Added a parameter in building.py to specifically decide whether dividing the building in storeys or not. By default, False.

insel/templates/thermal_demand_dynamic_simulation.py

@@ -3,7 +3,9 @@ from insel.insel import Insel
 
 class ThermalDemandDynamicSimulation:
   @staticmethod
-  def generate_thermal_dynamic_template(city_object, outputs_paths, weather_path, ig_path, simulation_period):
+  def generate_thermal_dynamic_template(building, outputs_paths, weather_path, ig_path, simulation_period):
+    number_usage_zones = len(building.usage_zones)
+
     file = ""
     file += "%Thermal Demand Dynamic Calculation\r\n"
     file += "%by Pilar Monsalvete Alvarez de Uribarri\r\n"
@@ -57,7 +59,8 @@ class ThermalDemandDynamicSimulation:
     # weather blocks
     i_block += 1
     n_weather = i_block
-    # todo: n_records is the number of columns to be read in the weather file
+    # todo: n_records is the number of columns to be read in the weather file ->
+    #  it should be = number of external surfaces
     n_records = 1000
     inputs = [str(n_hoy) + ".1"]
     parameters = [str(n_records) + " %[Nrec]",
@@ -69,7 +72,7 @@ class ThermalDemandDynamicSimulation:
     # internal gains and control blocks
     i_block += 1
     n_ig = i_block
-    n_records = len(city_object.usage_zones) * 5
+    n_records = number_usage_zones * 5
     inputs = [str(n_hoy) + ".1"]
     parameters = [str(n_records) + " %[Nrec]",
                   str(n_records * 12) + " %[RecLen]",
@@ -84,16 +87,14 @@ class ThermalDemandDynamicSimulation:
               str(n_clock) + ".3",
               str(n_clock) + ".4"]
     headline = ''
-    for i in range(0, len(city_object.usage_zones)):
+    for i in range(0, number_usage_zones):
       inputs.append(str(i_block+2) + "." + str(i*2+2))
       inputs.append(str(i_block+2) + "." + str(i*2+3))
       headline += "CoolingTZ_" + str(i+1) + " (Wh); " + "HeatingTZ_" + str(i+1) + " (Wh); "
     parameters = ["1 %[Mode]",
-                  "0 %[Suppress FNQ inputs]",
-                  #"2 %[Semicolon sep]",
                   "'" + str(outputs_paths) + "_demand.out' %[FileName]",
-                  "'*' %[FileFormat]"]
-                  #"'Year; month; day; hour; " + headline + "' %[Headline]"]
+                  "'*' %[FileFormat]",
+                  f"'Year; month; day; hour; {headline}' %[Headline]"]
     file = Insel.add_block(file, i_block, 'WRITE', inputs, parameters)
 
     i_block += 1
@@ -102,41 +103,39 @@ class ThermalDemandDynamicSimulation:
               str(n_clock) + ".3",
               str(n_clock) + ".4"]
     headline = ''
-    for i in range(0, len(city_object.usage_zones)):
+    for i in range(0, number_usage_zones):
       inputs.append(str(i_block+2) + "." + str(i+2))
       headline += "TempTZ_" + str(i+1) + " (C); "
     parameters = ["1 %[Mode]",
-                  "0 %[Suppress FNQ inputs]",
-                  #"2 %[Semicolon sep]",
                   "'" + str(outputs_paths) + "_temp.out' %[FileName]",
-                  "'*' %[FileFormat]"]
-                  #"'Year; month; day; hour; " + headline + "' %[Headline]"]
+                  "'*' %[FileFormat]",
+                  f"'Year; month; day; hour; {headline}' %[Headline]"]
     file = Insel.add_block(file, i_block, 'WRITE', inputs, parameters)
 
     # todo: NDelayRoom[usage_zone] = NDelayRoom[usage_zone-1] + 2/(10 surfaces) being surface = any wall or window + 2/window
-    NDelayRoom = [1]
+    NDelayRoom = [1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1]
     i_block += 1
     inputs = [str(n_hoy) + ".1"]
-    for i in range(0, len(city_object.usage_zones)):
-      inputs.append(str(i * 7 + NDelayRoom[i] + n_ig + 8 + 2*len(city_object.usage_zones)) + ".2")
-      inputs.append(str(i * 7 + NDelayRoom[i] + n_ig + 8 + 2*len(city_object.usage_zones)) + ".3")
+    for i in range(0, number_usage_zones):
+      inputs.append(str(i * 7 + NDelayRoom[i] + n_ig + 8 + 2 * number_usage_zones) + ".2")
+      inputs.append(str(i * 7 + NDelayRoom[i] + n_ig + 8 + 2 * number_usage_zones) + ".3")
     file = Insel.add_block(file, i_block, 'AVEC', inputs)
 
