Phpp passivistas certification booklet 20160205 by Stefan Pallantzas

PHPP BRIEF

INSTRUCTIONS

Place your mouse here to see the PHPP If no help appears when the mouse passes over cell B4, you can activate it by going into the Menu Bar Tools/Options/View, and under "Comments", select "Comment Indicator Only". help.

Passive House verification: meaning of field formats Example

Field Format

78,8

Meaning

Arial, blue, bold with yellow background

Input field: Please enter the required value here

01ud Triple-low-e Kr08 Arial Narrow, blue, with yellow background 80

Arial, blue, bold with grey background

6619

Arial, black, standard on white background

78,8

Arial, violet, bold with white background

126,0

Data entry field with drop down list Link (through Variants-macro). Attention: do not overwrite! Calculation field; please do not change Field with reference to another worksheet

Important result

Arial, black, large & bold on green background

Passive House planning: worksheet directory Worksheet name (to show/hide worksheets please use the separate 'Profile settings' tool)

Function

Required for the certification?

Brief description

Verification

Building data; summary of results

Building description, selection of the calculation method, summary of results

Overview

Overview of the specific data of the project entered

In-depth project description, overview of all results and input variables, specific details on building envelope, building services systems as well as general information.

Cross check

Data entry assistance

Information in case PHPP does not calculate, overview of errors, plausibility checks

yes

Variants

Calculation of variants

Input parameters and results for variant calculation. Predefined fields for frequent entries, as well as user-defined area.

Comparison

Comparison between two variants

Comparison between two variants from the perspective of energy demand and economic viability. Input of comparison configurations.

Climate

Climate region selection or definition of user data

Climate data for: 'Annual heating', 'Windows', 'Heating load', 'Heating', 'Summer', 'Cooling', 'Cooling units', 'Cooling load' worksheets

yes

U-Values

Calculation of standard building assembly U-Values Heat transmission coefficient calculations in accordance with DIN EN ISO 6946.

Areas

Areas summary

Building assembly areas, thermal bridges, treated floor area. Use exterior dimension references!

Ground

Calculation of reduction factors below ground

More precise calculation of heat losses through the ground

Components

Building component database

Database of certified, Passive House suitable components and entry of user-defined components

yes

Windows

UW-Value determination

Input of geometry, orientation, frame lengths, frame widths, U g and U-values of the frame, and the thermal bridge heat loss coefficients of the connections; from these inputs, determine UW and total radiation.

yes

Shading

Determination of shading coefficients

Input of shading parameters, e.g. balcony, neighbouring building, window reveal and calculating the shading factors

yes

Ventilation

Air flow rates, Exhaust/Supply air balancing, Pressurization test results

Sizing the ventilation system from extract and supply air requirements, infiltration air change rate and actual efficiency of heat recovery, input of pressurization test results

yes

Addl vent

Design and planning of ventilation systems with diverse ventilation units

Extension of the 'Ventilation' worksheet for dimensioning air flows, for special building uses and systems with various ventilation units

Annual heating

Annual space heating demand / Annual method

Calculation of the annual space heating demand according to the energy balance method following EN 13790: Transmission + Ventilation - h (Solar gains + Internal gains)

Heating

Space heating demand calculation Monthly method according to EN 13790

Calculation procedure for the monthly method following EN 13790. Make appropriate selection in the 'Verification' worksheet, if calculations should be performed following this procedure

yes

Heating Load

Building heating load calculation

Calculation of the nominal heating load using a balance procedure for the design day: max transmission + max ventilation - Ć&#x17E; (minimum solar gains + internal heat gains)

yes

SummVent

Determination of summer ventilation

Ventilation in cooling case and estimation of air flow rates for natural ventilation during the summer period

yes

Summer

Assessment of summer climate

Calculation of the frequency of overheating as a measure of summer comfort

Cooling

Monthly method for cooling demand

Annual useful cooling demand calculation

if present

Cooling units

Latent cooling energy

Calculation of the energy demand for dehumidification and choice of cooling method

if present

Cooling load

Building cooling load calculation

Calculation of the daily average cooling load of the building

DHW+Distribution

Distribution losses; DHW requirement and losses

Heat loss calculation of the distribution systems (heating; DHW); calculation of the useful heat requirement of DHW and storage losses

yes

SolarDHW

Solar DHW heating

Solar contribution calculation for DHW and space heating contribution

Electricity generation by photovoltaic

Electricity generation calculation of PV system

Electricity

Electricity demand for dwellings

Calculation of the electricity demand of Passive Houses with residential use

yes

Use non-res

Patterns of non-residential utilisation

Input or selection of utilisation patterns for planning of electricity demand and internal heat gains

Electricity non-res

Electricity demand for non-residential use

Calculation of the electricity demand for lighting, electric devices and kitchens for non-residential buildings

Aux Electricity

Auxiliary electricity demand

Calculation of auxiliary electricity and corresponding primary energy demand

yes

IHG

Internal heat gains in dwellings

Calculation of the internal heat gains based on the Electricity and Aux Electricity sheets.

IHG non-res

Internal heat gains for non-residential use

Calculation of the internal heat gains for non-residential buildings based on the 'Electricity non-res' worksheet and the occupancy

PER

Specific primary energy and CO 2 demands

Selection of heat generators, calculation of the primary energy and CO 2 specific demands from the present results

yes

Compact

Performance ratio of heat generator Compact heat pump unit

Calculation of the performance ratio of combined heat generation for heating and DHW by means of an electric heat pump compact unit exclusively, considering the specific project boundary conditions.

if present

Performance ratio of heat generation of the heat pump

Calculation of the performance ratio for heat generation for one to two electric-run heat pumps, considering the specific project boundary conditions.

if present

HP Ground

Ground probe or ground collector in combination with a heat pump

Heat source calculation for a ground probe or horizontal subsoil heat exchanger for ground-coupled heat pumps, considering the specific project boundary conditions.

if present

Boiler

Performance ratio of heat generator Boiler

For the calculation of the performance ratio of heat generation with standard boilers (NT and calorific boilers) for the project given boundary conditions.

if present

District Heating

District heat transfer station

Calculation of the final and primary energy demands (heat)

if present

Data

Database

Table of primary energy factors following [GEMIS] and database of EnEV (German energy efficiency regulation).

PHPP, Brief instructions

yes

yes yes if applicable

if used

yes

if solar panels are used

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit Verification Building: Passivistas:TheHouseProject Street: Anastaseos 112 str

Photo or Drawing

Papagou Athens Postcode/City: GR-15669 GR-Greece Province/Country: Attiki Building type: Detached house Climate data set: ud---03-Athens-Jessica Climate zone: 5: Warm

Altitude of location:

244 m

Home owner / Client: Stefan Pallantzas Street: Anastaseos 112 Postcode/City: GR-15669 Province/Country: Attiki Architecture: Athanasia Roditi Street: Chryssanthemon 18 Glyka Nera

Postcode/City: GR-15354 Province/Country: Attiki

Aggeliki Stathopoulou Spetson 18 15344 Gerakas

Postcode/City: GR-45333 Province/Country: Epirus

Energy consultancy: Stefan Pallantzas Street: Anastaseos 112

Year of construction:

2015

No. of dwelling units:

No. of occupants:

GR-Greece

Mechanical system: Ilias Igoumenidis Street: Michael Agelou 44

GR-Greece

Ioannina GR-Greece

Certification: Passive House Institute Street: Rheinstr. 44/46

Papagou, Athen

Postcode/City: GR-15669 Province/Country: Attiki

Papagou, Athen

Interior temperature winter [°C]: 2

Internal heat gains (IHG) heating case [W/m ]: Specific capacity [Wh/K per m² TFA]:

3,2

Darmstadt

Postcode/City: 64283 Province/Country: Hessen

GR-Greece

DE-Germany

20,0

Interior temp. summer [°C]:

25,0

3,0

IHG cooling case [W/m²]:

3,0

204

Mechanical cooling:

Specific building characteristics with reference to the treated floor area Treated floor area m² Space heating

Heating demand kWh/(m²a) Heating load W/m²

Space cooling

Cooling & dehum. demand kWh/(m²a) Cooling load W/m² Frequency of overheating (> 25 °C) %

Frequency excessively high humidity (> 12 g/kg) % Airtightness

Pressurization test result n50 1/h

Non-renewable Primary Energy (PE) Primary Energy Renewable (PER)

PE demand kWh/(m²a)

PER demand kWh/(m²a) Generation of renewable kWh/(m²a) energy

Criteria

Alternative criteria

11 11

≤

12 10 5

≤

114,6

yes yes

≤

yes

0,6

≤

1,0

yes

≤

51 24

≤

≥

yes 2

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. Task: First name: Susanne Theumer 2-Certifier Certificate ID Issued on: Darmstadt 13070-13071_PHI_EP_20160205_STh 05/02/16

PHPP, Verification

Fullfilled?2

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

EnerPHit Classic? Surname:

yes Signature:

City:

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

PHPP Check

EnerPHit with PHPP Version 9.3

Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

▼ Overview input errors Congratulations! There are no error messages in your PHPP. Verification Climate U-Values Areas Ground Components Windows Shading Ventilation Addl vent SummVent Cooling units DHW+Distribution SolarDHW PV Electricity Use non-res Electricity non-res Aux Electricity IHG IHG non-res PER Compact HP HP Ground Boiler District heating

▼ Are results missing from 'Verification' worksheet? Possible causes can be found next

â&#x2013;ź The following information is based on the energy balance calculation entered â&#x2013;ź Plausibility check

EnerPHit with PHPP Version 9.3

Climate data Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Country: ud-Eigene Daten

Annual heating demand

11,4

kWh/(m²a)

Heating load

10,8

W/m²

Region: Alle

Frequency of overheating

1-Sortierung: Alphabetisch

Climate data set: ud---03-Athens-Jessica Climate zone: 5: Warm

Altitude Weather station:

15,0

Building location:

244

Sensible cooling

11,0

% kWh/(m²a)

Latent cooling

1,2

kWh/(m²a)

Cooling load

9,6

W/m²

PER demand

51,0

kWh/(m²a)

Heating / cooling period

113

250

Data from monthly balance Heating Cooling 181

30 °C

184

d/a

200

Heating / cooling degree hours

-12

kKh/a

Radiation North

176

373

kWh/(m²a)

Radiation East

170

511

671

kWh/(m²a)

Radiation South

340

554

655

kWh/(m²a)

Radiation West

176

211

429

kWh/(m²a)

Horizontal radiation

276

570

1131

kWh/(m²a)

20 150 15 100 kWh/(m²month)

Data for heating Annual method

Result overview

Selection of climate data

Radiation North

Radiation South

°C kWh/(m²month) kWh/(m²month) kWh/(m²month) kWh/(m²month) kWh/(m²month) °C °C °C

PHPP, Climate

1 31

2 28

3 31

4 30

5 31

ud---03-Athens-Jessica

Latitude °

37,9

Longitude °

23,7

Altitude [m]

Exterior temperature Radiation North Radiation East Radiation South Radiation West Horizontal radiation Dew point temperature Sky temperature Ground temperature Comment:

8,5 8,5 11,3 14,3 16 20 29 36 45 44 79 98 106 88 120 105 43 48 79 95 66 76 132 168 4,7 4,3 6,4 8,4 -2,3 -1,7 0,1 2,2 17,1 16,3 16,2 16,8 Source: Meteonorm V7 (Hellenkion, new period). Load data by PHI.

19,2 46 115 92 115 206 11,5 6,5 17,9

6 30

7 31

15 24,3 51 121 84 119 224 14,3 10,4 21,0

8 31

9 30

Daily temperature swing Summer [K] 27,0 49 129 91 124 232 15,7 12,6 22,2

27,0 39 123 112 121 210 15,6 11,1 23,0

22,3 30 86 120 92 153 14,7 10,5 23,1

10 31

Horizontal radiation

Exterior temperature

Dew point temperature

0 2

11 30

12 31

13,7 18 46 112 54 75 10,0 3,9 19,6

10,0 15 33 85 39 53 6,4 0,0 18,3

8,4 18,2 26 65 114 64 106 12,5 8,1 20,7

Radiation West

1 Month Days

Radiation East

Heating load Weather 1 Weather 2 Radiation: [W/m²] 4,2 30 55 100 50 95

4,8 25 30 40 35 55

16,2

Cooling load Weather 1 Weather 2

PER factors

Radiation: [W/m²] 30,7 70 165 165 165 340 18,6 16,5 23,1

26,5 55 150 220 145 265 20,0 20,0 23,1

1,20 1,20 1,60 1,50 2,00

Household electricity Domestic hot water Heating Cooling Dehumidification

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

U-value of building assemblies

Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 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?

Ext.wall_brick

01ud

Heat transmission resistance [m²K/W]

2-Wand Adjacent to 1-Außenluft

interior Rsi

Orientation of building element

l [W/(mK)]

Area section 1

exterior Rse:

Area section 2 (optional)

0,13 0,04 l [W/(mK)] Area section 3 (optional)

l [W/(mK)]

Thickness [mm]

0,872 0,640 0,430 0,640 0,872 0,030 0,350

interior plaster perforated brick wall still air space perforated brick wall exterior plaster EXT. INSULATION acrylic plaster

30 60 80 60 30 150 4

Percentage of sec. 1

Percentage of sec. 2

Percentage of sec. 3

Total

41,4

100%

U-value supplement

U-value:

W/(m²K)

0,178

Assembly no.

W/(m²K)

Interior insulation?

02ud

Ext.wall.stone.air Heat transmission resistance [m²K/W]

2-Wand Adjacent to 1-Außenluft

interior Rsi

Orientation of building element

l [W/(mK)]

Area section 1

exterior Rse:

Area section 2 (optional)

0,13 0,04 l [W/(mK)] Area section 3 (optional)

l [W/(mK)]

Thickness [mm]

0,872 2,000 0,872 0,030 0,350

interior plaster natural stone exterior plaster EXT. INSULATION acrylic plaster

30 500 30 150 4

Percentage of sec. 1

Percentage of sec. 2

Percentage of sec. 3

Total

71,4

100%

U-value supplement

U-value:

W/(m²K)

0,182

Assembly no.

W/(m²K)

Interior insulation?

03ud

Ext.wall.stone.ground

Heat transmission resistance [m²K/W] Orientation of building element Adjacent to

2-Wand 2-Erdreich l [W/(mK)]

Area section 1

interior Rsi exterior Rse:

Area section 2 (optional)

0,13 0,00 l [W/(mK)] Area section 3 (optional)

l [W/(mK)]

Thickness [mm]

plaster natural stone INTERIOR INSULATION

0,872 2,000 0,030

0 500 50

gypsum board

0,210

gypsum plaster

0,250

Percentage of sec. 1

Percentage of sec. 2

Percentage of sec. 3

Total

57,0

100%

U-value supplement

PHPP, U-Values

W/(m²K)

U-value:

0,470

W/(m²K)

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Wärmeleitfähigkeit l

Assembly no.

Interior insulation?

04ud

Ext.wall.conc.20 Heat transmission resistance [m²K/W]

2-Wand Adjacent to 1-Außenluft

interior Rsi

Orientation of building element

l [W/(mK)]

Area section 1

exterior Rse:

Area section 2 (optional)

0,13 0,04 l [W/(mK)] Area section 3 (optional)

l [W/(mK)]

Thickness [mm]

0,872 2,100 0,872 0,030 0,350

interior plaster reinforced concrete exterior plaster EXT. INSULATION acrylic plaster

30 200 30 150 4

Percentage of sec. 1

Percentage of sec. 2

Percentage of sec. 3

Total

41,4

100%

U-value supplement

U-value:

W/(m²K)

0,187

Assembly no.

W/(m²K)

Interior insulation?

05ud

Ext.wall.conc.25 Heat transmission resistance [m²K/W]

2-Wand Adjacent to 1-Außenluft

interior Rsi

Orientation of building element

l [W/(mK)]

Area section 1

exterior Rse:

Area section 2 (optional)

0,13 0,04 l [W/(mK)] Area section 3 (optional)

l [W/(mK)]

Thickness [mm]

interior plaster reinforced concrete exterior plaster

0,872 2,100 0,872

20 250 30

EXT. INSULATION

0,030

150

acrylic plaster

0,350

Percentage of sec. 1

Percentage of sec. 2

Percentage of sec. 3

Total

45,4

100%

U-value supplement

U-value:

W/(m²K)

0,187

Assembly no.

W/(m²K)

Interior insulation?

06ud

Ext.wall.conc.30 Heat transmission resistance [m²K/W]

2-Wand Adjacent to 1-Außenluft

interior Rsi

Orientation of building element

l [W/(mK)]

Area section 1

exterior Rse:

Area section 2 (optional)

0,13 0,04 l [W/(mK)] Area section 3 (optional)

l [W/(mK)]

Thickness [mm]

0,872 2,100 0,872 0,030 0,350

interior plaster reinforced concrete exterior plaster EXT. INSULATION acrylic plaster

20 300 30 150 4

Percentage of sec. 1

Percentage of sec. 2

Percentage of sec. 3

Total

50,4

100%

U-value supplement

PHPP, U-Values

W/(m²K)

U-value:

0,186

W/(m²K)

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Wärmeleitfähigkeit l

Assembly no.

Interior insulation?

07ud

GF floor slab_wood Heat transmission resistance [m²K/W]

1-Dach Adjacent to 1-Außenluft

interior Rsi

Orientation of building element

l [W/(mK)]

Area section 1

exterior Rse:

Area section 2 (optional)

2,100 0,250 0,180 0,210 0,030 0,024 0,130

reinforced concrete wooden supports wooden rafts PARQUET INSULATION membrane laminate floor

l [W/(mK)] Area section 3 (optional)

l [W/(mK)]

Thickness [mm]

130 55 15 20 50 2 8

0,170

Percentage of sec. 1

Percentage of sec. 2

Percentage of sec. 3

Total

28,0

12,0%

88%

U-value supplement

0,13 0,04

U-value:

W/(m²K)

0,408

Assembly no.

W/(m²K)

Interior insulation?

08ud

BAS floor slab Heat transmission resistance [m²K/W]

3-Boden Adjacent to 2-Erdreich

interior Rsi

Orientation of building element

l [W/(mK)]

Area section 1

exterior Rse:

Area section 2 (optional)

0,13 0,00 l [W/(mK)] Area section 3 (optional)

l [W/(mK)]

Thickness [mm]

2,100 1,400 1,200 0,030 0,024 0,130

reinforced concrete screed concrete old mosaic INSULATION membrane laminate floor

130 50 30 50 2 8

Percentage of sec. 1

Percentage of sec. 2

Percentage of sec. 3

Total

27,0

100%

U-value supplement

U-value:

W/(m²K)

0,484

Assembly no.

W/(m²K)

Interior insulation?

09ud

roof slab Heat transmission resistance [m²K/W]

1-Dach Adjacent to 1-Außenluft

interior Rsi

Orientation of building element

l [W/(mK)]

Area section 1

exterior Rse:

Area section 2 (optional)

0,13 0,04 l [W/(mK)] Area section 3 (optional)

l [W/(mK)]

Thickness [mm]

0,872 2,100 1,400 0,031

plaster reinforced concrete screed concrete EXT. INSULATION

20 130 50 300

Percentage of sec. 1

Percentage of sec. 2

Percentage of sec. 3

Total

50,0

100%

U-value supplement

PHPP, U-Values

W/(m²K)

U-value:

0,100

W/(m²K)

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Assembly no.

Interior insulation?

10ud

GF floor slab_tiles Heat transmission resistance [m²K/W]

3-Boden Adjacent to 2-Erdreich

interior Rsi

Orientation of building element

l [W/(mK)]

Area section 1

exterior Rse:

Area section 2 (optional)

0,13 0,00 l [W/(mK)] Area section 3 (optional)

l [W/(mK)]

Thickness [mm]

2,100 1,400 1,200 0,030 0,024 0,130

reinforced concrete screed concrete old mosaic INSULATION membrane laminate floor

130 60 30 50 2 7

Percentage of sec. 1

Percentage of sec. 2

Percentage of sec. 3

Total

27,9

100%

U-value supplement

U-value:

W/(m²K)

0,485

Assembly no.

W/(m²K)

Interior insulation?

11ud

front door basement Heat transmission resistance [m²K/W]

2-Wand Adjacent to 1-Außenluft

interior Rsi

Orientation of building element

l [W/(mK)]

Area section 1

Aluplast pvc front door

exterior Rse:

Area section 2 (optional)

0,13 0,04 l [W/(mK)] Area section 3 (optional)

l [W/(mK)]

Thickness [mm]

0,125 0,035

60 21

Percentage of sec. 1

Percentage of sec. 2

Percentage of sec. 3

Total

8,1

100%

U-value supplement

U-value:

W/(m²K)

0,800

Assembly no.

W/(m²K)

Interior insulation?

