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Passive homesGUIDELINES FOR THE DESIGN AND CONSTRUCTION OF
PASSIVE HOUSE DWELLINGS IN IRELAND
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Sustainable Energy Ireland (SEI)
Sustainable Energy Ireland was established as Ireland’s national
energy agency under the Sustainable Energy Act 2002. SEI’smission
is to promote and assist the development of sustainable energy.
This encompasses environmentally andeconomically sustainable
production, supply and use of energy, in support of Government
policy, across all sectors of theeconomy including public bodies,
the business sector, local communities and individual consumers.
Its remit relates mainlyto improving energy efficiency, advancing
the development and competitive deployment of renewable sources of
energyand combined heat and power, and reducing the environmental
impact of energy production and use, particularly inrespect of
greenhouse gas emissions.
SEI is charged with implementing significant aspects of
government policy on sustainable energy and the climate
changeabatement, including:
• Assisting deployment of superior energy technologies in each
sector as required;
• Raising awareness and providing information, advice and
publicity on best practice;
• Stimulating research, development and demonstration;
• Stimulating preparation of necessary standards and codes;
• Publishing statistics and projections on sustainable energy
and achievement of targets.
It is funded by the Government through the National Development
Plan with programmes part financed by the EuropeanUnion.
© Sustainable Energy Ireland, 2007. All rights reserved.
No part of this material may be reproduced, in whole or in part,
in any form or by any means, without permission. The material
contained in thispublication is presented in good faith, but its
application must be considered in the light of individual projects.
Sustainable Energy Ireland can not be held
responsible for any effect, loss or expense resulting from the
use of material presented in this publication.
Prepared by MosArt Architecture and UCD Energy Research
Groupwith contribution from Sharon McManus as part of MEngSc
thesis.
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Table of Contents
Preface . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . ii
Foreword . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . iii
SECTION ONE
The‘Passive House’ . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . 1
1.1 Passive House and the Passivhaus Standard . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . 1
1.1.1 Definition of the Passivhaus Standard . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . 1
1.1.2 Technical Definition of the Passivhaus Standard for
Ireland . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . 3
1.2 Application of the Passivhaus Standard in the EU and Ireland
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . 3
1.2.1 Evolution of the Passivhaus Standard in Europe . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . 3
1.2.2 Application of the Passivhaus Standard in Ireland . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . 4
SECTION TWO
How to Design and Specify a Passive House in Ireland . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . 7
2.1 Building Design Process for a Passive House . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . 9
2.2 General Principles: Heat Energy Losses & Heat Energy
Gains . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . 10
2.2.1 Passive House Building Envelope . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . 10
2.2.2 Passive House Building Systems . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . 17
2.3 Energy Balance Calculations and Passive House Specification
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . 24
2.3.1 PHPP Software and Applications . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . 24
2.3.2 Passive House Certifications . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . 24
SECTION THREE
Passive House Prototype for Application in Ireland . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . 29
3.1 Design and Specification . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. 31
3.1.1 Combining Aesthetic and Energy Performance in House Design
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . 31
3.1.2 Decision Support using Passive House Planning Package
(PHPP) Software . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . 31
3.1.3 Prototype Passive House External Wall Sections . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . 32
3.1.4 Prototype Passive House Design including Mechanical and
Electrical Services . . . . . . . . . . . . . . . . . . . . . . . .
. . . 38
3.2 Cost Considerations . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . 39
i
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PrefaceBy Dr Wolfgang Feist, Founder of the Passive House
Institute, Germany
Energy Efficient Passive Houses – Reducing the Impact of Global
Warming
The February 2007 report of the Inter-Governmental Panel on
Climate Change(IPCC) has shown that climate change is already a
very serious global issue. Thenegative effects it will have on the
ecosystem, the world economy and on livingconditions are
anticipated to be on a massive scale.
Climate change is caused largely by human behaviour due mainly
to the use offossil fuels as our main source of energy generation.
