Certificate by: 10 Co. A67 F863 64283 Darmstadt...02ud Typical assembly-BGWALL below ground Heat transmission resistance [m²K/W] Orientation of building element 2-Wall interior R

Certificate

Client James Dean & Janet Allan3381 Radcliffe AveV7V 1G7 West Vancouver, CanadaBattersby & Howat Architects230-49 Dunlevy AveV6A 3A3 Vancouver, Canada

Building Integral GroupServices 200 Granville St, #180

V6C 1S4 Vancouver, CanadaEnergy ECON GROUP

V7M2L9 NORTH VANCOUVER, Canada

This building Alternative criteriaHeating

[kWh/(m²a)] 10 ≤ -[W/m²] 10 ≤ 10

Cooling[%] 3 ≤

AirtightnessPressurization test result (n50) [1/h] 0.4 ≤

Non-renewable primary energy (PE)[kWh/(m²a)] 102 ≤

Renewable primary energy (PER)[kWh/(m²a)] 43 ≤ 56

[kWh/(m²a)] 77 ≥ #REF!

Certifier: Robert Ryan , Robert Ryan, Earth Cycle Technologies

www.passivehouse.com 25084_ECT_PH_20191203_RR

The associated certification booklet contains more characteristic values for this building.

Building quality

Heating demandHeating load

Frequency of overheating (> 25 °C)

PER-demand

Generation (reference to ground area)

PE demand

#REF!

0

Criteria

15

Authorised by:

Certified Passive House Plus

Dean & Allan Residence 3381 Radcliffe Ave, V7V 1G7 West Vancouver, Canada

402-510 CHESTERFIELD AVENUE

Dr. Wolfgang Feist64283 DarmstadtGermany

Architect

0.6

60

Passive House buildings offer excellent thermal comfort and very good air quality all year round. Due to their high energy efficiency, energy costs as well as greenhouse gas emissions are extremely low.

The design of the above-mentioned building meets the criteria defined by the Passive House Institute for the 'Passive House Plus' standard:

Consultant

10

-

Earth Cycle Technologies10 SpringfieldWicklow Town Co. WicklowA67 F863

Passive House VerificationPhoto or Drawing Building:

Street:Postcode/City: V7V 1G7

Province/Country:Building type:

Climate data set: CA0003b-VancouverClimate zone: 4: Warm-temperate Altitude of location: 18 m

Home owner / Client:Street:

Postcode/City: V7V 1G7Province/Country:

Architecture: Mechanical system:Street: Street:

Postcode/City: V6A 3A3 Postcode/City: V6C 1S4Province/Country: Province/Country:

Energy consultancy: Certification:Street: Street:

Postcode/City: V7M2L9 Postcode/City: A67 F863Province/Country: Province/Country:

Year of construction: 2018 Interior temperature winter [°C]: 20.0 Interior temp. summer [°C]: 25.0No. of dwelling units: 1 Internal heat gains (IHG) heating case [W/m2]: 2.3 IHG cooling case [W/m²]: 4.9

No. of occupants: 3.2 Specific capacity [Wh/K per m² TFA]: 60 Mechanical cooling:

Specific building characteristics with reference to the treated floor area

Treated floor area m² 295.2 Criteria Fullfilled?2

Space heating Heating demand kWh/(m²a) 10 ≤ 15 -Heating load W/m² 10 ≤ - 10

Space cooling Cooling & dehum. demand kWh/(m²a) - ≤ - -Cooling load W/m² - ≤ - -

Frequency of overheating (> 25 °C) % 3 ≤ 10 yesFrequency excessively high humidity (> 12 g/kg) % 0 ≤ 20 yes

Airtightness Pressurization test result n50 1/h 0.4 ≤ 0.6 yes

PE demand kWh/(m²a) 102 ≤ - -

PER demand kWh/(m²a) 43 ≤ 45 43kWh/(m²a) 77 ≥ 60 56

2 Empty field: Data missing; '-': No requirement

Passive House Plus? yesTask: First name: Surname: Signature:

2-CertifierCertificate ID Issued on: City:

08/01/20

Non-renewable Primary Energy (PE)

Primary Energy Renewable (PER) Generation of renewable

energy

Robert

I confirm that the values given herein have been determined following the PHPP methodology and based on the characteristic values of the building. The PHPP calculations are attached to this verification.

yes

CA-Canada

CA-CanadaVancouver

3381 Radcliffe AveWest Vancouver

BC

Integral Group200 Granville St, #180

Robert Ryan, Earth Cycle Technologies10 Springfield

Wicklow TownWicklow

402-510 CHESTERFIELD AVENUENORTH VANCOUVER

BC

Dean & Allan Residence3381 Radcliffe Ave

West VancouverBC

James Dean & Janet Allan

CA-CanadaSingle Family Residence

Battersby & Howat Architects230-49 Dunlevy Ave

VancouverBC

ECON GROUP

IE-Ireland

yes

-

Alternative criteria

CA-Canada

CA-Canada

Ryan

25084_ECT_PH_20191203_RR Wicklow IE

BC

PHPP, Verification PHPP_V9_current

-

Climate data Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Data for heating Data from monthly balanceSelection of climate data Result overview Annual method Heating Cooling

Country: CA-Canada Annual heating demand 9.6 kWh/(m²a) Heating / cooling period 205 243 365 d/a

Region: British Columbia Heating load 9.6 W/m² Heating / cooling degree hours 68 75 -129 kKh/a

1-Alphabetic sorting Frequency of overheating 3.0 % Radiation North 113 175 358 kWh/(m²a)Climate data set: CA0003b-Vancouver Sensible cooling 5.8 kWh/(m²a) Radiation East 238 417 843 kWh/(m²a)

Climate zone: 4: Warm-temperate Latent cooling 0.0 kWh/(m²a) Radiation South 421 557 980 kWh/(m²a)Cooling load - W/m² Radiation West 251 313 661 kWh/(m²a)

Altitude PER demand 43.3 kWh/(m²a) Horizontal radiation 385 587 1259 kWh/(m²a)

Weather station: 39.0 mBuilding location: 18 m

Month 1 2 3 4 5 6 7 8 9 10 11 12 Heating load Cooling load PERDays 31 28 31 30 31 30 31 31 30 31 30 31 Weather 1 Weather 2 Weather 1 Weather 2 factors

CA0003b-Vancouver Latitude ° 49.3 Longitude ° -123.1 Altitude [m] 39 Daily temperature swing Summer [K] 7.8 Radiation: [W/m²] Radiation: [W/m²]

° C Exterior temperature 4.1 5.0 7.0 9.7 12.7 15.8 18.2 18.3 15.0 10.6 6.7 4.0 -2.2 0.6 19.6 19.6 1.20 Household electricitykWh/(m²month) Radiation North 9 14 24 36 48 54 51 38 27 19 11 7 13 8 62 62 1.15 Domestic hot waterkWh/(m²month) Radiation East 16 30 57 76 113 109 120 99 71 40 19 11 18 10 168 168 1.50 HeatingkWh/(m²month) Radiation South 41 67 97 94 107 97 105 113 106 78 47 33 39 18 150 150 1.00 CoolingkWh/(m²month) Radiation West 18 33 58 74 103 112 112 97 69 43 23 16 20 12 158 158 1.00 DehumidificationkWh/(m²month) Horizontal radiation 26 47 91 126 185 193 199 167 113 63 30 19 30 17 282 282

° C Dew point temperature 1.6 1.8 3.3 5.0 8.0 10.6 12.9 13.4 11.1 7.7 4.2 1.7 16.4 16.4° C Sky temperature -5.1 -5.7 -4.2 -1.9 0.6 3.9 6.1 7.3 4.7 1.4 -2.5 -5.2 13.7 16.4° C Ground temperature 12.6 12.2 12.1 13.7 14.4 15.3 16.0 16.4 16.4 14.8 14.1 13.3 12.1 12.1 16.4 16.4

Comment:

0

2

4

6

8

10

12

14

16

18

20

0

50

100

150

200

250

1 2 3 4 5 6 7 8 9 10 11 12

kWh/

(m²m

onth

) Radiation NorthRadiation East

Radiation South

Radiation West

Horizontal radiation

Exterior temperature

Dew point temperature

°C

PHPP, Climate PHPP_V9_current

-

U-value of building assemblies Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Secondary calculation: Equivalent thermal conductivity of still air spaces -> (on the right)Wedge-shaped assembly layer -> (on the right)

Unheated / uncooled attic -> (on the right)Assembly no. Building assembly description Interior insulation?

01ud Typical assembly-CONC-FLOORHeat transmission resistance [m²K/W]

Orientation of building element 3-Floor interior Rsi 0.17Adjacent to 2-Ground exterior Rse: 0.00

Area section 1 λ [W/(mK)] Area section 2 (optional) λ [W/(mK)] Area section 3 (optional) λ [W/(mK)] Thickness [mm]6 " Conc slab w/t 12" Conc thickenings 2.100 203

EPS GeoBoard 0.035 203

Percentage of sec. 1 Percentage of sec. 2 Percentage of sec. 3 Total

100% 40.6 cm

U-value supplement W/(m²K) U-value: 0.165 W/(m²K)

Assembly no. Interior insulation?

02ud Typical assembly-BGWALL below groundHeat transmission resistance [m²K/W]

Orientation of building element 2-Wall interior Rsi 0.13Adjacent to 2-Ground exterior Rse: 0.00

Area section 1 λ [W/(mK)] Area section 2 (optional) λ [W/(mK)] Area section 3 (optional) λ [W/(mK)] Thickness [mm]

4 " XPS 0.029 1028 " Conc 2.100 203

3.5" service cavity w/ Roxul mineral wool batt 0.035 2x4 studs 0.130 89


100% 39.4 cm

U-value supplement W/(m²K) U-value: 0.159 W/(m²K)


03ud Typical assembly-WALL above groundHeat transmission resistance [m²K/W]

Orientation of building element 2-Wall interior Rsi 0.13Adjacent to 1-Outdoor air exterior Rse: 0.04


.5 " Drywall board 0.250 13

Varia

nts

▼

PHPP, U-Values PHPP_V9_current

5.5" service cavity w/ Roxul mineral wool batt 0.035 2x6 studs 0.130 140

4" CLT 0.130 1056" Minerwool board 0.035 152


90% 10.0% 41.0 cm

U-value supplement 0.01 W/(m²K) U-value: 0.123 W/(m²K)


04ud Typical ROOF AssemblyHeat transmission resistance [m²K/W]

Orientation of building element 1-Roof interior Rsi 0.10Adjacent to 1-Outdoor air exterior Rse: 0.04


3" Roxul board 0.035 764" Polyiso 0.020 102EPS slope package 0.035 764" CLT 0.130 1052x4 down frame insulated 0.035 2x4 frame 0.130 89


90% 10.0% 44.8 cm

U-value supplement 0.01 W/(m²K) U-value: 0.088 W/(m²K)

Wärmeleitfähigkeit λWärmeleitfähigkeit λWärmeleitfähigkeit λWärmeleitfähigkeit λWärmeleitfähigkeit λ

PHPP, U-Values PHPP_V9_current

- Certified building systems ► Exception ►

Areas determination Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Summary Building assembly overview Average U-valueTemp.-zone Area group Group no. Area / Length Unit Comment [W/(m²K)]

Treated floor area 1 295.16 m² Treated floor area according to PHPP manual 8 Months 12 MonthsA North windows 2 29.76 m² North windows 0.695 641 1485A East windows 3 15.45 m² Results come from the 'Windows' worksheet. East windows 0.708 757 2027A South windows 4 70.15 m² Window areas are subtracted from individual opaque areas. South windows 0.645 8606 10405A West windows 5 4.06 m² which is displayed in the 'Windows' worksheet. West windows 0.731 165 438A Horizontal windows 6 0.00 m² Horizontal windows A Exterior door 7 0.00 m² Please subtract area of door from respective building assembly Exterior doorA External wall - Ambient 8 221.81 m² Temperature zone "A" is ambient air External wall - Ambient 0.123 69 167B External wall - Ground 9 150.52 m² Temperature zone "B" is the ground External wall - Ground 0.159A Roof/Ceiling - Ambient 10 157.81 m² Roof/Ceiling - Ambient 0.110 156 459B Floor slab / Basement ceiling 11 157.81 m² Floor slab / Basement ceiling 0.174