12ud

Ext.wall.stone.air_int.insul. Heat transmission resistance [m²K/W]

2-Wand Adjacent to 1-Außenluft

interior Rsi

Orientation of building element

l [W/(mK)]

Area section 1

gypsum plaster INTERIOR INSULATION interior plaster natural stone exterior plaster EXT. INSULATION acrylic plaster

exterior Rse:

Area section 2 (optional)

0,13 0,04 l [W/(mK)] Area section 3 (optional)

l [W/(mK)]

Thickness [mm]

0,250 0,030 0,872 2,000 0,872 0,030 0,350

20 50 30 500 30 150 4

Percentage of sec. 1

Percentage of sec. 2

Percentage of sec. 3

Total

78,4

100%

U-value supplement

PHPP, U-Values

W/(m²K)

U-value:

0,138

W/(m²K)

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Assembly no.

Interior insulation?

13ud Heat transmission resistance [m²K/W] Orientation of building element

interior Rsi

Adjacent to

exterior Rse: l [W/(mK)]

Area section 1

Area section 2 (optional)

Percentage of sec. 1

l [W/(mK)] Area section 3 (optional)

Percentage of sec. 2

l [W/(mK)]

Percentage of sec. 3

Thickness [mm]

Total

100%

U-value supplement

U-value:

W/(m²K)

Assembly no.

Interior insulation?

14ud Heat transmission resistance [m²K/W] Orientation of building element

interior Rsi

Adjacent to

exterior Rse: l [W/(mK)]

Area section 1

Area section 2 (optional)

Percentage of sec. 1

l [W/(mK)] Area section 3 (optional)

Percentage of sec. 2

l [W/(mK)]

Percentage of sec. 3

Thickness [mm]

Total

100%

U-value supplement

U-value:

W/(m²K)

Assembly no.

Interior insulation?

15ud Heat transmission resistance [m²K/W] Orientation of building element

interior Rsi

Adjacent to

exterior Rse: l [W/(mK)]

Area section 1

Area section 2 (optional)

Percentage of sec. 1

l [W/(mK)] Area section 3 (optional)

Percentage of sec. 2

l [W/(mK)]

Percentage of sec. 3

Thickness [mm]

Total

100%

U-value supplement

PHPP, U-Values

W/(m²K)

U-value:

W/(m²K)

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Assembly no.

Interior insulation?

16ud Heat transmission resistance [m²K/W] Orientation of building element

interior Rsi

Adjacent to

exterior Rse: l [W/(mK)]

Area section 1

Area section 2 (optional)

Percentage of sec. 1

l [W/(mK)] Area section 3 (optional)

Percentage of sec. 2

l [W/(mK)]

Percentage of sec. 3

Thickness [mm]

Total

100%

U-value supplement

U-value:

W/(m²K)

Assembly no.

Interior insulation?

17ud Heat transmission resistance [m²K/W] Orientation of building element

interior Rsi

Adjacent to

exterior Rse: l [W/(mK)]

Area section 1

Area section 2 (optional)

Percentage of sec. 1

l [W/(mK)] Area section 3 (optional)

Percentage of sec. 2

l [W/(mK)]

Percentage of sec. 3

Thickness [mm]

Total

100%

U-value supplement

U-value:

W/(m²K)

Assembly no.

Interior insulation?

18ud Heat transmission resistance [m²K/W] Orientation of building element

interior Rsi

Adjacent to

exterior Rse: l [W/(mK)]

Area section 1

Area section 2 (optional)

Percentage of sec. 1

l [W/(mK)] Area section 3 (optional)

Percentage of sec. 2

l [W/(mK)]

Percentage of sec. 3

Thickness [mm]

Total

100%

U-value supplement

PHPP, U-Values

W/(m²K)

U-value:

W/(m²K)

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Assembly no.

Interior insulation?

19ud Heat transmission resistance [m²K/W] Orientation of building element

interior Rsi

Adjacent to

exterior Rse: l [W/(mK)]

Area section 1

Area section 2 (optional)

Percentage of sec. 1

l [W/(mK)] Area section 3 (optional)

Percentage of sec. 2

l [W/(mK)]

Percentage of sec. 3

Thickness [mm]

Total

100%

U-value supplement

U-value:

W/(m²K)

Assembly no.

Interior insulation?

20ud Heat transmission resistance [m²K/W] Orientation of building element

interior Rsi

Adjacent to

exterior Rse: l [W/(mK)]

Area section 1

Area section 2 (optional)

Percentage of sec. 1

l [W/(mK)] Area section 3 (optional)

Percentage of sec. 2

l [W/(mK)]

Percentage of sec. 3

Thickness [mm]

Total

100%

U-value supplement

PHPP, U-Values

W/(m²K)

U-value:

W/(m²K)

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

PHPP, U-Values

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

PHPP, U-Values

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

PHPP, U-Values

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

PHPP, U-Values

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

PHPP, U-Values

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Certified building systems ► Exception ►

EnerPHit with PHPP Version 9.3

Areas determination Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Summary Temp.zone A A A A A A A B A B

Area group Treated floor area North windows East windows South windows West windows Horizontal windows Exterior door External wall - Ambient External wall - Ground Roof/Ceiling - Ambient Floor slab / Basement ceiling

Group no. 1 2 3 4 5 6 7 8 9 10 11 12 13 14

A P B

Thermal bridges Ambient Perimeter thermal bridges Thermal bridges FS/BC

15 16 17

Building element towards neighbour

Building assembly overview Comment

Area / Length

Unit

114,60 4,62 4,68 9,09 6,77 0,00 4,72 195,01 21,12 105,60 105,59 0,00 0,00 0,00

m² m² m² m² m² m² m² m² m² m² m² m² m² m²

Treated floor area according to PHPP manual

116,28 51,06 17,76

m m m

Units in m Units in m; temperature zone "P" is perimeter (see 'Ground' worksheet) Units in m

Thermal bridges - Overview Thermal bridges Ambient Perimeter thermal bridges Thermal bridges FS/BC

0,00

m²

No heat losses, only considered for the heating load calculation

Building element towards neighbour

457,21

m²

Total thermal envelope

Average Uvalue [W/(m²K)] 0,618 1,125 1,065 0,804

North windows East windows South windows West windows Horizontal windows Exterior door External wall - Ambient External wall - Ground Roof/Ceiling - Ambient Floor slab / Basement ceiling

Results come from the 'Windows' worksheet. Window areas are subtracted from individual opaque areas. which is displayed in the 'Windows' worksheet. Please subtract area of door from respective building assembly Temperature zone "A" is ambient air Temperature zone "B" is the ground

Temperature zones "A", "B","P" and "X" may be used. NOT "I" Temperature zones "A", "B","P" and "X" may be used. NOT "I" Temperature zone "X": Please provide user-defined reduction factor ( 0 < ft < 1):

0,920 0,177 0,470 0,100 0,452

Radiationgains heating season [kWh/a] 6 Months 119 317 636 185

Radiationload cooling period [kWh/a] 6 Months 278 151 397 482

149

369

Factor for X 75% Y [W/(mK)] 0,018 0,196 0,403

Average therm. envelope

0,327

Go to building components list

Area input Area no.

Building assembly description

To group No.

Assigned to group

Quanx( tity

1 2 3 4 5 6 7 8 9 10

Projected building footprint Treated floor area Exterior door N/E.gf.br_1 N/E.gf.br_2 N/E.gf.br_3 N/E.gf.con30_1 N/E.gf.con30_2 N/E.gf.con30_3 N/E.gf.con20_1 N/E.gf.con20_2 N/E.gf.con20_3 N/E.gf.con25_1

0 1 7 8 8 8 8 8 8 8 8 8 8

Projected building footprint Treated floor area Exterior door External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient

1 1 1 1 1 1 1 1 1 1 1 1 1

x x x x x x x x x x x x x

N/E.bas.s/a_1

External wall - Ambient

12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32

N/E.bas.s/g_2 N/W.gf.br_4 N/W.gf.br_5 N/W.gf.con30_4 N/W.gf.con30_5 N/W.gf.con30_6 N/W.gf.con20_4 N/W.gf.con20_5 N/W.bas.s/a_4 N/W.bas.br_3 S/W.gf.br_6 S/W.gf.br_7 S/W.gf.br_8 S/W.gf.br_9 S/W.gf.con30_7 S/W.gf.con30_8 S/W.gf.con30_9 S/W.gf.con20_6 S/W.gf.con20_7 S/W.gf.con20_8 S/W.gf.con20_9

9 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8

External External External External External External External External External External External External External External External External External External External External External

1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1

x x x x x x x x x x x x x x x x x x x x x

PHPP, Areas

wall wall wall wall wall wall wall wall wall wall wall wall wall wall wall wall wall wall wall wall wall

- Ground - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient - Ambient

( ( ( ( ( ( ( ( ( ( ( ( (

( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (

a [m]

1,34

Sort: BY ID

x x x x x x x x x x x x x x

b [m]

User determined [m²]

+ + + + + + + + + + + + +

105,60 114,60 11,53 6,80 16,05 1,51 1,51 1,51 2,27 1,34 3,16 0,84

5,00

x x x x x x x x x x x x x x x x x x x x x

+ + + + + + + + + + + + + + + + + + + + +

3,17 11,26 11,20 1,51 1,51 1,51 1,75 1,74 8,97 9,45 6,66 9,03 10,02 9,28 1,51 1,51 1,51 1,17 1,59 1,76 1,63

2,12

User subtraction [m²]

Subtraction window areas ) = [m²]

Area [m²] 105,6 114,6 2,8 11,5 4,0 11,4 1,5 1,5 1,5 2,3 1,3 3,2 0,8

U-Value [W/(m²K)]

Deviation from North

Angle of inclination from the horizontal

Orientation

Reduction factor shading

Exterior absorptivity

Exterior emissivity

Exterior door 01ud Ext.wall_brick 01ud Ext.wall_brick 01ud Ext.wall_brick 06ud Ext.wall.conc.30 06ud Ext.wall.conc.30 06ud Ext.wall.conc.30 04ud Ext.wall.conc.20 04ud Ext.wall.conc.20 04ud Ext.wall.conc.20 05ud Ext.wall.conc.25

1,00 0,178 0,178 0,178 0,186 0,186 0,186 0,187 0,187 0,187 0,187

40 40 40 40 40 40 40 40 40 40

90 90 90 90 90 90 90 90 90 90

North North North North North North North North North North

0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70

0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40

0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90

Selection building assembly / Building system

) ) )))))))))))-

0,0 0,0 4,6 0,0 0,0 0,0 0,0 0,0 0,0 0,0

= = = = = = = = = = = = =

0,0

5,0

12ud-Ext.wall.stone.air_int.insul.

0,138

North

0,70

0,40

0,90

)))))))))))))))))))))-

0,0 0,0 3,5 0,0 0,0 0,0 0,0 0,0 1,5 1,8 3,1 3,2 2,8 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0

= = = = = = = = = = = = = = = = = = = = =

3,2 11,3 7,7 1,5 1,5 1,5 1,8 1,7 7,5 7,7 3,6 5,9 7,2 9,3 1,5 1,5 1,5 1,2 1,6 1,8 1,6

03ud Ext.wall.stone.ground 01ud Ext.wall_brick 01ud Ext.wall_brick 06ud Ext.wall.conc.30 06ud Ext.wall.conc.30 06ud Ext.wall.conc.30 04ud Ext.wall.conc.20 04ud Ext.wall.conc.20 02ud Ext.wall.stone.air 01ud Ext.wall_brick 01ud Ext.wall_brick 01ud Ext.wall_brick 01ud Ext.wall_brick 01ud Ext.wall_brick 06ud Ext.wall.conc.30 06ud Ext.wall.conc.30 06ud Ext.wall.conc.30 04ud Ext.wall.conc.20 04ud Ext.wall.conc.20 04ud Ext.wall.conc.20 04ud Ext.wall.conc.20

0,470 0,178 0,178 0,186 0,186 0,186 0,187 0,187 0,182 0,178 0,178 0,178 0,178 0,178 0,186 0,186 0,186 0,187 0,187 0,187 0,187

40 310 310 310 310 310 310 310 310 310 220 220 220 220 220 220 220 220 220 220 220

90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90 90

North West West West West West West West West West South South South South South South South South South South South

0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70

0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40

0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90

2,83

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Certified building systems ► Exception ►

EnerPHit with PHPP Version 9.3

Areas determination Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Summary Temp.zone A A A A A A A B A B

Group no. 1 2 3 4 5 6 7 8 9 10 11 12 13 14

A P B

Thermal bridges Ambient Perimeter thermal bridges Thermal bridges FS/BC

15 16 17

Building element towards neighbour

Total thermal envelope

Building assembly overview Comment

Area / Length

Unit

114,60 4,62 4,68 9,09 6,77 0,00 4,72 195,01 21,12 105,60 105,59 0,00 0,00 0,00

m² m² m² m² m² m² m² m² m² m² m² m² m² m²

Treated floor area according to PHPP manual

116,28 51,06 17,76

m m m

Units in m Units in m; temperature zone "P" is perimeter (see 'Ground' worksheet) Units in m

Thermal bridges - Overview Thermal bridges Ambient Perimeter thermal bridges Thermal bridges FS/BC

0,00

m²

No heat losses, only considered for the heating load calculation

Building element towards neighbour

457,21

m²

Average Uvalue [W/(m²K)] 0,618 1,125 1,065 0,804

North windows East windows South windows West windows Horizontal windows Exterior door External wall - Ambient External wall - Ground Roof/Ceiling - Ambient Floor slab / Basement ceiling

0,920 0,177 0,470 0,100 0,452

Radiationgains heating season [kWh/a] 6 Months 119 317 636 185

Radiationload cooling period [kWh/a] 6 Months 278 151 397 482

149

369

Factor for X 75% Y [W/(mK)] 0,018 0,196 0,403

Average therm. envelope

0,327

Go to building components list )))-

0,0 0,0 0,0

= = =

0,8 0,8 3,2

05ud Ext.wall.conc.25 05ud Ext.wall.conc.25 01ud Ext.wall_brick

0,187 0,187 0,178

220 220 220

90 90 90

South South South

0,70 0,70 0,70

0,40 0,40 0,40

0,90 0,90 0,90

0,0

8,1

12ud-Ext.wall.stone.air_int.insul.

0,138

220

South

0,70

0,40

0,90

))))))))))))))-

2,3 2,3 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0

= = = = = = = = = = = = = =

8,7 6,2 1,9 1,5 1,0 1,5 1,7 1,3 0,3 0,8 18,0 105,6 44,3 14,4

01ud Ext.wall_brick 01ud Ext.wall_brick 01ud Ext.wall_brick 06ud Ext.wall.conc.30 06ud Ext.wall.conc.30 06ud Ext.wall.conc.30 04ud Ext.wall.conc.20 04ud Ext.wall.conc.20 04ud Ext.wall.conc.20 05ud Ext.wall.conc.25 03ud Ext.wall.stone.ground 09ud roof slab 07ud GF floor slab_wood 10ud GF floor slab_tiles

0,178 0,178 0,178 0,186 0,186 0,186 0,187 0,187 0,187 0,187 0,470 0,100 0,408 0,485

130 130 130 130 130 130 130 130 130 130 130 220

90 90 90 90 90 90 90 90 90 90 90 0

East East East East East East East East East East East Hor

0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70 0,70

0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40 0,40

0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90 0,90

0,90

33 34 35

S/W.gf.con25_2 S/W.gf.con25_3 S/W.bas.br_5

8 8 8

External wall - Ambient External wall - Ambient External wall - Ambient

1 1 1

x( x( x(

x x x

+ + +

0,84 0,84 5,09

S/W.bas.s/a_6

External wall - Ambient

8,14

37 38 39 40 41 42 43 44 45 46 47 48 49 50

S/E.gf.br_10 S/E.gf.br_11 S/E.gf.br_12 S/E.gf.con30_10 S/E.gf.con30_11 S/E.gf.con30_12 S/E.gf.con20_10 S/E.gf.con20_11 S/E.gf.con20_12 S/E.gf.con25_4 S/E.bas.s/g_7 ROOF SLAB GF floor slab wood GF floor slab tiles

8 8 8 8 8 8 8 8 8 8 9 10 11 11

External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ambient External wall - Ground Roof/Ceiling - Ambient Floor slab / Basement ceiling Floor slab / Basement ceiling

1 1 1 1 1 1 1 1 1 1 1 1 1 1

x x x x x x x x x x x x x x

+ + + + + + + + + + + + + +

11,01 8,53 1,94 1,51 1,00 1,51 1,71 1,32 0,30 0,84 17,95 105,60 44,32 14,44

( ( ( ( ( ( ( ( ( ( ( ( ( (

1,88

Aend

PHPP, Areas

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Certified building systems ► Exception ►

Areas determination Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Summary Temp.zone A A A A A A A B A B

Group no. 1 2 3 4 5 6 7 8 9 10 11 12 13 14

A P B

Thermal bridges Ambient Perimeter thermal bridges Thermal bridges FS/BC

15 16 17

Building element towards neighbour

Total thermal envelope

Building assembly overview Comment

Area / Length

Unit

114,60 4,62 4,68 9,09 6,77 0,00 4,72 195,01 21,12 105,60 105,59 0,00 0,00 0,00

m² m² m² m² m² m² m² m² m² m² m² m² m² m²

Treated floor area according to PHPP manual

116,28 51,06 17,76

m m m

Units in m Units in m; temperature zone "P" is perimeter (see 'Ground' worksheet) Units in m

Thermal bridges - Overview Thermal bridges Ambient Perimeter thermal bridges Thermal bridges FS/BC

0,00

m²

No heat losses, only considered for the heating load calculation

Building element towards neighbour

457,21

m²

Average Uvalue [W/(m²K)]

Please subtract area of door from respective building assembly Temperature zone "A" is ambient air Temperature zone "B" is the ground

0,618 1,125 1,065 0,804

North windows East windows South windows West windows Horizontal windows Exterior door External wall - Ambient External wall - Ground Roof/Ceiling - Ambient Floor slab / Basement ceiling

Results come from the 'Windows' worksheet. Window areas are subtracted from individual opaque areas. which is displayed in the 'Windows' worksheet.

0,920 0,177 0,470 0,100 0,452

Radiationgains heating season [kWh/a] 6 Months 119 317 636 185

46 149

Factor for X 75% Y [W/(mK)] 0,018 0,196 0,403

Average therm. envelope

0,327

Go to building components list

Thermal bridge inputs No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37

PHPP, Areas

Thermal bridge denomination ext. corner_GF int. corner_GF ext. corner_BAS int. corner_GF 1a BAS.int.stonewall-floor 1b BAS.int.stonewall-ceiling 2 BAS.ext.wall-ground 3a sit.BALKONY-wooden floor 3b sit.BALKONY-mosaic floor 4a kitc.BALKONY-basement 4b kitc.BALKONY-ground 5 entrance.VERANDA-floor 6a GF slab.per.-wooden floor 6b GF slab.per.-mosaic floor 7 ROOF parapet & fin 8 ROOF parapet 9 GF slab / column 10 GF slab / int.wall 11 BAS.int.stonewall-corner 12 BAS.int.stonewall-wc corner

Group No. 15 15 15 15 16 16 16 15 15 15 15 16 15 15 15 15 17 17 16 15

Assigned to group Thermal bridges Ambient Thermal bridges Ambient Thermal bridges Ambient Thermal bridges Ambient Perimeter thermal bridges Perimeter thermal bridges Perimeter thermal bridges Thermal bridges Ambient Thermal bridges Ambient Thermal bridges Ambient Thermal bridges Ambient Perimeter thermal bridges Thermal bridges Ambient Thermal bridges Ambient Thermal bridges Ambient Thermal bridges Ambient Thermal bridges FS/BC Thermal bridges FS/BC Perimeter thermal bridges Thermal bridges Ambient

Quan x( tity 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1

x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x x

( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( (

Length [m] 23,40 7,54 6,90 2,18 8,92 8,92 22,37 2,70 3,32 2,29 1,20 8,22 12,14 2,03 20,96 29,09 0,40 17,36 2,63 2,53

Sortierung ändern

Subtraction length )= [m] )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )= )=

Length l [m] 23,40 7,54 6,90 2,18 8,92 8,92 22,37 2,70 3,32 2,29 1,20 8,22 12,14 2,03 20,96 29,09 0,40 17,36 2,63 2,53

User determined Y-Wert [W/(mK)] -0,150 0,050 -0,100 0,050 -0,375 0,430 0,381 0,273 0,534 0,336 0,233 0,089 -0,080 -0,044 0,096 0,034 1,263 0,383 0,100 0,100

User determined f Rsi=0,25 (optional)

or or or or or or or or or or or or or or or or or or or or or or or or or or or or or or or or or or or or or or

Selection building system

Y-Value [W/(mK)]

f Rsi-Requirement met?

