def click_add_new_element(self, parent, name, type, area):
if type == "Outer Wall":
element = OuterWall(parent)
element.name = name
element.area = area
if type == "Inner Wall":
element = InnerWall(parent)
element.name = name
element.area = area
if type == "Window":
element = Window(parent)
element.name = name
element.area = area
if type == "GroundFloor":
element = GroundFloor(parent)
element.name = name
element.area = area
if type == "Ceiling":
element = Ceiling(parent)
element.name = name
element.area = area
if type == "Rooftop":
element = Rooftop(parent)
element.name = name
element.area = area
if type == "Floor":
element = Floor(parent)
element.name = name
element.area = area
return parent
def click_add_new_element(self, parent, name, type, area):
'''
adds a new element to a zone with specified name, area and type.
Parameters:
----------
parent : wall()
parent class of an element
name : str
individual name
type : string
type of element
area : float
area of the element
Returns
----------
parent : wall()
parent class of element
'''
if type == "Outer Wall":
element = OuterWall(parent)
element.name = name
element.area = area
if type == "Inner Wall":
element = InnerWall(parent)
element.name = name
element.area = area
if type == "Window":
element = Window(parent)
element.name = name
element.area = area
if type == "GroundFloor":
element = GroundFloor(parent)
element.name = name
element.area = area
if type == "Ceiling":
element = Ceiling(parent)
element.name = name
element.area = area
if type == "Rooftop":
element = Rooftop(parent)
element.name = name
element.area = area
if type == "Floor":
element = Floor(parent)
element.name = name
element.area = area
return parent
def generate_archetype(self):
"""Generates a SingleFamilyHouse archetype buildings
With given values, this function generates an archetype building for
Tabula Single Family House.
"""
self.thermal_zones = None
self._check_year_of_construction()
# help area for the correct building area setting while using typeBldgs
type_bldg_area = self.net_leased_area
self.net_leased_area = 0.0
for key, value in self.zone_area_factors.items():
zone = ThermalZone(parent=self)
zone.name = key
zone.area = type_bldg_area * value[0]
use_cond = UseCond(parent=zone)
use_cond.load_use_conditions(zone_usage=value[1])
zone.use_conditions = use_cond
zone.use_conditions.with_ahu = False
zone.use_conditions.persons *= zone.area * 0.01
zone.use_conditions.machines *= zone.area * 0.01
if self.facade_estimation_factors[self.building_age_group]['ow1'] != 0:
for key, value in self._outer_wall_names_1.items():
for zone in self.thermal_zones:
outer_wall = OuterWall(zone)
outer_wall.load_type_element(
year=self.year_of_construction,
construction=self._construction_type_1,
data_class=self.parent.data)
outer_wall.name = key
outer_wall.tilt = value[0]
outer_wall.orientation = value[1]
outer_wall.area = ((self.facade_estimation_factors[
self.building_age_group]['ow1'] * type_bldg_area) /
len(self._outer_wall_names_1))
if self.facade_estimation_factors[self.building_age_group]['ow2'] != 0:
for key, value in self._outer_wall_names_2.items():
for zone in self.thermal_zones:
outer_wall = OuterWall(zone)
outer_wall.load_type_element(
year=self.year_of_construction,
construction=self._construction_type_2,
data_class=self.parent.data)
outer_wall.name = key
outer_wall.tilt = value[0]
outer_wall.orientation = value[1]
outer_wall.area = ((self.facade_estimation_factors[
self.building_age_group]['ow2'] * type_bldg_area) /
len(self._outer_wall_names_2))
if self.facade_estimation_factors[
self.building_age_group]['win1'] != 0:
for key, value in self.window_names_1.items():
for zone in self.thermal_zones:
window = Window(zone)
window.load_type_element(
self.year_of_construction,
construction=self._construction_type_1,
data_class=self.parent.data)
window.name = key
window.tilt = value[0]
window.orientation = value[1]
window.area = ((self.facade_estimation_factors[
self.building_age_group]['win1'] * type_bldg_area) /
len(self.window_names_1))
if self.facade_estimation_factors[
self.building_age_group]['win2'] != 0:
for key, value in self.window_names_2.items():
for zone in self.thermal_zones:
window = Window(zone)
window.load_type_element(
self.year_of_construction,
construction=self._construction_type_2,
data_class=self.parent.data)
window.name = key
window.tilt = value[0]
window.orientation = value[1]
window.area = ((self.facade_estimation_factors[
self.building_age_group]['win2'] * type_bldg_area) /
len(self.window_names_2))
if self.facade_estimation_factors[self.building_age_group]['gf1'] != 0:
for key, value in self.ground_floor_names_1.items():
for zone in self.thermal_zones:
gf = GroundFloor(zone)
gf.load_type_element(
year=self.year_of_construction,
construction=self._construction_type_1,
data_class=self.parent.data)
gf.name = key
gf.tilt = value[0]
gf.orientation = value[1]
gf.area = ((self.facade_estimation_factors[
self.building_age_group]['gf1'] * type_bldg_area) /
len(self.ground_floor_names_1))
if self.facade_estimation_factors[self.building_age_group]['gf2'] != 0:
for key, value in self.ground_floor_names_2.items():
for zone in self.thermal_zones:
gf = GroundFloor(zone)
gf.load_type_element(
year=self.year_of_construction,
construction=self._construction_type_2,
data_class=self.parent.data)
gf.name = key
gf.tilt = value[0]
gf.orientation = value[1]
gf.area = ((self.facade_estimation_factors[
self.building_age_group]['gf2'] * type_bldg_area) /
len(self.ground_floor_names_2))
if self.facade_estimation_factors[self.building_age_group]['rt1'] != 0:
for key, value in self.roof_names_1.items():
for zone in self.thermal_zones:
rt = Rooftop(zone)
rt.load_type_element(
year=self.year_of_construction,
construction=self._construction_type_1,
data_class=self.parent.data)
rt.name = key
rt.tilt = value[0]
rt.orientation = value[1]
rt.area = ((self.facade_estimation_factors[
self.building_age_group]['rt1'] * type_bldg_area) /
len(self.roof_names_1))
if self.facade_estimation_factors[self.building_age_group]['rt2'] != 0:
for key, value in self.roof_names_2.items():
for zone in self.thermal_zones:
rt = Rooftop(zone)
rt.load_type_element(
year=self.year_of_construction,
construction=self._construction_type_2,
data_class=self.parent.data)
rt.name = key
rt.tilt = value[0]
rt.orientation = value[1]
rt.area = ((self.facade_estimation_factors[
self.building_age_group]['rt2'] * type_bldg_area) /
len(self.roof_names_2))
if self.facade_estimation_factors[
self.building_age_group]['door'] != 0:
for key, value in self.door_names.items():
for zone in self.thermal_zones:
door = Door(zone)
door.load_type_element(
year=self.year_of_construction,
construction=self._construction_type_1,
data_class=self.parent.data)
door.name = key
door.tilt = value[0]
door.orientation = value[1]
door.area = ((self.facade_estimation_factors[
self.building_age_group]['door'] * type_bldg_area) /
len(self.door_names))
for key, value in self.inner_wall_names.items():
for zone in self.thermal_zones:
inner_wall = InnerWall(zone)
inner_wall.load_type_element(year=self.year_of_construction,
construction="tabula_standard",
data_class=self.parent.data)
inner_wall.name = key
inner_wall.tilt = value[0]
inner_wall.orientation = value[1]
if self.number_of_floors > 1:
for key, value in self.ceiling_names.items():
for zone in self.thermal_zones:
ceiling = Ceiling(zone)
ceiling.load_type_element(year=self.year_of_construction,
construction="tabula_standard",
data_class=self.parent.data)
ceiling.name = key
ceiling.tilt = value[0]
ceiling.orientation = value[1]
for key, value in self.floor_names.items():
for zone in self.thermal_zones:
floor = Floor(zone)
floor.load_type_element(year=self.year_of_construction,
construction="tabula_standard",
data_class=self.parent.data)
floor.name = key
floor.tilt = value[0]
floor.orientation = value[1]
for zone in self.thermal_zones:
zone.set_inner_wall_area()
zone.set_volume_zone()
def generate_archetype(self):
"""Generates an office building.
With given values, this class generates an office archetype building
according to TEASER requirements.
"""
# help area for the correct building area setting while using typeBldgs
self.thermal_zones = None
type_bldg_area = self.net_leased_area
self.net_leased_area = 0.0
# create zones with their corresponding area, name and usage
for key, value in self.zone_area_factors.items():
zone = ThermalZone(self)
zone.area = type_bldg_area * value[0]
zone.name = key
use_cond = UseCond(zone)
use_cond.load_use_conditions(value[1], data_class=self.parent.data)
zone.use_conditions = use_cond
# statistical estimation of the facade
self._est_outer_wall_area = (self.est_factor_wall_area *
type_bldg_area**self.est_exponent_wall)
self._est_win_area = (self.est_factor_win_area *
type_bldg_area**self.est_exponent_win)
self._est_roof_area = (type_bldg_area /
self.number_of_floors) * self.gross_factor
self._est_floor_area = (type_bldg_area /
self.number_of_floors) * self.gross_factor
# manipulation of wall according to facade design
# (received from window_layout)
self._est_facade_area = self._est_outer_wall_area + self._est_win_area
if not self.window_layout == 0:
self._est_outer_wall_area = self._est_facade_area * self.corr_factor_wall
self._est_win_area = self._est_facade_area * self.corr_factor_win
else:
pass
# set the facade area to the four orientations
for key, value in self.outer_wall_names.items():
# North and South
if value[1] == 0 or value[1] == 180:
self.outer_area[value[1]] = self._est_outer_wall_area * (
self._est_length /
(2 * self._est_width + 2 * self._est_length))
# East and West
elif value[1] == 90 or value[1] == 270:
self.outer_area[value[1]] = self._est_outer_wall_area * (
self._est_width /
(2 * self._est_width + 2 * self._est_length))
for zone in self.thermal_zones:
# create wall and set building elements
outer_wall = OuterWall(zone)
outer_wall.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data,
)
outer_wall.name = key
outer_wall.tilt = value[0]
outer_wall.orientation = value[1]
for key, value in self.window_names.items():
if value[1] == 0 or value[1] == 180:
self.window_area[value[1]] = self._est_win_area * (
self._est_length /
(2 * self._est_width + 2 * self._est_length))
elif value[1] == 90 or value[1] == 270:
self.window_area[value[1]] = self._est_win_area * (
self._est_width /
(2 * self._est_width + 2 * self._est_length))
"""
There is no real classification for windows, so this is a bit hard
code - will be fixed sometime.