The magnitude of futureclimate changes is closely linked to
worldwide CO2 emissions into the earth’satmosphere. The worst
effects of global warming, such as a thawing of the
entireland-borne ice in Greenland and Antarctica, can still be
prevented. However, thisrequires a substantial reduction in
worldwide CO2 emissions far below thecurrent level.
There is hardly any doubt that an energy system ready for the
future will have tobe sustainable. Sustainable development is
economic development that can becontinued in the future without
causing significant problems for other people,the environment and
future generations.
Passive Housing can play a major role in reducing the impact of
global warming.The energy requirement of a passive house is so low
that a family will never againneed to worry about energy price
hikes. Passive Houses are virtually independentof fossil sources of
energy and can be fully supplied with renewable energy if acompact
heat pump unit is used in combination with an ecological
electricitysupplier. Due to the low energy requirement of passive
houses the regionallyavailable renewable energy sources are
sufficient to provide a constant supply ofenergy for everyone.
Ireland’s mild climate puts it in a favourable position to
introduce Passive Housesto mainstream construction compared to the
more severe climates prevalent incentral Europe.
ii
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Foreword
Sustainable Energy Ireland is Ireland’s national energy agency,
set up to support Irish government energy
policy objectives. Following the introduction of new
legislation, most notably the European Community
Directive on the Energy Performance of Buildings and the recent
announcement of the intent to regulate
and require the use of renewable energy systems in new
buildings, we are seeing the emergence of
extraordinary standards of energy performance for building
construction in Ireland, as well as a rapid
increase in the uptake of renewable energy technologies for
building services.
Ireland is facing a number of serious challenges includingrising
energy costs and meeting our emissions obligationsunder the Kyoto
protocol. These and other factors havegiven rise to a fundamental
rethink in the way we design,construct and operate buildings. As we
move forward, it isbecoming clear that building ‘green’ has evolved
and is fastbecoming the preferred choice, providing high quality,
highefficiency, dynamic and cost effective solutions forconsumers
and businesses. The passive house is theultimate low energy
building. The passive house standard isrecognised in Europe as the
most advanced in terms ofenergy performance of buildings and going
forward theEuropean Commission is set on implementing the
passivehouse standard and also on setting more
stringentrequirements for the refurbishment of existing
buildings.
Today, the passive house offers one of the most
desirabletechnological and economical solutions for
comfortableliving and working. It can be applied to new and
existingbuildings in the commercial, industrial, public
andresidential sectors. With close to 10,000 passive houses builtin
Europe, this well proven and tested innovative standard isnow
attracting significant interest in Ireland with pioneerslike MosArt
and Scandinavian Homes leading an emergingmovement in the
construction industry.
In response to the need to educate professionals and
theirclients on how to design, specify and construct passive
houses and facilitate the further development of thisstandard
here in Ireland SEI commissioned ‘Guidelines forthe Design and
Construction of Passive House Dwellings inIreland‘. These detailed
guidelines for self-builders andarchitects focus on new build
houses and cover bothconventional block construction and timber
frameconstruction methods. They will ultimately become part ofa
suite of guidelines to cover, for example, multipledwellings,
non-residential buildings, extensions,renovations etc.
The guidelines cover the rationale and definition of thepassive
house standard, how to design and specify a passivehouse along
with, construction options, associated services,cost considerations
and lifestyle issues. SEI hopes they willbe useful in increasing
awareness and understanding of thekey principles and techniques in
designing, constructingand operating the ultimate low energy
building – thepassive house.