-0,150 0,050 -0,100 0,050 -0,375 0,430 0,381 0,273 0,534 0,336 0,233 0,089 -0,080 -0,044 0,096 0,034 1,263 0,383 0,100 0,100

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Certified building systems ► Exception ►

Areas determination Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Summary Temp.zone A A A A A A A B A B

Group no. 1 2 3 4 5 6 7 8 9 10 11 12 13 14

A P B

Thermal bridges Ambient Perimeter thermal bridges Thermal bridges FS/BC

15 16 17

Building element towards neighbour

Total thermal envelope

Building assembly overview Comment

Area / Length

Unit

114,60 4,62 4,68 9,09 6,77 0,00 4,72 195,01 21,12 105,60 105,59 0,00 0,00 0,00

m² m² m² m² m² m² m² m² m² m² m² m² m² m²

Treated floor area according to PHPP manual

[W/(m²K)]

116,28 51,06 17,76

m m m

Units in m Units in m; temperature zone "P" is perimeter (see 'Ground' worksheet) Units in m

Thermal bridges - Overview Thermal bridges Ambient Perimeter thermal bridges Thermal bridges FS/BC

0,00

m²

No heat losses, only considered for the heating load calculation

Building element towards neighbour

457,21

m²

North windows East windows South windows West windows Horizontal windows Exterior door External wall - Ambient External wall - Ground Roof/Ceiling - Ambient Floor slab / Basement ceiling

Average Uvalue

0,618 1,125 1,065 0,804 0,920 0,177 0,470 0,100 0,452

Radiationgains heating season [kWh/a] 6 Months 119 317 636 185

46 149

Factor for X 75%

Average therm. envelope

Y [W/(mK)] 0,018 0,196 0,403 0,327

Go to building components list 38 39 40 41 42 43 44 45 46 47 48 49 50 TBend

PHPP, Areas

x x x x x x x x x x x x x

( ( ( ( ( ( ( ( ( ( ( ( (

)= )= )= )= )= )= )= )= )= )= )= )= )=

or or or or or or or or or or or or or

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Heat losses through the ground Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Building section 1 Ground characteristics

Climate data

l rc d

Thermal conductivity Heat capacity Periodic penetration depth

2,0 3,0

W/(mK)

Avg indoor temp. winter

MJ/(m³K)

Avg indoor temp. summer

2,59

Avg ground surface temperature

Ti Ti Tg,ave Tg,^ t n

Amplitude of Tg,ave Phase shifting of Te,m Length of the heating period Heating degree hours - exterior

55,8 22,3

m²

5,01

Uf YB*l U-value floor slab / basement ceiling incl. Uf' TBs Equivalent thickness floor dt

0,50 0,05 0,030

Orientation of perimeter insulation

(check only one field)

Building data

U-value floor slab/basement ceiling

Area of ground floor slab / basement ceilingA

P B'

Perimeter length Charact. dimension of floor slab

TBs floor slab / basement ceiling

20,0 25,0 18,1 9,3 1,4 3,7 30,8

°C °C °C °C Months Months kKh/a

0,447 0,00

W/(m²K)

0,447

W/(m²K)

4,47

W/K

Floor slab type (select only one) x Slab on grade

D dn ln

Perimeter insulation width/depth Perimeter insulation thickness Conductivity perimeter insulation

horizontal

vertical

W/(mK)

Heated basement or floor slab completely / partially below ground level Basement wall height below ground level

U-Value wall below ground

UwB

W/(m²K)

h z n V

U-Value wall above ground U-Value wall below ground

UW UWB

W/(m²K)

m h-1

U-Value basement floor slab

UfB

W/(m²K)

Area of ventilation openings

Wind velocity at 10 m height Wind shield factor

4,0 0,05

m/s

W/(m²K)

eP v fW YP,stat*l YP,harm*l

0,000 0,000

W/K

Unheated basement Height aboveground wall Basement wall height below ground level Air change unheated basement Air flow basement

0,20

W/(m²K)

m³

Suspended floor above a ventilated crawl space (at max. 0.5 m below ground)

UCrawl h UW

U-Value crawl space Height of crawl space wall U-Value crawl space wall

Additional thermal bridge heat losses at perimeter

Steady-state fraction

Phase shift

Months

Harmonic fraction

m² -

W/K

Groundwater correction Depth of the groundwater table

Groundwater flow rate

6,0 0,05

Groundwater correction factor

Steady-state heat flow

Fstat Fharm Qtot

1,00086957 -

m/d

Interim results

b LS Lpe L0

Phase shift Steady-state transmittance Exterior periodic transmittance Transmittance building

1,31 Months 16,08 W/K

Periodic heat flow

7,03 W/K

Heat losses during heating period

31,3 W 42,8 W 201 kWh

24,95 W/K

Monthly average temperatures in the ground for monthly method (building assembly 1) Month 1 2 3 4 5 6 Winter 17,1 16,3 16,2 16,7 17,8 19,2 Summer 18,9 18,1 18,0 18,5 19,6 21,0 Design ground temperature for 'Heating load' worksheet

7 20,4 22,2

8 21,2 23,0

16,2

9 21,3 23,1

10 20,7 22,5

11 19,6 21,4

For 'Cooling load' worksheet

Reduction factor for 'Annual heating' worksheet

12 18,3 20,1

Avg. value 18,7 20,5

23,1 0,26

Total result (all building parts) b LS Lpe L0

Phase shift Steady-state transmittance Exterior periodic transmittance Transmittance building

42,09 W/K

Periodic heat flow

18,31 W/K

Heat losses during heating period

Fstat Fharm Qtot

65,30 W/K

Charact. dimension of floor slab

1,30 Months

Steady-state heat flow

82,0 W 111,9 W 526 kWh 4,42 m

Monthly Average temperatures in the ground for monthly method (all building assemblies) Month Winter Summer

1 17,1 18,9

2 16,3 18,1

3 16,2 18,0

4 16,8 18,5

5 17,9 19,6

Design ground temperature for 'Heating load' worksheet

6 19,2 21,0 16,2

7 20,4 22,2

8 21,2 23,0

9 21,3 23,1

11 19,6 21,4

For 'Cooling load' worksheet

Reduction factor for 'Annual heating' worksheet

PHPP, Ground

10 20,7 22,5

12 18,3 20,1

Avg. value 18,7 20,5

23,1

0,26

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

PHPP, Ground

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

PHPP, Ground

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Certified building systems ► EnerPHit with PHPP Version 9.3

Passive House Components

Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) www.passivehouse.com/component-database Go to: 'AREAS' Thermal bridges (Psi-values) Ventilation units Glazing Compact units Window frame Heat recovery DHW

Building assemblies (U-Values) Recommended starting values for optimisation: U-values for walls and roofs | Floor slabs:

0,5 W/(m²K) | 1,1 W/(m²K)

1 ID

Building system

Building assembly

Summary of the constructions calculated in 'U values' worksheet 01ud 02ud 03ud 04ud 05ud 06ud 07ud 08ud 09ud 10ud

Ext.wall_brick Ext.wall.stone.air Ext.wall.stone.ground Ext.wall.conc.20 Ext.wall.conc.25 Ext.wall.conc.30 GF floor slab_wood BAS floor slab roof slab GF floor slab_tiles

PHPP, Components

Ext.wall_brick Ext.wall.stone.air Ext.wall.stone.ground Ext.wall.conc.20 Ext.wall.conc.25 Ext.wall.conc.30 GF floor slab_wood BAS floor slab roof slab GF floor slab_tiles

Total thickness

U-Value

Interior insulation

W/(m²K)

0,414 0,714 0,570 0,414 0,454 0,504 0,280 0,270 0,500 0,279

0,178 0,182 0,470 0,187 0,187 0,186 0,408 0,484 0,100 0,485

0 0 1 0 0 0 0 0 0 0

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Glazing

Glazing Recommended glazing type to start planning: Double thermally insulated glazing (Please consider the comfort criterion!)

Description

g-Value

Ug-Value W/(mÂ˛K)

01ud 02ud 03ud 04ud 05ud 06ud 07ud 08ud 09ud 10ud

Saint-Gobain Glass Deutschland - SGG PLANITHERM ULTRA N II (4:/18/4/18/:4 Ar 90%) Saint-Gobain Glass - SGG PLANITHERM XN (4:/18/4/18/:4 Ar 90%)

PHPP, Components

0,54 0,54

0,55 0,55

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Window frame

Window frame Uf-Value

01ud 02ud 03ud 04ud 05ud 06ud 07ud 08ud 09ud 10ud

Description

EX: timber 45 mm_bf_7 EX: timber 45 mm_bf_11 EX: timber 45 mm_bf_12 EX: timber 45 mm_bf_13.5 EX: timber 45 mm_bf_kitchendoor EX: timber 45 mm_bf_bathroom EX: timber 45 mm_bf_bedroom EX: timber 45 mm_bf_front.windoor EX: timber 45 mm_bf_bas_12 EX: timber 45 mm_bf_bas_9

PHPP, Components

Glazing edge thermal bridge

Frame width

left

right

bottom

above

left

right

W/(m²K)

2,50 2,50 2,50 2,50 2,50 2,50 2,50 2,50 2,50 2,50

0,070 0,110 0,120 0,090 0,100 0,100 0,140 0,050 0,135 0,130

0,075 0,063 0,060 0,045 0,100 0,100 0,070 0,050 0,065 0,065

Curtain wall facades:

Installation thermal bridge

above

YGlazing edge left

YGlazing edge right

YGlazing edge bottom

YGlazing edge top

YInstallation left

YInstallation right

YInstallation bottom

YInstallation top

χGC -value Glass carrier

W/(mK)

W/K

0,070 0,450 0,240 0,135 1,270 0,110 0,130 0,050 0,135 0,090

0,070 0,110 0,120 0,135 0,190 0,100 0,130 0,050 0,120 0,130

0,050 0,050 0,050 0,050 0,050 0,050 0,050 0,050 0,050 0,050

0,040 0,040 0,040 0,040 0,040 0,040 0,040 0,040 0,040 0,040

bottom

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Ventilation units with heat recovery Recommended specifications to start planning: Frost protection: No requirements; Humidity recovery: Yes ID

Description User defined area

01ud 02ud 03ud 04ud 05ud 06ud 07ud 08ud 09ud 10ud

LUEFTA LSD_BE 300DC Pluggit - Pluggit AventD 160

PHPP, Components

Ventilation units with heat recovery No requirements % Effective heat recovery efficiency

Additional Device Data 0,15 Energy recovery value hER

Electric efficiency

Application range

External pressure per section

Fittings Dpintern

Wh/m続

m続/h

95% 93%

0% 0%

0,45 0,37

50 70

150 140

100 100

inkl.

Frost protection necessary

Noise protection

35 dB(A) ja

/ /

Additional info

Supply air dB(A)

Extract air dB(A)

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit exemptions ►

Detailed window characteristic values ► EnerPHit with PHPP Version 9.3

Windows Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

kWh/(m²a)

0,75

0,95

Non-vertical radiation incidence 0,85

68 170 340 176 276

0,57 0,55 0,46 0,47 1,00

0,95 0,95 0,95 0,95 0,95

0,85 0,85 0,85 0,85 0,85

Global Window area orientation radiation (main

Shading

Dirt

orientations)

Standard values → North East South West Horizontal

Glazing fraction

0,58 0,55 0,62 0,63 0,00

Total or average value for all windows.

g-Value

Solar irradiation reduction factor

Description

Transmission losses heating period

Heating gains solar radiation heating period

W/(m2K)

kWh/(m2a)

kWh/a

85 271 298 101 276

88 162 298 167 0

57 168 341 88 0

715

654

0,27 0,25 0,23 0,24 0,00

4,62 4,68 9,09 6,77 0,00

0,62 1,13 1,06 0,80 0,00

2,70 2,60 5,67 4,30 0,00

0,54

0,24

25,17

0,92

15,26

Deviation from north

Angle of inclination from the horizontal

Orien- tation

Width

Height

Glazing

Frame

g-Value

Selection from 'Areas' worksheet

Selection from 'Components' worksheet

Perpendicular radiation

WIN.D.N/E.gf_1

North

0,400

2,160

2-N/E.gf.br_2

WIN.N/E.gf_2

North

1,360

1,700

3-N/E.gf.br_3

WIN.N/E.gf_3

North

1,360

1,700

3-N/E.gf.br_3

1 1 1 0 1 2 1 1

Door.N/W.gf_5 Door.S/W.gf_4 WIN.S/W.gf_6 WIN.S/W.gf_4b Door.S/W.gf_7 WIN.S/W.gf_8 WIN.S/E.gf_9 WIN.S/E.gf_10

310 220 220 220 220 220 130 130

90 90 90 90 90 90 90 90

West South South South South South East East

1,310 1,190 1,900 0,660 0,730 0,520 1,280 1,280

2,660 2,600 1,660 1,500 2,600 0,910 1,830 1,830

14-N/W.gf.br_5 22-S/W.gf.br_6 23-S/W.gf.br_7 23-S/W.gf.br_7 24-S/W.gf.br_8 24-S/W.gf.br_8 37-S/E.gf.br_10 38-S/E.gf.br_11

WIN.N/W.b1

310

West

1,340

1,330

21-N/W.bas.br_3

WIN.N/W.b2

310

West

1,140

1,320

20-N/W.bas.s/a_4

Sort: AS LIST 92ud-Single glazing 01ud-Saint-Gobain Glass Deutschland SGG PLANITHERM ULTRA N II (4:/18/4/18/:4 Ar 90%) 01ud-Saint-Gobain Glass Deutschland SGG PLANITHERM ULTRA N II (4:/18/4/18/:4 Ar 90%) 02ud-??????? Glass 02ud-??????? Glass 02ud-??????? Glass 02ud-??????? Glass 02ud-??????? Glass 02ud-??????? Glass 02ud-??????? Glass 02ud-??????? Glass 01ud-Saint-Gobain Glass Deutschland SGG PLANITHERM ULTRA N II (4:/18/4/18/:4 Ar 90%) 01ud-Saint-Gobain Glass Deutschland SGG PLANITHERM ULTRA N II (4:/18/4/18/:4 Ar 90%)

North East South West Horizontal

Transmission losses heating period Heating gains solar radiation heating period

400 300 200 100 0 kWh/a

North

East

South

West

Horizontal

Go to window frames list

Installed in

PHPP, Windows

Average global radiation

30,8 Window rough openings

Qua ntity

Glazing area

0,54 0,54 0,54 0,54 0,00

Go to glazing list Heating degree hours [kKh/a]:

Window U-Value

Window area

U-Value

Glazing

Sort: AS LIST 01ud-EX: timber 45 mm_bf_7

0,87

2 K) 5,80

13ud-Alumil S91

0,54

13ud-Alumil S91 15ud-76plus with roller blinds 150mm 15ud-76plus with roller blinds 150mm 14ud-76plus with roller blinds 79mm 11ud-76plus 108mm 16ud-76plus with roller blinds 108mm 11ud-76plus 108mm 15ud-76plus with roller blinds 150mm 15ud-76plus with roller blinds 150mm

Frames (avg.)

Installation situation

Y Glazing edge YGlazing edge (Avg.)

user determined value for Yinstallation or '1': Yinstallation from 'Components' worksheet '0': in the case of abutting windows

left

right

bottom

top

Window surf

Results

YInstallation (Avg.)

Window Area

W/(mK)

Glazing area

Uw installed

Glazed fraction per window

2 K) 2,50

W/(mK)

0,050

0,040

0,55

0,78

0,025

-0,029

2,3

1,35

0,62

58%

0,54

0,55

0,78

0,025

-0,029

2,3

1,35

0,62

58%

0,54 0,54 0,54 0,54 0,54 0,54 0,54 0,54

0,55 0,55 0,55 0,55 0,55 0,55 0,55 0,55

0,96 0,97 0,94 1,00 0,97 1,00 0,96 0,96

0,024 0,024 0,024 0,024 0,024 0,024 0,024 0,024

1 1 1 0 1 1 1 1

1 1 1 1 1 1 1 1

1 1 1 1 1 0 1 1

0,134 0,134 0,089 0,084 0,100 0,093 0,131 0,131

3,5 3,1 3,2

2,18 1,86 2,26

1,05 1,09 0,91

62% 60% 72%

1,9 0,9 2,3 2,3

1,12 0,42 1,30 1,30

1,14 1,36 1,13 1,13

59% 45% 55% 55%

12ud-Energeto 8000

0,54

0,55

0,83

0,024

-0,054

1,8

1,17

0,54

66%

12ud-Energeto 8000

0,54

0,55

0,83

0,024

-0,055

1,5

0,95

0,54

63%

W/(m

W/(mK) or 1/0

W/(m

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Calculation of shading coefficients Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

37,9

Orientation

Glazing area [m²]

Reduction factor winter rv

Reduction factor cooling rv,1

Reduction factor cooling load rv,2

Solar load [kWh/(m²Glazinga)]

North

2,70 2,60 5,67 4,30 0,00

57% 55% 46% 47% 100%

60% 19% 23% 57% 100%

60% 15% 19% 57% 100%

103 58 70 112 0

East South West Horizontal Horizon Quantity

0 1 1 1 1 1 0 1 2 1 1 1 1

Description

WIN.D.N/E.gf_1 WIN.N/E.gf_2 WIN.N/E.gf_3 Door.N/W.gf_5 Door.S/W.gf_4 WIN.S/W.gf_6 WIN.S/W.gf_4b Door.S/W.gf_7 WIN.S/W.gf_8 WIN.S/E.gf_9 WIN.S/E.gf_10 WIN.N/W.b1 WIN.N/W.b2

PHPP, Shading

Deviation from North

Angle of inclination from the horizontal

[Degree]

40 40 40 310 220 220 220 220 220 130 130 310 310

90 90 90 90 90 90 90 90 90 90 90 90 90

Orientation

Glazing width

Glazing height

Glazing area

w G [m] 0,26 1,00 1,00 1,01 0,89 1,74 0,44 0,51 0,30 0,98 0,98 1,10 0,90

hG [m] 2,02 1,34 1,34 2,16 2,10 1,30 1,28 2,18 0,69 1,33 1,33 1,06 1,05

AG [m2]

North North North West South South South South South East East West West

1,3 1,3 2,2 1,9 2,3 1,1 0,4 1,3 1,3 1,2 0,9

Lateral reveal

Height of the shading object

Horizontal distance

hHori [m] 5,27 4,39

dHori [m] 33,50 40,00

3,30 3,41 2,66 2,66 4,20 2,57 7,12 7,12 3,87 3,80

17,16 11,30 6,50 6,50 8,50 9,13 26,64 29,35 14,36 17,39

Window reveal depth

Distance from glazing edge to reveal

oReveal [m] 0,15 0,10 0,10 1,66 4,61 0,31 0,15 0,31 0,31 0,31 0,31 0,10 1,45

dReveal [m] 0,130 0,100 0,100 0,600 0,630 0,060 0,150 0,060 0,060 0,060 0,060 0,059 0,599

Reduction factors for shading in winter

Reveal / Overhang

Overhang depth

Distance from upper glazing edge to overhang

Additional reduction factor winter shading

Additional reduction factor summer shading

Reduction factor z for temporary sun protection

oover [m] 2,20 0,10 0,10 0,31 0,31 0,31 0,15 0,31 0,31 1,28 1,28 0,10 2,70

dover [m] 0,98 0,10 0,10 0,12 0,12 0,12 0,13 0,12 0,56 0,62 0,62 0,06 0,07

rother,w [%] 90% 60% 70% 90% 90%

rother,s [%] 90% 60% 70% 90% 90%

z [%]

90% 90%

Regulated / transparent

Latitude:

24% 24% 24% 24%

x x x x

24% 24%

x x

Reduction factors for shading in summer

Horizon

Reveal

Overhang

Total for heating case

Horizon

Reveal

Overhang

Total for cooling case

Total for cooling load

rH [%]

rR [%]

rO [%]

rS [%]

rH [%]

rR [%]

rO [%]

rS,1 [%]

rS,2 [%]

91%

97% 97% 93% 93% 90%

50% 64% 44% 24% 64%

92%

85% 86% 80%

95% 95% 62% 34% 90%

87% 88% 85%

96% 96% 77% 49% 92%

99% 99% 97% 93% 85%

53% 67% 59% 14% 26%

53% 67% 59% 11% 21%

74% 87% 86% 87% 80% 83%

74% 65% 83% 83% 95% 65%

94% 91% 76% 76% 95% 37%

47% 46% 54% 55% 73% 20%

82% 89% 88% 89% 83% 86%

80% 72% 89% 89% 97% 78%

93% 89% 61% 61% 99% 37%

22% 52% 19% 19% 79% 25%

17% 52% 15% 15% 79% 25%

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Ventilation data Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Treated floor area ATFA

m² m m³

Room height h Volume of ventilated space (ATFA*h) =VV

115 2,50 287

2,50

Several side exposed 0,10 0,07 0,04 15

One side exposed 0,03 0,02 0,01 20

('Areas' worksheet)

(Worksheet 'Annual heating')

Ventilation type Please select

1-Balancierte PH-Lüftung mit WRG

Infiltration air change rate Wind protection coefficients e and f Coefficient e for wind protection class No protection Moderate protection High protection Coefficient f

For annual demand:

For heating load:

Wind protection coefficient, e

0,07

0,18

Wind protection coefficient, f

Net air volume for press. test

0,56

323

For annual demand:

For heating load:

Air change rate at press. test

Excess extract air Infiltration air change rate

n50

1/h

1/h 1/h

nV,Rest

0,00

0,044

0,110

Vn50

Air permeability

0,40

m³

q50

m³/(hm²)

Selection of ventilation input - Results PHPP 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 quantities determined according to rooms or zones can be entered in the 'Addl vent' worksheet. Please select your design method here:

Ventilation unit / Heat recovery efficiency design ('Ventilation' worksheet, see below) Standard design ('Addl vent' worksheet) Multiple ventilation units, non-res

Average air flow rate m³/h

182

Extract air Average excess air change rate (extract air system) 1/h 1/h

0,63

0,00

Effective heat recovery efficiency unit [-]

90,7%

Energy recovery [-]

0,0%

Specific power input Wh/m³

0,36

Cooling degree 80,7% Average interior humidity during winter operation Jan Feb Mar Apr 46% 45% 51% 57%

PHPP, Ventilation

May -

Jun -

Jul -

Aug -

Sep -

38,7% h*SHX

Oct -

Nov 62%

Heat recovery efficiency SHX [-]

Efficiency SHX 48%

Dec 51%

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Standard data input for balanced ventilation (worksheet inactive. Calculation in 'Addl vent' worksheet) Dimensioning of ventilation system with only one ventilation unit

Occupancy Number of occupants Supply air per person Supply air requirement Extract air rooms Quantity Extract air requirement per room Total extract air requirement

m²/P P m³/(P*h) m³/h

Design air flow rate (maximum)

m³/h m³/h

36 3,2 30 95 Kitchen 1 60 140

m³/h

140

Bathroom (shower only)

Bathroom 1 40

WC 1 20

Recommended:

140

office 1 20

m³/h

Average air change rate calculation Type of operation

Factors referenced to maximum

Daily operation times h/d

maximum Standard Grundlüftung Minimum

Air flow rate m³/h 140 108 75 56 Average air flow rate (m³/h)

1,00 0,77 0,54 0,40

24,0 0,0

Average value

Air change rate 1/h 0,49 0,38 0,26 0,20 Average air change rate (1/h)

0,77

Selection of ventilation unit with heat recovery

Location of ventilation unit

1-Innerhalb therm.Hülle

Heat recovery efficiency Unit hWRG

Go to ventilation units list Sortierung: WIE LISTE

Energy recovery hERV

Specific efficiency [Wh/m³]

Application

Frost power input

[m³/h]

Ventilation unit selection Conductivity outdoor air duct Y Length of outdoor air duct Conductivity exhaust air duct Y Length of exhaust air duct Temperature of mechanical services room (Enter only if the central unit is outside of the thermal envelope) Effective heat recovery efficiency

W/(mK) m W/(mK) m °C

h*SHX hSHX

Secondary calculation Y-value supply or outdoor air duct Nominal width: Insulation thickness:

Thermal conductivity Nominal air flow rate DJ Exterior duct diameter Exterior diameter a-Interior a-Surface Y-value Surface temperature difference

PHPP, Ventilation

1 20

Room temperature (°C) Avg. ambient temp. heat. period (°C) Avg. ground temp (°C)

20 10,4 18,1

hHR,eff

Effective heat recovery efficiency subsoil heat exchanger SHX efficiency Heat recovery efficiency SHX

Reflective coating?

1-Nein

Implementation of frost protection Limit temperature [°C] Useful energy [kWh/a]

60% 48% Secondary calculation Y-value extract or exhaust air duct

125 30

mm mm

Nominal width: Insulation thickness:

Yes No

Reflective coating?

0,035

W/(mK) m³/h 10 K 0,125 m 0,185 m W/(m²K) W/(m²K) W/(mK) K

Thermal conductivity Nominal air flow rate DJ Exterior duct diameter Exterior diameter a-Interior a-Surface Y-value Surface temperature difference

125 30

mm mm

yes no

0,035

W/(mK) m³/h 10 K 0,125 m 0,185 m W/(m²K) W/(m²K) W/(mK) K

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Extended input for balanced ventilation Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Planning ventilation systems with multiple ventilation units Results of ventilation design and unit selection: Ventilation unit / Heat recovery efficiency design In Ventilation sheet (standard design) In 'Addl vent worksheet (this worksheet) Treated floor area ATFA Room height h Room air volume for ventilation (ATFA*h) = VV Number of occupants Room temperature Average external temp. heating period Average ground temp. Length of the heating period Ventilation type

('Ventilation' worksheet)

x m² 115 m 2,50 m³ 287 P 3,2 °C 20 °C 10,4 °C 18,1 d/a 113 1-Balancierte PH-Lüftung mit WRG

(Addl vent)

('Areas' worksheet) (Worksheet 'Annual heating') (Worksheet 'Annual heating') ('Ventilation' worksheet) (Worksheet 'Annual heating') ('Ventilation' worksheet) ('Ground' worksheet) ('Heating' worksheet) ('Ventilation' worksheet)

Ventilation unit no. 1 2 3 4 5 6 7 8 9 10

Description of the unit House Office

Result for overall vent. syst.

Design VSUP VETA

Annual average value VSUP VETA Air ch.rt.

m³/h 110 129

m³/h 110 72

1/h ---------------------

239

182

0,63

Effective heat recovery efficiency

Energy recovery

Spec. input

Heat recov. efficiency

92% 89%

efficiency 0% 0%

power 0,37 0,34

SHX 64% 0%

91%

0,36

39%

Recommendations for dimensioning air quantities Use of low odour and low VOCs building materials/furnishings: It is strongly recommended to use building materials that cause no or very low VOCs/odours instead of increasing the outdoor air volume in order to clear the air. This holds true independently from the chosen approach to determine air quality; emissions of all sources in the room should be considered, e.g. furniture, carpets and ventilation or air-conditioning unit. Assessment of volume flow rates according to the number of persons Also in non-residential buildings, the number of persons is fundamentally important for assessing the volume air flow rates. For good indoor air quality volumes between 20 to 30 m³/h/person are sufficient. Higher outdoor air amounts may lead to excessively dry indoor air in winter. The air flow rates are specified by classification according to EN 13779. The classification must be agreed with the client in advance. IDA 3 is adequate for office buildings. IDA 4 has proven satisfactory for school buildings as flushing ventilation is carried out during breaks anyway. For typical outdoor air CO 2 concentrations of around 400-500 ppm, it is possible to comply even with 1500 ppm. Exceeding this figure temporarily is permissible. Outdoor air flow rates per person: - Recommended for residential buildings: around 30 m³/(h person) - Recommended for offices and similar uses: around 30 m³/(h person) (AMEV: 28 m³/(h person); EN 13779 / IDA 3: at least 24 m³/(h person)) - Recommended for schools and day care centres: 15 to 20 m³/(h person) (Source: Guidelines for energy-efficient educational buildings, Passive House Institute, 2010) - Recommendation for sport halls: 60 m³/(h person) (DIN 18032-1) Flushing phase for intermittent ventilation operation In case the ventilation is to be used intermittently (turned off at night), then it should be flushed in the morning, approx. 1 to 2 hours before building is occupied. This should be done in order to refresh air from emissions such as VOCs. Flushing the building causes that the ventilation system works for a longer period (utilisation time + flushing phase). Please consider this at design stage.

PHPP, Addl vent

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Dimensioning of air quantities When dimensioning the air quantities, please consider the design recommendations given above. The operation period of the ventilation can be determined on the basis of daily utilisation hours, including flushing phase if applicable. In addition, time periods with reduced ventilation requirements (operation modes) can be taken into account by means of reduction factors.

Room Amount no. a 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30

1 1 1 1 1 1 1 1 1

Room name

TFA bedroom 1 TFA bedroom 2 TFA bathroom TFA kitchen TFA living room TFA entrance TFA corridor TFA basement TFA storage

Allocation to ventilation unit (No.) 1 1 1 1 1 1 1 2 1

Area A m² 15 13 5 18 23 8 3 31 5

Clear height Room vol. h Axh m m³ 3,10 46 3,10 39 2,00 11 3,10 55 3,10 70 3,10 25 3,10 9 2,15 66 0,89 4

Additional lines: Please mark complete lines above, copy and paste multiple times

PHPP, Addl vent

Volume flow per room VSUP VETA VTRANS m³/h m³/h m³/h 25 25 40 60 40 20 50 129 129 10

Air chng. rt. per room n 1/h 0,55 0,64 3,67 1,09 0,57 0,79 5,45 1,97 2,25

Utilisation times h/d d/week h d 24 7 24 7 24 7 24 7 24 7 24 7 24 7 24 7 24 7

Duration Reduction Operation Reduction Operation Reduction of holidays factor 1 red. 1 factor 2 red. 2 factor 3 d 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 15 100% 10% 60% 90% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100% 100%

Operation red. 3

VSUP m³/h 25 25

Annual average value: VETA VTRANS m³/h m³/h

40 60 40 20 50 72

72 10

182

---

Change rate 1/h 0,55 0,64 3,67 1,09 0,57 0,79 5,45 1,09 2,25

0,56

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Ventilation unit selection Up to 10 different ventilation units are considered. By changing the amount, identical units can be considered. The data from PHI certified ventilation units as well as the entry data lines for user data for other ventilation units can also be found in the worksheet 'Components'. When choosing to use a compact unit the standard design in the 'Ventilation' worksheet has to be used. Go to ventilation units list Venti-

Quan-

Description of

Selection of

Design vol.

Application range for

lation unit no.

tity

ventilation units

type of ventilation unit

flow per unit

volume flow rate from to

[-] 1 2 3 4 5 6 7 8 9 10

1 1

House Office

Change sorting type 02ud-Pluggit - Pluggit AventD 160 0736vs03-Systemair - SAVE VTC 200

Electrical

Pressure loss calculation

efficiency ODA-SUP ETA-EHA DpDuct DpDuct

Additional DpIntern

Application range per line DpExternal

Interior

Exterior

Heat recovery

Subtraction location DpIntern (x)

location (x)

efficiency Unit Effective

m続/h

degree

110 129

70 80

140 200

0,37 0,34

5 10

0 0

100 100

x x

Energy

Frost

Subsoil HX

recovery protection Efficiency efficiency necessary of heat

[-]

0,93 0,90

92% 89%

0% 0%

ja yes

Frost protection (electr. / hydr.)

Effective efficiency of

recovery

heat recovery

80% 0%

64% 0%

Tipe perature

Limit temperature

Useful VSUP

属C

kWh/a

1-Nein 1-Nein 1-Nein 1-Nein 1-Nein 1-Nein 1-Nein 1-Nein 1-Nein 1-Nein Total (directly electric) Total (hydraulic and heat generator)

0 0 0 0 0 0 0 0 0 0

0 0

Data entries for duct sections between the ventilation unit and the thermal envelope The duct sections between the ventilation unit and the thermal envelope should be as short as possible and should be well insulated, whether the ventilation unit is located indoors or outdoors. The dimensions of these duct sections can be entered here. The heat losses of the overlying duct sections will be considered for the effective heat recovery efficiency. One section of a duct entered here may also be used for multiple ventilation units. If in the section "Ventilation unit - selection" (above) a ventilation unit is selected as multiple units (amount larger than 1 for identical units), then the corresponding duct sections may simply be entered (duct sections for one ventilation unit). Temperature of installation location Quantity

1 1 1 1

Round duct ins. diameter mm

(only enter when at least one unit is installed outside of the thermal envelope) Rectangular duct Width mm

125 125 125 125

Insulation thickness Height mm

mm 30 30 30 30

Thermal Reflective conducti- insulation vity duct W/(m K) (x) 0,035 0,035 0,035 0,035

Duct Length of transmit- supply air tance duct W/(m K) m 0,437 0,437 0,427 0,427

0,5 0,5 0,5 0,5

Outdoor or supply air duct (1)

Exhaust Duct type or extract air duct (1)

1 1 1 1

Outdoor air Exhaust air Outdoor air Exhaust air

Design volume rate

110 110 129 129 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0

Assignment to ventilation unit (enter 1 for the corresponding ventilation unit) Vent. Vent. Vent. Vent. Vent. Vent. Vent. unit 1 unit 2 unit 3 unit 4 unit 5 unit 6 unit 7

Vent. unit 8

Vent. unit 9

Vent. unit 10

1 1 1 1

Additional lines: Please mark complete lines above, copy and paste multiple times

PHPP, Addl vent

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Design

volume flow rate

EnerPHit with PHPP Version 9.3

Specific energy for heating (annual method) Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

°C Interior temperature: 20,0 Building type: Detached house m² Treated floor area ATFA: 114,6

Area Building assembly External wall - Ambient External wall - Ground Roof/Ceiling - Ambient Floor slab / Basement ceiling

Windows Exterior door Exterior TB (length/m) Perimeter TB (length/m) Ground TB (length/m)

Temperature zone

U-Value

m²

A B A B A A X A A A P B

195,0 21,1 105,6 105,6

25,2 4,7 116,3 51,1 17,8

Total of all building envelope areas

Temp. factor ft

W/(m²K)

* * * * * * * * * * * *

kKh/a

0,177 0,470 0,100 0,452

* * * * * * * * * * * *

0,924 0,920 0,018 0,196 0,403

1,00 0,26 1,00 0,26 1,00 1,00 0,75 1,00 1,00 1,00 0,26 0,26

* * * * * * * * * * * *

30,8 30,8 30,8 30,8

= = = = = = = = = = = =

30,8 30,8 30,8 30,8 30,8

457,2

Transmission heat losses QT

Total ATFA

Effective heat recovery efficiency

114,6

Effective air volume, VV heff 91%

1063 80 326 385

9,27 0,70 2,84 3,36

715 133 63 81 58

6,24 1,16 0,55 0,70 0,50

–––––––––––

kWh/(m²a)

2902

25,3

Clear room height

m²

Ventilation system:

kWh/a

Per m² of treated floor area

m³

2,50

286,5

0,080

Efficiency of subsoil heat exchanger Heat recovery efficiency of SHX

hSHX

39%

hHR

nV,system

nV,Res

1/h

Ventilation heat losses QV

m³

1/h

286,5

1/h

0,634

Energetically effective air changes nV

* (1 -

0,94

cAir

Wh/(m³K)

0,080

1/h

0,044

0,33

kKh/a

30,8

kWh/a

kWh/(m²a)

233

2,0

kWh/a

kWh/(m²a)

3136

27,4

Reduction factor

QV kWh/a

Total heat losses QL

(

2902

Orientation of the area

Reduction factor See 'Windows' sheet

(perp. radiation)

North East South West Horizontal

0,27 0,25 0,23 0,24 0,00

0,54 0,54 0,54 0,54 0,00

night/weekend Saving

kWh/a

233

g-Value

) *

Area

Radiation HP

m²

* * * * *

4,62 4,68 9,09 6,77 0,00

1,0

kWh/(m²a)

* * * * *

kWh/a

85 271 298 101 276

= = = = =

Available solar heat gains QS

Total

kh/d

Internal heat gains QI

0,024

Length heating period

Spec. power qI

d/a

W/m²

113

2,97

Free heat QF Ratio of free heat to losses 5

–––––––––––

kWh/(m²a)

654

5,7

ATFA m²

kWh/a

kWh/(m²a)

924

8,1

kWh/a

kWh/(m²a)

QS + QI =

1579

13,8

QF / QV =

0,50

114,6

(1 - ( QF / QL ) ) / (1 - ( QF / QL ) ) =

Utilisation factor heat gains hG

57 168 341 88 0

98% kWh/a

kWh/(m²a)

Heat gains QG

hG * QF

1553

13,5

kWh/a

kWh/(m²a)

Annual heating demand QH

QL - QG

1583

kWh/(m²a)

Limiting value

PHPP, Annual heating

(Yes/No)

Requirement met?

Yes

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Specific energy for heating (monthly method) Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) The sum of the heating periods calculated through the monthly method will be presented on this side.

°C Interior temperature: 20 Building type: Detached house m² Treated floor area ATFA: 114,6 Spec. Capacity: Wh/(m²K) 204

Temperature zone Building assembly External wall - Ambient External wall - Ground Roof/Ceiling - Ambient Floor slab / Basement ceiling

Windows Exterior door Exterior TB (length/m) Perimeter TB (length/m) Ground TB (length/m)

A B A B A A X A A A P B

Area

U-Value

m²

W/(m²K)

195,0 21,1 105,6 105,6

25,2 4,7 116,3 51,1 17,8

* * * * * * * * * * * *

0,177 0,470 0,100 0,452

0,924 0,920 0,018 0,196 0,403

Month. red. fac.

* * * * * * * * * * * *

1,00 1,00 1,00 1,00 1,00 1,00 0,75 1,00 1,00 1,00 1,00 1,00

* * * * * * * * * * * *

42 11 42 11

Total

ATFA

2,50

)+ )

0,044

hHR

*(1*

nV,equi,fraction

m³

Ventilation losses ambient QV Ventilation losses ground QV,e

287 287

)*(1*(1-

cAir

1/h

* *

0,074 0,028

0,91 0,91

0,33 0,33

967 180 85 114 81

8,44 1,57 0,74 0,99 0,71

–––––––––––

kWh/(m²a)

3960

34,6

287

1/h

= =

0,074 0,028

Wh/(m³K)

* *

12,54 0,98 3,84 4,73

nV,equi,fraction

1/h

48% 48%

1437 113 441 543

m³

nV,Res

1/h

0,634 0,634

Per m² of treated floor area

Clear room height

m²

115

h*SHX

nV,system Effective air change rate Ambient nV,e Effective air change rate Ground nV,g

= = = = = = = = = = = =

42 42 42 11 11

Transmission heat losses QT Effective air volume VV

kWh/a

Gt kKh/a

kKh/a

* *

42 8

= =

kWh/a

kWh/(m²a)

293 23

2,6 0,2

–––––––––––

Ventilation heat losses QV

Total heat losses QL Orientation of the area

( Reduction factor see 'Windows' worksheet

kWh/a

3960

g-Value

315

0,27 0,25 0,23 0,24 0,00

* * * * *

) *

Area

1,0

0,54 0,54 0,54 0,54 0,00

* * * * *

4,6 4,7 9,1 6,8 0,0

Length Heat. Period

Spec. Power qI

d/a

W/m²

kh/d

0,024

2,8

kWh/a

kWh/(m²a)

4275

37,3

Global radiation

(perp. radiation) kWh/(m²a)

* * * * *

176 511 554 211 570

181

Free heat QF Ratio free heat to losses

3,0

kWh/a

= = = = =

119 317 636 185 0 435 –––––––––––

kWh/(m²a)

Total

1691

14,8

kWh/a

kWh/(m²a)

114,6

1480

12,9

kWh/a

kWh/(m²a)

QS + Q I

3171

27,7

QF / QL

0,74

94%

Available solar heat gains QS

Internal heat gains QI

315

Reduction factor night/weekend saving

m²

North East South West Horizontal Sum opaque areas

Total

ATFA m²

Utilisation factor heat gains hG

kWh/a

kWh/(m²a)

Heat gains QG

hG * QF

2974

25,9

kWh/a

kWh/(m²a)

Annual heating demand QH

QL - Q G

1302

kWh/(m²*a)

Limiting value

PHPP, Heating

(Yes/No)

Requirement met?

Yes

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Specific energy for heating (monthly method) Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

°C Interior temperature: 20 Building type: Detached house m² Treated floor area ATFA: 115

Jan 9,0 2,2 739 167 7,9 14 50 101 19 0 56 253 4,3 100%

Feb 8,1 2,5 665 189 7,5 16 43 90 25 0 59 229 4,0 100%

Mar 7,0 2,8 570 216 6,9 28 66 128 42 0 97 253 5,4 99%

Annual heating demand

414

393

179

Spec. heating demand

3,6

3,4

1,6

0,1

0,0

Heating degree hours - External Heating degree hours - Ground Losses - Exterior Losses - Ground Sum spec. losses Solar gains - North Solar gains - East Solar gains - South Solar gains - West Solar gains - Horiz. Solar gains - Opaque Internal heat gains Sum spec. gains solar + internal Utilisation factor

Apr 4,6 2,3 378 179 4,9 37 68 122 55 0 116 245 5,6 84%

May 1,2 1,6 95 123 1,9 47 69 121 71 0 137 253 6,1 31%

Jun -2,5 -0,7 -203 -49 -2,2 52 68 116 76 0 146 245 6,1 100%

Spec. heating demand

Jul -4,6 -1,6 -372 -118 -4,3 53 74 124 77 0 152 253 6,4 100%

Aug -4,5 -2,2 -367 -161 -4,6 45 79 140 69 0 142 253 6,4 100%

Sep -1,1 -2,2 -93 -162 -2,2 30 68 134 50 0 109 245 5,6 100%

Oct 1,8 -0,5 146 -37 1,0 23 59 116 33 0 81 253 4,9 19%

Nov 5,0 0,3 405 24 3,7 14 52 112 25 0 62 245 4,5 82%

Dec 7,9 1,3 645 99 6,5 10 38 84 19 0 45 253 3,9 100%

Year 32 6 2608 470 26,9 369 734 1387 560 0 1202 2984 63,1 25%

kKh kKh kWh kWh kWh/m² kWh kWh kWh kWh kWh kWh kWh kWh/m²

294

1302

kWh

0,0

0,1

2,6

11,4

kWh/m²

Sum spec. gains solar + internal

Sum spec. losses

Specific losses and gains heating balance [kWh/(m²month)]

10 8 6

4 2 0 Jan

Feb

Mar

Apr

May

Jun

Jul

Aug

Sep

Oct

Nov

Dec

-2 -4

-6

Annual heating demand: Comparison Monthly method Annual method

PHPP, Heating

('Heating') ('Annual heating')

1302 1583

kWh/a kWh/a

11,4 13,8

kWh/(m²a) reference to treated floor area according to PHPP kWh/(m²a) reference to treated floor area according to PHPP

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Heating load Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) Interior temperature: Building type: Treated floor area ATFA: Design temperature Weather 1: Weather 2: Ground design temp.