"""
for zone in self.thermal_zones:
window = Window(zone)
window.load_type_element(
self.year_of_construction,
"Kunststofffenster, "
"Isolierverglasung",
data_class=self.parent.data,
)
window.name = key
window.tilt = value[0]
window.orientation = value[1]
for key, value in self.roof_names.items():
self.outer_area[value[1]] = self._est_roof_area
for zone in self.thermal_zones:
roof = Rooftop(zone)
roof.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data,
)
roof.name = key
roof.tilt = value[0]
roof.orientation = value[1]
for key, value in self.ground_floor_names.items():
self.outer_area[value[1]] = self._est_floor_area
for zone in self.thermal_zones:
ground_floor = GroundFloor(zone)
ground_floor.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data,
)
ground_floor.name = key
ground_floor.tilt = value[0]
ground_floor.orientation = value[1]
for key, value in self.inner_wall_names.items():
for zone in self.thermal_zones:
inner_wall = InnerWall(zone)
inner_wall.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data,
)
inner_wall.name = key
inner_wall.tilt = value[0]
inner_wall.orientation = value[1]
if self.number_of_floors > 1:
for key, value in self.ceiling_names.items():
for zone in self.thermal_zones:
ceiling = Ceiling(zone)
ceiling.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data,
)
ceiling.name = key
ceiling.tilt = value[0]
ceiling.orientation = value[1]
# zone.inner_walls.append(ceiling)
for key, value in self.floor_names.items():
for zone in self.thermal_zones:
floor = Floor(zone)
floor.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data,
)
floor.name = key
floor.tilt = value[0]
floor.orientation = value[1]
else:
pass
for key, value in self.outer_area.items():
self.set_outer_wall_area(value, key)
for key, value in self.window_area.items():
self.set_window_area(value, key)
for zone in self.thermal_zones:
zone.set_inner_wall_area()
zone.set_volume_zone()
def import_building_from_excel(project, building_name, construction_age,
path_to_excel, sheet_names):
"""
Import building data from excel, convert it via the respective zoning and feed it to teasers logic classes.
Pay attention to hard coded parts, which are marked.
Parameters
----------
project: Project()
TEASER instance of Project
building_name: str
name of building to be set in the project
construction_age: int [y]
construction age of the building
path_to_excel: str
path to excel file to be imported
sheet_names: str or list
sheet names which shall be imported
return data: pandas.DataFrame
zoned DataFrame which is finally used to parametrize the teaser classes
return project: Project()
TEASER instance of Project filled with the imported building data
"""
def warn_constructiontype(element):
"""Generic warning function"""
if element.construction_type is None:
warnings.warn(
'In zone "%s" the %s construction "%s" could not be loaded from the TypeBuildingElements.json, '
"an error will occur due to missing data for calculation."
"Check for spelling and the correct combination of building age and construction type."
"Here is the list of faulty entries:\n%s"
"\nThese entries can easily be found checking the stated index in the produced ZonedInput.xlsx"
% (
group["zone"].iloc[0],
element.name,
group["OuterWallConstruction"].iloc[0],
group,
))
bldg = Building(parent=project)
bldg.name = building_name
bldg.year_of_construction = construction_age
bldg.with_ahu = True # HardCodedInput
if bldg.with_ahu is True:
bldg.central_ahu.heat_recovery = True # HardCodedInput
bldg.central_ahu.efficiency_recovery = 0.35 # HardCodedInput
bldg.central_ahu.temperature_profile = 25 * [273.15 + 18
] # HardCodedInput
bldg.central_ahu.min_relative_humidity_profile = 25 * [
0
] # HardCodedInput
bldg.central_ahu.max_relative_humidity_profile = 25 * [
1
] # HardCodedInput
bldg.central_ahu.v_flow_profile = 25 * [1] # HardCodedInput
# Parameters that need hard coding in teasers logic classes
# 1. "use_set_back" needs hard coding at aixlib.py in the init; defines
# if the in the useconditions stated
# heating_time with the respective set_back_temp should be applied.
# use_set_back = false -> all hours of the day
# have same set_temp_heat actual value: use_set_back = Check your current version!
# 2. HeaterOn, CoolerOn, hHeat, lCool, etc. can be hard coded in the text
# file
# "teaser / data / output / modelicatemplate / AixLib /
# AixLib_ThermalZoneRecord_TwoElement"
# actual changes: Check your current version!
# Parameters to be set for each and every zone (#HardCodedInput)
# -----------------------------
out_wall_tilt = 90
window_tilt = 90
ground_floor_tilt = 0
floor_tilt = 0
ceiling_tilt = 0
rooftop_tilt = 0
ground_floor_orientation = -2
floor_orientation = -2
rooftop_orientation = -1
ceiling_orientation = -1
# -----------------------------
# load_building_data from excel_to_pandas DataFrame:
data = import_data(path_to_excel, sheet_names)
# informative print
usage_types = get_list_of_present_entries(data["UsageType"])
print("List of present usage_types in the original Data set: \n%s" %
usage_types)
# define the zoning methodology/function
data = zoning_example(data)
# informative print
usage_types = get_list_of_present_entries(data["Zone"])
print("List of zones after the zoning is applied: \n%s" % usage_types)
# aggregate all rooms of each zone and for each set general parameter,
# boundary conditions
# and parameter regarding the building physics
zones = data.groupby(["Zone"])
for name, zone in zones:
# Block: Thermal zone (general parameter)
tz = ThermalZone(parent=bldg)
tz.name = str(name)
tz.area = zone["NetArea[m²]"].sum()
# room vice calculation of volume plus summing those
tz.volume = (np.array(zone["NetArea[m²]"]) *
np.array(zone["HeatedRoomHeight[m]"])).sum()
# Block: Boundary Conditions
# load UsageOperationTime, Lighting, RoomClimate and InternalGains
# from the "UseCondition.json"
tz.use_conditions = UseConditions(parent=tz)
tz.use_conditions.load_use_conditions(zone["Zone"].iloc[0],
project.data)
# Block: Building Physics
# Grouping by orientation and construction type
# aggregating and feeding to the teaser logic classes
grouped = zone.groupby(
["OuterWallOrientation[°]", "OuterWallConstruction"])
for name, group in grouped:
# looping through a groupby object automatically discards the
# groups where one of the attributes is nan
# additionally check for strings, since the value must be of type
# int or float
if not isinstance(group["OuterWallOrientation[°]"].iloc[0], str):
out_wall = OuterWall(parent=tz)
out_wall.name = (
"outer_wall_" +
str(int(group["OuterWallOrientation[°]"].iloc[0])) + "_" +
str(group["OuterWallConstruction"].iloc[0]))
out_wall.area = group["OuterWallArea[m²]"].sum()
out_wall.tilt = out_wall_tilt
out_wall.orientation = group["OuterWallOrientation[°]"].iloc[0]
# load wall properties from "TypeBuildingElements.json"
out_wall.load_type_element(
year=bldg.year_of_construction,
construction=group["OuterWallConstruction"].iloc[0],
)
warn_constructiontype(out_wall)
else:
warnings.warn(
'In zone "%s" the OuterWallOrientation "%s" is '
"neither float nor int, "
"hence this building element is not added.\nHere is the "
"list of faulty entries:\n%s"
"\n These entries can easily be found checking the stated "
"index in the produced ZonedInput.xlsx" % (
group["Zone"].iloc[0],
group["OuterWallOrientation[°]"].iloc[0],
group,
))
grouped = zone.groupby(["WindowOrientation[°]", "WindowConstruction"])
for name, group in grouped:
# looping through a groupby object automatically discards the
# groups where one of the attributes is nan
# additionally check for strings, since the value must be of type
# int or float
if not isinstance(group["OuterWallOrientation[°]"].iloc[0], str):
window = Window(parent=tz)
window.name = (
"window_" +
str(int(group["WindowOrientation[°]"].iloc[0])) + "_" +
str(group["WindowConstruction"].iloc[0]))
window.area = group["WindowArea[m²]"].sum()
window.tilt = window_tilt
window.orientation = group["WindowOrientation[°]"].iloc[0]
# load wall properties from "TypeBuildingElements.json"
window.load_type_element(
year=bldg.year_of_construction,
construction=group["WindowConstruction"].iloc[0],
)
warn_constructiontype(window)
else:
warnings.warn(
'In zone "%s" the window orientation "%s" is neither '
"float nor int, "
"hence this building element is not added. Here is the "
"list of faulty entries:\n%s"
"\nThese entries can easily be found checking the stated "
"index in the produced ZonedInput.xlsx" % (
group["Zone"].iloc[0],
group["WindowOrientation[°]"].iloc[0],
group,
))
grouped = zone.groupby(["IsGroundFloor", "FloorConstruction"])
for name, group in grouped:
if group["NetArea[m²]"].sum() != 0: # to avoid devision by 0
if group["IsGroundFloor"].iloc[0] == 1:
ground_floor = GroundFloor(parent=tz)
ground_floor.name = "ground_floor" + str(
group["FloorConstruction"].iloc[0])
ground_floor.area = group["NetArea[m²]"].sum()
ground_floor.tilt = ground_floor_tilt
ground_floor.orientation = ground_floor_orientation
# load wall properties from "TypeBuildingElements.json"
ground_floor.load_type_element(
year=bldg.year_of_construction,
construction=group["FloorConstruction"].iloc[0],
)
warn_constructiontype(ground_floor)
elif group["IsGroundFloor"].iloc[0] == 0:
floor = Floor(parent=tz)
floor.name = "floor" + str(
group["FloorConstruction"].iloc[0])
floor.area = group["NetArea[m²]"].sum() / 2 # only half of
# the floor belongs to this story
floor.tilt = floor_tilt
floor.orientation = floor_orientation