12 0.00 m² Temperature zones "A", "B","P" and "X" may be used. NOT "I"13 0.00 m² Temperature zones "A", "B","P" and "X" may be used. NOT "I" Factor for X

X 14 0.00 m² Temperature zone "X": Please provide user-defined reduction factor ( 0 < ft < 1):Thermal bridges - Overview Ψ [W/(mK)]

A Thermal bridges Ambient 15 53.10 m Units in m Thermal bridges Ambient 0.157P Perimeter thermal bridges 16 0.00 m Units in m; temperature zone "P" is perimeter (see 'Ground' worksheet) Perimeter thermal bridges B Thermal bridges FS/BC 17 0.00 m Units in m Thermal bridges FS/BCI Building element towards neighbour 18 0.00 m² No heat losses, only considered for the heating load calculation Building element towards neighbour

Total thermal envelope 807.36 m² Average therm. envelope 0.228

Go to building components list

Area input 2-Sorting: BY ID

Area no. Building assembly description Togroup No. Assigned to groupQuan-

tity x (a

[m] xb

[m] +User deter-mined [m²] -

User sub-traction

[m²]-

Subtraction window areas

[m²]) = Area[m²]

Selection building assembly /Building system

U-Value[W/(m²K)]

Deviation from North

Angle of inclination from the horizontal

Orientation Reduction factor shadingExterior

absorptivityExterior

emissivity

Projected building footprint 0 Projected building footprint 1 x ( x + 157.81 - ) = 157.8Treated floor area 1 Treated floor area 1 x ( x + 295.16 - ) = 295.2Exterior door 7 Exterior door x ( x + - ) - = Exterior door

1 ASSEMBLY-WALL4A 8 External wall - Ambient 1 x ( x + 42.04 - ) - 15.4 = 26.6 03ud-Typical assembly-WALL above ground 0.123 106 90 East 1.00 0.80 0.90

2 ASSEMBLY-WALL5A 8 External wall - Ambient 1 x ( x + 37.78 - ) - 47.8 = -10.0 03ud-Typical assembly-WALL above ground 0.123 196 90 South 0.70 0.40 0.90

3 ASSEMBLY-WALL3A 8 External wall - Ambient 1 x ( x + 22.67 - ) - 0.0 = 22.7 03ud-Typical assembly-WALL above ground 0.123 16 90 North 0.70 0.40 0.90

4 ASSEMBLY-WALL2A 8 External wall - Ambient 1 x ( x + 9.74 - ) - 0.0 = 9.7 03ud-Typical assembly-WALL above ground 0.123 106 90 East 0.70 0.40 0.90

5 ASSEMBLY-WALL2C 8 External wall - Ambient 1 x ( x + 30.89 - ) - 8.6 = 22.3 03ud-Typical assembly-WALL above ground 0.123 16 90 North 0.70 0.40 0.90

6 ASSEMBLY-WALL1A 8 External wall - Ambient 1 x ( x + 11.35 - ) - 18.2 = -6.8 03ud-Typical assembly-WALL above ground 0.123 16 90 North 0.70 0.40 0.90

7 ASSEMBLY-WALL8C 8 External wall - Ambient 1 x ( x + 15.33 - ) - 4.1 = 11.3 03ud-Typical assembly-WALL above ground 0.123 286 90 West 0.70 0.40 0.90

8 ASSEMBLY-BGWALL5B 9 External wall - Ground 1 x ( x + 12.60 - ) - 22.4 = -9.8 02ud-Typical assembly-BGWALL below ground 0.159 196 90 South 0.70 0.40 0.90

9 ASSEMBLY-BGWALL6B 9 External wall - Ground 1 x ( x + 6.85 - ) - 0.0 = 6.9 02ud-Typical assembly-BGWALL below ground 0.159 106 90 East 0.70 0.40 0.90


11 ASSEMBLY-BGWALL1B 9 External wall - Ground 1 x ( x + 10.42 - ) - 3.0 = 7.4 02ud-Typical assembly-BGWALL below ground 0.159 16 90 North 0.70 0.40 0.90

12 ASSEMBLY-CONC-FLOOR1A 11 Floor slab / Basement ceiling 1 x ( x + 81.83 - ) - 0.0 = 81.8 07ud-Typical Assembly-Concrete-FLOOR-XPS 0.179 0 180 Hor 0.70 0.40 0.90

13 ASSEMBLY-BGWALL3B 9 External wall - Ground 1 x ( x + 24.26 - ) - 0.0 = 24.3 02ud-Typical assembly-BGWALL below ground 0.159 16 90 North 0.70 0.40 0.90


15 ASSEMBLY-BGWALL7B 9 External wall - Ground 1 x ( x + 21.50 - ) - 0.0 = 21.5 02ud-Typical assembly-BGWALL below ground 0.159 90 0.00 0.00 0.00

16 ASSEMBLY-BGWALL8B 9 External wall - Ground 1 x ( x + 6.86 - ) - 0.0 = 6.9 02ud-Typical assembly-BGWALL below ground 0.159 286 90 West 1.00 0.80 0.90

17 ASSEMBLY-WALL4C 8 External wall - Ambient 1 x ( x + 11.41 - ) - 0.0 = 11.4 03ud-Typical assembly-WALL above ground 0.123 106 90 East 0.00 0.00 0.00

18 ASSEMBLY-WALL3C 8 External wall - Ambient 1 x ( x + 25.28 - ) - 0.0 = 25.3 03ud-Typical assembly-WALL above ground 0.123 106 90 East 0.70 0.40 0.90

19 ASSEMBLY-TJI-FLOOR1A 11 Floor slab / Basement ceiling 1 x ( x + 23.47 - ) - 0.0 = 23.5 06ud-Typical Assembly-CLT-FLOOR 0.168 0 180 Hor 0.00 0.00 0.00

20 ASSEMBLY-WALL1C 8 External wall - Ambient 1 x ( x + 4.55 - ) - 0.0 = 4.6 03ud-Typical assembly-WALL above ground 0.123 16 90 North 0.70 0.40 0.90

Radiation-gains heating

season [kWh/a]

Radiation-load cooling period

[kWh/a]

PHPP, Areas PHPP_V9_current


Areas determination Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)


Treated floor area 1 295.16 m² Treated floor area according to PHPP manual 8 Months 12 MonthsA North windows 2 29.76 m² North windows 0.695 641 1485A East windows 3 15.45 m² Results come from the 'Windows' worksheet. East windows 0.708 757 2027A South windows 4 70.15 m² Window areas are subtracted from individual opaque areas. South windows 0.645 8606 10405A West windows 5 4.06 m² which is displayed in the 'Windows' worksheet. West windows 0.731 165 438A Horizontal windows 6 0.00 m² Horizontal windows A Exterior door 7 0.00 m² Please subtract area of door from respective building assembly Exterior doorA External wall - Ambient 8 221.81 m² Temperature zone "A" is ambient air External wall - Ambient 0.123 69 167B External wall - Ground 9 150.52 m² Temperature zone "B" is the ground External wall - Ground 0.159A Roof/Ceiling - Ambient 10 157.81 m² Roof/Ceiling - Ambient 0.110 156 459B Floor slab / Basement ceiling 11 157.81 m² Floor slab / Basement ceiling 0.174







season [kWh/a]

Radiation-load cooling period

[kWh/a]

21 ASSEMBLY-CONC-FLOOR1B 11 Floor slab / Basement ceiling 1 x ( x + 43.77 - ) - 0.0 = 43.8 01ud-Typical assembly-CONC-FLOOR 0.165 0 180 Hor 0.00 0.00 0.00

22 ASSEMBLY-ROOF FLAT 2B 10 Roof/Ceiling - Ambient 1 x ( x + 3.94 - ) - 0.0 = 3.9 05ud-Typical Assembly-ROOF FLAT 0.110 0 0 Hor 0.70 0.80 0.90

23 ASSEMBLY-ROOF FLAT 1A 10 Roof/Ceiling - Ambient 1 x ( x + 111.90 - ) - 0.0 = 111.9 05ud-Typical Assembly-ROOF FLAT 0.110 0 0 Hor 1.00 0.80 0.90


25 ASSEMBLY-WALL7C 8 External wall - Ambient 1 x ( x + 19.75 - ) - 0.0 = 19.7 03ud-Typical assembly-WALL above ground 0.123 286 90 West 0.00 0.00 0.00

26 ASSEMBLY-WALL10A 8 External wall - Ambient 1 x ( x + 53.39 - ) - 0.0 = 53.4 03ud-Typical assembly-WALL above ground 0.123 286 90 West 0.00 0.00 0.00

27 ASSEMBLY-BGWALL10B 9 External wall - Ground 1 x ( x + 44.79 - ) - 0.0 = 44.8 02ud-Typical assembly-BGWALL below ground 0.159 286 90 West 0.70 0.80 0.90

28 ASSEMBLY-TJI-FLOOR2A 11 Floor slab / Basement ceiling 1 x ( x + 2.03 - ) - 0.0 = 2.0 08ud-Typical Assembly-Concrete-FLOOR-Aerogel 0.260 0 180 Hor 0.70 0.80 0.90

29 ASSEMBLY-TJI-FLOOR3A 11 Floor slab / Basement ceiling 1 x ( x + 6.71 - ) - 0.0 = 6.7 07ud-Typical Assembly-Concrete-FLOOR-XPS 0.179 0 180 Hor 0.70 0.80 0.90

30 ASSEMBLY-BGWALL9B 9 External wall - Ground 1 x ( x + 3.80 - ) - 0.0 = 3.8 02ud-Typical assembly-BGWALL below ground 0.159 196 90 South 0.70 0.80 0.90

31 ASSEMBLY-WALL5C 8 External wall - Ambient 1 x ( x + 3.10 - ) - 0.0 = 3.1 03ud-Typical assembly-WALL above ground 0.123 196 90 South 0.70 0.80 0.90

32 ASSEMBLY-WALL6C 8 External wall - Ambient 1 x ( x + 28.58 - ) - 0.0 = 28.6 03ud-Typical assembly-WALL above ground 0.123 196 90 South 0.70 0.80 0.90


34 x ( x + - ) - 0.0 =35 x ( x + - ) - 0.0 =36 x ( x + - ) - 0.0 =37 x ( x + - ) - 0.0 =38 x ( x + - ) - 0.0 =39 x ( x + - ) - 0.0 =40 x ( x + - ) - 0.0 =41 x ( x + - ) - 0.0 =42 x ( x + - ) - 0.0 =43 x ( x + - ) - 0.0 =44 x ( x + - ) - 0.0 =45 x ( x + - ) - 0.0 =46 x ( x + - ) - 0.0 =47 x ( x + - ) - 0.0 =48 x ( x + - ) - 0.0 =49 x ( x + - ) - 0.0 =50 x ( x + - ) - 0.0 =

Aend



Areas determinationDean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)


Treated floor area 1 295.16 m² Treated floor area according to PHPP manual 8 MonthsA North windows 2 29.76 m² North windows 0.695 641A East windows 3 15.45 m² Results come from the 'Windows' worksheet. East windows 0.708 757A South windows 4 70.15 m² Window areas are subtracted from individual opaque areas. South windows 0.645 8606A West windows 5 4.06 m² which is displayed in the 'Windows' worksheet. West windows 0.731 165A Horizontal windows 6 0.00 m² Horizontal windows A Exterior door 7 0.00 m² Please subtract area of door from respective building assembly Exterior doorA External wall - Ambient 8 221.81 m² Temperature zone "A" is ambient air External wall - Ambient 0.123 69B External wall - Ground 9 150.52 m² Temperature zone "B" is the ground External wall - Ground 0.159A Roof/Ceiling - Ambient 10 157.81 m² Roof/Ceiling - Ambient 0.110 156B Floor slab / Basement ceiling 11 157.81 m² Floor slab / Basement ceiling 0.174







season [kWh/a]

Thermal bridge inputs

No. Thermal bridge -denominationGroup

No. Assigned to groupQuan

tity x (Length

[m] -Subtraction

length[m]

)= Length l[m]

User determinedΨ-Wert

[W/(mK)]

User determinedfRsi=0,25

(optional)or Selection building system Ψ-Value[W/(mK)]

fRsi-Requirement met?