David TaylorCEO Sustainable Energy Ireland
iii
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SECTION ONE
The ‘Passive House’
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1.1 Passive House and thePassivhaus Standard
A passive house1 is an energy-efficientbuilding with year-round
comfort andgood indoor environmental conditionswithout the use of
active space heatingor cooling systems. The space heatrequirement
is reduced by means ofpassive measures to the point at whichthere
is no longer any need for aconventional heating system; the
airsupply system essentially suffices todistribute the remaining
heatrequirement. A passive house providesvery high level of thermal
comfort andprovision of whole-house eventemperature. The concept is
based onminimising heat losses and maximisingheat gains, thus
enabling the use ofsimple building services. Theappearance of a
passive house does notneed to differ from a conventional houseand
living in it does not require anylifestyle changes. Passive houses
arelight and bright due to large glazedareas designed to optimise
solar gains,as well as healthy buildings in which tolive and work
due to fresh air supplythrough the ventilation system.
The Passivhaus Standard is aconstruction standard developed by
thePassivhaus Institut in Germany(http://www.passiv.de). The
Standard canbe met using a variety of designstrategies,
construction methods andtechnologies and is applicable to
anybuilding type.
This publication outlines therequirements in applying that
standardin Ireland and in all cases when referringto a passive
house is describing a housebuilt to the requirements of
thePassivhaus Standard.
1.1.1 Definition of the PassivhausStandard
The Passivhaus Standard is a specificconstruction standard for
buildings withgood comfort conditions during winterand summer,
without traditional spaceheating systems and without activecooling.
Typically this includesoptimised insulation levels with
minimalthermal bridges, very low air-leakagethrough the building,
utilisation ofpassive solar and internal gains andgood indoor air
quality maintained by amechanical ventilation system withhighly
efficient heat recovery.Renewable energy sources are used asmuch as
possible to meet the resultingenergy demand (PEP, 2006),
includingthat required for the provision ofdomestic hot water
(DHW). It should benoted that the primary focus in buildingto the
Passivhaus Standard is directedtowards creating a thermally
efficientenvelope which makes the optimum useof free heat gains in
order to minimisespace heating requirement. While thereare also
limitations on the amount ofprimary energy that can be used by
adwelling for such uses as DHW, lightingand household appliances,
this will notbe the primary focus of these guidelines.That is not
intended to imply that suchenergy uses are insignificant,
however.In fact, a passive house will have thesame DHW requirements
as any typicalhouse in Ireland and given the lowenergy required for
space heating theenergy demand for DHW will represent arelatively
high proportion of the overallconsumption. In order to address
this,some guidance is provided on strategiesto ensure that
renewable energies areemployed as much as possible forproduction of
DHW.
1
The ‘Passive House’
Passive house in Ghent, Belgium (2004).Source: Passiefhuis
Platform vzw.
Passive house in Oberosterreich, Austria (2000).Source: IG
Passivhaus Osterreich Innovative Passivhausprojekte.
Interior of passive house in Oberosterreich, Austria(2000).
Source: IG Passivhaus Osterreich InnovativePassivhaus projekte.
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Structural air-tightness (reduction of airinfiltration) and
minimal thermalbridging are essential. A whole-housemechanical heat
recovery ventilationsystem (MHRV) is used to supplycontrolled
amounts of fresh air to thehouse. The incoming fresh air is
pre-heated via a heat exchanger, by theoutgoing warm stale air. If
additionalheat is required, a small efficient back-upsystem (using
a renewable energysource, for example) can be used toboost the
temperature of the fresh airsupplied to the house.
The energy requirement of a house builtto the Passivhaus
Standard is:
• Space heating requirement (deliver-ed energy) of
15kWh/(m2year)
treated floor area (TFA), and
• The upper limit for total primaryenergy demand for space and
waterheating, ventilation, electricity forfans and pumps,
householdappliances, and lighting notexceeding 120kWh/(m2year),
regard-less of energy source.
Additionally, the air-leakage test resultsmust not exceed 0.6
air changes perhour using 50Pa overpressurisation
andunder-pressurisation testing.