# load wall properties from "TypeBuildingElements.json"
floor.load_type_element(
year=bldg.year_of_construction,
construction=group["FloorConstruction"].iloc[0],
)
warn_constructiontype(floor)
else:
warnings.warn(
"Values for IsGroundFloor have to be either 0 or 1, "
"for no or yes respectively")
else:
warnings.warn(
'zone "%s" with IsGroundFloor "%s" and construction '
'type "%s" '
"has no floor nor groundfloor, since the area equals 0." %
(
group["Zone"].iloc[0],
group["IsGroundFloor"].iloc[0],
group["FloorConstruction"].iloc[0],
))
grouped = zone.groupby(["IsRooftop", "CeilingConstruction"])
for name, group in grouped:
if group["NetArea[m²]"].sum() != 0: # to avoid devision by 0
if group["IsRooftop"].iloc[0] == 1:
rooftop = Rooftop(parent=tz)
rooftop.name = "rooftop" + str(
group["CeilingConstruction"].iloc[0])
rooftop.area = group["NetArea[m²]"].sum(
) # sum up area of respective
# rooftop parts
rooftop.tilt = rooftop_tilt
rooftop.orientation = rooftop_orientation
# load wall properties from "TypeBuildingElements.json"
rooftop.load_type_element(
year=bldg.year_of_construction,
construction=group["CeilingConstruction"].iloc[0],
)
warn_constructiontype(rooftop)
elif group["IsRooftop"].iloc[0] == 0:
ceiling = Ceiling(parent=tz)
ceiling.name = "ceiling" + str(
group["CeilingConstruction"].iloc[0])
ceiling.area = group["NetArea[m²]"].sum() / 2 # only half
# of the ceiling belongs to a story,
# the other half to the above
ceiling.tilt = ceiling_tilt
ceiling.orientation = ceiling_orientation
# load wall properties from "TypeBuildingElements.json"
ceiling.load_type_element(
year=bldg.year_of_construction,
construction=group["CeilingConstruction"].iloc[0],
)
warn_constructiontype(ceiling)
else:
warnings.warn(
"Values for IsRooftop have to be either 0 or 1, "
"for no or yes respectively")
else:
warnings.warn(
'zone "%s" with IsRooftop "%s" and construction type '
'"%s" '
"has no ceiling nor rooftop, since the area equals 0." % (
group["Zone"].iloc[0],
group["IsRooftop"].iloc[0],
group["CeilingConstruction"].iloc[0],
))
grouped = zone.groupby(["InnerWallConstruction"])
for name, group in grouped:
if group["InnerWallArea[m²]"].sum() != 0: # to avoid devision by 0
in_wall = InnerWall(parent=tz)
in_wall.name = "inner_wall" + str(
group["InnerWallConstruction"].iloc[0])
in_wall.area = group["InnerWallArea[m²]"].sum() / 2 # only
# half of the wall belongs to each room,
# the other half to the adjacent
# load wall properties from "TypeBuildingElements.json"
in_wall.load_type_element(
year=bldg.year_of_construction,
construction=group["InnerWallConstruction"].iloc[0],
)
warn_constructiontype(in_wall)
else:
warnings.warn(
'zone "%s" with inner wall construction "%s" has no '
"inner walls, since area = 0." %
(group["Zone"].iloc[0], group["InnerWallConstructio"
"n"].iloc[0]))
# Block: AHU and infiltration #Attention hard coding
# set the supply volume flow of the AHU per zone
ahu_dict = {
"Bedroom": [15.778, 15.778],
"Corridorsinthegeneralcarearea": [5.2941, 5.2941],
"Examinationortreatmentroom": [15.743, 15.743],
"MeetingConferenceseminar": [16.036, 16.036],
"Stocktechnicalequipmentarchives": [20.484, 20.484],
"WCandsanitaryroomsinnonresidentialbuildings": [27.692, 27.692],
}
_i = 0
for key in ahu_dict:
if tz.name == key:
tz.use_conditions.min_ahu = ahu_dict[key][0]
tz.use_conditions.max_ahu = ahu_dict[key][1]
_i = 1
if _i == 0:
warnings.warn(
"The zone %s could not be found in your ahu_dict. Hence, "
"no AHU flow is defined. The default value is "
"0 (min_ahu = 0; max_ahu=0" % tz.name)
return project, data
def _load_building(prj, pyxb_bld, type, project_bind):
if type == "Building":
bldg = Building(prj)
elif type == "Office":
bldg = Office(prj)
elif type == "Institute":
bldg = Institute(prj)
elif type == "Institute4":
bldg = Institute4(prj)
elif type == "Institute8":
bldg = Institute8(prj)
elif type == "Residential":
bldg = SingleFamilyDwelling(prj)
bldg.name = pyxb_bld.name
bldg.street_name = pyxb_bld.street_name
bldg.city = pyxb_bld.city
bldg.type_of_building = pyxb_bld.type_of_building
bldg.year_of_construction = pyxb_bld.year_of_construction
bldg.year_of_retrofit = pyxb_bld.year_of_retrofit
bldg.number_of_floors = pyxb_bld.number_of_floors
bldg.height_of_floors = pyxb_bld.height_of_floors
if not pyxb_bld.ThermalZone:
bldg.net_leased_area = pyxb_bld.net_leased_area
if pyxb_bld.CentralAHU:
pyxb_ahu = pyxb_bld.CentralAHU
bldg.central_ahu = BuildingAHU(bldg)
bldg.central_ahu.heating = pyxb_ahu.heating
bldg.central_ahu.cooling = pyxb_ahu.cooling
bldg.central_ahu.dehumidification = pyxb_ahu.dehumidification
bldg.central_ahu.humidification = pyxb_ahu.humidification
bldg.central_ahu.heat_recovery = pyxb_ahu.heat_recovery
bldg.central_ahu.by_pass_dehumidification = \
pyxb_ahu.by_pass_dehumidification
bldg.central_ahu.efficiency_recovery = pyxb_ahu.efficiency_recovery
try:
if float(project_bind.version) >= 0.5:
bldg.central_ahu.efficiency_recovery_false = \
pyxb_ahu.efficiency_recovery_false
else:
bldg.central_ahu.efficiency_recovery_false = \
pyxb_ahu.efficiency_revocery_false
except AttributeError:
bldg.central_ahu.efficiency_recovery_false = \
pyxb_ahu.efficiency_revocery_false
bldg.central_ahu.profile_min_relative_humidity = \
pyxb_ahu.profile_min_relative_humidity
bldg.central_ahu.profile_max_relative_humidity = \
pyxb_ahu.profile_max_relative_humidity
bldg.central_ahu.profile_v_flow = \
pyxb_ahu.profile_v_flow
bldg.central_ahu.profile_temperature = \
pyxb_ahu.profile_temperature
for pyxb_zone in pyxb_bld.ThermalZone:
zone = ThermalZone(bldg)
zone.name = pyxb_zone.name
zone.area = pyxb_zone.area
zone.volume = pyxb_zone.volume
zone.infiltration_rate = pyxb_zone.infiltration_rate
zone.use_conditions = BoundaryConditions(zone)
pyxb_use = pyxb_zone.UseCondition.BoundaryConditions
zone.use_conditions.typical_length = pyxb_zone.typical_length
zone.use_conditions.typical_width = pyxb_zone.typical_width
zone.use_conditions.usage = \
pyxb_use.usage
zone.use_conditions.usage_time = \
pyxb_use.UsageOperationTime.usage_time
zone.use_conditions.daily_usage_hours = \
pyxb_use.UsageOperationTime.daily_usage_hours
zone.use_conditions.yearly_usage_days = \
pyxb_use.UsageOperationTime.yearly_usage_days
zone.use_conditions.yearly_usage_hours_day = \
pyxb_use.UsageOperationTime.yearly_usage_hours_day
zone.use_conditions.yearly_usage_hours_night = \
pyxb_use.UsageOperationTime.yearly_usage_hours_night
zone.use_conditions.daily_operation_ahu_cooling = \
pyxb_use.UsageOperationTime.daily_operation_ahu_cooling
zone.use_conditions.yearly_heating_days = \
pyxb_use.UsageOperationTime.yearly_heating_days
zone.use_conditions.yearly_ahu_days = \
pyxb_use.UsageOperationTime.yearly_ahu_days
zone.use_conditions.yearly_cooling_days = \
pyxb_use.UsageOperationTime.yearly_cooling_days
zone.use_conditions.daily_operation_heating = \
pyxb_use.UsageOperationTime.daily_operation_heating
try:
if float(project_bind.version) >= 0.4:
zone.use_conditions.maintained_illuminance = \
pyxb_use.Lighting.maintained_illuminance
else:
zone.use_conditions.maintained_illuminance = \
pyxb_use.Lighting.maintained_illuminace
except AttributeError:
zone.use_conditions.maintained_illuminance = \
pyxb_use.Lighting.maintained_illuminace
zone.use_conditions.usage_level_height = \
pyxb_use.Lighting.usage_level_height
zone.use_conditions.red_factor_visual = \
pyxb_use.Lighting.red_factor_visual
zone.use_conditions.rel_absence = \
pyxb_use.Lighting.rel_absence
zone.use_conditions.room_index = \
pyxb_use.Lighting.room_index
zone.use_conditions.part_load_factor_lighting = \
pyxb_use.Lighting.part_load_factor_lighting
zone.use_conditions.ratio_conv_rad_lighting = \
pyxb_use.Lighting.ratio_conv_rad_lighting
zone.use_conditions.set_temp_heat = \
pyxb_use.RoomClimate.set_temp_heat
zone.use_conditions.set_temp_cool = \
pyxb_use.RoomClimate.set_temp_cool
zone.use_conditions.temp_set_back = \
pyxb_use.RoomClimate.temp_set_back
zone.use_conditions.min_temp_heat = \
pyxb_use.RoomClimate.min_temp_heat
zone.use_conditions.max_temp_cool = \
pyxb_use.RoomClimate.max_temp_cool
zone.use_conditions.rel_humidity = \
pyxb_use.RoomClimate.rel_humidity
zone.use_conditions.cooling_time = \
pyxb_use.RoomClimate.cooling_time
zone.use_conditions.heating_time = \
pyxb_use.RoomClimate.heating_time
zone.use_conditions.min_air_exchange = \
pyxb_use.RoomClimate.min_air_exchange
zone.use_conditions.rel_absence_ahu = \
pyxb_use.RoomClimate.rel_absence_ahu
zone.use_conditions.part_load_factor_ahu = \
pyxb_use.RoomClimate.part_load_factor_ahu
zone.use_conditions.persons = \
pyxb_use.InternalGains.persons
zone.use_conditions.profile_persons = \
pyxb_use.InternalGains.profile_persons
zone.use_conditions.machines = \
pyxb_use.InternalGains.machines
zone.use_conditions.profile_machines = \
pyxb_use.InternalGains.profile_machines
zone.use_conditions.lighting_power = \
pyxb_use.InternalGains.lighting_power
zone.use_conditions.profile_lighting = \
pyxb_use.InternalGains.profile_lighting
zone.use_conditions.min_ahu = \
pyxb_use.AHU.min_ahu
zone.use_conditions.max_ahu = \
pyxb_use.AHU.max_ahu
zone.use_conditions.with_ahu = \
pyxb_use.AHU.with_ahu
zone.use_constant_ach_rate = \
pyxb_use.AHU.use_constant_ach_rate
zone.base_ach = \
pyxb_use.AHU.base_ach
zone.max_user_ach = \
pyxb_use.AHU.max_user_ach
zone.max_overheating_ach = \
pyxb_use.AHU.max_overheating_ach
zone.max_summer_ach = \
pyxb_use.AHU.max_summer_ach
zone.winter_reduction = \
pyxb_use.AHU.winter_reduction
for pyxb_wall in pyxb_zone.OuterWall:
out_wall = OuterWall(zone)
set_basic_data_teaser(pyxb_wall, out_wall)
set_layer_data_teaser(pyxb_wall, out_wall)
try:
if float(project_bind.version) >= 0.6:
for pyxb_wall in pyxb_zone.Door:
out_wall = Door(zone)
set_basic_data_teaser(pyxb_wall, out_wall)
set_layer_data_teaser(pyxb_wall, out_wall)
except AttributeError:
pass
for pyxb_wall in pyxb_zone.Rooftop:
roof = Rooftop(zone)
set_basic_data_teaser(pyxb_wall, roof)
set_layer_data_teaser(pyxb_wall, roof)
# zone.outer_walls.append(roof)
for pyxb_wall in pyxb_zone.GroundFloor:
gr_floor = GroundFloor(zone)
set_basic_data_teaser(pyxb_wall, gr_floor)
set_layer_data_teaser(pyxb_wall, gr_floor)
# zone.outer_walls.append(gr_floor)
for pyxb_wall in pyxb_zone.InnerWall:
in_wall = InnerWall(zone)
set_basic_data_teaser(pyxb_wall, in_wall)
set_layer_data_teaser(pyxb_wall, in_wall)
# zone.inner_walls.append(in_wall)
for pyxb_wall in pyxb_zone.Ceiling:
ceiling = Ceiling(zone)
set_basic_data_teaser(pyxb_wall, ceiling)
set_layer_data_teaser(pyxb_wall, ceiling)
# zone.inner_walls.append(ceiling)
for pyxb_wall in pyxb_zone.Floor:
floor = Floor(zone)
set_basic_data_teaser(pyxb_wall, floor)
set_layer_data_teaser(pyxb_wall, floor)
# zone.inner_walls.append(floor)
for pyxb_win in pyxb_zone.Window:
win = Window(zone)
set_basic_data_teaser(pyxb_win, win)
set_layer_data_teaser(pyxb_win, win)
def generate_from_gml(self):
"""Enriches lod1 or lod2 data from CityGML
Adds Zones, BoundaryConditions, Material settings for walls and
windows to the geometric representation of CityGML
"""
type_bldg_area = self.net_leased_area
self.net_leased_area = 0.0
# create zones with their corresponding area, name and usage
for key, value in self.zone_area_factors.items():
zone = ThermalZone(self)
zone.area = type_bldg_area * value[0]
zone.name = key
use_cond = UseCond(zone)
use_cond.load_use_conditions(value[1], data_class=self.parent.data)
zone.use_conditions = use_cond
zone.use_conditions.with_ahu = False
zone.use_conditions.persons *= zone.area * 0.01
zone.use_conditions.machines *= zone.area * 0.01
for surface in self.gml_surfaces:
if surface.surface_tilt is not None:
if surface.surface_tilt == 90:
outer_wall = OuterWall(zone)
outer_wall.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
outer_wall.name = surface.name
outer_wall.tilt = surface.surface_tilt
outer_wall.orientation = surface.surface_orientation
window = Window(zone)
window.load_type_element(self.year_of_construction,
"Kunststofffenster, "
"Isolierverglasung",
data_class=self.parent.data)
window.name = "asd" + str(surface.surface_tilt)
window.tilt = surface.surface_tilt
window.orientation = surface.surface_orientation
elif surface.surface_tilt == 0 and \
surface.surface_orientation == \
-2:
outer_wall = GroundFloor(zone)
outer_wall.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
outer_wall.name = surface.name
outer_wall.tilt = surface.surface_tilt
outer_wall.orientation = surface.surface_orientation
else:
outer_wall = Rooftop(zone)
outer_wall.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
outer_wall.name = surface.name
outer_wall.tilt = surface.surface_tilt
outer_wall.orientation = surface.surface_orientation
for key, value in self.inner_wall_names.items():
for zone in self.thermal_zones:
inner_wall = InnerWall(zone)
inner_wall.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
inner_wall.name = key
inner_wall.tilt = value[0]
inner_wall.orientation = value[1]
if self.number_of_floors > 1:
for key, value in self.ceiling_names.items():
for zone in self.thermal_zones:
ceiling = Ceiling(zone)
ceiling.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
ceiling.name = key
ceiling.tilt = value[0]
ceiling.orientation = value[1]
for key, value in self.floor_names.items():
for zone in self.thermal_zones:
floor = Floor(zone)
floor.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
floor.name = key
floor.tilt = value[0]
floor.orientation = value[1]
else:
pass
for surface in self.gml_surfaces:
if surface.surface_tilt is not None:
if surface.surface_tilt != 0 and surface.surface_orientation\
!= -2 and surface.surface_orientation != -1:
self.set_outer_wall_area(
surface.surface_area * (1 - self.est_factor_win_area),
surface.surface_orientation)
else:
self.set_outer_wall_area(surface.surface_area,
surface.surface_orientation)
for surface in self.gml_surfaces:
if surface.surface_tilt != 0 and surface.surface_orientation != \
-2 and surface.surface_orientation != -1:
self.set_window_area(
surface.surface_area * self.est_factor_win_area,
surface.surface_orientation)
for zone in self.thermal_zones:
zone.set_inner_wall_area()
zone.set_volume_zone()
def generate_archetype(self):
"""Generates a SingleFamilyDwelling building.
With given values, this class generates a archetype building for
single family dwellings according to TEASER requirements
"""
# help area for the correct building area setting while using typeBldgs
type_bldg_area = self.net_leased_area
self.net_leased_area = 0.0
self._number_of_heated_floors = self._est_factor_heated_cellar + \
self.number_of_floors + self.est_living_area_factor \
* self._est_factor_heated_attic
self._living_area_per_floor = type_bldg_area / \
self._number_of_heated_floors
self._est_ground_floor_area = self.est_bottom_building_closure * \
self._living_area_per_floor
self._est_roof_area = self.est_upper_building_closure * \
self._est_factor_dormer * self._est_area_per_floor * \
self._living_area_per_floor
self._top_floor_area = self._est_area_per_roof * \
self._living_area_per_floor
if self._est_roof_area == 0:
self._est_roof_area = self._top_floor_area
self._est_facade_area = self._est_facade_to_floor_area * \
self._living_area_per_floor + self._est_extra_floor_area
self._est_win_area = self.est_factor_win_area * type_bldg_area
self._est_cellar_wall_area = self.est_factor_cellar_area * \
self._est_factor_heated_cellar * self._est_facade_area
self._est_outer_wall_area = (self._number_of_heated_floors *
self._est_facade_area) - \
self._est_cellar_wall_area - \
self._est_win_area
# self._est_factor_volume = type_bldg_area * 2.5
for key, value in self.zone_area_factors.items():
zone = ThermalZone(self)
zone.name = key
zone.area = type_bldg_area * value[0]
use_cond = UseCond(zone)
use_cond.load_use_conditions(value[1], data_class=self.parent.data)
zone.use_conditions = use_cond
zone.use_conditions.with_ahu = False
zone.use_conditions.persons *= zone.area * 0.01
zone.use_conditions.machines *= zone.area * 0.01
for key, value in self.outer_wall_names.items():
# North and South
if value[1] == 0 or value[1] == 180.0:
self.outer_area[value[1]] = self._est_outer_wall_area / \
self.nr_of_orientation
# East and West
elif value[1] == 90 or value[1] == 270:
self.outer_area[value[1]] = self._est_outer_wall_area / \
self.nr_of_orientation
for zone in self.thermal_zones:
# create wall and set building elements
outer_wall = OuterWall(zone)
outer_wall.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
outer_wall.name = key
outer_wall.tilt = value[0]
outer_wall.orientation = value[1]
for key, value in self.window_names.items():
if value[1] == 0 or value[1] == 180:
self.window_area[value[1]] = self._est_win_area / \
self.nr_of_orientation
elif value[1] == 90 or value[1] == 270:
self.window_area[value[1]] = self._est_win_area / \
self.nr_of_orientation
'''
There is no real classification for windows, so this is a bit hard
code - will be fixed sometime
'''
for zone in self.thermal_zones:
window = Window(zone)
window.load_type_element(self.year_of_construction,
"Kunststofffenster, "
"Isolierverglasung",
data_class=self.parent.data)
window.name = key
window.tilt = value[0]
window.orientation = value[1]
for key, value in self.roof_names.items():
self.outer_area[value[1]] = self._est_roof_area
for zone in self.thermal_zones:
roof = Rooftop(zone)
roof.load_type_element(year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
roof.name = key
roof.tilt = value[0]
roof.orientation = value[1]
for key, value in self.ground_floor_names.items():
self.outer_area[value[1]] = self._est_ground_floor_area
for zone in self.thermal_zones:
ground_floor = GroundFloor(zone)
ground_floor.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
ground_floor.name = key
ground_floor.tilt = value[0]
ground_floor.orientation = value[1]
for key, value in self.inner_wall_names.items():
for zone in self.thermal_zones:
inner_wall = InnerWall(zone)
inner_wall.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
inner_wall.name = key
inner_wall.tilt = value[0]
inner_wall.orientation = value[1]
# zone.inner_walls.append(inner_wall)
if self.number_of_floors > 1:
for key, value in self.ceiling_names.items():
for zone in self.thermal_zones:
ceiling = Ceiling(zone)
ceiling.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
ceiling.name = key
ceiling.tilt = value[0]
ceiling.orientation = value[1]
# zone.inner_walls.append(ceiling)
for key, value in self.floor_names.items():
for zone in self.thermal_zones:
floor = Floor(zone)
floor.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
floor.name = key
floor.tilt = value[0]
floor.orientation = value[1]
# zone.inner_walls.append(floor)
else:
pass
for key, value in self.outer_area.items():
self.set_outer_wall_area(value, key)
for key, value in self.window_area.items():
self.set_window_area(value, key)
for zone in self.thermal_zones:
zone.set_inner_wall_area()
zone.set_volume_zone()
def load_teaser_json(path, project):
"""Load a project from json.
TEASERs internal file format to store information.