Building assembly

4,2 4,8 16,2

Radiation: °C °C

Roof/Ceiling - Ambient Floor slab / Basement ceiling

Windows Exterior door Exterior TB (length/m) Perimeter TB (length/m) Ground TB (length/m) Building element towards neighbour

East

South

West

Horizontal

30 25

55 30

100 40

50 35

95 55

W/m² W/m²

°C

Temperature zone

External wall - Ambient External wall - Ground

North

°C 20 Detached house 114,6 m²

A B A B A A X A A A P B I

Area

U-Value

m²

W/(m²K)

195,0 21,1 105,6 105,6

* * * * * * * * * * * * *

25,2 4,7 116,3 51,1 17,8

Factor always 1 (except "X")

0,177 0,470 0,100 0,452

* * * * * * * * * * * * *

0,924 0,920 0,018 0,196 0,403

1,00 1,00 1,00 1,00 1,00 1,00 0,75 1,00 1,00 1,00 1,00 1,00 1,00

* * * * * * * * * * * * *

TempDiff 1

TempDiff 2

PT 1

15,8 3,8 15,8 3,8 15,8 15,8 15,8 15,8 15,8 15,8 3,8 3,8 3,0

or or or or or or or or or or or or or

15,2 3,8 15,2 3,8 15,2 15,2 15,2 15,2 15,2 15,2 3,8 3,8 3,0

= = = = = = = = = = = = =

Total

545 38 167 182

367 68 32 38 27

PT 2 W

or or or or or or or or or or or or or

–––––––––––

Transmission heat load PT ATFA m²

Ventilation system:

Clear room height m

114,6

Effective air volume, VV

2,50

1465

91%

–––––––––––

1420

42%

0,144

m³

48%

Heat recovery efficiency SHX

353 66 31 38 27

287 hSHX 1

hHR

Heat recovery efficiency

524 38 161 182

Heat recovery efficiency SHX

42%

hSHX 2

of the heat exchanger

nV,Res (Heating Load) 1/h

0,110

Energetically effective air changes nV

FHR

nV,system 1/h

0,634

FHR 1/h

*(1-

0,95

0,144

1/h

Ventilation heat load PV VV

m³

286,5

1/h

0,144

cAir

1/h

0,144

TempDiff 1

Wh/(m³K)

0,33

15,8

PV 1

TempDiff 2

PV 2

15,2

215

PL 1

Total heating load PL =

1680

Orientation

Area

g-Value

Reduction factor

Radiation 1

Radiation 2

PT 1

of the area North

m²

(perp. radiation)

(see 'Windows' worksheet)

W/m²

4,6 4,7 9,1 6,8 0,0

East South West Horizontal

PL 2

P T + PV

* * * * *

0,5 0,5 0,5 0,5 0,0

* * * * *

0,27 0,25 0,23 0,24 0,40

* * * * *

35 82 85 33 95

or or or or or

25 35 40 30 55

= = = = =

Total

23 51 98 29 0

Internal heating load PI

201

Spec. power

ATFA

PI 1

W/m²

m²

2,5

115

283

or or or or or

17 22 46 26 0 –––––––––––

110

PI 2 W

PG 1

Heating power (gains) PG

1627 PT 2

–––––––––––

Solar heating power PS

207

283 PG 2

P T + PI

484

394

PL - PG

1196

1233

Heating load PH

1233

Area specific space heating load PH / ATFA

10,8

W/m²

Input max. supply air temperature

°C

Max. supply air temperature JSupply,Max

°C

Supply air temperature without heating

For comparison: heating load transportable by the supply Air PSupply Air,Max

JSupply,Min =

1847

°C

19,2

W specific:

16,1

W/m²

(Yes/No)

Supply air heating: Sufficient?

PHPP, Heating load

Yes

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Summer ventilation Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Building volume: Max. indoor absolute humidity: Internal humidity sources: Results passive cooling Frequency of overheating: max. humidity: Frequency of exceeded humidity:

287 12 100

28,1% 14,8 12,1%

Building type: Detached house Heat recovery hHRV: 81% Energy recovery hER: 0% Subsoil heat exchanger h*SHX: 48%

m³ g/kg g/(P*h)

at the overheating limit Jmax = 25 °C g/kg

Results active cooling Useful cooling demand: 11,0 Dehumidification demand: 1,2 Frequency of exceeded humidity: 4,8%

kWh/(m²a) kWh/(m²a)

Summer basic ventilation to ensure adequate air quality Air change rate via vent. system with supply air:

0,54

Air change rate via extract air system:

HRV/ERV in summer (check only one field) None Automatic bypass, controlled by temperature difference x Automatic bypass, controlled by enthalpy difference Always

1/h

1/h Wh/m³

Specific power consumption (for extract air system)

Window ventilation air change rate:

1/h

Effective air change rate h*SHX

nV,system

hHR

nV,equi,fraction

1/h

Exterior nV,e without HR Ground nL,g without HR

1/h

0,540 0,540 0,540 0,540

*(1*(1* *

48% 48% 48% 48%

)*(1) *(1-

0,81 0,81

)= = )= =

0,054 0,278 0,050 0,262

= = = = =

5,1 26,3 4,8 24,7 4,2

Ventilation conductance

exterior HV,e without HR ground HV,g without HR Infiltration, window, extract air system

nV,equi,fraction

m³

1/h

287 287 287 287 287

* * * * *

0,054 0,278 0,050 0,262 0,044

cAir Wh/(m³K)

* * * * *

0,33 0,33 0,33 0,33 0,33

W/K W/K W/K W/K W/K

Additional summer ventilation for cooling Additional ventilation regulation Minimum acceptable indoor temp.

20,0

°C

Type of additional ventilation

Window night ventilation, manual

Mechanical, automatically Controlled ventilation

PHPP, SummVent

Night ventilation value

0,17

Corresponding air change rate 0,00 during operation, in addition to basic air change Specific power consumption 0,37

1/h 1/h Wh/m³

Controlled by (please check) Temperature diff. x Humidity diff.

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Secondary calculation: Hygienic air change rate through window ventilation Estimation for window air change rate to ensure sufficient air quality Description Open duration [h/d] Climate boundary conditions Temperature diff interior - exterior Wind velocity

K m/s

Window group 1 Quantity Clear width Clear height Tilting window (check if appropriate) Opening width (for tilting windows)

m m

Window group 2 (cross ventilation) Quantity Clear width Clear height Tilting window (check if appropriate) Opening width (for tilting windows)

m m

Difference in height to window 1

Result: Air change rate

0,00

1 0

Total 0,00

1/h

Secondary calculation: Additional night ventilation for cooling Air change value during additional window night ventilation Description Reduction factor Climate boundary conditions Temperature diff interior - exterior Wind velocity

NIGHT 1st FL 90%

1 0

Window group 1 Quantity Clear width Clear height Tilting window (check if appropriate) Opening width (for tilting windows)

2 1,00 1,35 x 0,055

Window group 2 (cross ventilation) Quantity Clear width Clear height Tilting window (check if appropriate) Opening width (for tilting windows)

2 1,12 1,33 x 0,055

1 0

m m m

Difference in height to window 1

Result: Night ventilation values

PHPP, SummVent

K m/s

0,17

0,00

Total 0,17

1/h

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Summer: Passive cooling Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) Building type: Detached house Upper temperature limit: °C 25 Nominal humidity: g/kg 12 Spec. capacity: 204 Wh/(m²K) Building assembly External wall - Ambient External wall - Ground Roof/Ceiling - Ambient Floor slab / Basement ceiling

Windows Exterior door Exterior TB (length/m) Perimeter TB (length/m) Ground TB (length/m)

114,6 287 2,8

Treated floor area ATFA: Building volume: Internal humidity sources: Area

U-Value

Temperature zone

m²

W/(m²K)

A B A B A A X A A A P B

195,0 21,1 105,6 105,6

25,2 4,7 116,3 51,1 17,8

* * * * * * * * * * * *

0,177 0,470 0,100 0,452

0,924 0,920 0,018 0,196 0,403

Red. factor fT,Summer

* * * * * * * * * * * *

m² m³

g/(m²h)

HSummer heat conductance

1,00 1,00 1,00 1,00 1,00 1,00 0,75 1,00 1,00 1,00 1,00 1,00

= = = = = = = = = = = =

34,6 9,9 10,6 47,8

23,3 4,3 2,0 10,0 7,2 –––––––––––

Exterior thermal transmittance, HT,e Ground thermal transmittance, HT,g Summer ventilation

Ventilation parameter Temperature amplitude summer Minimum acceptable indoor temperature Heat capacity air Supply air changes Outdoor air changes Window night ventilation air change rate, manual @ 1K Air change rate due to mech. automatically controlled vent. Specific power consumption for hHR hERV h*SHX

Angle factor

Shading factor

Summer

North 0,9 East 0,9 South 0,9 West 0,9 Horizontal 0,9 Sum opaque areas

W/K

74,9

W/K

from 'SummVent' worksheet

Ventilation unit conductance exterior HV,e 5,1 W/K without HR 26,3 W/K ground HV,g 4,8 W/K without HR 24,7 W/K Ventilation conductance, others 4,2 W/K exterior

Orientation of the area

74,8

* * * * *

0,60 0,15 0,19 0,57 1,00

Shading dirt

Summer ventilation regulation 8,4 20,0 0,33 0,54 0,04 0,17 0,00 0,37 81% 0% 48%

g-Value

K °C Wh/(m³K) 1/h 1/h 1/h 1/h Wh/m³

HRV/ERV None Controlled by temperature Controlled by enthalpy Always

Additional ventilation x

Controlled by temperature Controlled by humidity

Area

Portion of glazing

Aperture

(perp. radiation) m²

* * * * *

0,95 0,95 0,95 0,95 0,95

* * * * *

0,54 0,54 0,54 0,54 0,00

* * * * *

m²

4,6 4,7 9,1 6,8 0,0

* * * * *

58% 55% 62% 63% 0%

Solar aperture Specif. power qI

3,0

Frequency of overheating hJ  Jmax

0,7 0,2 0,5 1,1 0,0 1,0 –––––––––––

m²/m²

Total

3,5

0,03

W/m²

341

3,0

ATFA

W/m²

Internal heat gains QI

= = = = =

m²

115

At the overheating limit Jmax = 25 °C

28,1%

If the "frequency over 25°C" exceeds 10%, additional measures to protect against the heat during the summer are necessary. Daily internal temperature stroke Transmission Ventilation kWh/d

(

PHPP, Summer

7,5

Solar load

kWh/d

3,7

Spec. capacity

kWh/d

13,1

1/k

1000

ATFA:

Wh/(m²K)

204

m²

115

1,0

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Cooling: energy value for useful cooling energy Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

°C 25 Detached house Treated Floor Area ATFA: 115 m²

Interior Temperature:

Building type:

Heating degree hours - Exterior Heating degree hours - Ground

Jan 12,7 5,9

Feb 11,5 5,8

Mar 10,7 6,6

Apr 8,2 5,9

May 4,9 5,3

Jun 1,1 2,9

Jul -0,9 2,1

Aug -0,8 1,5

Sep 2,4 1,4

Oct 5,5 3,2

Nov 8,5 3,9

Dec 11,6 5,0

Year 75 49

kKh kKh

Losses - Exterior

1453

1310

1214

930

543

107

-119

-113

265

619

971

1321

8502

kWh

Losses - Ground

510

494

553

509

473

312

264

226

214

334

374

451

4714

kWh

Losses summer ventilation

459

415

365

262

138

163

280

408

2604

kWh

Sum spec. heat losses

21,1

19,4

18,6

14,8

10,1

4,0

1,3

1,0

4,8

9,7

14,2

19,0

138,0

kWh/m²

Solar load North

410

kWh

Solar load East

266

kWh

Solar load South

732

kWh

Solar load West

720

kWh

Solar load Horiz.

kWh

Solar load Opaque

116

137

146

152

142

109

1202

kWh

Internal heat gains Sum spec. loads solar + internal

253 3,7

229 3,5

253 4,6

245 4,9

253 5,4

245 5,5

253 5,7

253 5,6

245 4,8

253 4,2

245 3,8

253 3,4

2984 55,1

kWh kWh/m²

Utilisation factor losses

17%

18%

25%

33%

54%

99%

100%

90%

43%

27%

18%

32%

186

501

521

1263

kWh

0,0

1,6

4,4

4,5

0,5

0,0

11,0

kWh/m²

0,0 100%

0,7 87%

0,5 90%

0,0 100%

1,2 90%

kWh/m²

Useful cooling energy demand Spec. cooling demand Specif. dehumidification demand Sensible fraction

Useful cooling demand

Spec. cooling demand

Sum spec. heat losses

Sum spec. loads solar + internal

Specific losses, loads, Useful cooling demand [kWh/(m²month)]

0 Jan

PHPP, Cooling

Feb

Mar

Apr

May

Jun

Jul

Aug

Sep

Oct

Nov

Dec

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Cooling: energy value for useful cooling energy Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

The sum of the cooling periods calculated through the monthly method will be presented on this side. Building type: Detached house

25 12 204

Interior temperature summer: Nominal humidity: Spec. capacity:

Treated floor area ATFA: Building volume:

°C

g/kg

Internal humidity sources:

External wall - Ground Roof/Ceiling - Ambient Floor slab / Basement ceiling

Windows Exterior door Exterior TB (length/m) Perimeter TB (length/m) Ground TB (length/m)

A B A B A A X A A A P B

Area

U-Value

m²

W/(m²K)

m³

g/(m²h)

195,0 21,1 105,6 105,6

25,2 4,7 116,3 51,1 17,8

* * * * * * * * * * * *

0,177 0,470 0,100 0,452

0,924 0,920 0,018 0,196 0,403

kKh/a

* * * * * * * * * * * *

1,00 1,00 1,00 1,00 1,00 1,00 0,75 1,00 1,00 1,00 1,00 1,00

kWh/a

per m² treated floor area

422 163 129 783

3,68 1,42 1,13 6,83

284 53 25 122 117

2,48 0,46 0,22 1,07 1,02

–––––––––––

kWh/(m²a)

2099

18,3

Mon. red. fac.

* * * * * * * * * * * *

12 16 12 16

12 12 12 12 16

Transmission losses QT (negative: heat loads) Summer ventilation

m²

Wh/(m²K)

Temperature zone Building assembly External wall - Ambient

114,6 287 2,8

= = = = = = = = = = = = Total

from 'SummVent' worksheet

Ventilation conductance, vent. unit exterior HV,e 5,1 W/K without HR 26,3 W/K ground HV,g 4,8 W/K without HR 24,7 W/K Ventilation conductance, others 4,2 W/K exterior

Ventilation parameter Temperature amplitude summer Minimum acceptable indoor temperature Heat capacity air Supply air changes Outdoor air changes Window night vent. air change rate, manual @ 1K Air changes rate due to mech., autom. controlled vent.

Specific power consumption for hHR hERV h*SHX h*SHX

nV,system

Hygienic air change Effective air change rate Ambient nV,e Effective air change rate Ground nV,g

Ventilation losses ambient QV Ventilation losses ground QV,e Heat losses summer ventilation

8,4 20,0 0,33 0,54 0,04 0,17 0,00 0,37 81% 0% 48%

1/h

0,540 0,540

*(1*

48% 48%

nV,equi,fraction

m³

1/h

287 287 287

* * *

0,323 0,262 0,156

)*(1*(1-

K °C Wh/(m³K) 1/h 1/h 1/h 1/h Wh/m³

Summer ventilation regulation HRV/ERV in summer None x Controlled by temp. Controlled by enthalpy Always Additional ventilation x Controlled by temp. Controlled by humidity

hHR

nV,Rest

(considers bypass)

1/h

0,00 0,00

)+ )

cAir

0,33 0,33 0,33

1/h

= =

0,323 0,262

Wh/(m³K)

* * *

0,044

nV,equi,fraction

kKh/a

* * *

9 31 28

= = =

kWh/a

kWh/(m²a)

266 759 416

2,3 6,6 3,6

–––––––––––

Ventilation heat losses QV

Total heat losses QL Orientation of the area

kWh/a

2099 Reduction factor

g-Value

Area

East South West Horizontal

1441

12,6

kWh/a

kWh/(m²a)

3540

30,9

Global radiation

(perp. radiation) m²

North

1441

Total

0,30 0,09 0,12 0,31 0,40

* * * * *

0,54 0,54 0,54 0,54 0,00

* * * * *

4,6 4,7 9,1 6,8 0,0

kWh/(m²a)

* * * * *

373 671 655 429 1131

kWh/a

= = = = =

Sum opaque areas

278 151 397 482 0 767 –––––––––––

Available solar heat gains QS kh/d

Internal heat gains QI

0,024

Length heat. period

Spec. power qI

d/a

W/m²

184

Sum heat loads QF Ratio of losses to free heat gains

3,0

2075

18,1

kWh/a

kWh/(m²a)

1504

13,1

kWh/a

kWh/(m²a)

QS + QI

3580

31,2

QL / QF

0,99

65%

2316

20,2

kWh/a

kWh/(m²a)

1263

ATFA m²

114,6

Utilisation factor heat losses hG

kWh/a

hG * QL

Useful heat losses QV,n Useful cooling demand QK

QF - QV,n

kWh/(m²*a)

Recommended maximum value

PHPP, Cooling

kWh/(m²a)

Total

kWh/(m²a)

(Yes/No)

Requirement met?

Yes

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Compressor - cooling units Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Building type: Detached house °C Interior temperature summer: 25,0 Nominal humidity: g/kg 12,0 Internal humidity sources: g/(m²h) 2,8

Treated floor area ATFA: Mechanical cooling: Air change rate via ventilation system with supply air:

Supply air cooling check as appropriate On/Off mode (check as appropriate) Max. cooling capacity (sensible + latent) Temperature reduction dry Seasonal energy efficiency ratio

x 1,0 19,0 3,0

x Recirculation cooling check as appropriate On/Off mode (check as appropriate) Max. cooling capacity (sensible + latent) Volume flow rate at nominal power Temperature reduction dry Variable air volume (check if appropriate) Seasonal energy efficiency ratio

x 2,0 450,0 13,1

114,6 x 0,5

m²

kW K

kW m³/h K

3,2

Additional dehumidification check as appropriate Waste heat to room (please check if applicable) Seasonal energy efficiency ratio Panel cooling check as appropriate Seasonal energy efficiency ratio

Useful cooling total

Sensible

Latent

kWh/(m²a)

11,0

1,2

COP

Electricity demand (kWh/a)

Sensible fraction

kWh/(m²a)

90%

Cooling contribution by:

Supply air cooling Recirculation cooling Dehumidification Remaining for panel cooling Cooling distribution

( (

Total

(

+ 11,0

2,0

3,0

3,2

11,0

2,0

4,1

85%

0,0

100%

3,2

100%

3,2

4,1

85%

(Yes/No)

Unsatisfied demand

PHPP, Cooling units

0,0

0,1

Cooling demand covered?