In order to maintain high comfort levelsin any building, heat
losses must bereplaced by heat gains. Heat losses occurthrough the
building fabric due totransmission through poorly insulatedwalls,
floor, ceiling and glazing as well as
2
Air-leakage (or infiltration) is theuncontrolled penetration of
outsideair into a building. It takes placethrough openings,
primarily throughinadequate and imperfect sealingbetween window
frames and walls,between the opening sections of thewindow and
along the joints of thebuilding envelope.
Thermal bridging refers to a material,or assembly of materials,
in abuilding envelope through whichheat is transferred at a
substantiallyhigher rate (due to higher thermalconductivity) than
through thesurrounding materials. Junctionsbetween window or door
and wall,wall and floor, and wall and roofshould be designed
carefully to avoidthermal bridging. A thermal bridgeincreases heat
loss through thestructure, and in some extreme casesmay cause
surface condensation orinterstitial condensation into
theconstruction. Surface mould growthor wood rot may be the
consequencesof a thermal bridge.
Measure/Solution Passivhaus Standard for the Prototype House in
the Irish Climate
1. Super Insulation Insulation Walls U < 0.175 W/m2K
Insulation Roof U < 0.15 W/m2K Insulation Floor U < 0.15
W/m2K Window Frames, Doors U < 0.8 W/m2K Window Glazing U <
0.8 W/m2K Thermal Bridges Linear heat Coefficient Ψ < 0.01 W/mK
Structural Air Tightness n50 < 0.6/ air changes per hour 2. Heat
Recovery/ Air Quality Ventilation counter flow air to air heat
exchanger
Heat Recovery Efficiency > 75%
Minimal Space Heating Post heating ventilation air/ Low
temperature heating
Efficient small capacity heating system Biomass, compact unit,
gas etc. Air quality through ventilation rate Min 0.4 ac/hr or
30m3/pers/hr Ventilation Supply Ducts Insulated Applicable 3.
Domestic Hot Water Biomass, compact unit, gas, heat pump, etc. DHW
cylinder and pipes well insulated Applicable Solar thermal system
Recommended 4. Passive Solar Gain Window Glazing Solar energy
transmittance g > 50% DHW solar heating Area to be dictated by
house size and
occupancy Solar Orientation Minimal glazing to north Thermal
Mass within Envelope Recommended 5. Electric Efficiency Energy
labelled Household appliances A rated appliances Hot water
connection to washing machines/ dishwashers
Recommended
Compact Fluorescent Lighting Recommended Regular maintenance
ventilation filters Recommended Energy Efficient fans Recommended
6. On-site Renewables Solar thermal system Recommended Biomass
system Recommended Photovoltaics Application in a case by case
basis Wind Turbine Application in a case by case basis Other
including geothermal Application in a case by case basis
Table 1. Technical Definition of the Passivhaus Standard for
Ireland.
Passive house in Hannover, Germany (2004).Source: IG Passivhaus
Deutschland InnovativePassivhaus projekte.
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from uncontrolled cold air infiltrationthrough leaky
construction and poorlyfitted windows and doors. In a
typicaldwelling, such heat losses have to bebalanced by heat gains
mostlycontributed by a space heating system.The internal heat gains
from occupantsand other sources such as householdappliances as well
as passive solar gainscontribute a relatively small proportionof
the total overall need in aconventional dwelling. In a
passivehouse, the heat losses are reduced sodramatically (through
better insulationand airtight detailing) such that thesame internal
gains and passive solargain now contribute a relatively
highproportion of the total need. As a resultof this, a smaller
space heating system istherefore required compared to that
needed in a conventional dwelling.
A new built semi-detached, two-storeyIrish house built to comply
with therequirements of Building RegulationsTechnical Guidance
Document (TGD)Part L 2005, Conservation of Fuel andEnergy), uses
approx. 75kWh/m2
delivered energy for space heating and159kWh/m2 primary energy.
ThePassivhaus Standard requirement forspace heating is
15kWh/(m2year)delivered energy. When compared, thereduction in
space heating demandrepresents 80%.