1 Schoeck Isokorb, concrete balcony 15 Thermal bridges Ambient 1 x ( 10.60 - ) = 10.60 0.040 0.940 or 0.040 ██2 CLT overhang 15 Thermal bridges Ambient 1 x ( 40.00 - ) = 40.00 0.180 or 0.1803 Fireplace chimney 15 Thermal bridges Ambient 1 x ( 2.50 - ) = 2.50 0.290 or 0.2904 x ( - ) = or5 x ( - ) = or6 x ( - ) = or7 x ( - ) = or8 x ( - ) = or9 x ( - ) = or10 x ( - ) = or11 x ( - ) = or12 x ( - ) = or13 x ( - ) = or14 x ( - ) = or15 x ( - ) = or16 x ( - ) = or17 x ( - ) = or18 x ( - ) = or19 x ( - ) = or20 x ( - ) = or21 x ( - ) = or22 x ( - ) = or23 x ( - ) = or24 x ( - ) = or25 x ( - ) = or26 x ( - ) = or27 x ( - ) = or28 x ( - ) = or29 x ( - ) = or30 x ( - ) = or31 x ( - ) = or32 x ( - ) = or33 x ( - ) = or34 x ( - ) = or35 x ( - ) = or36 x ( - ) = or37 x ( - ) = or


-

Heat losses through the ground Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Building section 1

Ground characteristics Climate data Thermal conductivity λ 2.0 W/(mK) Avg indoor temp. winter Ti 20.0 °CHeat capacity ρc 2.0 MJ/(m³K) Avg indoor temp. summer Ti 25.0 °CPeriodic penetration depth δ 3.17 m Avg ground surface temperature Tg,ave 11.6 °C

Amplitude of Tg,ave Tg,^ 7.2 °CPhase shifting of Te,m τ 1.2 MonthsLength of the heating period n 6.7 MonthsHeating degree hours - exterior Gt 67.7 kKh/a

Building data U-value floor slab/basement ceiling Uf 0.165 W/(m²K)Area of ground floor slab / basement ceilinA 157.8 m² TBs floor slab / basement ceiling ΨB*l 0.70 W/KPerimeter length P 32.9 m U-value floor slab / basement ceiling in Uf' 0.169 W/(m²K)Charact. dimension of floor slab B' 9.59 m Equivalent thickness floor dt 11.82 m

Floor slab type (select only one)

Slab on gradePerimeter insulation width/depth D m Orientation of perimeter insulation horizontalPerimeter insulation thickness dn m (check only one field) vertical xConductivity perimeter insulation λn W/(mK)

x Heated basement or floor slab completely / partially below ground levelBasement wall height below ground level z 2.00 m U-Value wall below ground UwB 0.159 W/(m²K)

Unheated basementHeight aboveground wall h m U-Value wall above ground UW W/(m²K)Basement wall height below ground level z m U-Value wall below ground UWB W/(m²K)Air change unheated basement n 0.20 h-1 U-Value basement floor slab UfB W/(m²K)Air flow basement V m³

Suspended floor above a ventilated crawl space (at max. 0.5 m below ground)U-Value crawl space UCrawl W/(m²K) Area of ventilation openings εP m²Height of crawl space wall h m Wind velocity at 10 m height v 4.0 m/sU-Value crawl space wall UW W/(m²K) Wind shield factor fW 0.05 -

Additional thermal bridge heat losses at perimeter Steady-state fraction ΨP,stat*l 0.000 W/KPhase shift β Months Harmonic fraction ΨP,harm*l 0.000 W/K

Groundwater correctionDepth of the groundwater table zW 3.0 m Groundwater correction factor GW 1.03349676 -Groundwater flow rate qW 0.05 m/d

Interim resultsPhase shift β 1.40 Months Steady-state heat flow Φstat 235.7 W

Steady-state transmittance LS 28.11 W/K Periodic heat flow Φharm 24.3 WExterior periodic transmittance Lpe 8.21 W/K Heat losses during heating period Qtot 1279 kWhTransmittance building L0 37.21 W/K

Monthly average temperatures in the ground for monthly method (building assembly 1)Month 1 2 3 4 5 6 7 8 9 10 11 12 Avg. valueWinter 12.6 12.2 12.1 12.5 13.2 14.0 14.8 15.2 15.2 14.8 14.1 13.3 13.7Summer 13.8 13.4 13.4 13.7 14.4 15.3 16.0 16.4 16.4 16.0 15.3 14.5 14.9

Design ground temperature for 'Heating load' worksheet 12.1 For 'Cooling load' worksheet 16.4

Reduction factor for 'Annual heating' worksheet 0.51

Total result (all building parts)Phase shift β 1.40 Months Steady-state heat flow Φstat 235.7 W

Steady-state transmittance LS 28.11 W/K Periodic heat flow Φharm 24.3 WExterior periodic transmittance Lpe 8.21 W/K Heat losses during heating period Qtot 1279 kWhTransmittance building L0 37.21 W/K Charact. dimension of floor slab B' 9.59 m

Monthly Average temperatures in the ground for monthly method (all building assemblies)Month 1 2 3 4 5 6 7 8 9 10 11 12 Avg. valueWinter 12.6 12.2 12.1 12.5 13.2 14.0 14.8 15.2 15.2 14.8 14.1 13.3 13.7Summer 13.8 13.4 13.4 13.7 14.4 15.3 16.0 16.4 16.4 16.0 15.3 14.5 14.9

Design ground temperature for 'Heating load' worksheet 12.1 For 'Cooling load' worksheet 16.4

Reduction factor for 'Annual heating' worksheet 0.51

PHPP, Ground PHPP_V9_current

- Certified building systems ►

Passive House Components Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Go to: 'AREAS' www.passivehouse.com/component-databaseThermal bridges (Psi-values) Ventilation unitsGlazing Compact unitsWindow frame Heat recovery DHW

Building assemblies (U-Values)Recommended starting values for optimisation: U-values for walls and roofs | Floor slabs: 0.3 W/(m²K) | 0.37 W/(m²K)

1

ID Building system Building assembly Totalthickness U-ValueInterior

insulation

Summary of the constructions calculated in 'U values' worksheet m W/(m²K) -

01ud Typical assembly-CONC-FLOOR Typical assembly-CONC-FLOOR 0.406 0.165 002ud Typical assembly-BGWALL below ground Typical assembly-BGWALL below ground 0.394 0.159 003ud Typical assembly-WALL above ground Typical assembly-WALL above ground 0.410 0.123 004ud Typical ROOF Assembly Typical ROOF Assembly 0.448 0.088 005ud Typical Assembly-ROOF FLAT Typical Assembly-ROOF FLAT 0.489 0.110 006ud Typical Assembly-CLT-FLOOR Typical Assembly-CLT-FLOOR 0.340 0.168 007ud Typical Assembly-Concrete-FLOOR-XPS Typical Assembly-Concrete-FLOOR-XPS 0.457 0.179 008ud Typical Assembly-Concrete-FLOOR-Aerogel Typical Assembly-Concrete-FLOOR-Aerogel 0.453 0.260 009ud10ud

PHPP, Components PHPP_V9_current

http://www.passiv.de/komponentendatenbank

Glazing GlazingRecommended glazing type to start planning:

Triple thermally insulated glazing (Please consider the comfort criterion!)

ID Description g-Value Ug-Value

W/(m²K)

01ud PH Glazing 0.69 0.6302ud SG31 0.55 0.5003ud SG41 0.46 0.5004ud SG51 0.33 0.5005ud Saint Gobin Calumen III 1.1 0.47 0.7006ud07ud08ud09ud10ud


Window frame Window frame

Uf-Value Frame width Glazing edge thermal bridge Installation thermal bridgeCurtain wall

facades:

ID Description left right bottom above left right bottom above ΨGlazing edgeleft

ΨGlazing edgeright

ΨGlazing edgebottom

ΨGlazing edgetop

ΨInstallationleft

ΨInstallationright

ΨInstallationbottom

ΨInstallationtop

χGC -valueGlass carrier

W/(m²K) W/(m²K) W/(m²K) W/(m²K) m m m m W/(mK) W/(mK) W/(mK) W/(mK) W/(mK) W/(mK) W/(mK) W/(mK) W/K

01ud Schüco - AWS 90.SI+ - SWISSP. Ultimate 0.80 0.80 0.80 0.80 0.188 0.188 0.188 0.188 0.024 0.024 0.024 0.024 0.040 0.040 0.040 0.04002ud RAICO - FRAME+ 90 WI - SWISSP. Ultimate 0.79 0.79 0.79 0.79 0.173 0.173 0.173 0.173 0.027 0.027 0.027 0.027 0.040 0.040 0.040 0.04003ud Skyframe 3 series04ud skyframe 3 series05ud06ud07ud08ud09ud10ud


Ventilation units with heat recovery Ventilation units with heat recovery

Additional Device Data

ID DescriptionEffective heat

recovery efficiency

Energy recovery value ηER

Electric efficiency Application range

External pressure

per section

Fittings Dpintern

Frost protection necessary

Noise protection Additional info

User defined area % % Wh/m³ m³/h m³/h Pa Pa 35 dB(A) Supply air dB(A)Extract air

dB(A)01ud Zehnder - ComfoAir550, ComfoD550, WHR960 84% 0% 0.31 110 308 100 incl. yes / 48 48 without additional a 02ud PAUL - novus 300 93% 0% 0.24 121 231 100 incl. yes / 65 4603ud04ud05ud06ud07ud08ud09ud10ud

Recommended specifications to start planning: Frost protection: Yes; Humidity recovery: Yes 75 % 0.45


- EnerPHit exemptions ► Detailed window characteristic values ►

Windows Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Window area orientationGlobal

radiation (main orientations)

Shading DirtNon-vertical

radiation incidence

Glazing fraction g-Value

Solar irradiationreduction factor Window area

WindowU-Value

Glazingarea

Average global

radiation

Transmission losses heating

period

Heating gains solar radiation heating period

Standard values → kWh/(m²a) 0.75 0.95 0.85 m2 W/(m2K) m2 kWh/(m2a) kWh/a kWh/aNorth 113 0.49 0.95 0.85 0.68 0.46 0.27 29.76 0.69 20.13 116 North 1400 425East 238 0.47 0.95 0.85 0.68 0.46 0.26 15.45 0.71 10.48 283 East 741 513South 421 0.76 0.95 0.85 0.78 0.46 0.48 70.15 0.64 54.45 415 South 3062 6410West 251 0.54 0.95 0.85 0.64 0.46 0.28 4.06 0.73 2.61 210 West 201 110Horizontal 385 1.00 0.95 0.85 0.00 0.00 0.00 0.00 0.00 0.00 385 Horizontal 0 0Total or average value for all windows. 0.46 0.39 119.41 0.67 87.68 5403 7458

Go to glazing list Go to window frames listHeating degree hours [kKh/a 67.7

Window rough openings Installed in Glazing Frame g-Value U-Value Ψ

Glazing edge

Installation situation user determined value for Ψinstallation or

'1': Ψinstallation from 'Components' worksheet'0': in the case of abutting windows

Results

Quan-tity

Description Deviation from north


Orien- tation Width Height Selection from 'Areas' worksheetSelection from 'Components'

worksheetSelection from 'Components'

worksheet

Perpen-dicular

radiationGlazing Frames (avg.)