Parameters
----------
path: string
path of teaserjson file
project: Project()
Teaser instance of Project()
"""
__building_class = {
"Office": {
"method": "bmvbs",
"teaser_class": Office
},
"Institute": {
"method": "bmvbs",
"teaser_class": Institute
},
"Institute4": {
"method": "bmvbs",
"teaser_class": Institute4
},
"Institute8": {
"method": "bmvbs",
"teaser_class": Institute8
},
"Building": {
"method": "undefined",
"teaser_class": Building
},
"SingleFamilyDwelling": {
"method": "iwu",
"teaser_class": SingleFamilyDwelling
},
"SingleFamilyHouse": {
"method": "tabula_de",
"teaser_class": SingleFamilyHouse
},
"TerracedHouse": {
"method": "tabula_de",
"teaser_class": TerracedHouse
},
"MultiFamilyHouse": {
"method": "tabula_de",
"teaser_class": MultiFamilyHouse
},
"ApartmentBlock": {
"method": "tabula_de",
"teaser_class": ApartmentBlock
},
}
with open(path, "r+") as f:
prj_in = json.load(f, object_pairs_hook=collections.OrderedDict)
project.name = prj_in["project"]["name"]
project.weather_file_path = prj_in["project"]["weather_file_path"]
project.number_of_elements_calc = prj_in["project"][
"number_of_elements_calc"]
project.merge_windows_calc = prj_in["project"]["merge_windows_calc"]
project.used_library_calc = prj_in["project"]["used_library_calc"]
project.modelica_info.start_time = prj_in["project"]["modelica_info"][
"start_time"]
project.modelica_info.stop_time = prj_in["project"]["modelica_info"][
"stop_time"]
project.modelica_info.interval_output = prj_in["project"]["modelica_info"][
"interval_output"]
project.modelica_info.current_solver = prj_in["project"]["modelica_info"][
"current_solver"]
project.modelica_info.equidistant_output = prj_in["project"][
"modelica_info"]["equidistant_output"]
project.modelica_info.results_at_events = prj_in["project"][
"modelica_info"]["results_at_events"]
project.modelica_info.version = prj_in["project"]["modelica_info"][
"version"]
for bldg_name, bldg_in in prj_in["project"]["buildings"].items():
bl_class = __building_class[bldg_in["classification"]
["class"]]["teaser_class"]
bldg = bl_class(parent=project)
bldg.name = bldg_name
bldg.street_name = bldg_in["street_name"]
bldg.city = bldg_in["city"]
bldg.year_of_construction = bldg_in["year_of_construction"]
bldg.year_of_retrofit = bldg_in["year_of_retrofit"]
bldg.number_of_floors = bldg_in["number_of_floors"]
bldg.height_of_floors = bldg_in["height_of_floors"]
# bldg.net_leased_area = bldg_in["net_leased_area"]
bldg.outer_area = bldg_in["outer_area"]
bldg.window_area = bldg_in["window_area"]
try:
bldg.central_ahu = BuildingAHU(parent=bldg)
bldg.central_ahu.heating = bldg_in["central_ahu"]["heating"]
bldg.central_ahu.cooling = bldg_in["central_ahu"]["cooling"]
bldg.central_ahu.dehumidification = bldg_in["central_ahu"][
"dehumidification"]
bldg.central_ahu.humidification = bldg_in["central_ahu"][
"humidification"]
bldg.central_ahu.heat_recovery = bldg_in["central_ahu"][
"heat_recovery"]
bldg.central_ahu.by_pass_dehumidification = bldg_in["central_ahu"][
"by_pass_dehumidification"]
bldg.central_ahu.efficiency_recovery = bldg_in["central_ahu"][
"efficiency_recovery"]
bldg.central_ahu.efficiency_recovery_false = bldg_in[
"central_ahu"]["efficiency_recovery_false"]
bldg.central_ahu.min_relative_humidity_profile = bldg_in[
"central_ahu"]["min_relative_humidity_profile"]
bldg.central_ahu.max_relative_humidity_profile = bldg_in[
"central_ahu"]["max_relative_humidity_profile"]
bldg.central_ahu.v_flow_profile = bldg_in["central_ahu"][
"v_flow_profile"]
bldg.central_ahu.temperature_profile = bldg_in["central_ahu"][
"temperature_profile"]
except KeyError:
pass
for tz_name, zone_in in bldg_in["thermal_zones"].items():
tz = ThermalZone(parent=bldg)
tz.name = tz_name
tz.area = zone_in["area"]
tz.volume = zone_in["volume"]
tz.use_conditions = UseConditions(parent=tz)
tz.use_conditions.usage = zone_in["use_conditions"]["usage"]
tz.use_conditions.typical_length = zone_in["use_conditions"][
"typical_length"]
tz.use_conditions.typical_width = zone_in["use_conditions"][
"typical_width"]
tz.use_conditions.with_heating = zone_in["use_conditions"][
"with_heating"]
tz.use_conditions.with_cooling = zone_in["use_conditions"][
"with_cooling"]
tz.use_conditions.with_ideal_thresholds = zone_in[
"use_conditions"]["with_ideal_thresholds"]
tz.use_conditions.T_threshold_heating = zone_in["use_conditions"][
"T_threshold_heating"]
tz.use_conditions.T_threshold_cooling = zone_in["use_conditions"][
"T_threshold_cooling"]
tz.use_conditions.fixed_heat_flow_rate_persons = zone_in[
"use_conditions"]["fixed_heat_flow_rate_persons"]
tz.use_conditions.activity_degree_persons = zone_in[
"use_conditions"]["activity_degree_persons"]
tz.use_conditions.persons = zone_in["use_conditions"]["persons"]
tz.use_conditions.internal_gains_moisture_no_people = zone_in[
"use_conditions"]["internal_gains_moisture_no_people"]
tz.use_conditions.ratio_conv_rad_persons = zone_in[
"use_conditions"]["ratio_conv_rad_persons"]
tz.use_conditions.machines = zone_in["use_conditions"]["machines"]
tz.use_conditions.ratio_conv_rad_machines = zone_in[
"use_conditions"]["ratio_conv_rad_machines"]
tz.use_conditions.lighting_power = zone_in["use_conditions"][
"lighting_power"]
tz.use_conditions.ratio_conv_rad_lighting = zone_in[
"use_conditions"]["ratio_conv_rad_lighting"]
tz.use_conditions.use_constant_infiltration = zone_in[
"use_conditions"]["use_constant_infiltration"]
tz.use_conditions.infiltration_rate = zone_in["use_conditions"][
"infiltration_rate"]
tz.use_conditions.max_user_infiltration = zone_in[
"use_conditions"]["max_user_infiltration"]
tz.use_conditions.max_overheating_infiltration = zone_in[
"use_conditions"]["max_overheating_infiltration"]
tz.use_conditions.max_summer_infiltration = zone_in[
"use_conditions"]["max_summer_infiltration"]
tz.use_conditions.winter_reduction_infiltration = zone_in[
"use_conditions"]["winter_reduction_infiltration"]
tz.use_conditions.min_ahu = zone_in["use_conditions"]["min_ahu"]
tz.use_conditions.max_ahu = zone_in["use_conditions"]["max_ahu"]
tz.use_conditions.with_ahu = zone_in["use_conditions"]["with_ahu"]
tz.use_conditions.heating_profile = zone_in["use_conditions"][
"heating_profile"]
tz.use_conditions.cooling_profile = zone_in["use_conditions"][
"cooling_profile"]
tz.use_conditions.persons_profile = zone_in["use_conditions"][
"persons_profile"]
tz.use_conditions.machines_profile = zone_in["use_conditions"][
"machines_profile"]
tz.use_conditions.lighting_profile = zone_in["use_conditions"][
"lighting_profile"]
for wall_name, wall_in in zone_in["outer_walls"].items():
out_wall = OuterWall(parent=tz)
out_wall.name = wall_name
set_basic_data_teaser(wall_in, out_wall)
set_layer_data_teaser(wall_in, out_wall)
for door_name, door_in in zone_in["doors"].items():
door = Door(parent=tz)
door.name = door_name
set_basic_data_teaser(door_in, door)
set_layer_data_teaser(door_in, door)
for roof_name, roof_in in zone_in["rooftops"].items():
roof = Rooftop(parent=tz)
roof.name = roof_name
set_basic_data_teaser(roof_in, roof)
set_layer_data_teaser(roof_in, roof)
for gf_name, gf_in in zone_in["ground_floors"].items():
gf = GroundFloor(parent=tz)
gf.name = gf_name
set_basic_data_teaser(gf_in, gf)
set_layer_data_teaser(gf_in, gf)
for win_name, win_in in zone_in["windows"].items():
win = Window(parent=tz)
win.name = win_name
set_basic_data_teaser(win_in, win)
set_layer_data_teaser(win_in, win)
for iw_name, iw_in in zone_in["inner_walls"].items():
in_wall = InnerWall(parent=tz)
in_wall.name = iw_name
set_basic_data_teaser(iw_in, in_wall)
set_layer_data_teaser(iw_in, in_wall)
for fl_name, fl_in in zone_in["floors"].items():
floor = Floor(parent=tz)
floor.name = fl_name
set_basic_data_teaser(fl_in, floor)
set_layer_data_teaser(fl_in, floor)
for cl_name, cl_in in zone_in["ceilings"].items():
ceil = Ceiling(parent=tz)
ceil.name = cl_name
set_basic_data_teaser(cl_in, ceil)
set_layer_data_teaser(cl_in, ceil)
def from_scratch(
number_of_elements,
save=False,
path=utilities.get_default_path()):
"""This function creates the test room from scratch.
Notes: The standard defines an solar absorption coefficient for interior
surfaces of 0.6. We do not consider this, but we could by multiplying
the solar radiation after the window by 0.6.
