def test_apply_mvs(self, margs): """ """ main.apply_pvcompare( storeys=self.storeys, country=self.country, latitude=self.latitude, longitude=self.longitude, year=self.year, static_inputs_directory=self.static_inputs_directory, user_inputs_pvcompare_directory=self.user_inputs_pvcompare_directory, user_inputs_mvs_directory=self.user_inputs_mvs_directory, collections_mvs_inputs_directory=self.user_inputs_collection_mvs, plot=False, pv_setup=None, overwrite_grid_parameters=True, overwrite_pv_parameters=True, ) main.apply_mvs( scenario_name=self.scenario_name, outputs_directory=self.outputs_directory, user_inputs_mvs_directory=self.user_inputs_mvs_directory, ) assert os.path.isdir(os.path.join(self.outputs_directory, self.scenario_name))
def test_implementations_tes(self, margs): """ This test checks if the results of two different ways of implementing a stratified thermal storage match. You can include a stratified thermal storage in the model using two ways: 1. With storage component with `inflow_direction` and `outflow_direction` to the heat bus 2. With a storage bus, a storage component and `inflow_direction` and `outflow_direction` as Transformer feeding in and from that bus Please note that the cost parameters of `inflow_direction` and `outflow_direction` of the Transformer should be set to zero, since they cannot be assigned to a real plant component with cost parameters Parameters ---------- margs """ # Simulation of first way of implementation main.apply_pvcompare( storeys=self.storeys, country=self.country, latitude=self.lat, longitude=self.lon, year=self.year, static_inputs_directory=self.static_inputs_directory, user_inputs_pvcompare_directory=self.user_inputs_pvcompare_directory, user_inputs_mvs_directory=self.user_inputs_mvs_directory, plot=False, pv_setup=self.pv_setup, overwrite_grid_parameters=True, overwrite_pv_parameters=True, ) # RUN MVS OEMOF SIMULATTION main.apply_mvs( scenario_name=self.scenario_name, outputs_directory=self.outputs_directory, user_inputs_mvs_directory=self.user_inputs_mvs_directory, ) # Read results of simulation with first way of implementation results_storage_heat_bus = pd.read_excel( os.path.join( self.outputs_directory, self.scenario_name, "mvs_outputs", "timeseries_all_busses.xlsx", ), sheet_name="Heat bus", ) # Revert changes made in storage_xx.csv file self.storage_xx_original.to_csv( os.path.join(self.mvs_csv_inputs_path, "storage_TES.csv"), na_rep="NaN" ) # Calculated files in time_series directory need to be deleted to ensure # the next simulation is run completely time_series_directory = os.path.join( self.user_inputs_mvs_directory, "time_series" ) time_series = os.listdir(time_series_directory) for file_name in time_series: if file_name != "file_exists.csv": os.remove(os.path.join(time_series_directory, file_name)) # Modify mvs csv input data as a preparation for the simulation of # the second way of implementation (see below) # Add "TES bus" to busses energy_busses = self.energy_busses_original.copy() energy_busses["TES bus"] = "Heat" energy_busses.to_csv( os.path.join(self.mvs_csv_inputs_path, "energyBusses.csv"), na_rep="NaN" ) # Add TES input and output converter to transformers energy_conversion = self.energy_conversion_original.copy() energy_conversion["TES converter in"] = [ "kW", "True", "None", 0, 0, 30, 0, 0, 0, 0, 1, "Heat bus", "TES bus", "Heat", "transformer", ] energy_conversion["TES converter out"] = [ "kW", "True", "None", 0, 0, 30, 0, 0, 0, 0, 1, "TES bus", "Heat bus", "Heat", "transformer", ] energy_conversion.to_csv( os.path.join(self.mvs_csv_inputs_path, "energyConversion.csv"), na_rep="NaN" ) # Adapt inflow and outflow direction of storage to "TES bus" energy_storage = self.energy_storage_original.copy() energy_storage.at["inflow_direction", "storage_TES"] = "TES bus" energy_storage.at["outflow_direction", "storage_TES"] = "TES bus" energy_storage.to_csv( os.path.join(self.mvs_csv_inputs_path, "energyStorage.csv"), na_rep="NaN" ) # Simulation of second way of implementation main.apply_pvcompare( storeys=self.storeys, country=self.country, latitude=self.lat, longitude=self.lon, year=self.year, static_inputs_directory=self.static_inputs_directory, user_inputs_pvcompare_directory=self.user_inputs_pvcompare_directory, user_inputs_mvs_directory=self.user_inputs_mvs_directory, plot=False, pv_setup=self.pv_setup, overwrite_grid_parameters=True, overwrite_pv_parameters=True, ) # RUN