ΨGlazing edge (Avg.)

left right bottom top ΨInstallation (Avg.)

Window Area

Glazing area

Uwinstalled

Glazed fraction per

window

° ° m m 1-Sorting: LIKE LIST 1-Sorting: LIKE LIST - W/(m2K) W/(m2K) W/(mK) W/(mK) or 1/0 W/(mK) m2 m2 W/(m2K) %

1 WIN1 106 90 East 3.791 2.566 1-ASSEMBLY-WALL4A 03ud-SG41 0734wi03-Schüco - AWS 90.SI+ - SWISSP. Ultimate 0.46 0.50 0.80 0.024 1 1 1 1 0.040 9.7 7.48 0.65 77%

1 WIN6 196 90 South 3.391 3.235 2-ASSEMBLY-WALL5A 03ud-SG41 0734wi03-Schüco - AWS 90.SI+ - SWISSP. Ultimate 0.46 0.50 0.80 0.024 1 1 1 1 0.040 11.0 8.62 0.64 79%

1 WIN9 196 90 South 4.883 2.616 8-ASSEMBLY-BGWALL5B 03ud-SG41 0734wi03-Schüco - AWS 90.SI+ - SWISSP. Ultimate 0.46 0.50 0.80 0.024 1 1 1 1 0.040 12.8 10.10 0.64 79%







1 WIN11 286 90 West 1.492 2.718 7-ASSEMBLY-WALL8C 03ud-SG41 0734wi03-Schüco - AWS 90.SI+ - SWISSP. Ultimate 0.46 0.50 0.80 0.024 1 1 1 1 0.040 4.1 2.61 0.73 64%


1 WIN17 16 90 North 3.175 0.940 11-ASSEMBLY-BGWALL1B 03ud-SG41 0734wi03-Schüco - AWS 90.SI+ - SWISSP. Ultimate 0.46 0.50 0.80 0.024 1 1 1 1 0.040 3.0 1.58 0.81 53%

1 WIN16 16 90 North 0.921 3.035 6-ASSEMBLY-WALL1A 03ud-SG41 0734wi03-Schüco - AWS 90.SI+ - SWISSP. Ultimate 0.46 0.50 0.80 0.024 1 0 1 1 0.040 2.8 1.45 0.77 52%



1 WIN13 16 90 North 1.657 2.718 5-ASSEMBLY-WALL2C 03ud-SG41 0734wi03-Schüco - AWS 90.SI+ - SWISSP. Ultimate 0.46 0.50 0.80 0.024 1 0 1 1 0.040 4.5 3.00 0.69 67%

1 WIN12 16 90 North 1.499 2.718 5-ASSEMBLY-WALL2C 03ud-SG41 0734wi03-Schüco - AWS 90.SI+ - SWISSP. Ultimate 0.46 0.50 0.80 0.024 1 1 1 1 0.040 4.1 2.63 0.73 65%

1 1 1 11 1 1 11 1 1 11 0 1 10 1 1 11 1 1 11 1 1 11 1 1 11 1 1 11 1 1 11 1 1 11 1 1 11 1 1 11 1 1 11 1 1 11 1 1 11 1 1 11 1 1 11 1 1 1

0

2,000

4,000

6,000

8,000

North East South West HorizontalkWh/a

Transmission losses heating period

Heating gains solar radiation heating period

X6A0TX6A1T

PHPP, Windows PHPP_V9_current

-

Calculation of shading coefficients Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Orientation Glazing Reduction factor Reduction factor Reduction factor Solar loadLatitude: 49.281 ° area [m²] winter rv cooling rv,1 cooling load rv,2 [kWh/(m²Glazinga)]

North 20.13 49% 52% 52% 74East 10.48 47% 58% 58% 193

South 54.45 76% 50% 50% 191West 2.61 54% 64% 64% 168

Horizontal 0.00 100% 100% 100% 0

Horizon Lateral reveal Reveal / Overhang Reduction factors for shading in winter Reduction factors for shading in summer

Quan-tity Description

Deviation from North


Orientation Glazing width Glazing height Glazing area Height of the shading object Horizontal distanceWindow reveal

depthDistance from glazing

edge to reveal Overhang depthDistance from

upper glazing edge to overhang

Additional reduction factor winter

shading

Additional reduction factor summer

shading

Reduction factor z for temporary sun

protection

Reg

ulat

ed /

trans

pare

nt

Horizon Reveal Overhang Total for heating case Horizon Reveal OverhangTotal for

cooling caseTotal for

cooling load

[Degree] [Degree] wG [m] hG [m] AG [m2] hHori [m] dHori [m] oReveal [m] dReveal [m] oover [m] dover [m] rother,w [%] rother,s [%] z [%] rH [%] rR [%] rO [%] rS [%] rH [%] rR [%] rO [%] rS,1 [%] rS,2 [%]1 WIN1 106 90 East 3.41 2.19 7.5 2.70 3.80 0.15 0.130 0.00 0.00 100% 100% 100% 53% 97% 100% 52% 64% 99% 100% 63% 63%1 WIN6 196 90 South 3.01 2.86 8.6 0.00 0.00 0.15 0.130 1.60 0.47 100% 100% 100% 100% 98% 88% 86% 100% 97% 61% 59% 59%1 WIN9 196 90 South 4.51 2.24 10.1 1.90 6.80 0.15 0.130 4.47 0.07 100% 100% 100% 86% 99% 58% 49% 90% 98% 20% 17% 17%1 WIN10 196 90 South 2.68 2.24 6.0 1.50 45.70 0.15 0.130 4.47 0.07 100% 100% 100% 100% 98% 58% 56% 99% 97% 20% 19% 19%1 WIN8 196 90 South 0.23 2.24 0.5 1.90 6.80 0.15 0.130 4.47 0.07 100% 100% 100% 86% 87% 58% 43% 90% 84% 20% 15% 15%1 WIN7 196 90 South 4.75 2.87 13.7 0.00 0.00 0.15 0.130 1.60 0.47 100% 100% 100% 100% 99% 88% 87% 100% 98% 61% 60% 60%1 WIN4 196 90 South 3.25 2.19 7.1 0.00 0.00 0.15 0.130 1.21 0.71 100% 100% 100% 100% 98% 90% 89% 100% 98% 71% 69% 69%1 WIN2 106 90 East 0.56 2.35 1.3 2.70 3.80 0.15 0.130 0.00 0.00 100% 100% 100% 53% 86% 100% 46% 64% 94% 100% 60% 60%1 WIN3 106 90 East 0.56 2.98 1.7 6.30 3.80 0.15 0.130 0.00 0.00 100% 100% 100% 29% 86% 100% 25% 40% 94% 100% 37% 37%1 WIN11 286 90 West 1.12 2.34 2.6 3.00 5.00 0.15 0.130 0.00 0.00 100% 100% 100% 59% 91% 100% 54% 67% 96% 100% 64% 64%1 WIN5 196 90 South 3.85 2.19 8.4 0.00 0.00 0.15 0.130 1.21 0.71 100% 100% 100% 100% 98% 90% 89% 100% 98% 71% 69% 69%1 WIN17 16 90 North 2.80 0.56 1.6 7.60 15.00 0.15 0.130 3.25 3.63 100% 100% 100% 68% 97% 79% 52% 70% 97% 84% 57% 57%1 WIN16 16 90 North 0.54 2.66 1.4 6.10 15.00 0.15 0.130 3.25 0.07 100% 100% 100% 72% 89% 56% 36% 75% 91% 57% 38% 38%1 WIN15 16 90 North 2.40 2.66 6.4 6.10 15.00 0.15 0.130 3.25 0.07 100% 100% 100% 72% 97% 56% 39% 75% 97% 57% 41% 41%1 WIN14 16 90 North 2.80 1.82 5.1 6.10 15.00 0.15 0.130 3.25 0.07 100% 100% 100% 72% 97% 47% 33% 75% 97% 49% 36% 36%1 WIN13 16 90 North 1.28 2.34 3.0 2.70 17.70 0.15 0.130 0.30 0.25 100% 100% 100% 88% 94% 94% 78% 89% 95% 98% 83% 83%1 WIN12 16 90 North 1.12 2.34 2.6 2.70 17.70 0.15 0.130 0.30 0.25 100% 100% 100% 88% 94% 94% 77% 89% 94% 98% 82% 82%

PHPP, Shading PHPP_V9_current

-

Ventilation data Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Treated floor area ATFA m² 295 ('Areas' worksheet)Room height h m 2.50 2.50Volume of ventilated space (ATFA*h) VV m³ 738 (Worksheet 'Annual heating')

Ventilation typePlease select

Infiltration air change rate

Wind protection coefficients e and f Several One

Coefficient e for wind protection class side sideexposed exposed

No protection 0.10 0.03Moderate protection 0.07 0.02High protection 0.04 0.01Coefficient f 15 20

For annual demand: For heating load:

Wind protection coefficient, e 0.07 0.18

Wind protection coefficient, f 15 15 Net air volume for press. test Vn50 Air permeability q50

Air change rate at press. test n50 1/h 0.43 0.43 738 m³ 0.39 m³/(hm²)

For annual demand: For heating load:

Excess extract air 1/h 0.00 0.00Infiltration air change rate nV,Rest 1/h 0.030 0.075

Selection of ventilation input - ResultsPHPP offers two methods for dimensioning air quantities and choosing the ventilation unit. With "Standard data input for balanced ventilation", supply or extract air quantities for residential buildings and parameters for ventilation systems with a maximum of 1 ventilation unit can be planned. Projects with up to 10 different ventilation units and air quantitiesdetermined according to rooms or zones can be entered in the 'Addl vent' worksheet. Please select your design method here:

Average Extract air Effective heat Specific HeatVentilation unit / Heat recovery efficiency design air flow Average excess recovery power recovery

x Standard design ('Ventilation' worksheet, see below) rate air change rate (extract air system) efficiency unit Energy recovery input efficiency SHXMultiple ventilation units, non-res ('Addl vent' worksheet) m³/h 1/h 1/h [-] [-] Wh/m³ [-]

221 0.30 0.00 82.6% 0.0% 0.31 0.0%Cooling degree Efficiency SHX

η∗SHX 0%

Average interior humidity during winter operationJan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec37% 37% 41% 45% 53% - - - - 53% 43% 37%

1-Balanced PH ventilation with HR

PHPP, Ventilation PHPP_V9_current

Standard data input for balanced ventilationPassive House with PHPP Version 9.3

Dimensioning of ventilation system with only one ventilation unit

Occupancy m²/P 92Number of occupants P 3.2Supply air per person m³/(P*h) 30Supply air requirement m³/h 96 BathroomExtract air rooms Kitchen Bathroom (shower only) WC LaundaryQuantity 1 2 0 0 1Extract air requirement per room m³/h 60 40 20 20 10Total extract air requirement m³/h 150

Design air flow rate (maximum) m³/h 288 Recommended: 288 m³/h

Average air change rate calculationFactors referenced to

Type of operation Daily operation times maximum Air flow rate Air change rateh/d m³/h 1/h

maximum 1.00 288 0.39Standard 24.0 0.77 221 0.30Basic ventilation 0.54 155 0.21Minimum 0.40 115 0.16

Average air flow rate (m³/h) Average air change rate (1/h)Average value 0.77 221 0.30

Selection of ventilation unit with heat recovery

Location of ventilation unit

Heat recovery Energy recovery Specific Application FrostGo to ventilation units list efficiency efficiency power input1-Sorting: LIKE LIST Unit ηWRG ηERV [Wh/m³] [m³/h]

Ventilation unit selection 0.84 0.00 0.31 110 - 308 yes

Implementation of frost protection 2-Elec.Conductivity outdoor air duct Y W/(mK) 0.334 Limit temperature [°C] -3Length of outdoor air duct m 2.4 Useful energy [kWh/a] 22Conductivity exhaust air duct Y W/(mK) 0.187Length of exhaust air duct m 2.4 Room temperature (°C) 20Temperature of mechanical services room °C Avg. ambient temp. heat. period (°C) 7.0(Enter only if the central unit is outside of the thermal envelope) Avg. ground temp (°C) 11.6