Parameters
----------
number_of_elements: int
Number of elements of model
path: str (optional)
Path where Project should be stored as .teaserXML
save: bool (optional)
True if Project should be stored as .teaserXML at path
Returns
-------
prj: Project
Project that contains the building with the test room
"""
prj = Project(load_data=True)
prj.name = "ASHRAE140Verification"
bldg = Building(parent=prj)
bldg.name = "TestBuilding"
tz = ThermalZone(parent=bldg)
tz.name = "TestRoom900"
tz.area = 8.0 * 6.0
tz.volume = tz.area * 2.7
tz.infiltration_rate = 0.41
tz.use_conditions = BoundaryConditions(parent=tz)
roof = Rooftop(parent=tz)
roof.name = "Roof"
roof.area = 8.0 * 6.0
roof.orientation = -1.0
roof.tilt = 0.0
roof.inner_convection = 1
roof.outer_convection = 24.67
roof.inner_radiation = 5.13
roof.outer_radiation = 4.63
layer_r1 = Layer(parent=roof, id=0)
layer_r1.thickness = 0.01
material_r1 = Material(layer_r1)
material_r1.name = "Plasterboard"
material_r1.density = 950.0
material_r1.heat_capac = 840.0 / 1000
material_r1.thermal_conduc = 0.16
material_r1.ir_emissivity = 0.9
layer_r2 = Layer(parent=roof, id=1)
layer_r2.thickness = 0.1118
material_r2 = Material(layer_r2)
material_r2.name = "Fiberglass"
material_r2.density = 12
material_r2.heat_capac = 840 / 1000
material_r2.thermal_conduc = 0.04
layer_r3 = Layer(parent=roof, id=2)
layer_r3.thickness = 0.019
material_r3 = Material(layer_r3)
material_r3.name = "Roofdeck"
material_r3.density = 530
material_r3.heat_capac = 900 / 1000
material_r3.thermal_conduc = 0.14
material_r3.solar_absorp = 0.6
material_r3.ir_emissivity = 0.9
out_wall_north = OuterWall(parent=tz)
out_wall_north.name = "OuterWallNorth"
out_wall_north.area = 8.0 * 2.7
out_wall_north.orientation = 0.0
out_wall_north.tilt = 90.0
out_wall_north.inner_convection = 3.16
out_wall_north.outer_convection = 24.67
out_wall_north.inner_radiation = 5.13
out_wall_north.outer_radiation = 4.63
layer_own1 = Layer(parent=out_wall_north, id=0)
layer_own1.thickness = 0.1
material_own1 = Material(layer_own1)
material_own1.name = "Concrete"
material_own1.density = 1400.0
material_own1.heat_capac = 1000 / 1000
material_own1.thermal_conduc = 0.51
material_own1.ir_emissivity = 0.9
layer_own2 = Layer(parent=out_wall_north, id=1)
layer_own2.thickness = 0.062
material_own2 = Material(layer_own2)
material_own2.name = "FoamInsulation"
material_own2.density = 10
material_own2.heat_capac = 1400 / 1000
material_own2.thermal_conduc = 0.04
layer_own3 = Layer(parent=out_wall_north, id=2)
layer_own3.thickness = 0.009
material_own3 = Material(layer_own3)
material_own3.name = "WoodSiding"
material_own3.density = 530
material_own3.heat_capac = 900 / 1000
material_own3.thermal_conduc = 0.14
material_own3.solar_absorp = 0.6
material_own3.ir_emissivity = 0.9
out_wall_east = OuterWall(parent=tz)
out_wall_east.name = "OuterWallEast"
out_wall_east.area = 6.0 * 2.7
out_wall_east.orientation = 90.0
out_wall_east.tilt = 90.0
out_wall_east.inner_convection = 3.16
out_wall_east.outer_convection = 24.67
out_wall_east.inner_radiation = 5.13
out_wall_east.outer_radiation = 4.63
layer_owe1 = Layer(parent=out_wall_east, id=0)
layer_owe1.thickness = 0.1
material_owe1 = Material(layer_owe1)
material_owe1.name = "Concrete"
material_owe1.density = 1400.0
material_owe1.heat_capac = 1000 / 1000
material_owe1.thermal_conduc = 0.51
material_owe1.ir_emissivity = 0.9
layer_owe2 = Layer(parent=out_wall_east, id=1)
layer_owe2.thickness = 0.062
material_owe2 = Material(layer_owe2)
material_owe2.name = "FoamInsulation"
material_owe2.density = 10
material_owe2.heat_capac = 1400 / 1000
material_owe2.thermal_conduc = 0.04
layer_owe3 = Layer(parent=out_wall_east, id=2)
layer_owe3.thickness = 0.009
material_owe3 = Material(layer_owe3)
material_owe3.name = "WoodSiding"
material_owe3.density = 530
material_owe3.heat_capac = 900 / 1000
material_owe3.thermal_conduc = 0.14
material_owe3.solar_absorp = 0.6
material_owe3.ir_emissivity = 0.9
out_wall_south = OuterWall(parent=tz)
out_wall_south.name = "OuterWallSouth"
out_wall_south.area = (8.0 * 2.7) - 2 * (3 * 2) # minus two windows
out_wall_south.orientation = 180.0
out_wall_south.tilt = 90.0
out_wall_south.inner_convection = 3.16
out_wall_south.outer_convection = 24.67
out_wall_south.inner_radiation = 5.13
out_wall_south.outer_radiation = 4.63
layer_ows1 = Layer(parent=out_wall_south, id=0)
layer_ows1.thickness = 0.1
material_ows1 = Material(layer_ows1)
material_ows1.name = "Concrete"
material_ows1.density = 1400.0
material_ows1.heat_capac = 1000.0 / 1000
material_ows1.thermal_conduc = 0.51
material_ows1.ir_emissivity = 0.9
layer_ows2 = Layer(parent=out_wall_south, id=1)
layer_ows2.thickness = 0.062
material_ows2 = Material(layer_ows2)
material_ows2.name = "FoamInsulation"
material_ows2.density = 10
material_ows2.heat_capac = 1400 / 1000
material_ows2.thermal_conduc = 0.04
layer_ows3 = Layer(parent=out_wall_south, id=2)
layer_ows3.thickness = 0.009
material_ows3 = Material(layer_ows3)
material_ows3.name = "WoodSiding"
material_ows3.density = 530
material_ows3.heat_capac = 900 / 1000
material_ows3.thermal_conduc = 0.14
material_ows3.solar_absorp = 0.6
material_ows3.ir_emissivity = 0.9
out_wall_west = OuterWall(parent=tz)
out_wall_west.name = "OuterWallWest"
out_wall_west.area = 6 * 2.7
out_wall_west.orientation = 270.0
out_wall_west.tilt = 90.0
out_wall_west.inner_convection = 3.16
out_wall_west.outer_convection = 24.67
out_wall_west.inner_radiation = 5.13
out_wall_west.outer_radiation = 4.63
layer_oww1 = Layer(parent=out_wall_west, id=0)
layer_oww1.thickness = 0.1
material_oww1 = Material(layer_oww1)
material_oww1.name = "Concrete"
material_oww1.density = 1400.0
material_oww1.heat_capac = 1000.0 / 1000
material_oww1.thermal_conduc = 0.51
material_oww1.ir_emissivity = 0.9
layer_oww2 = Layer(parent=out_wall_west, id=1)
layer_oww2.thickness = 0.062
material_oww2 = Material(layer_oww2)
material_oww2.name = "FoamInsulation"
material_oww2.density = 10
material_oww2.heat_capac = 1400 / 1000
material_oww2.thermal_conduc = 0.04
layer_oww3 = Layer(parent=out_wall_west, id=2)
layer_oww3.thickness = 0.009
material_oww3 = Material(layer_oww3)
material_oww3.name = "WoodSiding"
material_oww3.density = 530
material_oww3.heat_capac = 900 / 1000
material_oww3.thermal_conduc = 0.14
material_oww3.solar_absorp = 0.6
material_oww3.ir_emissivity = 0.9
in_wall_floor = Floor(parent=tz)
in_wall_floor.name = "InnerWallFloor"
in_wall_floor.area = 6 * 8
in_wall_floor.orientation = -2.0
in_wall_floor.tilt = 0.0
in_wall_floor.inner_convection = 4.13
in_wall_floor.inner_radiation = 5.13
layer_iwf1 = Layer(parent=in_wall_floor, id=0)
layer_iwf1.thickness = 0.025
material_iwf1 = Material(layer_iwf1)
material_iwf1.name = "Concrete"
material_iwf1.density = 1400
material_iwf1.heat_capac = 1000 / 1000
material_iwf1.thermal_conduc = 1.13
material_iwf1.ir_emissivity = 0.9
layer_iwf2 = Layer(parent=in_wall_floor, id=1)
layer_iwf2.thickness = 1.007
material_iwf2 = Material(layer_iwf2)
material_iwf2.name = "Insulation"
material_iwf2.density = 0.000000000001 # 0.0001, as small as possible
material_iwf2.heat_capac = 0.000000000001 # 0.0001, as small as possible
material_iwf2.thermal_conduc = 0.04
win_1 = Window(parent=tz)
win_1.name = "WindowSouthLeft"
win_1.area = 3 * 2
win_1.tilt = 90.0
win_1.orientation = 180.0
win_1.inner_convection = 3.16
win_1.inner_radiation = 5.13
win_1.outer_convection = 16.37
win_1.outer_radiation = 4.63
win_1.g_value = 0.789
win_1.a_conv = 0.03 # for the given U-value extracted from VDI 6007-2/-3
win_1_layer = Layer(parent=win_1)
win_1_layer.id = 1
win_1_layer.thickness = 0.024
win_1_material = Material(win_1_layer)
win_1_material.name = "GlasWindow"
win_1_material.thermal_conduc = 0.15
win_1_material.transmittance = 0.907
win_1_material.ir_emissivity = 0.9
win_2 = Window(parent=tz)
win_2.name = "WindowSouthRight"
win_2.area = 3 * 2
win_2.tilt = 90.0
win_2.orientation = 180.0
win_2.inner_convection = 3.16
win_2.inner_radiation = 5.13
win_2.outer_convection = 16.37
win_2.outer_radiation = 4.63
win_2.g_value = 0.789
win_2.a_conv = 0.03 # for the given U-value extracted from VDI 6007-2/-3
win_2_layer = Layer(parent=win_2)
win_2_layer.id = 1
win_2_layer.thickness = 0.024
win_2_material = Material(win_2_layer)
win_2_material.name = "GlasWindow"
win_2_material.thermal_conduc = 0.15
win_2_material.transmittance = 0.907
win_2_material.ir_emissivity = 0.9
# This is a dummy ground floor to export three and four elements models.
# Please set values for floor plate in three element and four element
# models to default.
if number_of_elements >= 3:
out_wall_gf = GroundFloor(parent=tz)
out_wall_gf.name = "ExtWallGroundFloor"
out_wall_gf.area = 6 * 8
out_wall_gf.orientation = -2.0
out_wall_gf.tilt = 0.0
out_wall_gf.inner_convection = 4.13
out_wall_gf.inner_radiation = 5.13
layer_ofgw1 = Layer(parent=out_wall_gf, id=0)
layer_ofgw1.thickness = 1.003
material_ofgw1 = Material(layer_ofgw1)
material_ofgw1.name = "Insulation"
material_ofgw1.density = 0.0001 # as small as possible
material_ofgw1.heat_capac = 0.0001 # as small as possible
material_ofgw1.thermal_conduc = 0.04
if save:
prj.save_project(file_name='ASHRAE140_900', path=path)
return prj
def generate_archetype(self):
"""Generates a residential building.