     i_block += 1
     inputs = [str(n_hoy) + ".1"]
-    for i in range(0, len(city_object.usage_zones)):
-      inputs.append(str(i * 7 + NDelayRoom[i] + n_ig + 8 + 2 * len(city_object.usage_zones)) + ".1")
+    for i in range(0, number_usage_zones):
+      inputs.append(str(i * 7 + NDelayRoom[i] + n_ig + 8 + 2 * number_usage_zones) + ".1")
     file = Insel.add_block(file, i_block, 'AVEC', inputs)
 
     i_block += 1
     n_cumc = i_block
     inputs = [str(n_clock) + ".2"]
-    for i in range(0, len(city_object.usage_zones)):
+    for i in range(0, number_usage_zones):
       inputs.append(str(i_block - 2) + "." + str(2*i+2))
       inputs.append(str(i_block - 2) + "." + str(2*i+3))
     file = Insel.add_block(file, i_block, 'CUMC', inputs)
 
-    for i in range(0, len(city_object.usage_zones)):
+    for i in range(0, number_usage_zones):
       i_block += 1
       inputs = [str(n_cumc) + "." + str(2*i+2),
                 str(i_block - 2) + "." + str(2*i+3)]
@@ -150,30 +149,25 @@ class ThermalDemandDynamicSimulation:
     i_block += 1
     inputs = [str(n_clock) + ".1",
               str(n_clock) + ".2"]
-    headline = ''
-    for i in range(0, len(city_object.usage_zones)):
-      inputs.append(str(i_block-2*len(city_object.usage_zones)+2*i+1) + ".1")
-      headline += "CoolingTZ_" + str(i + 1) + " (Wh); " + "HeatingTZ_" + str(i + 1) + " (Wh); "
+    for i in range(0, number_usage_zones):
+      inputs.append(str(i_block - 2 * number_usage_zones + 2 * i + 1) + ".1")
     parameters = ["1 %[Mode]",
-                  "0 %[Suppress FNQ inputs]",
-                  #"2 %[Semicolon sep]",
                   "'" + str(outputs_paths) + "_month.out' %[FileName]",
-                  "'*' %[FileFormat]"]
-                  #"'Year; month; day; hour; " + headline + "' %[Headline]"]
+                  "'*' %[FileFormat]",
+                  f"'Total heated area: {building.floor_area} (m2)' %[Headline]"]
     file = Insel.add_block(file, i_block, 'WRITE', inputs, parameters)
 
     # Zero constant for different uses
     i_block += 1
     n_zero = i_block
     parameters = ["0 %[ZeroConst]"]
-    file = Insel.add_block(file, i_block, 'WRITE', parameters=parameters)
+    file = Insel.add_block(file, i_block, 'CONST', parameters=parameters)
 
-    print(file)
     # Zones:
     n_start_zones = i_block
     n_zone = []
     i_zone = 0
-    for usage_zone in city_object.usage_zones:
+    for usage_zone in building.usage_zones:
       i_block += 1
       n_zone.append(i_block)
       inputs = [str(n_gain_moy) + ".1",
@@ -187,7 +181,8 @@ class ThermalDemandDynamicSimulation:
                 str(n_weather) + ".1",                # ventilation temperature
                 str(n_zone[i_zone] + 4) + ".1",       # from chs
                 ]
-      parameters = [usage_zone.gross_volume  + " %[RoomAirVol]",
+      print('usage_zone has no sense here!!!')
+      parameters = [usage_zone.volume + " %[RoomAirVol]",
                     usage_zone.initial_temperature + " %[Tini]",
                     usage_zone.cooling_on + " %[CSOn]",
                     usage_zone.cooling_maximum_power + " %[CPMax]",
@@ -196,6 +191,7 @@ class ThermalDemandDynamicSimulation:
                     usage_zone.thermal_bridges  + " %[TBridges]",
                     usage_zone.n_surfaces  + " %[Nwalls+Nwindow]"
                     ]
+      print('aaaaa')
       for surface in usage_zone.surfaces:
         parameters.append(str(surface.area) + " " + str(surface.interior_covective_coefficient) + " %[Area] + [ConvCoefi]")
       file = Insel.add_block(file, i_block, 'UBROOMV2', inputs, parameters)
@@ -416,5 +412,6 @@ class ThermalDemandDynamicSimulation:
 #				myInselModel.add(Integer.toString(numZero) + ".1");           //If there is no windows, conected to const = 0
 #			}
 #		}
+      print(file)
       i_zone += 1
     return file