Effective heat recovery efficiency ηHR,eff 82.6%

Effective heat recovery efficiency subsoil heat exchangerSHX efficiency η∗SHXHeat recovery efficiency SHX ηSHX 0%

Secondary calculation Secondary calculation Ψ-value supply or outdoor air duct Ψ-value extract or exhaust air duct

Nominal width 125 mm Nominal width: 125 mmInsulation thick 50 mm Insulation thickness 150 mm

Reflective coating? x Yes Reflective coating? x yesNo no

Thermal conductivity 0.040 W/(mK) Thermal conductivity 0.040 W/(mK)Nominal air flow rate 221 m³/h Nominal air flow rate 221 m³/h

∆ϑ 13 K ∆ϑ 13 KExterior duct diameter 0.125 m Exterior duct diameter 0.125 m

Exterior diameter 0.225 m Exterior diameter 0.425 mα−Interior 21.20 W/(m²K) α−Interior 21.20 W/(m²K)α-Surface 2.63 W/(m²K) α-Surface 2.04 W/(m²K)

Ψ−value 0.334 W/(mK) Ψ−value 0.187 W/(mK)Surface temperature difference 2.328 K Surface temperature difference 0.889 K

01ud-Zehnder - ComfoAir550, ComfoD550, WHR960

1-Inside thermal envelope

PHPP, Ventilation PHPP_V9_current

Specific energy for heating (annual method) Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Interior temperature: 20.0 °CBuilding type: Single Family Residence

Treated floor area ATFA: 295.2 m²Per m²

Area U-Value Temp. factor ft Gt of treatedBuilding assembly Temperature zone m² W/(m²K) kKh/a kWh/a floor areaExternal wall - Ambient A 221.8 * 0.123 * 1.00 * 67.7 = 1855 6.28External wall - Ground B 150.5 * 0.159 * 0.51 * 67.7 = 824 2.79Roof/Ceiling - Ambient A 157.8 * 0.110 * 1.00 * 67.7 = 1171 3.97Floor slab / Basement ceiling B 157.8 * 0.174 * 0.51 * 67.7 = 945 3.20

A * * 1.00 * =A * * 1.00 * =X * * 0.00 * =

Windows A 119.4 * 0.668 * 1.00 * 67.7 = 5403 18.31Exterior door A * * 1.00 * =Exterior TB (length/m) A 53.1 * 0.157 * 1.00 * 67.7 = 565 1.92Perimeter TB (length/m) P * * 0.51 * = 0.00Ground TB (length/m) B * * 0.51 * = 0.00

Total of all building envelope areas 807.4 ––––––––––– kWh/(m²a)

Transmission heat losses QT Total 10764 36.5

ATFA Clear room heightm² m m³

Ventilation system: Effective air volume, VV 295.2 * 2.50 = 737.9Effective heat recovery efficiency ηeff 83%Efficiency of subsoil heat exchanger

Heat recovery efficiency of SHX ηSHX 0% nV,system ηHR nV,Res1/h 1/h 1/h

Energetically effective air changes nV 0.300 * (1 - 0.83 ) + 0.030 = 0.082VV nV cAir Gt m³ 1/h Wh/(m³K) kKh/a kWh/a kWh/(m²a)

Ventilation heat losses QV 737.9 * 0.082 * 0.33 * 67.7 = 1355 4.6Reduction factor

QT QV night/weekendkWh/a kWh/a Saving kWh/a kWh/(m²a)

Total heat losses QL ( 10764 + 1355 ) 1.0 = 12119 41.1

Orientation Reduction factor g-Value Area Radiation HPof the area See 'Windows' sheet (perp. radiation)

m² kWh/(m²a) kWh/a

North 0.27 * 0.46 * 29.76 * 116 = 425East 0.26 * 0.46 * 15.45 * 283 = 513South 0.48 * 0.46 * 70.15 * 415 = 6410West 0.28 * 0.46 * 4.06 * 210 = 110Horizontal 0.00 * 0.00 * 0.00 * 385 = 0

––––––––––– kWh/(m²a)

Available solar heat gains QS Total 7458 25.3

Length heating period Spec. power qI ATFAkh/d d/a W/m² m² kWh/a kWh/(m²a)

Internal heat gains QI 0.024 * 205 * 2.27 * 295.2 = 3295 11.2

kWh/a kWh/(m²a)

Free heat QF QS + QI = 10753 36.4

Ratio of free heat to losses QF / QV = 0.89

Utilisation factor heat gains hG (1 - ( QF / QL )5 ) / (1 - ( QF / QL )

6 ) = 88% kWh/a kWh/(m²a)

Heat gains QG ηG * QF = 9451 32.0

kWh/a kWh/(m²a)

Annual heating demand QH QL - QG = 2668 9

kWh/(m²a) (Yes/No)

Limiting value 15 Requirement met? Yes

PHPP, Annual heating PHPP_V9_current

Specific energy for heating (monthly method) Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

The sum of the heating periods calculated through the monthly method will be presented on this side.Interior temperature: 20 °C

Building type: Single Family ResidenceTreated floor area ATFA: 295.2 m²

Spec. Capacity: 60 Wh/(m²K) Per m²

Temperature zone Area U-Value Month. red. fac. Gt of treatedBuilding assembly m² W/(m²K) kKh/a kWh/a floor areaExternal wall - Ambient A 221.8 * 0.123 * 1.00 * 75 = 2045 6.93External wall - Ground B 150.5 * 0.159 * 1.00 * 38 = 921 3.12Roof/Ceiling - Ambient A 157.8 * 0.110 * 1.00 * 75 = 1291 4.37Floor slab / Basement ceiling B 157.8 * 0.174 * 1.00 * 38 = 1056 3.58

A * * 1.00 * =A * * 1.00 * =X * * 0.00 * =

Windows A 119.4 * 0.668 * 1.00 * 75 = 5958 20.19Exterior door A * * 1.00 * =Exterior TB (length/m) A 53.1 * 0.157 * 1.00 * 75 = 623 2.11Perimeter TB (length/m) P * * 1.00 * = 0.00Ground TB (length/m) B * * 1.00 * = 0.00 ––––––––––– kWh/(m²a)

Transmission heat losses QT Total 11894 40.3

ATFA Clear room heightEffective m² m m³ air volume VV 295 * 2.50 = 738

nV,system η∗SHX ηHR nV,Res nV,equi,fraction1/h 1/h 1/h

Effective air change rate Ambient nV,e 0.300 *(1- 0% )*(1- 0.83 )+ 0.030 = 0.082Effective air change rate Ground nV,g 0.300 * 0% *(1- 0.83 ) = 0.000

VV nV,equi,fraction cAir Gt m³ 1/h Wh/(m³K) kKh/a kWh/a kWh/(m²a)

Ventilation losses ambient QV 738 * 0.082 * 0.33 * 75 = 1494 5.1Ventilation losses ground QV,e 738 * 0.000 * 0.33 * 49 = 0 0.0

–––––––––––

Ventilation heat losses QV Total 1494 5.1

Reduction factor QT QV night/weekend

kWh/a kWh/a saving kWh/a kWh/(m²a)

Total heat losses QL ( 11894 + 1494 ) * 1.0 = 13388 45.4

Orientation Reduction factor g-Value Area Global radiationof the area see 'Windows' worksheet (perp. radiation)

m² kWh/(m²a) kWh/a

North 0.27 * 0.46 * 29.8 * 175 = 641East 0.26 * 0.46 * 15.4 * 417 = 757South 0.48 * 0.46 * 70.2 * 557 = 8606West 0.28 * 0.46 * 4.1 * 313 = 165Horizontal 0.00 * 0.00 * 0.0 * 587 = 0Sum opaque areas 519

––––––––––– kWh/(m²a)

Available solar heat gains QS Total 10689 36.2

Length Heat. Period Spec. Power qI ATFAkh/d d/a W/m² m² kWh/a kWh/(m²a)

Internal heat gains QI 0.024 * 243 * 2.3 * 295.2 = 3906 13.2

kWh/a kWh/(m²a)

Free heat QF QS + QI = 14596 49.4

Ratio free heat to losses QF / QL = 1.09

Utilisation factor heat gains hG = 72% kWh/a kWh/(m²a)

Heat gains QG ηG * QF = 10541 35.7

kWh/a kWh/(m²a)

Annual heating demand QH QL - QG = 2847 10

kWh/(m²*a) (Yes/No)

Limiting value 15 Requirement met? Yes

PHPP, Heating PHPP_V9_current

Specific energy for heating (monthly method) Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Interior temperature: 20 °CBuilding type: Single Family Residence

Treated floor area ATFA: 295 m²

Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec YearHeating degree hours - External 12.0 10.3 9.9 7.7 5.7 3.3 1.6 1.5 3.8 7.2 9.8 12.1 85 kKhHeating degree hours - Ground 5.5 5.3 5.9 4.5 4.1 3.4 3.0 2.7 2.6 3.9 4.2 5.0 50 kKhLosses - Exterior 1838 1573 1516 1172 872 502 247 231 584 1099 1493 1849 12975 kWhLosses - Ground 284 272 301 232 213 176 154 138 133 199 218 257 2577 kWhSum spec. losses 7.2 6.2 6.2 4.8 3.7 2.3 1.4 1.3 2.4 4.4 5.8 7.1 52.7 kWh/m²Solar gains - North 32 51 92 140 194 209 206 152 107 70 39 23 1315 kWhSolar gains - East 38 69 122 151 216 204 226 195 148 89 45 28 1531 kWhSolar gains - South 619 1015 1475 1442 1650 1533 1634 1745 1614 1186 714 505 15133 kWhSolar gains - West 7 14 25 34 49 54 54 45 30 19 10 7 348 kWhSolar gains - Horiz. 0 0 0 0 0 0 0 0 0 0 0 0 0 kWhSolar gains - Opaque 25 45 82 108 154 158 165 141 100 58 29 19 1082 kWhInternal heat gains 498 450 498 482 498 482 498 498 482 498 482 498 5868 kWhSum spec. gains solar + internal 4.1 5.6 7.8 8.0 9.4 8.9 9.4 9.4 8.4 6.5 4.5 3.7 85.6 kWh/m²Utilisation factor 99% 92% 76% 59% 39% 26% 14% 13% 29% 66% 96% 100% 50%Annual heating demand 913 330 85 14 1 0 0 0 0 27 446 1031 2847 kWhSpec. heating demand 3.1 1.1 0.3 0.0 0.0 0.0 0.0 0.0 0.0 0.1 1.5 3.5 9.6 kWh/m²

Annual heating demand: Comparison

Monthly method ('Heating') 2847 kWh/a 9.6 kWh/(m²a) reference to treated floor area according to PHPPAnnual method ('Annual heating') 2668 kWh/a 9.0 kWh/(m²a) reference to treated floor area according to PHPP

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Spec. heating demand Sum spec. gains solar + internal Sum spec. losses

PHPP, Heating PHPP_V9_current

Heating load Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Interior temperature: 20 °CBuilding type: Single Family Residence

Treated floor area ATFA: 295.2 m²Design temperature Radiation: North East South West Horizontal

Weather 1: -2.2 °C 13 18 39 20 30 W/m²Weather 2: 0.6 °C 8 10 18 12 17 W/m²

Ground design temp. 12.1 °C

Area U-Value Factor TempDiff 1 TempDiff 2 PT 1 PT 2Building assembly Temperature zone m² W/(m²K) always 1(except "X") K K W W

External wall - Ambient A 221.8 * 0.123 * 1.00 * 22.2 or 19.4 = 607 or 531External wall - Ground B 150.5 * 0.159 * 1.00 * 7.9 or 7.9 = 189 or 189Roof/Ceiling - Ambient A 157.8 * 0.110 * 1.00 * 22.2 or 19.4 = 383 or 335Floor slab / Basement ceiling B 157.8 * 0.174 * 1.00 * 7.9 or 7.9 = 216 or 216