With given values, this class generates a type residential
building according to TEASER requirements.
"""
# help area for the correct building area setting while using typeBldgs
type_bldg_area = self.net_leased_area
self.net_leased_area = 0.0
self._est_ground_floor_area = type_bldg_area / self.number_of_floors
self._est_roof_area = type_bldg_area / self.number_of_floors
self._est_win_area = self.est_factor_win_area * type_bldg_area * \
(1 - self._est_factor_neighbour / 4)
self._est_outer_wall_area = (self.est_factor_facade_to_volume *
type_bldg_area *
self.height_of_floors -
self._est_ground_floor_area -
self._est_roof_area -
self._est_win_area)*(1 - self._est_factor_neighbour / 4)
for key, value in self.zone_area_factors.items():
zone = ThermalZone(self)
zone.name = key
zone.area = type_bldg_area * value[0]
use_cond = UseCond(zone)
use_cond.load_use_conditions(value[1])
zone.use_conditions = use_cond
for key, value in self.outer_wall_names.items():
# North and South
if value[1] == 0 or value[1] == 180.0:
self.outer_area[value[1]] = self._est_outer_wall_area / \
self.nr_of_orientation
# East and West
elif value[1] == 90 or value[1] == 270:
self.outer_area[value[1]] = self._est_outer_wall_area / \
self.nr_of_orientation
for zone in self.thermal_zones:
# create wall and set building elements
outer_wall = OuterWall(zone)
outer_wall.load_type_element(self.year_of_construction,
self.construction_type)
outer_wall.name = key
outer_wall.tilt = value[0]
outer_wall.orientation = value[1]
for key, value in self.window_names.items():
if value[1] == 0 or value[1] == 180:
self.window_area[value[1]] = self._est_win_area / \
self.nr_of_orientation
elif value[1] == 90 or value[1] == 270:
self.window_area[value[1]] = self._est_win_area / \
self.nr_of_orientation
'''
There is no real classification for windows, so this is a bit hard
code - will be fixed sometime
'''
for zone in self.thermal_zones:
window = Window(zone)
window.load_type_element(self.year_of_construction,
"Kunststofffenster, Isolierverglasung"
)
window.name = key
window.tilt = value[0]
window.orientation = value[1]
for key, value in self.roof_names.items():
self.outer_area[value[1]] = self._est_roof_area
for zone in self.thermal_zones:
roof = Rooftop(zone)
roof.load_type_element(self.year_of_construction,
self.construction_type)
roof.name = key
roof.tilt = value[0]
roof.orientation = value[1]
for key, value in self.ground_floor_names.items():
self.outer_area[value[1]] = self._est_ground_floor_area
for zone in self.thermal_zones:
ground_floor = GroundFloor(zone)
ground_floor.load_type_element(self.year_of_construction,
self.construction_type)
ground_floor.name = key
ground_floor.tilt = value[0]
ground_floor.orientation = value[1]
for key, value in self.inner_wall_names.items():
for zone in self.thermal_zones:
inner_wall = InnerWall(zone)
inner_wall.load_type_element(self.year_of_construction,
self.construction_type)
inner_wall.name = key
inner_wall.tilt = value[0]
inner_wall.orientation = value[1]
# zone.inner_walls.append(inner_wall)
if self.number_of_floors > 1:
for key, value in self.ceiling_names.items():
for zone in self.thermal_zones:
ceiling = Ceiling(zone)
ceiling.load_type_element(self.year_of_construction,
self.construction_type)
ceiling.name = key
ceiling.tilt = value[0]
ceiling.orientation = value[1]
# zone.inner_walls.append(ceiling)
for key, value in self.floor_names.items():
for zone in self.thermal_zones:
floor = Floor(zone)
floor.load_type_element(self.year_of_construction,
self.construction_type)
floor.name = key
floor.tilt = value[0]
floor.orientation = value[1]
# zone.inner_walls.append(floor)
else:
pass
for key, value in self.outer_area.items():
self.set_outer_wall_area(value, key)
for key, value in self.window_area.items():
self.set_window_area(value, key)
for zone in self.thermal_zones:
zone.set_inner_wall_area()
zone.set_volume_zone()
def generate_archetype(self):
"""Generates a residential building.
With given values, this class generates a type residential
building according to TEASER requirements.
"""
# help area for the correct building area setting while using typeBldgs
self.thermal_zones = None
type_bldg_area = self.net_leased_area
self.net_leased_area = 0.0
self._est_ground_floor_area = type_bldg_area / self.number_of_floors
self._est_roof_area = type_bldg_area / self.number_of_floors
self._est_win_area = self.est_factor_win_area * type_bldg_area * \
(1 - self._est_factor_neighbour / 4)
self._est_outer_wall_area = (self.est_factor_facade_to_volume *
type_bldg_area *
self.height_of_floors -
self._est_ground_floor_area -
self._est_roof_area -
self._est_win_area) *\
(1 - self._est_factor_neighbour / 4)
for key, value in self.zone_area_factors.items():
zone = ThermalZone(self)
zone.name = key
zone.area = type_bldg_area * value[0]
use_cond = UseCond(zone)
use_cond.load_use_conditions(value[1])
zone.use_conditions = use_cond
for key, value in self.outer_wall_names.items():
# North and South
if value[1] == 0 or value[1] == 180.0:
self.outer_area[value[1]] = self._est_outer_wall_area / \
self.nr_of_orientation
# East and West
elif value[1] == 90 or value[1] == 270:
self.outer_area[value[1]] = self._est_outer_wall_area / \
self.nr_of_orientation
for zone in self.thermal_zones:
# create wall and set building elements
outer_wall = OuterWall(zone)
outer_wall.load_type_element(self.year_of_construction,
self.construction_type)
outer_wall.name = key
outer_wall.tilt = value[0]
outer_wall.orientation = value[1]
for key, value in self.window_names.items():
if value[1] == 0 or value[1] == 180:
self.window_area[value[1]] = self._est_win_area / \
self.nr_of_orientation
elif value[1] == 90 or value[1] == 270:
self.window_area[value[1]] = self._est_win_area / \
self.nr_of_orientation
'''
There is no real classification for windows, so this is a bit hard
code - will be fixed sometime
'''
for zone in self.thermal_zones:
window = Window(zone)
window.load_type_element(
self.year_of_construction,
"Kunststofffenster, Isolierverglasung")
window.name = key
window.tilt = value[0]
window.orientation = value[1]
for key, value in self.roof_names.items():
self.outer_area[value[1]] = self._est_roof_area
for zone in self.thermal_zones:
roof = Rooftop(zone)
roof.load_type_element(self.year_of_construction,
self.construction_type)
roof.name = key
roof.tilt = value[0]
roof.orientation = value[1]
for key, value in self.ground_floor_names.items():
self.outer_area[value[1]] = self._est_ground_floor_area
for zone in self.thermal_zones:
ground_floor = GroundFloor(zone)
ground_floor.load_type_element(self.year_of_construction,
self.construction_type)
ground_floor.name = key
ground_floor.tilt = value[0]
ground_floor.orientation = value[1]
for key, value in self.inner_wall_names.items():
for zone in self.thermal_zones:
inner_wall = InnerWall(zone)
inner_wall.load_type_element(self.year_of_construction,
self.construction_type)
inner_wall.name = key
inner_wall.tilt = value[0]
inner_wall.orientation = value[1]
# zone.inner_walls.append(inner_wall)
if self.number_of_floors > 1:
for key, value in self.ceiling_names.items():
for zone in self.thermal_zones:
ceiling = Ceiling(zone)
ceiling.load_type_element(self.year_of_construction,
self.construction_type)
ceiling.name = key
ceiling.tilt = value[0]
ceiling.orientation = value[1]
# zone.inner_walls.append(ceiling)
for key, value in self.floor_names.items():
for zone in self.thermal_zones:
floor = Floor(zone)
floor.load_type_element(self.year_of_construction,
self.construction_type)
floor.name = key
floor.tilt = value[0]
floor.orientation = value[1]
# zone.inner_walls.append(floor)
else:
pass
for key, value in self.outer_area.items():
self.set_outer_wall_area(value, key)
for key, value in self.window_area.items():
self.set_window_area(value, key)
for zone in self.thermal_zones:
zone.set_inner_wall_area()
zone.set_volume_zone()
def generate_from_gml(self):
"""enriches lod1 or lod2 data from citygml
adds Zones, BoundaryConditions, Material settings for walls and
windows to the geometric representation of CityGML
number or height of floors need to be specified
"""
type_bldg_area = self.net_leased_area
self.net_leased_area = 0.0
# create zones with their corresponding area, name and usage
for key, value in self.zone_area_factors.items():
zone = ThermalZone(self)
zone.area = type_bldg_area * value[0]
zone.name = key
use_cond = UseCond(zone)
use_cond.load_use_conditions(value[1])
zone.use_conditions = use_cond
zone.use_conditions.with_ahu = False
zone.use_conditions.persons *= zone.area * 0.01
zone.use_conditions.machines *= zone.area * 0.01
for surface in self.gml_surfaces:
if surface.surface_tilt == 90:
outer_wall = OuterWall(zone)
outer_wall.load_type_element(self.year_of_construction,
self.construction_type)
outer_wall.name = surface.name
outer_wall.tilt = surface.surface_tilt
outer_wall.orientation = surface.surface_orientation
window = Window(zone)
window.load_type_element(self.year_of_construction,
"Kunststofffenster, Isolierverglasung")
window.name = "asd"+str(surface.surface_tilt)
window.tilt = surface.surface_tilt
window.orientation = surface.surface_orientation
elif surface.surface_tilt == 0 and surface.surface_orientation ==\
-2:
outer_wall = GroundFloor(zone)
outer_wall.load_type_element(self.year_of_construction,
self.construction_type)
outer_wall.name = surface.name
outer_wall.tilt = surface.surface_tilt
outer_wall.orientation = surface.surface_orientation
else:
outer_wall = Rooftop(zone)
outer_wall.load_type_element(self.year_of_construction,
self.construction_type)
outer_wall.name = surface.name
outer_wall.tilt = surface.surface_tilt
outer_wall.orientation = surface.surface_orientation
for key, value in self.inner_wall_names.items():
for zone in self.thermal_zones:
inner_wall = InnerWall(zone)
inner_wall.load_type_element(self.year_of_construction,
self.construction_type)
inner_wall.name = key
inner_wall.tilt = value[0]
inner_wall.orientation = value[1]
if self.number_of_floors > 1:
for key, value in self.ceiling_names.items():
for zone in self.thermal_zones:
ceiling = Ceiling(zone)
ceiling.load_type_element(self.year_of_construction,
self.construction_type)
ceiling.name = key
ceiling.tilt = value[0]
ceiling.orientation = value[1]
for key, value in self.floor_names.items():
for zone in self.thermal_zones:
floor = Floor(zone)
floor.load_type_element(self.year_of_construction,
self.construction_type)
floor.name = key
floor.tilt = value[0]
floor.orientation = value[1]
else:
pass
for surface in self.gml_surfaces:
self.set_outer_wall_area(surface.surface_area *
(1- self.est_factor_win_area),
surface.surface_orientation)
for surface in self.gml_surfaces:
if surface.surface_tilt != 0 and surface.surface_orientation !=\
-2 and surface.surface_orientation != -1:
self.set_window_area(surface.surface_area *
self.est_factor_win_area,
surface.surface_orientation)
for zone in self.thermal_zones:
zone.set_inner_wall_area()
zone.set_volume_zone()
def generate_archetype(self):
'''Generates a residential building.
