Included export for heat pump energy system

2021-10-29 15:27:25 +00:00 · 2021-10-29 15:27:25 +00:00 · 20ca5a0fc3
commit 20ca5a0fc3
parent ae0e2a905f
1 changed files with 85 additions and 0 deletions
--- a/exports/energy_systems/heat_pump_export.py
+++ b/exports/energy_systems/heat_pump_export.py
@ -0,0 +1,85 @@
+"""
+HeatPumpExport exports heatpump coefficient into several formats
+SPDX - License - Identifier: LGPL - 3.0 - or -later
+Copyright © 2021 Project Author Peter Yefi peteryefi@gmail.com
+"""
+import numpy as np
+from scipy.optimize import curve_fit
+from typing import Dict, Tuple
+import pandas as pd
+
+
+class HeatPumpExport:
+  """
+  Exports heat pump values as coefficients
+  of some defined function
+  """
+
+  def __init__(self, base_path, city):
+    self._base_path = (base_path / 'heat_pumps/coefficients.xlsx')
+    self._city = city
+
+  def export_xlsx(self):
+    """
+    Writes the coefficients computed from heat performance
+    and cooling performance data to excel sheet
+    :return: None
+    """
+    writer = pd.ExcelWriter(self._base_path)
+    heat_column_names = ["a1", "a2", "a3", "a4", "a5", "a6"]
+    cool_column_names = ["b1", "b2", "b3", "b4", "b5", "b6"]
+    heat_coff, cool_coff = self._compute_coefficients()
+    for (k_cool, v_cool), (k_heat, v_heat) in \
+        zip(heat_coff.items(), cool_coff.items()):
+      heat_df = pd.DataFrame([v_heat["heat_cap"], v_heat["comp_power"]], columns=heat_column_names,
+                             index=["Heat Capacity", "Compressor Power"])
+      heat_df.to_excel(writer, sheet_name=k_heat)
+      cool_df = pd.DataFrame([v_heat["cool_cap"], v_heat["comp_power"]], columns=cool_column_names,
+                             index=["Cooling Capacity", "Compressor Power"])
+      cool_df.to_excel(writer, sheet_name=k_cool, startrow=10)
+
+      writer.save()
+
+  def _compute_coefficients(self) -> Tuple[Dict, Dict]:
+    """
+    Compute heat output and electrical demand coefficients
+    from heating and cooling performance data
+    :return: Tuple[Dict, Dict]
+    """
+    out_temp = [25, 30, 32, 35, 40, 45] * 6
+    heat_x_values = np.repeat([-5, 0, 7, 10, 15], 6)
+    cool_x_values = np.repeat([6, 7, 8, 9, 10, 11], 6)
+    cooling_coff = {}
+    heating_coff = {}
+    for energy_system in self._city.energy_systems:
+      # Compute heat output coefficients
+      heating_cap_popt, _ = curve_fit(self._objective_function, [heat_x_values, out_temp],
+                                      energy_system.heat_pump.heating_capacity)
+      heating_comp_power_popt, _ = curve_fit(self._objective_function, [heat_x_values, out_temp],
+                                             energy_system.heat_pump.heating_comp_power)
+      # Compute electricity demand coefficients
+      cooling_cap_popt, _ = curve_fit(self._objective_function, [cool_x_values, out_temp],
+                                      energy_system.heat_pump.cooling_capacity)
+      cooling_comp_power_popt, _ = curve_fit(self._objective_function, [cool_x_values, out_temp],
+                                             energy_system.heat_pump.cooling_comp_power)
+
+      heating_coff[energy_system.heat_pump.model] = {"heat_cap": heating_cap_popt.tolist(),
+                                                     "comp_power": heating_comp_power_popt.tolist()}
+      cooling_coff[energy_system.heat_pump.model] = {"cool_cap": cooling_cap_popt.tolist(),
+                                                     "comp_power": cooling_comp_power_popt.tolist()}
+    return heating_coff, cooling_coff
+
+  def _objective_function(self, xdata, a1, a2, a3, a4, a5, a6):
+    """
+    Objective function for computing coefficients
+    :param xdata:
+    :param a1: float
+    :param a2: float
+    :param a3: float
+    :param a4: float
+    :param a5: float
+    :param a6: float
+    :return:
+    """
+    x, y = xdata
+    return (a1 * x ** 2) + (a2 * x) + (a3 * x * y) + (a4 * y) + (a5 * y ** 2) + a6