A * * 1.00 * 22.2 or 19.4 = orA * * 1.00 * 22.2 or 19.4 = orX * * 0.00 * 22.2 or 19.4 = or

Windows A 119.4 * 0.668 * 1.00 * 22.2 or 19.4 = 1769 or 1546Exterior door A * * 1.00 * 22.2 or 19.4 = orExterior TB (length/m) A 53.1 * 0.157 * 1.00 * 22.2 or 19.4 = 185 or 162Perimeter TB (length/m) P * * 1.00 * 7.9 or 7.9 = orGround TB (length/m) B * * 1.00 * 7.9 or 7.9 = orBuilding element towards neighbour I * * 1.00 * 3.0 or 3.0 = or

Transmission heat load PT ––––––––––– –––––––––––Total = 3350 or 2978

ATFA Clear room heightVentilation system: m² m m³

Effective air volume, VV 295.2 * 2.50 = 738ηSHX 1 ηSHX 2

Heat recovery efficiency ηHR 83% Heat recovery efficiency SHX 0% Heat recovery efficiency SHX 0% or 0%of the heat exchanger

nV,Res (Heating Load) nV,system ΦΗΡ ΦΗΡ1/h 1/h 1/h 1/h

Energetically effective air changes nV 0.075 + 0.300 *(1- 0.83 or 0.83 ) = 0.127 or 0.127Ventilation heat load PV

VV nV nV cAir TempDiff 1 TempDiff 2 PV 1 PV 2m³ 1/h 1/h Wh/(m³K) K K W W

737.9 * 0.127 or 0.127 * 0.33 * 22.2 or 19.4 = 687 or 601

PL 1 PL 2Total heating load PL W W

PT + PV = 4038 or 3579

Orientation Area g-Value Reduction factor Radiation 1 Radiation 2 PT 1 PT 2of the area m² (perp. radiation) (see 'Windows' worksheet) W/m² W/m² W WNorth 29.8 * 0.5 * 0.27 * 13 or 8 = 47 or 29East 15.4 * 0.5 * 0.26 * 22 or 12 = 40 or 21South 70.2 * 0.5 * 0.48 * 38 or 18 = 591 or 277West 4.1 * 0.5 * 0.28 * 17 or 11 = 9 or 6Horizontal 0.0 * 0.0 * 0.40 * 30 or 17 = 0 or 0

––––––––––– –––––––––––

Solar heating power PS Total = 687 or 332

Spec. power ATFA PI 1 PI 2Internal heating load PI W/m² m² W W

1.8 * 295 = 522 or 522

PG 1 PG 2

Heating power (gains) PG W WPT + PI = 1209 or 854

PL - PG = 2829 or 2724

Heating load PH = 2829 W

Area specific space heating load PH / ATFA = 9.6 W/m²

Input max. supply air temperature 52 °C °C °CMax. supply air temperature ϑSupply,Max 52 °C Supply air temperature without heating ϑSupply,Min 16.2 16.6

For comparison: heating load transportable by the supply Air PSupply Air,Max = 2619 W specific: 8.9 W/m²(Yes/No)

Supply air heating: Sufficient? No

PHPP, Heating load PHPP_V9_current

-

Summer ventilation Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Building type: Single Family ResidenceBuilding volume: 738 m³ Heat recovery ηHRV: 83%

Max. indoor absolute humidity: 12 g/kg Energy recovery ηER: 0%Internal humidity sources: 100 g/(P*h) Subsoil heat exchanger η*SHX: 0%

Results passive cooling Results active coolingFrequency of overheating: 3.0% at the overheating limit ϑmax = 25 °C Useful cooling demand: 5.8 kWh/(m²a)

max. humidity: 11.8 g/kg Dehumidification demand: 0.0 kWh/(m²a)Frequency of exceeded humidity: 0.1% Frequency of exceeded humidity: 0.1%

Summer basic ventilation to ensure adequate air quality

Air change rate via vent. system with supply air: 0.45 1/h HRV/ERV in summer (check only one field)None

Automatic bypass, controlled by temperature difference xAutomatic bypass, controlled by enthalpy difference

Always

Air change rate via extract air system: 1/hSpecific power consumption (for extract air system) 0.20 Wh/m³

Window ventilation air change rate: 2.50 1/h

Effective air change ratenV,system η∗SHX ηΗΡ nV,equi,fraction

1/h 1/hExterior nV,e 0.450 *(1- 0% )*(1- 0.83 ) = 0.078 without HR 0.450 *(1- 0% ) = 0.450Ground nL,g 0.450 * 0% *(1- 0.83 ) = 0.000 without HR 0.450 * 0% = 0.000

Ventilation conductanceVV nV,equi,fraction cAir m³ 1/h Wh/(m³K)

exterior HV,e 738 * 0.078 * 0.33 = 19.0 W/K without HR 738 * 0.450 * 0.33 = 109.6 W/Kground HV,g 738 * 0.000 * 0.33 = 0.0 W/K without HR 738 * 0.000 * 0.33 = 0.0 W/KInfiltration, window, extract air system 738 * 2.530 * 0.33 = 616.1 W/K

Additional summer ventilation for cooling

Additional ventilation regulationMinimum acceptable indoor temp. 22.0 °C

Type of additional ventilation

Window night ventilation, manual Night ventilation value 0.15 1/h

Corresponding air change rate 1/h Controlled by (please check)Mechanical, automatically during operation, in addition to basic air change Temperature diff.Controlled ventilation Specific power consumption Wh/m³ Humidity diff. x

PHPP, SummVent PHPP_V9_current

Secondary calculation: Hygienic air change rate through window ventilationEstimation for window air change rate to ensure sufficient air quality

Description Day 1st FLOpen duration [h/d] 6

Climate boundary conditionsTemperature diff interior - exterior 4 KWind velocity 1 m/s

Window group 1Quantity 2Clear width 0.90 mClear height 2.00 mTilting window (check if appropriate)Opening width (for tilting windows) m

Window group 2 (cross ventilation)Quantity 2Clear width 1.20 mClear height 2.00 mTilting window (check if appropriate)Opening width (for tilting windows) m

Difference in height to window 1 3.00 m

TotalResult: Air change rate 2.24 0.00 0.00 0.00 0.00 0.00 2.24 1/h

Secondary calculation: Additional night ventilation for coolingAir change value during additional window night ventilation

Description NightReduction factor 100%

Climate boundary conditionsTemperature diff interior - exterior 1 1 1 1 1 1 KWind velocity 0 0 0 0 0 0 m/s

Window group 1Quantity 1Clear width 0.90 mClear height 2.00 mTilting window (check if appropriate) xOpening width (for tilting windows) 0.060 m

Window group 2 (cross ventilation)Quantity 1Clear width 0.90 mClear height 2.00 mTilting window (check if appropriate) xOpening width (for tilting windows) 0.060 m

Difference in height to window 1 4.00 m

TotalResult: Night ventilation values 0.15 0.00 0.00 0.00 0.00 0.00 0.15 1/h

PHPP, SummVent PHPP_V9_current

Summer: Passive cooling Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Building type: Single Family Residence Treated floor area ATFA: 295.2 m²Upper temperature limit: 25 °C Building volume: 738 m³

Nominal humidity: 12 g/kg Internal humidity sources: 1.1 g/(m²h)Spec. capacity: 60 Wh/(m²K)

Area U-Value Red. factor fT,Summer HSummer heat conductance

Building assembly Temperature zone m² W/(m²K)

External wall - Ambient A 221.8 * 0.123 * 1.00 = 27.4External wall - Ground B 150.5 * 0.159 * 1.00 = 24.0Roof/Ceiling - Ambient A 157.8 * 0.110 * 1.00 = 17.3Floor slab / Basement ceiling B 157.8 * 0.174 * 1.00 = 27.5

A * * 1.00 =A * * 1.00 =X * * 0.00 =

Windows A 119.4 * 0.668 * 1.00 = 79.8Exterior door A * * 1.00 =Exterior TB (length/m) A 53.1 * 0.157 * 1.00 = 8.3Perimeter TB (length/m) P * * 1.00 =Ground TB (length/m) B * * 1.00 =

–––––––––––

Exterior thermal transmittance, HT,e 132.8 W/KGround thermal transmittance, HT,g 51.5 W/K

Summer ventilation from 'SummVent' worksheet

Ventilation unit conductance Ventilation parameter Summer ventilation regulationexterior HV,e 19.0 W/K Temperature amplitude summer 7.8 K HRV/ERV without HR 109.6 W/K Minimum acceptable indoor temperature 22.0 °C Noneground HV,g 0.0 W/K Heat capacity air 0.33 Wh/(m³K) Controlled by temperature x without HR 0.0 W/K Supply air changes 0.45 1/h Controlled by enthalpyVentilation conductance, others Outdoor air changes 2.53 1/h Alwaysexterior 616.1 W/K Window night ventilation air change rate, manual @ 1K 0.15 1/h Additional ventilation

Air change rate due to mech. automatically controlled vent. 0.00 1/h Controlled by temperatureSpecific power consumption for 0.00 Wh/m³ Controlled by humidity xηHR 83%ηERV 0%η∗SHX 0%

Orientation Angle Shading Shading g-Value Area Portion of glazing Apertureof the area factor factor dirt (perp. radiation)

Summer Summer m² m²

North 0.9 * 0.52 * 0.95 * 0.46 * 29.8 * 68% = 4.1East 0.9 * 0.58 * 0.95 * 0.46 * 15.4 * 68% = 2.4South 0.9 * 0.50 * 0.95 * 0.46 * 70.2 * 78% = 10.6West 0.9 * 0.64 * 0.95 * 0.46 * 4.1 * 64% = 0.7Horizontal 0.9 * 1.00 * 0.95 * 0.00 * 0.0 * 0% = 0.0Sum opaque areas 1.0

––––––––––– m²/m²

Solar aperture Total 18.8 0.06

Specif. power qI ATFAW/m² m² W W/m²

Internal heat gains QI 4.9 * 295 = 1434 4.9

Frequency of overheating hϑ ≥ Jmax 3.0% At the overheating limit ϑmax = 25 °C

If the "frequency over 25°C" exceeds 10%, additional measures to protect against the heat during the summer are necessary.

