keys():
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heating_consumption_results = pd.DataFrame(building.heating_consumption[cte.MONTH],
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columns=[f'{building.name} heating consumption Wh'])
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else:
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heating_consumption_results = pd.DataFrame(array, columns=[f'{building.name} heating consumption Wh'])
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if cte.MONTH in building.cooling_consumption.keys():
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cooling_consumption_results = pd.DataFrame(building.cooling_consumption[cte.MONTH],
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columns=[f'{building.name} cooling consumption Wh'])
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else:
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cooling_consumption_results = pd.DataFrame(array, columns=[f'{building.name} cooling consumption Wh'])
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if cte.MONTH in building.domestic_hot_water_consumption.keys():
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dhw_consumption_results = pd.DataFrame(building.domestic_hot_water_consumption[cte.MONTH],
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columns=[f'{building.name} domestic hot water consumption Wh'])
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else:
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dhw_consumption_results = pd.DataFrame(array, columns=[f'{building.name} domestic hot water consumption Wh'])
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if cte.MONTH in building.heating_peak_load.keys():
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heating_peak_load_results = pd.DataFrame(building.heating_peak_load[cte.MONTH],
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columns=[f'{building.name} heating peak load W'])
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else:
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heating_peak_load_results = pd.DataFrame(array, columns=[f'{building.name} heating peak load W'])
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if cte.MONTH in building.cooling_peak_load.keys():
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cooling_peak_load_results = pd.DataFrame(building.cooling_peak_load[cte.MONTH],
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columns=[f'{building.name} cooling peak load W'])
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else:
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cooling_peak_load_results = pd.DataFrame(array, columns=[f'{building.name} cooling peak load W'])
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if cte.MONTH in building.onsite_electrical_production.keys():
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monthly_onsite_electrical_production = building.onsite_electrical_production[cte.MONTH]
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onsite_electrical_production = pd.DataFrame(monthly_onsite_electrical_production,
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columns=[f'{building.name} onsite electrical production Wh'])
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else:
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onsite_electrical_production = pd.DataFrame(array,
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columns=[f'{building.name} onsite electrical production Wh'])
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heating = 0
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cooling = 0
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for system in building.energy_systems:
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for demand_type in system.demand_types:
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if demand_type == cte.HEATING:
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heating = 1
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if demand_type == cte.COOLING:
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cooling = 1
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if cte.MONTH in building.heating_peak_load.keys() and cte.MONTH in building.cooling_peak_load.keys():
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peak_lighting = 0
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peak_appliances = 0
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for thermal_zone in building.internal_zones[0].thermal_zones:
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lighting = thermal_zone.lighting
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for schedule in lighting.schedules:
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for value in schedule.values:
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if value * lighting.density * thermal_zone.total_floor_area > peak_lighting:
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peak_lighting = value * lighting.density * thermal_zone.total_floor_area
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appliances = thermal_zone.appliances
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for schedule in appliances.schedules:
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for value in schedule.values:
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if value * appliances.density * thermal_zone.total_floor_area > peak_appliances:
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peak_appliances = value * appliances.density * thermal_zone.total_floor_area
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monthly_electricity_peak = [0.9 * peak_lighting + 0.7 * peak_appliances] * 12
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conditioning_peak = []
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for i, value in enumerate(building.heating_peak_load[cte.MONTH]):
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if cooling * building.cooling_peak_load[cte.MONTH][i] > heating * value:
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conditioning_peak.append(cooling * building.cooling_peak_load[cte.MONTH][i])
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else:
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conditioning_peak.append(heating * value)
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monthly_electricity_peak[i] += 0.8 * conditioning_peak[i]
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electricity_peak_load_results = pd.DataFrame(monthly_electricity_peak
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, columns=[f'{building.name} electricity peak load W'])
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else:
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electricity_peak_load_results = pd.DataFrame(array, columns=[f'{building.name} electricity peak load W'])
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if cte.MONTH in building.distribution_systems_electrical_consumption.keys():
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extra_electrical_consumption = pd.DataFrame(building.distribution_systems_electrical_consumption[cte.MONTH],
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columns=[
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f'{building.name} electrical consumption for distribution Wh'])
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else:
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extra_electrical_consumption = pd.DataFrame(array,
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columns=[
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f'{building.name} electrical consumption for distribution Wh'])
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if print_results is None:
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print_results = heating_results
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else:
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print_results = pd.concat([print_results, heating_results], axis='columns')
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print_results = pd.concat([print_results,
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cooling_results,
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lighting_results,
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appliances_results,
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dhw_results,
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heating_consumption_results,
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cooling_consumption_results,
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dhw_consumption_results,
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heating_peak_load_results,
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cooling_peak_load_results,
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electricity_peak_load_results,
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onsite_electrical_production,
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extra_electrical_consumption], axis='columns')
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file += '\n'
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file += f'name: {building.name}\n'
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file += f'year of construction: {building.year_of_construction}\n'
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file += f'function: {building.function}\n'
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file += f'floor area: {building.floor_area}\n'
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if building.average_storey_height is not None and building.eave_height is not None:
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file += f'storeys: {int(building.eave_height / building.average_storey_height)}\n'
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else:
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file += f'storeys: n/a\n'
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file += f'volume: {building.volume}\n'
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|
full_path_results = Path(self._path / 'demand.csv').resolve()
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|
print_results.to_csv(full_path_results, na_rep='null')
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full_path_metadata = Path(self._path / 'metadata.csv').resolve()
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with open(full_path_metadata, 'w') as metadata_file:
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metadata_file.write(file)
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