main.py

@@ -10,9 +10,6 @@ import helpers.constants as cte
 from imports.geometry_factory import GeometryFactory
 from imports.geometry.helpers.geometry_helper import GeometryHelper
 from city_model_structure.city import City
-from city_model_structure.building import Building
-from city_model_structure.attributes.polygon import Polygon
-from city_model_structure.attributes.surface import Surface
 
 name_gml = 'one_building_in_kelowna.gml'
 function_format = 'hft'
@@ -28,38 +25,17 @@ outputs_path = (example_path / 'tests' / 'tests_outputs').resolve()
 tmp_path = (example_path / 'tests' / 'tmp').resolve()
 weather_path = (Path(__file__).parent.parent / 'libs' / 'data' / 'weather').resolve()
 keep_files = False
-pickle_created = False
+pickle_created = True
 pickle_file = 'tests/tests_data/one_building_in_kelowna.pickle'
 
-# todo: simplification of the data model
-
 if not pickle_created:
   city = GeometryFactory('citygml', full_path_gml).city
 
-  # Building division by storey
-  for building in city.buildings:
-    building.average_storey_height = 1.5
-    building.storeys_above_ground = 2
-    storeys = building.storeys
-
-    if len(storeys) != len(building.thermal_zones):
-      # todo:assign one thermal zone per storey
-      for storey in storeys:
-        surfaces = []
-        for face in storey.faces:
-          # todo: review for obj with windows
-          points = []
-          for vertex_index in face:
-            points.append(storey.vertices[vertex_index])
-          solid_polygon = Polygon(points)
-          perimeter_polygon = solid_polygon
-          surface = Surface(solid_polygon, perimeter_polygon)
-          surfaces.append(surface)
-
   weather_format = 'epw'
   city.climate_reference_city = climate_reference_city
   city.climate_file = (tmp_path / f'{climate_reference_city}.cli').resolve()
   WeatherFactory(weather_format, city, base_path=weather_path, file_name=weather_file_name).enrich()
+
   for building in city.buildings:
     if cte.HOUR not in building.external_temperature:
       print('No external temperature found')
@@ -82,13 +58,13 @@ if not pickle_created:
   else:
     sra.call_sra(weather_format, keep_files=keep_files)
     sra.set_irradiance_surfaces(city, mode=1)
-  #  print(city.buildings[0].surfaces[1].global_irradiance['hour'].sra)
 
   for building in city.buildings:
     if function_format == 'hft':
       building.function = GeometryHelper.hft_to_function[building.function]
     elif function_format == 'pluto':
       building.function = GeometryHelper.pluto_to_function[building.function]
+
   city = EnrichCity(city).enriched_city(construction_format, usage_format, schedules_format)
 
   city.save(pickle_file)
@@ -97,19 +73,18 @@ else:
 
 # todo: when the enrichment step goes after SRA, check whether srw has changed
 #  after reading the construction library or not
-quit()
-
 # Demand calculation (one model per building)
-for city_object in city.city_objects:
-  full_path_out = (outputs_path / city_object.name).resolve()
-  full_path_wea = (tmp_path / (city_object.name + '.weather')).resolve()
-  full_path_ig = (tmp_path / (city_object.name + '.ig')).resolve()
+for building in city.buildings:
+  full_path_out = (outputs_path / building.name).resolve()
+  full_path_wea = (tmp_path / (building.name + '.weather')).resolve()
+  full_path_ig = (tmp_path / (building.name + '.ig')).resolve()
 
-  insel_file_name = city_object.name + '.insel'
+  insel_file_name = building.name + '.insel'
   try:
-    content = Templates.generate_thermal_dynamic_template(city_object, full_path_out, full_path_wea, full_path_ig, Sp)
-    insel = Insel(example_path, insel_file_name, content, mode=2, keep_files=keep_files).results
+    content = Templates.generate_thermal_dynamic_template(building, full_path_out, full_path_wea, full_path_ig, Sp)
+    print(content)
+    #insel = Insel(example_path, insel_file_name, content, mode=2, keep_files=keep_files).results
   except:
     print(sys.exc_info()[1])
-    print('Building ' + city_object.name + ' could not be processed')
+    print('Building ' + building.name + ' could not be processed')
     continue