Yes

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Compressor - cooling units Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Humidity loads and humidity removal Internal humidity sources Infiltration/Window/Extract air system Supply air ventilation system Summer ventilation window Summer ventilation mechanically Total humidity load Dehumidification by supply air cooling Dehumidification by circulation cooling Additional dehumidification Total dehumidification Unnecessary dehumidification Missing dehumidification

Jan 1,5 -0,5 -5,6 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0

Feb 1,3 -0,4 -5,2 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0

Mar 1,5 -0,4 -5,1 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0

Apr 1,4 -0,3 -4,2 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0

May 1,5 -0,2 -3,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0

Jun 1,4 -0,1 -1,5 -0,4 0,0 0,0 0,0 0,1 0,0 0,1 0,1 0,0

Jul 1,5 -0,1 -0,7 -0,1 0,0 0,7 0,0 1,0 0,0 1,0 0,4 0,1

Aug 1,5 -0,1 -0,8 -0,1 0,0 0,5 0,0 0,9 0,0 0,9 0,4 0,0

Sep 1,4 -0,1 -1,3 -0,5 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0

Oct 1,5 -0,2 -2,5 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0

Nov 1,4 -0,3 -3,5 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0

Dec 1,5 -0,4 -5,1 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0 0,0

Year 17 -3 -38 -1 0 1 0 2 0 2 1 0

Internal humidity sources

Dehumidification by supply air cooling

Supply air ventilation system

Dehumidification by circulation cooling

Infiltration/Window/Extract air system

Additional dehumidification

Summer ventilation window

Unnecessary dehumidification

Summer ventilation mechanically

Missing dehumidification

kWh/m² kWh/m² kWh/m² kWh/m² kWh/m² kWh/m² kWh/m² kWh/m² kWh/m² kWh/m² kWh/m²

Humidity loads (left) Dehumidification energy (right) [kWh/(m² month)]

0 Jan

PHPP, Cooling units

Feb

Mar

Apr

May

Jun

Jul

Aug

Sep

Oct

Nov

Dec

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Cooling load Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) Building type: Detached house

Treated floor area ATFA: Building volume: Interior temperature:

Temperature:

Outdoor air

Dew point

Sky

Radiation:

114,6 287 25

m²

Horizontal

North

East

South

West

Spec. capacity:

m³

Nominal humidity:

°C

Internal humidity sources:

Weather 1:

30,7

°C

18,6

°C

16,5

°C

165

340

W/m²

Weather 2:

26,5

°C

20,0

°C

20,0

°C

150

220

145

265

W/m²

Ground design temp.

23,1

°C

18,1

°C

SHX

Area m²

Temperature zone

Building assembly

A B A B A A X A A A P B I

External wall - Ambient External wall - Ground Roof/Ceiling - Ambient Floor slab / Basement ceiling

Windows Exterior door Exterior TB (length/m) Perimeter TB (length/m) Ground TB (length/m) Building element towards neighbour Radiation correction outdoor air Radiation correction sky

U-Value W/(m²K)

* * * * * * * * * * * * *

195,0 21,1 105,6 105,6

25,2 4,7 116,3 51,1 17,8

0,177 0,470 0,100 0,452

0,924 0,920 0,018 0,196 0,403

Factor always 1 (except "X")

* * * * * * * * * * * * *

TempDiff 1 K

1,00 1,00 1,00 1,00 1,00 1,00 0,75 1,00 1,00 1,00 1,00 1,00 1,00 -5,2 5,1

Lambient W/K LSky W/K

* * * * * * * * * * * * * * *

5,7 -1,9 5,7 -1,9 5,7 5,7 5,7 5,7 5,7 5,7 -1,9 -1,9 3,0 5,7 -8,5

PT 1

TempDiff 2 K

or or or or or or or or or or or or or or or

= = = = = = = = = = = = = = =

Total

or or or or or or or or or or or or or or or

133 25 12 -19 -14 -30 -43

Ventilation load Exterior PV,o Ground PL,e Summer ventilation PL,S

nV,equi,fraction

m³

nV,equi,fraction

1/h

cAir

1/h

TempDiff 1 K

Wh/(m³K)

53 -19 16 -92

35 7 3 -19 -14 -8 -26

PV 1

-63 PV 2

287

0,323

0,33

5,7

1,5

175

287

0,262

0,33

-6,9

-172

287

0,000

0,33

0,0

–––––––––––

Ventilation heat load PV

Total

Orientation

Area

of the area North East South West

g-Value

m²

(perp. radiation)

* * * * *

4,6 4,7 9,1 6,8 0,0

Horizontal

Reduction factor

0,5 0,5 0,5 0,5 0,0

Radiation 1

(see 'Windows' worksheet)

* * * * *

0,30 0,07 0,10 0,31 0,40

W/m²

* * * * *

101 176 174 115 340

W/m²

or or or or or

= = = = =

Total

Sum opaque areas

75 32 88 129 0 221

or or or or or or

–––––––––––

Solar load PS Spec. power

Internal heating load PI

3,0

m²

PT + PV + PS + PI

341

1100

639

1100

9,6

W/m²

JSupply,Min

Supply air temperature without cooling

For comparison: cooling load, transportable through the supply air PSupply;Max

Area specific cooling load PC / ATFA °C

PI 2

341

487

Cooling load PC

Please enter the minimum supply air temperature.

115

60 36 103 99 0 189 –––––––––––

545

PI 1

ATFA

W/m²

-125 PT 2

80 198 203 88 265

0 –––––––––––

PT 1

Radiation 2

= specific:

g/kg

–––––––––––-

211

TempDiff 2 K

g/kg

198 -19 61 -92

–––––––––––

Transmission heat load PT

Wh/(m²K)

PT 2

1,5 -1,9 1,5 -1,9 1,5 1,5 1,5 1,5 1,5 1,5 -1,9 -1,9 3,0 1,5 -5,0

204 12,0 2,8

°C

24,6

22,4

234

124

W/m²

2,0

1,1 (yes/no)

Air conditioning over the supply air possible? Daily internal temperature stroke Transmission

Ventilation

Solar load

Time

Spec. capacity

h/d

Wh/(m²K)

(

Dehumidific. load

211,2

2,7

545,5

ATFA m²

204

115

13,4 183 264 318

or or or or

14,7 183 492 318

0,8

from 'Cooling' worksheet

Absolute humidity exterior air Outdoor air mass flow Summer vent. air mass flow Humidity load, outdoor air

13,4 15 0 22

or or or or

14,7 15 0 40

g/kg kg/h kg/h g/h

Absolute humid. supply air Supply air mass flow Humid. load, supply air Humidity load, internal

Enthalpy of vaporisation Wh/kg

707,639

Humidity load g/kg

1000

603

PD 1

Humidity load

g/h

g/kg kg/h g/h g/h

851

PD 2

g/h

427

602

Dehumidification load PT

602

Area specific dehumidification load PT / ATFA

5,3

W/m²

Monthly average values

Specific cooling demand Specific dehumidification demand Sensible fraction

Jan 0,0 0,0 100%

Feb 0,0 0,0 100%

Mar 0,0 0,0 100%

Minimum of sensible cooling load fraction occurred

PHPP, Cooling load

Apr 0,0 0,0 100%

May 0,0 0,0 100%

Jun 1,6 0,0 100%

Jul 4,4 0,7 87%

Aug 4,5 0,5 90%

Sep 0,5 0,0 100%

Oct 0,0 0,0 100%

Nov 0,0 0,0 100%

Dec 0,0 0,0 100%

kWh/m² kWh/m²

100%

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Heat distribution and domestic hot water (DHW) system Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) Interior temperature: 20 °C Building type: Detached house Treated floor area ATFA:

115

m²

Occupancy: Number of dwelling units:

3,2 2

Pers

Annual heating demand qHeating Length of heating period:

1302 113

kWh/a d

Average heating load Pave: Marginal usability of additional heat gains:

0,5 92%

Interior temperature summer:

°C

Annual useful cooling dem. qCool Length cooling period:

1263 184

kWh/a d

Average cooling load P Average: Marginal utility of additional heat losses:

0,3 43%

Inside thermal envelope

Space heat distribution Length of distribution pipes Nominal width of pipe Insulation thickness Insulation reflective coating? Thermal conductivity of insulation Heat loss coefficient per m of insulated pipe Insulation quality of mountings, pipe suspensions, etc. Thermal bridge supplement Total heating loss coefficient per m of pipe

Temp. of the room through which the pipes pass Design forward flow temperature Design system heating load Forward flow temperature control ('x' if applicable) Design return flow temperature Annual heat emission per m of plumbing Possible utilisation factor of released heat Annual heat losses of heating distribution

ϑX ϑV

Pheating ϑR q*HL hG QHL

m mm mm W/(mK) W/(mK) W/K W/(mK) °C °C kW °C kWh/(m·a) kWh/a

Outside thermal envelope

Total values

1 - keine

Absolute

Specific

kWh/a

kWh/(m²a)

0,0

Annual heat losses of heating storage

kWh/a

0,0

Annual heat losses of heating

kWh/a

0,0

Performance ratio of heat distribution

PHPP, DHW+Distribution

ea,HL

100%

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

DHW useful heat DHW demand for showers, per person and day (with 60°C) DHW demand others, per person and day (with 60°C) Performance of shower drain-water heat recovery Effective DHW demand VDHW Average cold water temperature of the supply ϑTW DHW demand for washing machines and dishwashers non-electric Effective useful heat DHW

QDHW

litre/person/d litre/person/d litre/person/d °C kWh/a

16,0 9,0 0% 25 18,1 0

kWh/a

kWh/(m²a)

kWh/a

1412

12,3

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

PHPP, DHW+Distribution

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Auxiliary calculation - shower drain-water heat recovery

PHPP, DHW+Distribution

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Inside thermal envelope

DHW distribution Temp. of room through which the pipes pass Design forward flow temperature DHW circulation pipes Length of circulation pipes (forward + return flow) Nominal width of pipe Insulation thickness Insulation reflective coating? Thermal conductivity of insulation Heat loss coefficient per m of insulated pipe Insulation quality of mountings, pipe suspensions, etc. Thermal bridge supplement Total heating loss coefficient per m of pipe

JX Jdist

°C °C

LHS

m mm mm W/(mK) W/(mK) W/K W/(mK)

Daily circulation period of operation. Design return flow temperature Circulation period of operation per year Annual heat released per m of pipe

tdCirc ϑR tCirc q*Z

h/d °C h/a kWh/m/a

Annual heat loss from circulation lines

DHW individual pipes Exterior pipe diameter Accumulated length per single pipes Amount of tapping points in building Average pipe length per tapping point Tap openings per person per day Utilisation days per year Heat loss per tap opening Amount of tap openings per year and person Annual heat loss of individual pipes

Total heat losses of DHW distribution Performance ratio of DHW distribution pipes

PHPP, DHW+Distribution

dU_Pipe LU ntapping point LU, average

qIndividual nTap QU

QWL ea,HL

Total values

20,0 60,0

10,0 60,0

1 - keine

Absolute

Specific

18,0

kWh/a

m m m d kWh/tap opening Tap openings per year kWh/a

Outside thermal envelope

0,018 20,00 5,00 4,0 5 365 0,0365 1825 212

kWh/a

kWh/(m²a)

0,0

kWh/a

kWh/(m²a)

212

1,8

kWh/a

kWh/(m²a)

212

1,8

115%

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Storage heat losses Selection of storage tank

Storage 1

Storage 2

Buffer storage tank (only heating)

Compact unit

2-nur Warmwasser

0-kein Speicher

0-No

Storage necessary for HP Solar DHW connection

Heat loss rate Storage volume Standby fraction

W/K litre -

Location of storage tank, inside or outside of thermal envelope Temperature of mechanical room Typical storage tank temperature Manual entry of storage temperature Average standby heat losses storage tank Additional heat losses storage tank, solar operation Possibly utilisation factor of heat losses Annual heat losses DHW storage tank Annual heat losses buffer storage tank

°C °C °C

3,0 200 50% 2-außerhalb 10,0 60,0 60,0

W W kWh/a

75 75 --1314 ---

3,0 --1-innerhalb

2-außerhalb

-----

kWh/a

kWh/(m²a)

1314

11,5

---

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

1526

13,3

Performance ratio DHW-distribution + storage

ea,WL

208% kWh/a

kWh/(m²a)

QgDHW

2937

25,6

Total heating demand of DHW system Including storage tank

PHPP, DHW+Distribution

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Inside thermal envelope

Cooling distribution Length of distribution pipes Nominal width of pipe Insulation thickness Insulation reflective coating? Thermal conductivity of insulation Heat loss coefficient per m pipe

Temp. of room through which the pipes pass Design forward flow temperature Dimensioning of cooling load of the system Forward flow temperature control ('x' if applicable) Design return flow temperature Annual heat absorption per m of pipe Possibly utilisation factor of this heat absorption Annual heat losses of cooling distribution

ϑX ϑV

Performance ratio cold water distribution pipes

PHPP, DHW+Distribution

Pheating

Outside thermal envelope

25,0

Total values 5

Absolute

Specific

m mm mm W/(mK) W/(mK) °C °C kW

ϑR q*HL hG QHL

°C kWh/(m·a) kWh/a

ea,HL

kWh/a

kWh/(m²a)

0,0

100%

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Solar thermal system Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) Building type: Detached house Treated floor area ATFA:

114,6

m²

Projected building footprint AProjected:

105,6

m²

Latitude ('Climate' worksheet)

37,9

DHW demand ('DHW+Distribution')

2937

kWh/a

Heating demand ('Heating' and 'DHW+Distribution' worksheets)

1302

kWh/a

Occupancy

3,2 48-roof slab

Location: Selection in 'Areas' worksheet Size of selected area Free area (less solar thermal and electrical systems) Deviation from North

7-verbesserter Flachkollektor

Collector

106

m²

Heating support (please check, if applicable)

101,4

m²

DHW priority (check if appropriate)

180

Angle of inclination from the horizontal

Alternative input: Deviation from North

180

Alternative input: Angle of inclination from the horizontal

Solar collector area

4,20

m²

Specific collector area

1,3

m²/Pers

Height of the collector field

1,07

Height of horizon

hHori

0,00

Horizontal distance

aHori

1000,00

Additional reduction factor shading

rother

100%

Results

Projected building footprint area

Absolute

kWh/(m²Projected*a)

kWh/a

Determination of PER factors Yield reference PV syst.

PERel

PERsol.therm

kWhel/a

kWhprim-el/kWhel

kWhel kWhth*kWhprimel/kWhel

0,29

Solar contribution total

87%

24,2

2554

902

Solar contribution to DHW

87%

24,2

2554

901,8

1,20

0,0

1,60

kgCO2eq/ m²Projected*a

kgCO2eq/a

1,1

115

Solar contribution to space heating

1-CO2 -Faktoren GEMIS 4.6 (Deutschland)

PHPP SolarDHW

Persons

kgCO2eq/ kWhFinal

0,045

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Heating demand covered by solar Radiation on tilted collector surface

1000

100%

900

90%

800

80%

700

70%

600

60%

500

50%

400

40%

300

30%

200

20%

100

10%

Heating demand DHW-preparation Space heating demand Heating demand Radiation on tilted collector surface Please enter: Solar production for DHW Please enter: Solar production for heating DHW heating demand covered by solar Space heating demand covered by solar Heating demand covered by solar Solar fraction Electricity generation of reference PV system

PHPP SolarDHW

Solar coverage

Solar radiation, heating demand [kWh/month]

Heating demand Solar fraction Electricity generation of reference PV system

0% Jan

Feb

Mar

Apr

May

Jun

Jul

Aug

Sep

Oct

Nov

Dec

Jan 249 0 249 476

Feb 225 0 225 463

Mar 249 0 249 715

Apr 241 0 241 752

May 249 0 249 772

Jun 241 0 241 773

Jul 249 0 249 819

Aug 249 0 249 867

Sep 241 0 241 771

Oct 249 0 249 623

Nov 241 0 241 521

Dec 249 0 249 380

162 0 162 65% 55

158 0 158 70% 53

232 0 232 93% 82

241 0 241 100% 86

249 0 249 100% 88

241 0 241 100% 87

249 0 249 100% 92

249 0 249 100% 97

241 0 241 100% 87

219 0 219 88% 71

183 0 183 76% 60

129 0 129 52% 44

Year 2937 0 2937 7934 0 0 2554 0 2554 87% 902

kWh/month kWh/month kWh/month kWh/month kWh/month kWh/month kWh/month kWh/month kWh/month kWh/month

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Photovoltaic systems Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) Climate data set: ud---03-Athens-Jessica Building type: Detached house Projected building footprint: Name of system

Anlage 1

Anlage 2

105,6

Anlage 3

m²

Anlage 4

Anlage 5

Reference PV syst.

48-roof slab

Location: Selection in 'Areas' worksheet

48-roof slab

Size of selected area

105,6

Deviation from North

220

180

m² °

Angle of inclination from horizontal

Alternative input: Deviation from North

220

Alternative input: Angle of inclination from the horizontal

Information from the module data sheet 5-Poly-Si

Technology

"1-"

Nominal current

IMPP0

8,20

Nominal voltage

UMPP0

30,40

Nominal power

249

Temperature coefficient short-circuit current

Temperature coefficient open-circuit voltage

Module dimensions: Height

1,658

Module dimensions: Width

0,994

"1-"

4-Mono-Si

7,71

30,50

235

0,050

0,040

%/K

-0,410

-0,340 1,658

%/K m

0,994

1,6

Module area [m²]

Further specifications nM

Number of modules

Height of module array

2,5 1

Height of horizon

hHori

0,2 0,0

Horizontal distance

aHori

1000,0

Additional reduction factor shading

rother

100%

Efficiency of the inverter

hHRV

95%

Results Area of module field

0,0

Free area on the selected building element Allocation to building element

4,2

m²

101,4

m²

0,0

Annual losses due to shading

kWh Total

902 8,5

0 0

0,00

117,2 0,0

0,0 #ΔΙΑΙΡ./0!

113

Annual electricity yield of the inverter, absolute Related to projected building footprint area CO2-equivalent emissions according to 1-CO2 -Faktoren GEMIS 4.6 (Deutschland) PE-factor according to 1-PE-Faktoren (nicht regenerativ) PHI Zertifizierung

kWh/(m²*Month)

Jan

Total

Feb Anlage 1

1 0,9

Yield [kWh/month]

0,8 0,7 0,6 0,5

Anlage 3

Anlage 4

Anlage110 5

143

170

Apr

176

179

143

May

210

184

Jun

225

184

225

Jul

234

195

1 234

Aug

217

206

217

Sep

164

184

Oct

116

148

116

0,8 85

176 210

164

Nov

124

Dec

1792

1889

1792

0,6

Jan

kWh/month

Feb

Mar

Apr

0,4 0

May

Jun

Jul

Aug

0,2 0

Sep

Oct

Nov

Dec

0,2 0,1 0 Jan

Feb

Mar

Apr

Year kWh/a

May

Jun

Jul

Aug

Sep

Oct

Nov

902

kWhprim/kWhEnd

1,2

Total monthly yield

0,4

kg/a

Mar

Year kWh/(m²a)

0,3

PHPP PV

84 Anlage

kWh/m²AProjected*a

Ambient temperature [°C]

Solar radiation on tilted surface

kWh/a

0 0

0 Dec

0 0 0

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

PHPP PV

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

PER and PE specific values ► EnerPHit with PHPP Version 9.3

Electricity demand for residential buildings Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

kWh/Use

1,00

/(P*a) *

3,2

2-Kaltwasseranschluss

Clothes washing

0,57

kWh/Use

2,50

kWh/Use

3,13

kWh/Use

0 0 1 1

1 1 1 1

kWh/d

0,29 0,22

kWh/d

1 1 1

11 100 50

4-Kondensationstrockner

Energy consumed by evaporation Refrigerating Freezing or combination Cooking with:

Lighting Consumer electronics Small appliances, etc.

kWh/Use Average lamp efficiency [lm/W]

W kWh

Total aux. electricity

114 * 100% * 67 * 100% * 340 100% 0

/(P*a) *

3,2

0,75

/(P*a) *

3,2

= =

0,50

/(P*a) *

3,2

* * * *

1,00 1,00 1,00 1,00

* * * *

365 365 365 500

d/a d/a d/a /(P*a)

* * * *

2 2 2 3,2

HH HH HH P

= = = =

0 0 211 350

* * *

1,00 1,00 1,00

* * *

2,90 0,37 1,00

kh/(P*a)* kh/(P*a)* /(P*a) *

3,2 3,2 3,2

P P P

= = =

102 * 100% 117 * 100% 159 * 100% 577

0,50

1-Strom

0 * * * * * *

114

340

0% 0%

100% 100% 100% 100%

0,13

*(1-

* (1+ 0,05 ) *

0,13

*(1-

* (1+ 0,00 ) * = = = =

0 0 211 350

= = =

102 117 159 577

* (1+ 0,30 ) *

0% 100%

Non-electric demand (kWh/a)

Solar fraction

Marginal performance ratio

Additional demand

Residual dampness

kWh/d

0,65

2-Kaltwasseranschluss

Clothes drying with:

13% 100%

Electricity demand (kWh/a)

0,55

Non-electric fraction

Solar fraction of DHW Laundry&Dish Marginal performance ratio DHW Marginal performance ratio Heating

Electric fraction

2,6 2,6 2,6 0,4

Useful energy (kWh/a)

Dishwashing

1,20 1,20 1,10 0,43

Reference quantity

Application

Norm demand

Frequency

PER and PE factors (KWh/kWh) Electricity: Non-electric energy carrier for cooking, drying: Energy carrier for heating: Energy carrier for DHW:

Utilisation factor

Within the thermal envelope? (1/0)

Column no.