Daily internal temperature strokeTransmission Ventilation Solar load Spec. capacity ATFA:

kWh/d kWh/d kWh/d 1/k Wh/(m²K) m²

( 12.4 + 71.8 + 63.4 ) * 1000 / ( 60 * 295 ) = 8.3 K

PHPP, Summer PHPP_V9_current

-

Heat distribution and domestic hot water (DHW) system Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Interior temperature: 20 °C Interior temperature summer: 25 °CBuilding type: Single Family Residence

Treated floor area ATFA: 295 m²Occupancy: 3.2 Pers

Number of dwelling units: 1Annual heating demand qHeating 2847 kWh/a Annual useful cooling dem. qCool 1698 kWh/a

Length of heating period: 205 d Length cooling period: 365 dAverage heating load Pave: 0.6 kW Average cooling load P Average: 0.2 kW

Marginal usability of additional heat gains: 53% Marginal utility of additional heat losses: 0%

Inside thermal envelope Outside thermal envelope Total values

Space heat distribution 1 2 3 4 5 1 2 3 4 5 Absolute SpecificLength of distribution pipes LH m 12.5 3.0Nominal width of pipe mm 13 13Insulation thickness mm 50 18Insulation reflective coating? -Thermal conductivity of insulation W/(mK) 0.044 0.044Heat loss coefficient per m of insulated pipe W/(mK) 0.129 0.190Insulation quality of mountings, pipe suspensions, etc. - 1-None 1-None 1-None 1-None 1-None 1-None 1-None 1-None 1-None 1-NoneThermal bridge supplement W/K 3.875 2.450Total heating loss coefficient per m of pipe Ψ W/(mK) 0.439 1.006

Temp. of the room through which the pipes pass ϑX °C 20 20 20 20 20 11.0 11.0 11.0 11.0 11.0Design forward flow temperature ϑV °C 55.0 55.0 55.0 55.0 55.0 55.0 55.0 55.0 55.0 55.0Design system heating load Pheating kW 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0 7.0Forward flow temperature control ('x' if applicable) x x x x x x x x x xDesign return flow temperature ϑR °C 45.0 45.0Annual heat emission per m of plumbing q*HL kWh/(m·a) 10 23Possible utilisation factor of released heat ηG - 53% 53% kWh/a kWh/(m²a)Annual heat losses of heating distribution QHL kWh/a 58 32 90 0.3

Annual heat losses of heating storage kWh/a 0 0.0

Annual heat losses of heating kWh/a 90 0.3Performance ratio of heat distribution ea,HL - 103%

PHPP, DHW+Distribution PHPP_V9_current

DHW useful heatDHW demand for showers, per person and day (with 60°C) litre/person/d 16.0DHW demand others, per person and day (with 60°C) litre/person/d 9.0Performance of shower drain-water heat recovery - 0%Effective DHW demand VDHW litre/person/d 25Average cold water temperature of the supply ϑTW °C 11.6DHW demand for washing machines and dishwashers non-elect kWh/a 0 kWh/a kWh/(m²a)Effective useful heat DHW QDHW kWh/a 1636 1636 5.5

Auxiliary calculation - DHW demand calculation (for non-res)


Auxiliary calculation - shower drain-water heat recovery

Steady-state operation 1-Sorting: LIKE LISTSelection heat recovery Heat recovery DHWNominal efficiency of heat exchanger η0Nominal air flow l/min

Flow rate shower l/minConnexion to DHWConnexion to cold waterForward flow temperature DHW TDHW °C 60Temperature cold water TCW °C 12Room temperature TRoom °C 20Temperature DHW use TDW °C 40Temperature drain water TDrain °C 35Temperature proportion of heat exchanger -Forward flow temperature after heat exchanger °C -Steady-state efficiency of the system - 0%

Dynamic

Duration of shower min 15.0Eff. time of non-use for HR s 0Eff. time of non-use for bathtub shower s 10

Drain water pipes for HRHorizontal pipe length m 15.00Efficiency of flow velocity m/s 0.3Eff. time of non-use s 50

Fresh water pipes after HR To HW & CW Only to HW Only to CWLength of pipe mExterior pipe diameter mFlow rate during non-use time l/min 0.0 0.0 0.0Effective time of non-use s 0 0 0

Total of non-use time until branch of CW/HW s 60Time of non-use CW-HW s 0.0Time of non-use CW-HW s 0.0

Dynamic efficiency of system 0%

X14A0T


Inside thermal envelope Outside thermal envelope Total values

DHW distribution 1 2 3 4 5 1 2 3 4 5 Absolute SpecificTemp. of room through which the pipes pass ϑX °C 20.0 20.0 20.0 20.0 20.0 11.0 11.0 11.0 11.0 11.0Design forward flow temperature ϑdist °C 60.0 60.0 60.0 60.0 60.0 60.0 60.0 60.0 60.0 60.0

DHW circulation pipesLength of circulation pipes (forward + return flow) LHS m 0.0Nominal width of pipe mm 20Insulation thickness mm 40Insulation reflective coating? -Thermal conductivity of insulation W/(mK) 0.035Heat loss coefficient per m of insulated pipe W/(mK) 0.135Insulation quality of mountings, pipe suspensions, etc. - 3 - Good 1-None 1-None 1-None 1-None 1-None 1-None 1-None 1-None 1-NoneThermal bridge supplement W/K 0.140Total heating loss coefficient per m of pipe Ψ W/(mK) #DIV/0!

Daily circulation period of operation. tdCirc h/d 18.0Design return flow temperature ϑR °CCirculation period of operation per year tCirc h/a 6570Annual heat released per m of pipe q*Z kWh/m/a kWh/a kWh/(m²a)Annual heat loss from circulation lines QZ kWh/a 0 0.0

DHW individual pipesExterior pipe diameter dU_Pipe m 0.012Accumulated length per single pipes LU m 20.00Amount of tapping points in building ntapping point - 3.00Average pipe length per tapping point LU, average m 6.7Tap openings per person per day - 6Utilisation days per year d 365Heat loss per tap opening qIndividual kWh/tap opening 0.0239Amount of tap openings per year and person nTap Tap openings per year 2190 kWh/a kWh/(m²a)Annual heat loss of individual pipes QU kWh/a 167 167 0.6

kWh/a kWh/(m²a)

Total heat losses of DHW distribution QWL 167 0.6

Performance ratio of DHW distribution pipes ea,HL - 110%


Storage heat lossesStorage 1 Storage 2 Buffer storage tank (only heating) Compact unit

Selection of storage tank

Storage necessary for HP x (x)Solar DHW connection x

Heat loss rate W/K 2.5Storage volume litre 250 ---Standby fraction - 30%

Location of storage tank, inside or outside of thermal envelope 1-Inside 1-Inside 1-InsideTemperature of mechanical room °C 20.0Typical storage tank temperature °C 60.0Manual entry of storage temperature °C

Average standby heat losses storage tank W 30Additional heat losses storage tank, solar operation W 70 --- ---Possibly utilisation factor of heat losses --- --- --- kWh/a kWh/(m²a)Annual heat losses DHW storage tank kWh/a 876 --- 876 3.0Annual heat losses buffer storage tank --- --- ---

Auxiliary calculation - heat losses through storage tank according to EU efficiency classes

Total energy demand of domestic hot water kWh/a kWh/(m²a)Heat losses of DHW distribution and storage QWL 1043 3.5

Performance ratio DHW-distribution + storage ea,WL 164%

Total heating demand of DHW system kWh/a kWh/(m²a)

Including storage tank QgDHW 2679 9.1

0-No 2-DHW only 0-No storage tank 0-No storage tank


-

Photovoltaic systems Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Climate data set: CA0003b-Vancouver

Building type: Single Family ResidenceProjected building footprint: 157.8 m²

Name of system System 1 System 2 System 3 System 4 System 5 Reference PV syst.Location: Selection in 'Areas' worksheet 23-ASSEMBLY-ROOF FLAT 1A

Size of selected area 111.9 m²Deviation from North 180 °Angle of inclination from horizontal 35 °Alternative input: Deviation from North 180 °Alternative input: Angle of inclination from the horizontal 35 °

Information from the module data sheetTechnology 5-Poly-Si 4-Mono-Si

Nominal current IMPP0 7.71 7.71 ANominal voltage UMPP0 30.50 30.50 VNominal power Pn 235 0 0 0 0 235 Wp

Temperature coefficient short-circuit current α 0.040 0.040 %/KTemperature coefficient open-circuit voltage β -0.340 -0.340 %/KModule dimensions: Height 1.658 1.658 mModule dimensions: Width 0.994 0.994 m

1.6 Module area [m²]

Further specificationsNumber of modules nM 46 0.0Height of module array 1.0 m Height of horizon hHori m

Horizontal distance aHori m

Additional reduction factor shading rother 94%Efficiency of the inverter ηHRV 95% 95%

ResultsArea of module field 75.8 0.0 0.0 0.0 0.0 0.0 m²

Free area on the selected building element 36.1 m²

Allocation to building element 68%

Annual losses due to shading 772 kWh

TotalAnnual electricity yield of the inverter, absolute 12100 12100 kWh/aRelated to projected building footprint area 76.7 77 kWh/m²AProjeCO2-equivalent emissions according to 1-CO2 factors GEMIS (Germany) 762.3 762.3 kg/aPE-factor according to 1-PE-factors (non-renewable) PHI Certification 0.00 0.0 0.00 kWhprim/kWh

Solar radiation on tilted surface Jan 38 38kWh/(m²*Month) Feb 67 67

Mar 116 116Apr 140 140May 185 185Jun 181 181Jul 191 191Aug 179 179Sep 138 138Oct 85 85Nov 44 44Dec 29 29Year kWh/(m²a) 1394 1394

Total monthly yield Jan 331 331kWh/month Feb 580 580

Mar 1009 1009Apr 1220 1220May 1611 1611Jun 1573 1573Jul 1658 1658Aug 1550 1550Sep 1196 1196Oct 739 739Nov 381 381Dec 250 250Year kWh/a 12100 12100

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Total System 1 System 2 System 3 System 4 System 5

PHPP PV PHPP_V9_current

- PER and PE specific values ►

Electricity demand for residential buildings Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Households 1 PER and PE factors (KWh/kWh) Electricity: 1.20 2.6 Solar fraction of DHW Laundry&DishPersons 3.2 Non-electric energy carrier for cooking, drying: 1.20 2.6 Marginal performance ratio DHW 33%Living area (m²) 295 Energy carrier for heating: 1.10 2.6 Marginal performance ratio Heating 33%Heating demand [kWh/(m²a)] 9.6 Energy carrier for DHW: 1.13 2.6

Column no. 1 2 3 4 5 6 7 8 8a 9 10 11 12 13

Application

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Addi

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Dishwashing 1 1 1.10 kWh/Use * 1.00 * 65 /(P*a) * 3.2 P = 228 * 100% = 2282-Cold water connection * 0% * (1+ 0.30 ) * 0.33 *(1- ) =Clothes washing 1 2 1.10 kWh/Use * 1.00 * 57 /(P*a) * 3.2 P = 200 * 100% = 2002-Cold water connection * 0% * (1+ 0.05 ) * 0.33 *(1- ) =Clothes drying with: 1 2 3.50 kWh/Use Residual dampness 0.88 * 57 /(P*a) * 3.2 P = 558 100% = 5584-Condensation dryer 0.60 = 0 0% 1.00 * 0Energy consumed by evaporation 0 2 0.00 kWh/Use * 0.60 * 57 /(P*a) * 3.2 P = 0 * 100% * (1+ 0.00 ) * 0.33 *(1- 0.74 ) = 0Refrigerating 1 1 1.00 kWh/d * 1.00 * 365 d/a * 1 HH = 365 * 100% = 365Freezing 1 1 0.88 kWh/d * 1.00 * 365 d/a * 1 HH = 321 * 100% = 321or combination 0 1 1.00 kWh/d * 1.00 * 365 d/a * 1 HH = 0 * 100% = 0Cooking with: 1 1 0.25 kWh/Use * 1.00 * 500 /(P*a) * 3.2 P = 399 * 100% = 3991-Electricity * 0% 0Lighting 1 1 14 W 50 * 1.00 * 2.90 kh/(P*a * 3.2 P = 133 * 100% = 133Consumer electronics 1 1 100 W * 1.00 * 0.55 kh/(P*a * 3.2 P = 176 * 100% = 176Small appliances, etc. 1 1 50 kWh * 1.00 * 1.00 /(P*a) * 3.2 P = 160 * 100% = 160Total aux. electricity 4255 4255Other:

infloor mats 1 1 3000 kWh/a 3000 3000kWh/a 0 0kWh/a 0 0

DHW Non-Electric - Wash&Dish

Total 9796 kWh 9796 kWh 0 kWh 0Non-Renewable Non-Electric DHW Wash&Dish

Specific demand 33.2 kWh/(m2a) 0.0 kWh/(m2a) 0.0

Recommended maximum value 18

Average lamp efficiency[lm/W]

PHPP, Electricity PHPP_V9_current

- PER and PE specific values ►

Aux Electricity Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Treated floor area 295 m² Heat recovery efficiency ventilation unit 0.83 Annual space heating demand 10 kWh/(m2a)Heating period 205 d Operation vent. system Winter 4.92 kh/a Boiler rated power 15 kWAir volume 738 m³ Operation vent. system Summer 3.84 kh/a DHW system heating demand 2679 kWh/aDwelling units 1 HH Air change rate 0.30 h-1 Design forward flow temperature 55 °C