With given values, this class generates a type residential
building according to TEASER requirements
Berechnungsgrundlagen: IWU, "Kurzverfahren Energieprofil"; 2005.
'''
#help area for the correct building area setting while using typeBldgs
type_bldg_area = self.net_leased_area
self.net_leased_area = 0.0
self._number_of_heated_floors = self._est_factor_heated_cellar + \
self.number_of_floors + self.est_living_area_factor\
*self._est_factor_heated_attic
self._living_area_per_floor = type_bldg_area / \
self._number_of_heated_floors
self._est_ground_floor_area = self.est_bottom_building_closure * \
self._living_area_per_floor
self._est_roof_area = self.est_upper_building_closure * \
self._est_factor_dormer * self._est_area_per_floor * \
self._living_area_per_floor
self._top_floor_area = self._est_area_per_roof * \
self._living_area_per_floor
if self._est_roof_area == 0:
self._est_roof_area = self._top_floor_area
self._est_facade_area = self._est_facade_to_floor_area * \
self._living_area_per_floor + self._est_extra_floor_area
self._est_win_area = self.est_factor_win_area * type_bldg_area
self._est_cellar_wall_area = self.est_factor_cellar_area * \
self._est_factor_heated_cellar * self._est_facade_area
self._est_outer_wall_area = (self._number_of_heated_floors * \
self._est_facade_area) - self._est_cellar_wall_area - \
self._est_win_area
# self._est_factor_volume = type_bldg_area * 2.5
for key, value in self.zone_area_factors.items():
zone = ThermalZone(self)
zone.name = key
zone.area = type_bldg_area * value[0]
use_cond = UseCond(zone)
use_cond.load_use_conditions(value[1])
zone.use_conditions = use_cond
for key, value in self.outer_wall_names.items():
# North and South
if value[1] == 0 or value[1] == 180.0:
self.outer_area[value[1]] = self._est_outer_wall_area / \
self.nr_of_orientation
# East and West
elif value[1] == 90 or value[1] == 270:
self.outer_area[value[1]] = self._est_outer_wall_area / \
self.nr_of_orientation
for zone in self.thermal_zones:
# create wall and set building elements
outer_wall = OuterWall(zone)
outer_wall.load_type_element(self.year_of_construction,
self.construction_type)
outer_wall.name = key
outer_wall.tilt = value[0]
outer_wall.orientation = value[1]
for key, value in self.window_names.items():
if value[1] == 0 or value[1] == 180:
self.window_area[value[1]] = self._est_win_area / \
self.nr_of_orientation
elif value[1] == 90 or value[1] == 270:
self.window_area[value[1]] = self._est_win_area / \
self.nr_of_orientation
'''
There is no real classification for windows, so this is a bit hard
code - will be fixed sometime
'''
for zone in self.thermal_zones:
window = Window(zone)
window.load_type_element(self.year_of_construction,
"Kunststofffenster, Isolierverglasung")
window.name = key
window.tilt = value[0]
window.orientation = value[1]
for key, value in self.roof_names.items():
self.outer_area[value[1]] = self._est_roof_area
for zone in self.thermal_zones:
roof = Rooftop(zone)
roof.load_type_element(self.year_of_construction, \
self.construction_type)
roof.name = key
roof.tilt = value[0]
roof.orientation = value[1]
for key, value in self.ground_floor_names.items():
self.outer_area[value[1]] = self._est_ground_floor_area
for zone in self.thermal_zones:
ground_floor = GroundFloor(zone)
ground_floor.load_type_element(self.year_of_construction, \
self.construction_type)
ground_floor.name = key
ground_floor.tilt = value[0]
ground_floor.orientation = value[1]
for key, value in self.inner_wall_names.items():
for zone in self.thermal_zones:
inner_wall = InnerWall(zone)
inner_wall.load_type_element(self.year_of_construction,
self.construction_type)
inner_wall.name = key
inner_wall.tilt = value[0]
inner_wall.orientation = value[1]
# zone.inner_walls.append(inner_wall)
if self.number_of_floors > 1:
for key, value in self.ceiling_names.items():
for zone in self.thermal_zones:
ceiling = Ceiling(zone)
ceiling.load_type_element(self.year_of_construction,
self.construction_type)
ceiling.name = key
ceiling.tilt = value[0]
ceiling.orientation = value[1]
# zone.inner_walls.append(ceiling)
for key, value in self.floor_names.items():
for zone in self.thermal_zones:
floor = Floor(zone)
floor.load_type_element(self.year_of_construction,
self.construction_type)
floor.name = key
floor.tilt = value[0]
floor.orientation = value[1]
# zone.inner_walls.append(floor)
else:
pass
for key, value in self.outer_area.items():
self.set_outer_wall_area(value, key)
for key, value in self.window_area.items():
self.set_window_area(value, key)
for zone in self.thermal_zones:
zone.set_inner_wall_area()
zone.set_volume_zone()
def generate_archetype(self):
'''Generates an office building.
With given values, this class generates a type building according to
TEASER requirements.
'''
#help area for the correct building area setting while using typeBldgs
type_bldg_area = self.net_leased_area
self.net_leased_area = 0.0
# create zones with their corresponding area, name and usage
for key, value in self.zone_area_factors.items():
zone = ThermalZone(self)
zone.area = type_bldg_area * value[0]
zone.name = key
use_cond = UseCond(zone)
use_cond.load_use_conditions(value[1],
data_class=self.parent.data)
zone.use_conditions = use_cond
zone.use_conditions.persons = zone.area * 0.01 * \
zone.use_conditions.persons
zone.use_conditions.machines = zone.area * 0.01 * \
zone.use_conditions.machines
# self.thermal_zones.append(zone)
# statistical estimation of the facade
self._est_outer_wall_area = self.est_factor_wall_area * \
type_bldg_area ** self.est_exponent_wall
self._est_win_area = self.est_factor_win_area * \
type_bldg_area ** self.est_exponent_win
self._est_roof_area = (type_bldg_area / self.number_of_floors) * \
self.gross_factor
self._est_floor_area = (type_bldg_area / self.number_of_floors) * \
self.gross_factor
# manipulation of wall according to facade design
# (received from window_layout)
self._est_facade_area = self._est_outer_wall_area + self._est_win_area
if not self.window_layout == 0:
self._est_outer_wall_area = self._est_facade_area * \
self.corr_factor_wall
self._est_win_area = self._est_facade_area * self.corr_factor_win
else:
pass
# set the facade area to the four orientations
for key, value in self.outer_wall_names.items():
# North and South
if value[1] == 0 or value[1] == 180:
self.outer_area[value[1]] = self._est_outer_wall_area * \
(self._est_length / (2 * self._est_width + 2 * self._est_length))
# East and West
elif value[1] == 90 or value[1] == 270:
self.outer_area[value[1]] = self._est_outer_wall_area * \
(self._est_width / (2 * self._est_width + 2 * self._est_length))
for zone in self.thermal_zones:
# create wall and set building elements
outer_wall = OuterWall(zone)
outer_wall.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
outer_wall.name = key
outer_wall.tilt = value[0]
outer_wall.orientation = value[1]
for key, value in self.window_names.items():
if value[1] == 0 or value[1] == 180:
self.window_area[value[1]] = self._est_win_area * \
(self._est_length / (2 * self._est_width + 2 * self._est_length))
elif value[1] == 90 or value[1] == 270:
self.window_area[value[1]] = self._est_win_area * \
(self._est_width / (2 * self._est_width + 2 * self._est_length))
'''
There is no real classification for windows, so this is a bit hard
code - will be fixed sometime.
'''
for zone in self.thermal_zones:
window = Window(zone)
window.load_type_element(self.year_of_construction,
"Kunststofffenster, Isolierverglasung",
data_class=self.parent.data)
window.name = key
window.tilt = value[0]
window.orientation = value[1]
for key, value in self.roof_names.items():
self.outer_area[value[1]] = self._est_roof_area
for zone in self.thermal_zones:
roof = Rooftop(zone)
roof.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
roof.name = key
roof.tilt = value[0]
roof.orientation = value[1]
# zone.outer_walls.append(roof)
for key, value in self.ground_floor_names.items():
self.outer_area[value[1]] = self._est_floor_area
for zone in self.thermal_zones:
ground_floor = GroundFloor(zone)
ground_floor.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
ground_floor.name = key
ground_floor.tilt = value[0]
ground_floor.orientation = value[1]
# zone.outer_walls.append(ground_floor)
for key, value in self.inner_wall_names.items():
for zone in self.thermal_zones:
inner_wall = InnerWall(zone)
inner_wall.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
inner_wall.name = key
inner_wall.tilt = value[0]
inner_wall.orientation = value[1]
# zone.inner_walls.append(inner_wall)
if self.number_of_floors > 1:
for key, value in self.ceiling_names.items():
for zone in self.thermal_zones:
ceiling = Ceiling(zone)
ceiling.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
ceiling.name = key
ceiling.tilt = value[0]
ceiling.orientation = value[1]
# zone.inner_walls.append(ceiling)
for key, value in self.floor_names.items():
for zone in self.thermal_zones:
floor = Floor(zone)
floor.load_type_element(
year=self.year_of_construction,
construction=self.construction_type,
data_class=self.parent.data)
floor.name = key
floor.tilt = value[0]
floor.orientation = value[1]
# zone.inner_walls.append(floor)
else:
pass
for key, value in self.outer_area.items():
self.set_outer_wall_area(value, key)
for key, value in self.window_area.items():
self.set_window_area(value, key)
for zone in self.thermal_zones:
zone.set_inner_wall_area()
zone.set_volume_zone()