MVS OEMOF SIMULATTION main.apply_mvs( scenario_name=self.scenario_name_with_TES_bus, outputs_directory=self.outputs_directory, user_inputs_mvs_directory=self.user_inputs_mvs_directory, ) # Read results of simulation with second way of implementation results_storage_tes_bus = pd.read_excel( os.path.join( self.outputs_directory, self.scenario_name_with_TES_bus, "mvs_outputs", "timeseries_all_busses.xlsx", ), sheet_name="Heat bus", ) # Assert that results of both implementations match assert ( results_storage_heat_bus["TES input power"].values.all() == results_storage_tes_bus["TES converter in"].values.all() ) assert ( results_storage_heat_bus["TES output power"].values.all() == results_storage_tes_bus["TES converter out"].values.all() ) # Revert changes made in mvs csv input files self.storage_xx_original.to_csv( os.path.join(self.mvs_csv_inputs_path, "storage_TES.csv"), na_rep="NaN" ) self.energy_busses_original.to_csv( os.path.join(self.mvs_csv_inputs_path, "energyBusses.csv"), na_rep="NaN" ) self.energy_conversion_original.to_csv( os.path.join(self.mvs_csv_inputs_path, "energyConversion.csv"), na_rep="NaN" ) self.energy_storage_original.to_csv( os.path.join(self.mvs_csv_inputs_path, "energyStorage.csv"), na_rep="NaN" ) self.energy_production_original = pd.read_csv( os.path.join(self.mvs_csv_inputs_path, "energyProduction.csv"), header=0, index_col=0, ) scenarios = [self.scenario_name, self.scenario_name_with_TES_bus] for scenario in scenarios: outputs_directory = os.path.join(self.outputs_directory, scenario) if os.path.exists(outputs_directory): shutil.rmtree(outputs_directory)
user_inputs_mvs_directory = constants.EXAMPLE_USER_INPUTS_MVS_ELECTRICITY pv_setup = None outputs_directory = constants.EXAMPLE_OUTPUTS_DIRECTORY # RUN PVCOMPARE PRE-CALCULATIONS: # - calculate PV timeseries # - if sectorcoupling: calculate heat pump generation # - calculate electricity and heat demand main.apply_pvcompare( storeys=storeys, country=country, latitude=latitude, longitude=longitude, year=year, static_inputs_directory=static_inputs_directory, user_inputs_pvcompare_directory=user_inputs_pvcompare_directory, user_inputs_mvs_directory=user_inputs_mvs_directory, plot=False, pv_setup=pv_setup, overwrite_grid_parameters=True, overwrite_pv_parameters=True, ) # RUN MVS OEMOF SIMULATTION main.apply_mvs( scenario_name=scenario_name, outputs_directory=outputs_directory, user_inputs_mvs_directory=user_inputs_mvs_directory, )
def loop_mvs( latitude, longitude, years, storeys, country, variable_name, variable_column, csv_file_variable, start, stop, step, scenario_name, user_inputs_mvs_directory=None, outputs_directory=None, ): """ Starts multiple MVS simulations with a range of values for a specific parameter. This function applies :py:func:`~.main.apply_pvcompare`, one time. After that :py:func:`~.main.apply_mvs` is executed in a loop. Before each loop a specific variable value is changed. The results, stored in two excel sheets, are copied into `loop_output_directory`. Parameters ---------- latitude: float latitude of the location longitude: foat longitude of the location years: list year(s) for simulation storeys:int number of storeys country: str country of location variable_name: str name of the variable that is atapted in each loop variable_column: str name of the variable column in the csv file csv_file_variable: str name of the csv file the variable is saved in start: int first value of the variable stop: int last value of the variable. notice that stop > start step: int step of increase scenario_name: str Name of the Scenario. The name should follow the scheme: "Scenario_A1", "Scenario_A2", "Scenario_B1" etc. user_inputs_mvs_directory: str or None Default: `user_inputs_mvs_directory = constants.DEFAULT_USER_INPUTS_MVS_DIRECTORY` outputs_directory: str or None Path to output directory. Default: `outputs_directory = constants.DEFAULT_OUTPUTS_DIRECTORY` Returns ------- """ if outputs_directory is None: outputs_directory = constants.DEFAULT_OUTPUTS_DIRECTORY loop_output_directory = create_loop_output_structure( outputs_directory, scenario_name, variable_name ) # define filename of variable that should be looped over if user_inputs_mvs_directory is None: user_inputs_mvs_directory = constants.DEFAULT_USER_INPUTS_MVS_DIRECTORY csv_filename = os.path.join( user_inputs_mvs_directory, "csv_elements", csv_file_variable ) # loop over years for year in years: # apply pvcompare main.apply_pvcompare( latitude=latitude, longitude=longitude, year=year, storeys=storeys, country=country, user_inputs_mvs_directory=user_inputs_mvs_directory, ) # loop over the variable i = start while i <= stop: # change variable value and save this value to csv csv_file = pd.read_csv(csv_filename, index_col=0) csv_file.loc[[variable_name], [variable_column]] = i csv_file.to_csv(csv_filename) # define mvs_output_directory for every looping step mvs_output_directory = os.path.join( outputs_directory, scenario_name, "mvs_outputs_loop_" + str(variable_name) + "_" + str(year) + "_" + str(i), ) # apply mvs for every looping step main.apply_mvs( scenario_name=scenario_name, mvs_output_directory=mvs_output_directory, user_inputs_mvs_directory=user_inputs_mvs_directory, outputs_directory=outputs_directory, ) # copy excel sheets to loop_output_directory number_digits = len(str(stop)) - len(str(i)) if number_digits == 0: j = str(i) elif number_digits == 1: j = "0" + str(i) elif number_digits == 2: j = "00" + str(i) elif number_digits == 3: j = "000" + str(i) elif number_digits == 4: j = "0000" + str(i) excel_file1 = "scalars.xlsx" new_excel_file1 = "scalars_" + str(year) + "_" + str(j) + ".xlsx" src_dir = os.path.join(mvs_output_directory, excel_file1) dst_dir = os.path.join(loop_output_directory, "scalars", new_excel_file1) shutil.copy(src_dir, dst_dir) excel_file2 = "timeseries_all_busses.xlsx" new_excel_file2 = ( "timeseries_all_busses_" + str(year) + "_" + str(j) + ".xlsx" ) src_dir = os.path.join(mvs_output_directory, excel_file2) dst_dir = os.path.join(loop_output_directory, "timeseries", new_excel_file2) shutil.copy(src_dir, dst_dir) # add another step i = i + step logging.info("starting postprocessing KPI") postprocessing_kpi( scenario_name=scenario_name, variable_name=variable_name, outputs_directory=outputs_directory, )
def single_loop_pvcompare( scenario_name, storeys, country, latitude, longitude, year, user_inputs_pvcompare_directory, user_inputs_mvs_directory, outputs_directory, plot, pv_setup, loop_output_directory, loop_type, step, ): """ Parameters ---------- scenario_name: str name of the scenario. storeys: int number of storeys country: str country name latitude: float latitude of the location longitude: foat longitude of the location year: int year user_inputs_pvcompare_directory: str or None If None, `constants.DEFAULT_USER_INPUTS_PVCOMPARE_DIRECTORY` is used as user_input_directory. Default: None. user_inputs_mvs_directory: str or None Default: `user_inputs_mvs_directory = constants.DEFAULT_USER_INPUTS_MVS_DIRECTORY` outputs_directory: str or None Path to output directory. Default: `outputs_directory = constants.DEFAULT_OUTPUTS_DIRECTORY` plot: bool default: False loop_output_directory: str output directory defined in 'pvcompare.outputs.create_loop_output_structure()'. loop_type: str possible values: 'location', 'year', 'storeys', 'technology', 'hp_temp'. Defines the variable or variables that are changed with each loop. step: str or int Gradation of the loop variable. Returns ------- None """ main.apply_pvcompare( storeys=storeys, country=country, latitude=latitude, longitude=longitude, year=year, user_inputs_pvcompare_directory=user_inputs_pvcompare_directory, user_inputs_mvs_directory=user_inputs_mvs_directory, plot=plot, pv_setup=pv_setup, ) # define mvs_output_directory for every looping step mvs_output_directory = os.path.join( outputs_directory, scenario_name, "mvs_outputs_loop_" + str(loop_type) + "_" + str(year) + "_" + str(step), ) main.apply_mvs( scenario_name, user_inputs_mvs_directory=user_inputs_mvs_directory, mvs_output_directory=mvs_output_directory, outputs_directory=outputs_directory, ) excel_file1 = "scalars.xlsx" new_excel_file1 = "scalars_" + str(year) + "_" + str(step) + ".xlsx" src_dir = os.path.join(mvs_output_directory, excel_file1) dst_dir = os.path.join(loop_output_directory, "scalars", new_excel_file1) shutil.copy(src_dir, dst_dir) excel_file2 = "timeseries_all_busses.xlsx" new_excel_file2 = ( "timeseries_all_busses_" + "_" + str(year) + "_" + str(step) + ".xlsx" ) src_dir = os.path.join(mvs_output_directory, excel_file2) dst_dir = os.path.join(loop_output_directory, "timeseries", new_excel_file2) shutil.copy(src_dir, dst_dir)