Column no. 1 2 3 4 5 6 7 8 9 10 11

Application

Exis

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[1/0

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[1/0

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Nor

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Ventilation systemWinter ventilation 1 0.31 Wh/m³ * 0.30 h-1 * 4.9 kh/a * 738 m³ = 338 considered in heat recovery efficiencyDefroster HX 1 1 Data entries in 'Ventilation' worksheet or in 'Addl vent' 22 * 0.2 / 4.92 = 1Summer ventilation 1 0.90 0.31 Wh/m³ * 0.45 h-1 * 3.8 kh/a * 738 m³ = 395 * 1.0 / 3.84 = 93

Internal heat sources ' Additional summer ventilation' 0.0Additional vent. summer 0 0.00 Wh/m³ * 0.00 h-1 * 3.8 kh/a * 738 m³ = 0 * 1.0 / 3.84 =Heating system Controlled / non controlled

Enter the rated power of the pump W

Circulator pump heating 78 W * 1.0 * 4.9 kh/a * 1 = 0 * 1.0 / 4.92 = 0Boiler electricity consumption at 30% load W

Aux. energy - Heat. boiler 0 0 55 W * 1.00 * 0.00 kh/a * 1 = 0 * 1.0 / 4.92 = 0Aux. energy - Wood fired/Pellet boiler 0 0 Data entries in 'Boiler' worksheet. Aux. energy demand including possible drinking water production. 0 * 1.0 / 4.92 = 0

DHW systemEnter average power consumption of pump W

Circulation pump DHW 0 0 30 W * 1.00 * 5.5 kh/a * 1 = 0 * 1.0 / 8.76 = 0 0Enter the rated power of the pump W

Storage load pump DHW 67 W * 1.00 * 0.2 kh/a * 1 = 0 * 1.0 / 8.76 = 0 0Boiler electricity consumption at 100% load W

DHW boiler aux. energy 0 0 165 W * 1.00 * 0.0 kh/a * 1 = 0 * 1.0 / 8.76 = 0 0Enter the rated power of the solar DHW pump W

Solar aux. electricity 0 1 49 W * 1.00 * 1.8 kh/a * 1 = 0 * 1.0 / 8.76 = 0 0

Aux. electricity cooling and dehumidificationAux. electricity cooling 1 1 3500 kWh/a * 1.00 * 1.0 * 1 = 3500 * 1.0 / 3.84 = 911Aux. electricity dehum. kWh/a * 1.00 * 1.0 * 1 = 0 * 1.0 / 3.84 = 0Misc. aux. electricity Misc. aux. electricity kWh/a * 1.00 * 1.0 * 1 = 0 * 1.0 / 8.76 = 0 0

Total 4255 1 1004

Specific demand kWh/(m²a) (treated floor area) 14.4

PHPP, Aux Electricity PHPP_V9_current

- Biomass ►

Primary Energy Renewable PER Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Building type: Single Family ResidenceTreated floor area ATFA: 295 m²

Selection of heat generation system Projected building footprint AProjected: 158 m²Primary heat generator Heating DHW Addl. input in following worksheets Heating demand incl. distribution & hydr. frost protection 10 kWh/(m²a)2-Heat pump 100% 100% HP, possibly HP ground Cooling energy dem. incl. dehumidification kWh/(m²a)

Secondary heat generator (optional) DHW demand including distribution: 9 kWh/(m²a)- 0% 0% -

Energy demand Final energy PER PE CO2Reference: Treated floor area Contribution (final

energy)Final energy

demandPER factor Effective PER

factor (including biomass

PER specific value

PE factor PE Value CO2 emissions factor

(CO2-eq)

CO2eq emissions

kWh/(m²a) kWh/kWh kWh/kWh kWh/(m²a) kWh/kWh kWh/(m²a) kg/kWh kg/(m²a)

43.3 102.1 20.9Heating 1.10 5.0 2.60 11.9 2.4Electricity (HP compact unit) 1.50 2.60 0.532Electricity (heat pump) 100% 3.3 1.50 1.10 3.7 2.60 8.7 0.532 1.8District heating: 1-None 2.8|4.5|3.3 0.000Wood and other biomass 1.10 - -Natural gas / RE gas 1.75 1.10 0.250Heating oil / RE methanol 2.30 1.10 0.320Solar thermal systemElectricity (direct through DHW storage tank) 1.50 2.60 0.532Electricity (direct through heating resistance) 1.50 2.60 0.532

Aux. electricity (vent.winter, frost protection, circ.pump, boiler, wood / pellets) 1.2 1.50 1.10 1.3 2.60 3.2 0.532 0.6

Cooling and dehumidification 1.00 13.2 34.3 7.0Electricity cooling (heat pump) 1.00 2.60 0.532Auxiliary electricity cooling, ventilation summer 13.2 1.00 13.2 2.60 34.3 0.532 7.0Electricity dehumidification (heat pump) 1.00 2.60 0.532Auxiliary electricity (dehumidification) 1.00 2.60 0.532

DHW generation 1.13 3.1 2.60 7.2 1.5Electricity (HP compact unit) 1.15 2.60 0.532Electricity (heat pump) 100% 2.8 1.15 1.13 3.1 2.60 7.2 0.532 1.5District heating: 1-None 2.8|4.5|3.3 0.000Wood and other biomass 1.10 - -Natural gas / RE gas 1.75 1.10 0.250Heating oil / Methanol 2.30 1.10 0.320Solar thermal systemElectricity (direct) 1.15 2.60 0.532

Aux. electricity (circ.pump + storage charge, aux.energy DHW + solar DHW) 1.15 2.60 0.532

Household electricity 18.8 1.17 21.9 48.8 10.0Electricity (household or non-residential lighting, etc.) 18.8 1.20 1.17 21.9 2.60 48.8 0.532 10.0Auxiliary electricity (other) 1.20 2.60 0.532

Gas / RE gas dry/cook 0.0 1.75 0.0 2.60 0.0 0.270 0.0

Energy generation Final energy PER PE CO2Reference: Projected building footprint area Final energy

generationFinal energy generation

PER specific value

PE factor PE Value Emission factor (CO2-eq)

CO2eq emissions

kWh/a kWh/(m²AProjected*a) kWh/(m²AProjecteda) kWh/kWh kWh/(m²a) kg/kWh kg/a

76.7 0.0 762.3PV electricity 12100 76.7 1.00 76.7 0.0 0.0 0.063 762.3Solar thermal system 0 0.0 1.00 0.0 1.2 0.0

0.0

PE demand requirement in case of verification through PE (non-renewable) [kWh/(m²a)] -

Current building reaches following

class for aspect102 Requirement met? -

AirtightnessAnnual heat. dem. Heating load Useful cool. energy Cooling load n50Treated floor area Treated floor area Treated floor area Treated floor area PER demand PER generation PER demand PER generation

kWh/(m²a) W/m² kWh/(m²a) W/m² 1/h Passive House Premium Passive House PlusRequirement Passive House Premium 0 92 0 32Requirement Passive House Plus 15 10 - - 0.60 15 92 30 32Requirement Passive House Classic 30 120 45 60Requirement PHI Low Energy Building 30 - 1.00 45 148 60 88

10 10 - - 0.4 45 200 60 200Premium Passive House Classic PHI Low Energy Building

0 0 0 060 0 75 0

Summary Final energy PER specific value PE Value CO2eq emissions CO2eq substitution

balance60 0 75 0

Though, from the scientific point of view, not entirely correct, different energy carriers will be added together here. This is done to meet the criteria of other energy standards such as Effizienzhaus Plus.

1-PE-factors (non-renewable) PHI

Certification1-CO2 factors

GEMIS (Germany) 1-CO2 factors

GEMIS (Germany)

75 28 90 28

MWh/a MWh/a MWh/a kg/a kg/a 75 200 90 200Demand 11.6 12.8 30.15 6169 6169 Current buildingGeneration -12.1 -12.1 0.00 120297 -5675 43 77Demand, cumulative generation (annual balance) -0.50 0.67 30.15 126466 494

Demand w/o household electricity 6.1 6.3 15.74 3221 3221Demand w/o household electricity, cum. generation -6.05 -5.80 15.74 123518 -2454

Premium

Useful energy, performance

1-PE-factors (non-renewable) PHI Certification 1-CO2 factors GEMIS (Germany)

Contribution margin (useful energy)

PER factor

kWh/kWh

Primary Energy Renewable PER

PremiumCurrent building reaches following class for aspect

Achievable energy standard through the verification of renewable primary energy(assessment of individual aspects)

0

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PER demand [kWh/(m²TFA*a)]Passive House Premium Passive House PlusPassive House Classic PHI Low Energy BuildingCurrent building

Premium

Plus

Classic

PHPP, PER PHPP_V9_current

-

Heat pump Passive House with PHPP Version 9.3Dean & Allan Residence / Climate: Vancouver / TFA: 295 m² / Heating: 9.6 kWh/(m²a) / Freq. overheating: 3 % / PER: 43.3 kWh/(m²a)

Building type: Single Family ResidenceTreated floor area ATFA: 295 m²

Covered fraction of space heating demand ('PER' worksheet) 100%Space heating demand + distribution losses QH+QHL: (DHW+Distribution) 2937 kWh/aSolar fraction for space heat ηSolar, H ('SolarDHW' worksheet) 0%Effective annual heating demand QH,Wi=QH*(1-ηSolar, H) 2937 kWh/a

Covered fraction of DHW demand ('PER' worksheet) 100%Total heating demand of DHW system QgDHW (DHW+Distribution) 2679 kWh/aSolar fraction for DHW ηSolar, DHW ('SolarDHW' worksheet) 0%Effective DHW demand QDHW,Wi=QDHW*(1-ηSolar, DHW) 2679 kWh/aNumber of heat pumps in the system 1

Functionality Heating & DHW

HeatingSelection of HP: 4-SANDEN DHW Heat source: 1-Outdoor air

Selection of distribution system 3-Supply air heatingDesign distribution temperature θdesign (DHW+Distribution) 55.00 °CNominal power of distribution system Pnom 2.83 kW

Distribution system (to be completed by experienced users only)Nominal power of distribution system Pnom kW

Radiator exponent n

Heat storage tank (buffer storage tank 'DHW+Distribution' worksheet) 0-No Specific heat losses storage U * A Storage W/K

Storage location in thermal envelope 1-Inside

Room temperature (storage location: outside of thermal envelope) (DHW+Distribution) °CSink temperature of heat pump for heating θsnk 61.50 °C

Entries in relation to the domestic hot water systemSelection of HP: 4-SANDEN DHW Heat source: 1-Outdoor air

DHW temperature (DHW+Distribution) 60.00 °COrientation of DHW storage tank ('storage 1' in 'DHW+Distribution' worksheet) 1-InsideSpecific heat losses storage U * A Storage 2.5 W/KRoom temperature (storage location: outside of thermal envelope) (DHW+Distribution) 20.00 °C

Type of backup heater 1-Elec. Immersion heaterΔθ of electric continuous flow water heater Κ

Additional options in case of one heat pump for both functions: Heating & DHWSame heat pump's sink temperature for Heating and for DHW 1-Yes

Heat pump priority (Manufacturer, tech. data) 1-DHW-priorityControl strategy

Heat pump control strategy 2-IdealHeating

Depth ground water / Ground collector / Ground probe z mPower of pump for ground heat exchanger Ppump kW

PHPP, HP PHPP_V9_current

-HeatingHeat pump: SANDEN DHW

Source: 1-Outdoor airθ_source θ_sink Heating capacity COP

°C °C kWTest point 1 -8.0 65.0 4.0 2.1Test point 2 2.0 65.0 3.6 2.8Test point 3 10.0 65.0 4.0 3.7Test point 4 20.0 65.0 4.1 4.2Test point 5 35.0 65.0 4.6 5.0Test p

Documents

Certificate by: 10 Co. A67 F863 64283 Darmstadt...02ud Typical assembly-BGWALL below ground Heat transmission resistance [m²K/W] Orientation of building element 2-Wall interior R