2 3,2 115 11,4

Used ? (1/0)

Households Persons Living area (m²) Heating demand [kWh/(m²a)]

1,00

*(1-

0 0,73

Other: kWh/a kWh/a kWh/a

0 0 0

0 0 0 DHW Non-Electric - Wash&Dish

Total

2036

kWh

2036

kWh

Non-Renewable Non-Electric DHW Wash&Dish

Specific demand

Recommended maximum value

PHPP, Electricity

17,8

kWh/(m2a)

0,0

kWh/(m2a)

0,0

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Use non-residential buildings Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Latitude [°]:

38 7

0,8

500

0,8

0,30

0,70

10,00

22 Group office

207

500

0,8

0,30

0,70

23 Open-plan office

250

2750

2543

207

500

0,8

0,00

1,00

15,00

24 Meeting

250

2750

2543

207

500

0,8

0,50

1,00

2,00

25 Counter area

250

2750

2543

207

200

0,8

0,00

1,00

26 Retail

300

3600

2999

601

300

0,8

0,00

1,00

7,00

27 Classroom

200

1400

1398

300

0,8

0,25

0,90

2,00

28 University auditorium

150

1500

1409

500

0,8

0,25

0,70

0,75

29 Bedroom

365

8760

4407

4353

300

0,8

0,00

0,50

365

4015

755

3260

200

0,8

0,25

0,30

250

1750

1748

200

0,8

0,00

1,00

32 Restaurant

300

4200

2404

1796

200

0,8

0,00

1,00

33 Kitchen non-residential

300

3900

2404

1496

500

0,8

0,00

1,00

34 Kitchen, Storage, Preparation

300

3900

2404

1496

300

0,8

0,50

1,00

35 WC, Sanitary

250

2750

2543

207

200

0,8

0,90

1,00

36 Other habitable rooms

250

2750

2543

207

300

0,8

0,50

1,00

37 Secondary areas

250

2750

2543

207

100

0,8

0,90

1,00

38 Circulation area

250

2750

2543

207

100

0,0

0,80

1,00

39 Storage, Services

250

2750

2543

207

100

0,8

0,98

1,00

40 Server room

365

8760

4407

4353

500

0,8

0,50

41 Workshop

250

2250

2192

500

0,8

0,00

1,00

42 Theatre auditorium

250

1001

946

200

0,8

0,00

1,00

43 Theatre foyer

250

1001

946

300

0,8

0,50

1,00

44 Theatre stage

250

2500

1253

1247

1000

0,8

0,00

0,60

45 Fair, Congress

150

1350

1260

300

0,8

0,50

1,00

46 Exhibition

250

2001

1850

151

200

0,8

0,00

1,00

47 Library reading room

300

3600

2999

601

500

0,8

0,00

1,00

48 Open access library

300

3600

2999

601

200

0,8

0,00

1,00

49 Library repository

300

3600

2999

601

100

0,8

0,90

1,00

50 Gymnasium

300

4500

3002

1498

300

0,8

0,30

1,00

51 Parking garage

250

2750

2543

207

0,0

0,95

1,00

52 Public parking garage

365

5475

3290

2185

0,0

0,80

1,00

30 Hotel room 31 Canteen

PHPP, Use non-res

Height of utilisation level (0.8 or 0.0 m)

207

2543

Height of utilisation level (0.8 or 0.0 m)

2543

2750

Illumination level [lux]

2750

250

Lighting

250

Annual utilisation days [d/a]

Daily utilisation hours [h/d]

End utilisation [h]

Begin utilisation [h]

21 Single office

Utilisation pattern

Average occupancy [m²/Pers.]

Part use factor of building operating period for lighting

Relative absenteeism

Daily operating hours of ventilation

Daily operating hours of heating

Annual utilisation hours during night-time [h/a]

Annual utilisation hours during daytime [h/a]

Annual utilisation hours [h/a]

0,8

1,50

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

PER and PE specific values ► EnerPHit with PHPP Version 9.3

Electricity demand for non-residential buildings (at the moment this worksheet is inactive. Calculation takes place in the 'Electricity' worksheet). Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) Treated floor area ATFA:

114,6

m²

Auxiliary electricity demand:

577,1

kWh/a

PER factors: 1,20 1,75

PE factors: kWh/kWh 2,6 kWh/kWh 1,1

1,1

North East South

kWh/kWh

West

Nonperpendicul ar radiation

0,57 0,55 0,46 0,47

0,95

0,85

Glazing fraction

0,58 0,55 0,62 0,63

W/m²

[x]

h/a

PHPP, Electricity non-res

Spec. electricity demand (kWh/(m²a))

W/m²

Electricity demand (kWh/a)

Full load hours of lighting

User determined: Lighting full load hours

Window width

Lighting check

Utilisation hours per year

Lintel height

Motion detector used?

Room height

Lighting control

Room width

[x]

Installed lighting power (standard)

Room depth

User data: Installed lighting power

Window existing?

Degrees

Geometry: input of a typical room

Light transmission glazing

Deviation from North

Lux

Orientation

Power of nominal lighting

m²

Room category

Net ground area

Room / Zone

Dirt factor

87%

Facade with windows

Lighting / non-residential

Shading

Daylight utilisation

Electricity: RE gas / Natural gas: Energy carrier for DHW: Solar fraction of DHW Marginal performance ratio DHW:

Window properties (from 'Windows' worksheet):

h/a

kWh/a

kWh/(m²a)

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

69%

None

0,0

Manual

Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector Without motion detector

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

* (1-

2,0

* (1-

2,0

* (1-

2,0

* (1-

2,0

400

300

100

0,0

2,0

8760

0,0

8760

0,0

PC in energy saving mode

Monitor 2

0 0

Monitor in energy saving mode

Copier

0 0

Copier in energy saving mode

Printer

0 0

Printer in energy saving mode

Server

0 0

Existing [1/0]

Within the thermal envelope [1/0]

Room category (predominant utilisation pattern of building)

Telephone system

Utilisation hours per year [h/a]

Server in energy saving mode

) ) -

Solar fraction

Marginal performance ratio

PC 2

Electric fraction

Monitor in energy saving mode

Electricity demand [kWh/a] 0

)

Electricity demand [kWh/a]

0,0

Non-electric fraction

Non-electric demand (kWh/a)

0,0

Additional demand

Useful energy [kWh/a]

)

Useful energy (kWh/a) 0

Norm consumption

Monitor 1

Duration of utilisation in energy saving mode [h/a] =

PC in energy saving mode

Kitchen / Aux. electricity

Number of meals per day of use

PC 1

Relative absenteeism

Utilisation hours per year [h/a]

Power consumption [W]

Existing [1/0]

Quantity

Within the thermal envelope [1/0]

Room category

Office equipment

8 kWh / Meal

Electricity

Dishwashing

Cold water connection

Refrigerating

0,25

* *

kWh / Cover

0,10

* *

kWh/d

365

= 55%

0,0 0

= * (1+

0,30

1,20

*(1-

0,87

0,0 0

100%

0,0

100%

0,0

100%

0,0

100%

0,0

100%

0,0

100%

0,0

100%

0,0

100%

0,0

100%

577

Total

577

PHPP, Electricity non-res

Total auxiliary electricity

Specific demand

0% 0%

kWh

Hot water nonelectric dishwashing

Cooking:

0,0 577,1

0,0

577

0,0

kWh/a

kWh/(mÂ˛a) kWh/(mÂ˛a)

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

PER and PE specific values ► EnerPHit with PHPP Version 9.3

Aux Electricity Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

m²

Heat recovery efficiency ventilation unit

0,91

Annual space heating demand

113

Operation vent. system Winter

2,71

kh/a

Boiler rated power

Air volume

287

m³

Operation vent. system Summer

6,05

kh/a

DHW system heating demand

Air change rate

0,63

h-1

Design forward flow temperature

kWh/a °C

Internal heat gains summer [W]

kWh/(m2a) kW

Internal heat gains winter [W]

2937

Utilisation period [h/a]

Available as interior heat

Electricity demand [kWh/a]

Reference size

Period of operation

Application

Utilisation factor

Column no.

Norm demand

Dwelling units

Within the thermal envelope [1/0]

115

Heating period

Existing [1/0]

Treated floor area

Ventilation system Winter ventilation

Defroster HX

Summer ventilation

0,55

Additional vent. summer

0,36

Wh/m³

0,63

h-1

2,7

kh/a

287

m³

Data entries in 'Ventilation' worksheet or in 'Addl vent'

0,36 0,37

0,55

Wh/m³

0,54 0,00

h-1

* *

6,0

kh/a

287

6,0

kh/a

287

m³ m³

176

considered in heat recovery efficiency

0,1

2,71

335

1,0

6,05

Internal heat sources ' Additional summer ventilation'

0,0

1,0

6,05

3,9

Controlled / non controlled

Heating system Enter the rated power of the pump

Circulator pump heating Boiler electricity consumption at 30% load

Aux. energy - Heat. boiler

Aux. energy - Wood fired/Pellet boiler

1,0

2,7

kh/a

1,0

2,71

1,00

0,00

kh/a

1,0

2,71

1,0

2,71

Data entries in 'Boiler' worksheet. Aux. energy demand including possible drinking water production.

DHW system Enter average power consumption of pump

1,00

4,5

kh/a

1,0

8,76

1,00

0,2

kh/a

1,0

8,76

1,00

0,0

kh/a

1,0

8,76

1,00

1,8

kh/a

1,0

8,76

Aux. electricity cooling

kWh/a

1,00

1,0

6,05

kWh/a

1,00

* *

1,0

Aux. electricity dehum.

1,0

6,05

kWh/a

1,00

1,0

8,76

Circulation pump DHW

Enter the rated power of the pump

Storage load pump DHW

Boiler electricity consumption at 100% load

DHW boiler aux. energy

W W

165

Enter the rated power of the solar DHW pump

Solar aux. electricity

W W

Aux. electricity cooling and dehumidification

Misc. aux. electricity Misc. aux. electricity

Total Specific demand

PHPP, Aux Electricity

577 kWh/(m²a) (treated floor area)

5,0 PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Internal heat gains for residential buildings (at the moment this worksheet is inactive) Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Utilisation: 10-Dwelling Type of values used: 2-Standard

IHG heating

2,97

W/m²

IHG cooling

2,97

W/m²

No input is necessary

Go to utilisation pattern selection

kWh/d kWh/d kWh/Use W W kWh

W/P W W W W W/P

0,50 1,00 1,00 1,00 1,00 1,00 1,00 1,00

57 365 365 365 500 2,9 0,37 1,0

1,00 1,00 1,00 1,00 1,00 1,00 1,00

8,76 8,76 8,76 8,76 8,76 8,76 8,76

/(P*a) /(P*a) /(P*a) d/a d/a d/a /(P*a) kh/(P*a) kh/(P*a) /(P*a)

kh/a

114 67 340 0 0 0 0 211 350 102 117 159

* * * * (1-

* * * * * * *

0 2228

0 212 0 0 -696

kh/a kh/a kh/a kh/a

* * * *

Total IHG Specific IHG Heat available from internal sources

PHPP, IHG

0,30 0,30 0,70 0,80 0,00 1,00 1,00 1,00 0,50 1,00 1,00 1,00

/ / /

8,76 8,76 8,76

= = =

4 2 27

/ / / / / / / /

8,76 8,76 8,76 8,76 8,76 8,76 8,76 8,76

0 0,55

/ /

8,76 8,76

1,00 1,00 1,00 1,00 1,00

/ / / / /

8,76 8,76 8,76 8,76 8,76

= = = = = = = = = = = = = = = = =

0 0 0 24 20 12 13 18 0 0 140 -10 0 24 0 0 -79

kh/a kh/a

113

d/a

Internal heat gains [W]

W/P

kWh/d

/(P*a)

Utilisation period [h/a]

80,0 -3,3 0,0 24,1 0,0 0,0 -25,0

kWh/Use

65 57 57

Availability

0,0 1 1 0 1 0 0 1

kWh/Use

1,00 0,65 0,75

kWh/(m²a) d/a

Included in electricity balance?

0 3 3 0 1 1 1 3

kWh/Use

11 113

Useful energy [kWh/a]

0,6 0,6 2,5 0,0 -3,1 0,0 0,0 0,3 0,2 11,1 100,0 50,0

kWh/Use

0 0 0 1 1 1 1 1

1 1 1 1 1 1 1 1 1 1 1 1

Heating demand Heating period

Frequency

1 1 1

P m²

Utilisation factor

Norm consumption

Dishwashing Clothes washing Clothes drying with: 4-Kondensationstrockner Energy consumed by evaporation Refrigerating Freezing or combination Cooking Lighting Consumer electronics Household appliances/Other Auxiliary appliances (cf. aux Electricity sheet) Other applications (cf. Electricity sheet) Persons Cold water DHW - circulation DHW - individual pipes DHW storage tank heating case DHW storage tank cooling case Evaporation

Within the thermal envelope [1/0]

Application

3,2 115

Existing [1/0] or occupancy

Persons Living area

195

W/m²

1,70 4,6

kWh/(m²a)

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Internal heat gains for non residential buildings (at the moment this worksheet is inactive) Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Utilisation: 10-Dwelling

IHG

2,97

W/m²

Type of values used: 2-Standard

Invalid input

{

Persons B

Invalid input

{

Persons C

Invalid input

{

Persons D

Invalid input

{

Persons E

Invalid input

{

Persons F

Invalid input

{

Persons G

Invalid input

{

Utilisation hours per year [h/a]

°C

1,00

8760

1,00

8760

1,00

8760

1,00

8760

1,00

8760

1,00

8760

1,00

8760

-15

1,00

8760

Lighting / Equipment / Aux. electricity

Availability

Useful energy [kWh/a]

Evaporation (person specific)

27 Not a standard value Not a standard value Not a standard value Not a standard value Not a standard value Not a standard value Not a standard value

Average heat release

Persons A

Heat emitted per person [W]

Planning 0 = according to ground area or usable zone 1 = according to occupancy

Average occupancy [Pers./m²]

Internal heat gains aux. electricity:

Utilisation period [h/a]

d/a Ground area of useful zone [m²]

113

Utilisation period [h/a]

Room temperature: Heating period:

Relative presence

P m²

Number of occupants

Select

Selection of user profile

Persons

3,2 114,6

Activity of persons

Persons: Treated floor area:

Average heat release persons [W]

No input is necessary

8,76

Office applications (within therm. envelope)

8,76

Cooking (within therm. envelope)

0,5

8,76

Dishwashing (within therm. envelope)

0,3

8,76

Cooling (within therm. envelope)

8,76

Other

8,76

(within thermal envelope)

Total IHG Specific IHG Heat available from internal sources

PHPP, IHG non-res

Utilisation period [d/a]

Availability

Occupied days per year [d/a]

-1,9

Loss night-time [W]

DT: Cold water temp. - Room temp. [K]

Cold water due to flushing WC

Loss daytime [W]

Number of WCs (calculation value)

Amount of WCs: Utilisation of standard values for schools?

Number of WCs (user data)

Predominant utilisation pattern of building (Data transferred from 'Electricity non-res' worksheet; input kitchen)

Heat loss due to cold water (calculation from column AJ)

On/Off [1 / 0]

Auxiliary appliances (see 'Aux Electricity' worksheet)

Average power cold water

Lighting

113

d/a

-1

365

W/m²

0,0

kWh/(m²a)

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Biomass ► EnerPHit with PHPP Version 9.3

Primary Energy Renewable PER Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a)

Building type: Detached house

115 106 11

Treated floor area ATFA: Selection of heat generation system Primary heat generator 6-Strom direkt (Widerstandsheizung/Durchlauferhitzer) Secondary heat generator (optional) 5-Strom direkt (WW Wärmespeicher) Energy demand Reference: Treated floor area

Contribution margin (useful energy) Heating

DHW

100%

Projected building footprint AProjected: Addl. input in following worksheets

Heating demand incl. distribution & hydr. frost protection

100%

PER

Final energy demand

PER factor

kWh/(m²a)

kWh/kWh

Effective PER factor (including biomass contingent) kWh/kWh

1,10

kWh/(m²a)

11,4

1,60 1,60

1,10

12,5

2,60 2,60 2,60 0,70 1,10 1,10 0,00 2,60 2,60

1,5

1,60

1,10

1,7

2,60

Cooling and dehumidification Electricity cooling (heat pump) Auxiliary electricity cooling, ventilation summer Electricity dehumidification (heat pump) Auxiliary electricity (dehumidification)

4,1 2,9

1,50 1,50 1,50 2,00 2,00

10,5 6,1 4,4

0,43

6,6 4,0

1,19

0,7

2,60

1,19 1,19

15,2 15,2

22,3 3,3

0,29 1,19

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

0,6

1,20

Household electricity Electricity (household or non-residential lighting, etc.) Auxiliary electricity (other)

12,7 12,7

Gas / RE gas dry/cook

0,0

Energy generation Reference: Projected building footprint area

87% 13%

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

1,75

Final energy Final energy Final energy generation generation kWh/a

PV electricity Solar thermal system

1,20 1,20

0 2554

PER factor

PER specific value

kWh/kWh

kWh/(m²AProjecteda)

1,00 1,00

24,2 0,0 24,2

Requirement met?

Useful energy, performance Achievable energy standard through the verification of Annual heat. dem. Heating load Useful cool. energy Cooling load renewable primary energy (assessment of individual aspects) Treated floor area Treated floor area Treated floor area Treated floor area kWh/(m²a) W/m² kWh/(m²a) W/m² Requirement EnerPHit Premium Requirement EnerPHit Plus 15 17 11 Requirement EnerPHit Classic Requirement 11 11 12 10 Current building reaches following class for aspect Premium Premium

Summary

Final energy

PER specific value

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. Demand Generation Demand, cumulative generation (annual balance) Demand w/o household electricity Demand w/o household electricity, cum. generation

PHPP, PER

MWh/a 6,7 -2,6 4,19

MWh/a 5,8 -2,6 3,29

5,3 2,73

4,1 1,56

PE Value

CO2eq emissions

1-PE-Faktoren (nicht 1-CO2 -Faktoren regenerativ) PHI GEMIS 4.6 Zertifizierung (Deutschland) MWh/a kg/a 10,88 2342 -3,12 115 7,76 2457 7,09 3,97

1566 1681

33,5

20,4 6,9

29,5

0,532 0,532 -0,070 0,250 0,320 0,045 0,532 0,532

6,0

4,0

0,532

0,8 3,7 2,2 1,6

0,532 0,532 0,532 0,532

3,1

0,0 8,7

0,532 0,532 -0,070 0,250 0,320 0,045 0,532

1,003 1,8

1,5

0,532

0,3

33,1 33,1

6,8 6,8

0,532 0,532

0,0

0,270

PE factor

PE Value

Emission factor (CO2-eq)

kWh/kWh

kWh/(m²a)

kg/kWh

PER

kg/(m²a)

10,2

2,60 2,60 2,60

0,0 24,2 0,0 Current building reaches following class for aspect

11,2

0,0

kWh/(m²AProjected*a)

CO2eq emissions

1-CO2 -Faktoren GEMIS 4.6 (Deutschland)

18,2 10,6 7,6

2,60 2,60 2,60 2,60 0,39 2,60 2,60 0,70 1,10 1,10 0,00 2,60

1,20 1,20 0,85|1,24|0,93 1,10 1,75 2,30 0,29 1,20

CO2 emissions factor (CO2-eq) kg/kWh

95,0

14,2

0,0

CO2 CO2eq emissions kg/a

29,6 1,2

1,1 0,045

29,6

1,1

Primary Energy Renewable PER

Airtightness n50 1/h 1,00

0,6 Premium

CO2eq substitution balance

200

PER demand 180 Premium EnerPHit 160 0 15 140 30 Premium 45 120 45 EnerPHit 100 Classic 0 80 60 PER generation [kWh/(m²Projected*a)]

100%

kWh/(m²a)

CO2 PE Value

kWh/kWh kWh/(m²a) 1-PE-Faktoren (nicht regenerativ) PHI Zertifizierung

1,60 1,60 0,85|1,24|0,93 1,10 1,75 2,30

Aux. electricity (vent.winter, frost protection, circ.pump, boiler, wood / pellets)

DHW generation Electricity (HP compact unit) Electricity (heat pump) District heating: 20-Gas-BHKW (70% KWK) Wood and other biomass Natural gas / RE gas Heating oil / Methanol Solar thermal system Electricity (direct)

kWh/(m²a)

PE PE factor

PER specific value

51,0 Heating Electricity (HP compact unit) Electricity (heat pump) District heating: 20-Gas-BHKW (70% KWK) Wood and other biomass Natural gas / RE gas Heating oil / RE methanol Solar thermal system Electricity (direct through DHW storage tank) Electricity (direct through heating resistance)

kWh/(m²a)

Final energy Contribution (final energy)

m²

Cooling energy dem. incl. dehumidification DHW demand including distribution:

m²

PER generation 104 104 120 136 200

PER demand EnerPHit Plus 0 30 45 60 60

PER generation 44 44 60 76 200

0 0

300 300

300

60 40

60 Plus

1-CO2 -Faktoren Classic 75 0 GEMIS 4.6 0 15 (Deutschland) 75 kg/a 2342 Current building EnerPHit Premium -531 51 1811

16 30

300 45

PER200 demand [kWh/(m²TFA*a)]

EnerPHit Plus

300 EnerPHit Classic

Current building

1566 1034

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Passive House compact unit with exhaust air heat pump Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) Calculation based on measured values of the laboratory evaluation for component certification Building type: Detached house Treated floor area ATFA: Covered fraction of space heating demand

('PER' worksheet)

QH+QHL: (DHW+Distribution)

Space heating demand + distribution losses

hSolar, H ('SolarDHW' worksheet)

Solar contribution for space heating Effective annual heating demand

115

m²

0% 1302

QH,Wi=QH*(1-hSolar, H)

kWh

0% kWh Including DHW connection for washing machines & dishwashers

Covered fraction of DHW demand

('PER' worksheet)

Total heating demand of DHW system Solar contribution for DHW Effective DHW demand

QgDHW (DHW+Distribution)

2937

hSolar, DHW ('SolarDHW' worksheet)

87% 0

QDHW ,Wi=QDHW *(1-hSolar, DHW )

2937

kWh

87% 0

kWh

Sort: AS LIST Compact unit selection:

Go to list of compact units

Measured values from laboratory test Ventilation Effective heat recovery efficiency

heff (Test stand)

Electric efficiency

Outdoor air temperature Measured thermal power heat pump Heating Measured COP Heating

Test point 1

Measured thermal power DHW storage heating-up Measured thermal power DHW storage reload Measured COP DHW storage heating-up Measured COP DHW storage reload

Measured thermal power heat pump Standby Measured COP Standby

Test point 3

Test point 4

°C

PHP,Heating

COPHeating

Test point 1

Test point 2

Test point 3

Test point 4

°C

Tamb

PDHW,Heating-Up

PDHW,Reload

COPDHW,Heating-Up

COPDHW,Reload

Standby (inputs required only if different from storage reload) Outdoor air temperature

Test point 2

Tamb

Domestic hot water Outdoor air temperature

Wh/m³

(Test stand)

Heating

Test point 1

Test point 2

Test point 3

Test point 4

°C

Tamb

PHP,Standby

COPStandby

Specific heat loss storage incl. connections

U * A Storage (Test stand)

Average storage temperature in standby mode

TDHW,Standby (Test stand)

Heat pump priority

Efficiency SHX exhaust air mixing Heat recovery efficiency SHX exhaust air mixing (if applicable) Volume flow rate of added exhaust air (if applicable)

W/K °C

separate heat pumps

DHW priority

Room temperature (°C)

Av. ambient temp. Heating P. (°C)

Av. Ground temp (°C)

Heating priority

h*SHX hSHX,add (Design Value)

Vadd (Test stand)

m³/h

Hydraulic frost protection

Heat supplied by direct electricity Space heat supplied by HP Winter DHW supplied by HP

QE,dir

kWh/a

QHP,Heating

kWh/a

QHP,DHW,Winter

Winter standby heat supplied by HP

QHP,Standby,Winter

Summer DHW supplied by HP

QHP,DHW,Summer

Summer standby heat supplied by HP

kWh/a kWh/a

QHP,Standby,Summer

kWh/a kWh/a

Performance factor of heat generator, DHW & space heating Seasonal performance factor

Final energy demand heat generation

SPFH-3 kWh/a

kWh/(m²a)

kWh/a

kWh/(m²a)

kg/a

kg/(m²a)

kg/a

kg/(m²a)

Qfinal

Annual PE demand (non-renewable primary energy)

Annual CO2-equivalent emissions

PHPP, Compact

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Heat pump Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) Building type: Detached house Treated floor area ATFA: 115 Covered fraction of space heating demand Space heating demand + distribution losses Solar fraction for space heat Effective annual heating demand Covered fraction of DHW demand Total heating demand of DHW system Solar fraction for DHW Effective DHW demand

('PER' worksheet)

QH+QHL: hSolar, H QH,Wi=QH*(1-hSolar, H)

(DHW+Distribution) ('SolarDHW' worksheet)

('PER' worksheet)

QgDHW hSolar, DHW QDHW,Wi=QDHW *(1-hSolar, DHW )

(DHW+Distribution) ('SolarDHW' worksheet)

Number of heat pumps in the system

m²

0% 1302 0% 0

kWh/a kWh/a

0% 1623 87% 0 1

kWh/a kWh/a

Heating & DHW

Functionality Heating Selection of HP: Selection of distribution system Design distribution temperature Nominal power of distribution system

Heat source: θdesign

(DHW+Distribution)

Pnom

#ΤΙΜΗ!

°C

0,00

Distribution system (to be completed by experienced users only) Nominal power of distribution system Radiator exponent Heat storage tank (buffer storage tank 'DHW+Distribution' worksheet) Specific heat losses storage

Pnom

n 0-No U * A Storage

W/K 2-Outside

Storage location in thermal envelope Room temperature (storage location: outside of thermal envelope) Sink temperature of heat pump for heating

(DHW+Distribution)

°C °C

θsnk

Entries in relation to the domestic hot water system Selection of HP:

Heat source: (DHW+Distribution)

DHW temperature Orientation of DHW storage tank ('storage 1' in 'DHW+Distribution' worksheet) Specific heat losses storage

60,00

°C

2-Outside U * A Storage

3,0 (DHW+Distribution)

Room temperature (storage location: outside of thermal envelope)

10,00

W/K °C

Type of backup heater Δθ of electric continuous flow water heater

Additional options in case of one heat pump for both functions: Heating & DHW 1-Yes

Same heat pump's sink temperature for Heating and for DHW (Manufacturer, tech. data)

Heat pump priority Control strategy Heat pump control strategy Heating Depth ground water / Ground collector / Ground probe Power of pump for ground heat exchanger

PHPP, HP

z Ppump

0,00

m kW

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Heating Heat pump: Source: θ_source °C

θ_sink °C

Heating capacity kW

COP

Test point 1 Test point 2 Test point 3 Test point 4 Test point 5 Test point 6 Test point 7 Test point 8 Test point 9 Test point 10 Test point 11 Test point 12 Test point 13 Test point 14 Test point 15

ΔθSink

Temperature difference in sink

DHW Heat pump: Source: θ_source °C

θ_sink °C

Heating capacity kW

COP

Temperature difference in sink

Electr. energy consumption pump (grnd. water / ground) Energy by direct electricity Space heat supplied by HP Winter DHW supplied by HP Summer DHW supplied by HP Space heating supplied by HP without storage losses Winter DHW supplied by HP without storage losses Summer DHW supplied by HP without storage losses Electrical consumption of HP

Seasonal performance factor of heat pump Final electrical energy demand heat generation

ΔθSink

QEl,Pump

kWh/a

QEl,dir

kWh/a

QHP,Heating

kWh/a

QHP,DHW,Winter

kWh/a

QHP,DHW,Summer

kWh/a

QHP,Heating

kWh/a

QHP,DHW,Winter

kWh/a

QHP,DHW,Summer

kWh/a

QelHP

kWh/a 1. HP: Heating or heating & DHW

2. HP: Domestic hot water

kWh/a

kWh/(m²a)

kg/a

kg/(m²a)

SPFH-1 Qfinal

Annual primary energy demand Annual CO2-equivalent emissions

PHPP, HP

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Heat pump ground (ground collectors / ground probes) Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) Building type: Detached house Treated floor area ATFA:

115

m²

Ground probes Probe field configuration Length of probe Probes spacing/distance Depth (z=H/2) Type of probe Borehole radius Inner radius of pipe Exterior pipe radius Distance between pipes Inner radius of pipe casing (only coaxial) Exterior radius casing pipe (only coaxial) Thermal conductivity of pipe Thermal conductivity of back fill Probe time constant Internal borehole resistance Borehole resistance

Ground collectors

('HP' worksheet)

Ground Soil type Density of the ground Thermal capacity of ground Thermal conductivity of ground Soil temperature conductivity Ground temperature gradient Brine Brine (characteristics at 2 °C) Density of the brine dynamic viscosity of the brine Heat capacity brine Thermal conductivity of brine Brine - mass flow

A H B z A rb ri ra BU ri2 ra2 λR λF tp Ra Rb

Individual probe 0 m m 0 m Double-U

A ρE cpE λE aE ΔTG

Sand, 9% moisture 1440 kg/m³ 1507 J/(kgK) 1,0 W/(mK) 4,516E-07 m/s² 0,022 K/m

A ρS ηS cpS λS mS

Inner radius of pipe Exterior pipe radius Thermal conductivity of pipe Pipe depth Ground water depth Pipe spacing Base area Pipe outer surface Pipe length

m m m m m m W/(mK) W/(mK) d Km/W Km/W

zpipe zgw

#ΔΙΑΙΡ./0! #ΔΙΑΙΡ./0!

m m W/(mK) m m m 2 m m2 m

Brine Brine (characteristics at 2 °C) Density of the brine dynamic viscosity of the brine Heat capacity brine Thermal conductivity of brine Brine - mass flow

A ρS ηS cpS λS mS

Specific heat extraction rate

qex

W/m

U*A

W/K

Climate Period duration Average ground surface temp. Surface temperature amplitude Phase shifting surface

Ethylene glycol 25% 1052 kg/m³ 0,0052 kg/(ms) 3950 J/(kgK) 0,48 W/(mK)

ri ra λr

Tm0 T1 t02

Ethylene glycol 25% 1052 kg/m³ 0,0052 kg/(ms) 3950 J/(kgK) 0,48 W/(mK) kg/s

365 18,1 9,3 42

d °C °C d

kg/s

Operation type Waste heat from active cooling to ground probe? Please check, if applicable. Heat pump operation duration Specific heat extraction rate as an annual average

Ground characteristics

A B C D E F G H I J

Sand, 9% moisture Sand, 13% moisture Ground, coarse gravel Loam, 36% moisture Clay Clay / Silt Slate Silt Rock

Properties of the brine

A B C D E

Ethylene glycol 25% Potassium carbonate Potassium formate Water

PHPP, HP ground

h/a W/m W/K

qex H/Rb

Thermal conductivity [W/(mK)]

Density [kg/m³]

Heat capacity [J/(kg K)]

Heat capacity [MJ/(m³ K)]

0,980 1,500 0,520 2,300 1,280 2,200 2,100 1,500 3,500

1440 1600 2000 1650 1500 2550 2700 1920 2500

1507 1800 1840 2847 880 882 870 2938 2500

2,170 2,880 3,680 4,700 1,320 2,250 2,350 5,640 6,250

Temperature

Density

[°C] 2 2 2 2

[kg/m³] 1052 1265 1226 997

Heat Thermal capacity conductivity [J/(kg K)] [W/(mK)] 3950 0,480 2941 0,544 3190 0,534 4190 0,590

Thermal conductivity [10-7 m²/s] 4,520 5,210 1,410 4,900 9,700 9,780 8,940 2,660 5,600

Dynamic viscosity [kg/(ms)] 0,0052 0,0031 0,00237 0,001307

Source

Result ground probe calculation Month

[Neiß 1977] [Neiß 1977] [VDI 1984] [Neiß 1977] [VDI 1984] [VDI 2000] [VDI 2000] [ISO 13370] [ISO 13370]

Borehole temperature °C

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

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

Boiler (gas, oil and wood) Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) Building type: Detached house Treated floor area ATFA: Covered fraction of space heating demand

Solar contribution for space heating

hSolar, H

Effective annual heating demand

QH,Wi=QH*(1-hSolar, H)

Space heating demand without distribution losses

Covered fraction of DHW demand

1302

(DHW+Distribution)

hSolar, DHW

Solar contribution for DHW

kWh

('SolarDHW' worksheet)

0% 0

kWh

('Verification' worksheet)

1302

kWh

('PER' worksheet)

QgDHW

Total heating demand of DHW system

m²

('PER' worksheet)

QH+QHS:

Space heating demand + distribution losses

Effective DHW demand

115

(DHW+Distribution)

2937

('SolarDHW' worksheet)

87% 0

QDHW,Wi=QDHW *(1-hSolar, DHW )

kWh

1-keine

Boiler type

Fuel PER factors (renewable primary energy)

('Data' worksheet)

#ΤΙΜΗ!

kWhPER/kWhFinal

PE factor (non-renewable primary energy)

('Data' worksheet)

#ΤΙΜΗ!

kWhPE/kWhFinal

CO2 emissions factor (CO2-equivalent)

('Data' worksheet)

#ΤΙΜΗ!

g/kWh

Useful heat provided

QUse

Max. heating power required for heating the building Length of the heating period Length of DHW heating period

PBH

kWh/a 1,23

tHP

2713

tDHW

8760

('Heating load' worksheet)

Use characteristic values entered (check if appropriate)? Project data Design output

Pnom

Installation of boiler (Outdoor: 0, Indoor: 1)

(Manufacturer)

Boiler efficiency at nominal output

h100%

(Manufacturer)

Standby heat loss boiler at 70 °C

qB,70

(Manufacturer)

Average return flow temperature measured at 30% load

J30%

(Manufacturer)

Input values (biomass heat generator)

Efficiency of heat generator in steady-state operation Average fraction of heat output released to heating circuit Temperature difference betw. power-on and power-off

Input field

Project data h30%

Efficiency of heat generator in basic cycle

Input values (oil and gas boiler) Boiler efficiency at 30% load

Standard values 15

(Rating plate)

Standard values

Input field

Standard values

Input field

°C Project data

hGZ

(Manufacturer)

60% 70%

hSO

(Manufacturer)

zHC,m

(Manufacturer)

m²

0,4

In case of inside installation: area of installation room

Ainstall

(Project)

m²

Useful heat output per basic cycle

QN,GZ

(Manufacturer)

kWh

22,5

kWh

QN,m

(Manufacturer)

15,0

QHE,GZ

(Manufacturer)

kWh

Pel,SB

(Manufacturer)

Average power output of the heat generator Heat generator with built in conveyor for pellets Unit only with regulation (no fan / no starting aid) Auxiliary energy demand for a basic cycle Power consumption in steady-state operation

Utilisation factor of heat generator space heating Utilisation factor heat generator DHW Utilisation factor heat generator DHW & space heating

hH,g,K =f j*hk'' hDW,g,K =h100%/f j,DW hg,K

0% 0% 0% kWh/a

Final energy demand space heating

QFinal,HE = QH,wi* eH,g,K

Final energy demand DHW

QFinal,TW = QDHW,wi* eTW,g,K

Total final energy demand

QFinal = QEnd,HE + QEnd,TW

kWh/(m²a)

0 0

0,0

kg/a

kg/(m²a)

Annual PE demand (non-renewable primary energy)

Annual CO2-equivalent emissions

PHPP, Boiler

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

EnerPHit with PHPP Version 9.3

District heating and combined heat power (CHP) Passivistas:TheHouseProject / Climate: Athens-Jessica / TFA: 115 m² / Heating: 11,4 kWh/(m²a) / Cooling: 12,2 kWh/(m²a) / PER: 51 kWh/(m²a) Building type: Detached house Treated floor area ATFA: Covered fraction of space heating demand

('PER' worksheet)

Annual heating demand kWh/a Solar contribution for space heating

hSolar, H

Effective annual heating demand

QH,Wi=QH*(1-hSolar, H)

Covered fraction of DHW demand QDHW

DHW demand

hSolar, DHW

Solar contribution for DHW Effective DHW demand

(DHW+Distribution)

115

0% 1302

('SolarDHW' worksheet)

('PER' worksheet)

(DHW+Distribution)

2937

('SolarDHW' worksheet)

87% 0

QDHW,Wi=QDHW *(1-hSolar, DHW )

m²

kWh

PE factor (non- CO2 emissions renewable) factor (CO2-eq)

20-Gas-BHKW (70% KWK)

Definition of heat source for PE factor and CO2 emissions

kWhPE/kWhFinal

kg/kWh

0,70

-0,070

PER factors energy carrier

PER factors CGS

Definition of heat source for calculation of PER factor Heat net

Efficiency district heating net

80% Fraction

Efficiency Electricity

Heat

PHC complex

85%

40%

50%

Within biomass budget

Boiler for peak loads

15%

96%

Excess of biomass budget

1,60

1,24

DHW Summer

1,20

0,93

PHC complex & boiler for peak loads

Total

100%

Performance ratio of heat transfer station Utilisation factor of heat transfer station

Final energy demand heat generation Annual PE demand (non-renewable primary energy)

Annual CO2-equivalent emissions

PHPP, District heating

ha,HX

100%

ha,SHX

Qfinal = QUse* ea,DH

1,10

kWh/a

kWh/(m²a)

0,0

kg/a

kg/(m²a)

0,0

0,85

PHPP_V9.3a_EN_Passivistas_20160205.xlsx

Table of PER and PE factors as well as CO2-equivalent emission factors of different energy carriers and uses from different sources Transfer to 'PER' worksheet

Energy type

Number

Fuel source

Electricity

Environmental energy, solar thermal energy

User defined energy carrier (for generation, please enter user defined factords for demand in columns N and O) District heat

Gas CGS

Heating oil-EL CGS

District heating: User determined District heating combined heat power (CHP) District heating from heating station

Energy carrier

10 20 30 31 41 42 32 21 43 44 50 46 47 33 22 48 60 61 00 01 02 03 04 05 06 62 63 64 65 66 67 71 72 73 80 81 74 98 99 1 10 11 12 20 21 22 30 31 32 40 13 14 15 16

PER-factor

1-PE-Faktoren (nicht regenerativ) PHI Zertifizierung

kWhprim-el/ kWhFinal

kWhprim/ kWhFinal

None Heating oil 2,30 Natural gas 1,75 LPG 1,75 Hard coal 2,30 Brown coal 2,30 Biogas 1,10 Pyrolysis oil or bio oil 1,10 Wood 1,10 Wood logs 1,10 Pellets 1,10 Forest woodchips 1,10 Poplar woodchips 1,10 RE-Gas 1,75 RE-Methanol 2,30 Biomass 1,10 Electricity-mix Electricity mix from CHC Primary electricity 1,00 Household electricity 1,20 Electricity for DHW 1,20 Electricity for heating 1,60 Electricity for cooling 1,50 Electricity for dehumidification 2,00 Platzhalter_EE-Stromanwendung Electricity from photovoltaics 1,00 Monocrystalline photovoltaic electric solar energy 1,00 panels Polycrystalline photovoltaic electric solar energy 1,00 panels Onshore wind power 1,00 Offshore wind power 1,00 Hydroelectric power station > 10MW 1,00 Ground heat, geothermal energy 0,00 Ambient high temperature 0,00 Ambient low temperature 0,00 Solar thermal flat plate collector (generation) 1,00 Solar thermal evacuated tube collector (generation) 1,00 Waste heat 0,00 Eigener Energietr채ger 1-None 10-Hard coal CGS 70% PHC 11-Hard coal CGS 35% PHC 12-Hard coal CGS 0% PHC 20-Gas CGS 70% PHC 21-Gas CGS 35% KWK 22-Gas HS 0% PHC 30-Oil CGS 70% PHC 31-Oil CGS 35% PHC 32-Oil CGS 0% PHC 40-Eigene Eingabe: 90% KWK Fossil fuel Renewable fuel Fossil fuel Renewable fuel

Calculation in 'District heating' worksheet

Heat generator

1,10 1,10 1,10 1,10 1,20 1,10 1,10 0,20 0,20 0,20 0,20 0,20

2,60 2,50 2,60 2,60 2,60 2,60 2,60 2,60 0,00 0,00 0,00 0,00 0,00 0,00 0,00 0,00 0,00 0,00 0,00 0,00

0,00 0,80 1,10 1,50 0,70 1,10 1,50 0,80 1,10 1,50 0,80 0,70 0,00 1,30 0,10

x) Gas will be used No. 1 10 11 12 13 20 21 30 31 32 40

Type 1-None 10-Improved gas condensing boiler 11-Improved oil condensing boiler 12-Gas condensing boiler 13-Oil condensing boiler 20-Low temperature boiler gas 21-Low temperature boiler oil 30-Firewood pieces (direct and indirect heat emission) 31-Wood pellets (direct and indirect heat emission) 32-Wood pellets (only indirect heat emission) 40-Reserve

Fuel ('Comparison' worksheet)

1 2 1 2 1 2

x x

3 4 4

Dishwashers and washing machines 1-DHW connection 2-Cold water connection Clothes drying 1-Clothes line 2-Drying closet (cold!) 3-Drying closet (cold!) in extract air 4-Condensation dryer 5-Electric exhaust air dryer 6-Gas exhaust air dryer Cooking 1-Electricity 2-Natural gas 3-LPG

PHPP, Data

Availability electricity 1 1 0,9 0,7 1 1

Availability evaporation 1 1 0,9 0 1 1

Electric fraction

PE factor 2,60 1,10 1,10

100% 0% 0%

CO2 factor 0,53 0,25 0,27

PER-factor 1,20 1,75 1,75

PHPP_V9.3a_EN_Passivistas_20160205.xlsx