1.1.2 Technical Definition of thePassivhaus Standard for
Ireland
In Table 1, a range of U-values arespecified in order to meet
the Passivhaus
Standard of space heating requirement(delivered energy) of
15kWh/(m2year) forthe Irish climate. Specifying U-values
isdependent upon many variables andcan only be verified through
testing theperformance of the dwelling design inthe PHPP software.
The U-valuesincluded in Table 1 have been tested forthe prototype
passive house presentedlater in Section 3. This prototype house isa
semi-detached two storey house ofvery compact form. A
detachedbungalow house of sprawling formwould require much lower
U-values tomeet the Passivhaus Standard. Due tothe mild Irish
climate, it is possible to useU-values for walls in the
prototypehouse that are higher than thosetypically recommended by
thePassivhaus Institute for colder centralEuropean climates.
A sensitivity analysis was undertakenusing different U-values
for theprototype house in order to see, forexample, whether it
would be possibleto relax the building fabric requirementse.g.
double glazing, in Ireland and stillachieve the Passivhaus
Standard. Theresults of this analysis are included inSection 2.
1.2 Applications of thePassivhaus Standard inthe EU and
Ireland
1.2.1 Evolution of the PassivhausStandard in Europe
The Passivhaus Standard originated in1988 by Professor Bo
Adamson of theUniversity of Lund, Sweden and Dr.Wolfgang Feist of
the Institute forHousing and the Environment. Theconcept was
developed through anumber of research projects and firsttested on a
row of terraced houses by Dr.Wolfgang Feist in 1991 in
Darmstadt,Germany. The Passivhaus Institut(http://www.passiv.de)
was founded inDarmstadt, Germany in 1996 by Dr.Wolfgang Feist as an
independentresearch institution. Since then, it hasbeen at the
forefront of the PassiveHouse movement in Germany and hasbeen
instrumental in disseminating thestandard throughout Europe
andoverseas (more details in Section 2).
3
Comparison of delivered energy in conventional house and in
house built to Passivhaus Standard.Source: Passivhaus Institut.
http://www.passiv.de.
0
10
20
30
40
50
60
70
80
21
kWh/
m y
Building Regulations 2005(TGD) Part L
Passive House
80% Reduction2
Delivered space heating energy comparison, Building Regulations
(TGD) Part L and Passivhaus Standard.Source: UCD Energy Research
Group.
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Dwellings built to the PassivhausStandard have been constructed
all overEurope in recent years but mostespecially in Germany and
Austria wherethe Passivhaus Standard was firstapplied.2 Over 10,000
dwellings havebeen built to the standard throughoutEurope,
including 4,000 in Germany andAustria, Norway, Sweden, Denmark
andBelgium and this number is continuingto grow. CEPHEUS3 (Cost
Efficient PassiveHouses as European Standards) was aresearch
project (1998–2001) thatassessed and validated the
PassivhausStandard on a wider European scale. Theproject was
sponsored by the EuropeanUnion as part of the THERMIEProgramme of
the EuropeanCommission, Directorate-General ofTransport and Energy.
Under CEPHEUS,14 housing developments were built,resulting in a
total of 221 homesconstructed to the Passivhaus Standardin five
European countries. Anotherproject supported by the
EuropeanCommission, Dictorate General forEnergy and Transport is
PEP, whichstands for ‘Promotion of EuropeanPassive Houses’
(http://www.europeanpassivehouses.org). PEP is a consortiumof
European partners aiming to spreadthe knowledge and experience on
thepassive house concept throughout theprofessional building
community,beyond the select group of specialists.
1.2.2 Application of PassivhausStandard in Ireland
The Kyoto Protocol came into force in2005 and the proposed
targets ofreducing CO2 emissions by 8%compared to 1990 levels by
the period2008–2012 became legally binding forEU Member States
(UNFCCC, 1997).Ireland’s target under the Kyoto Protocolto limit
green house gas emissions to13% above 1990 levels by that periodwas
reached in 1997, and it is likely thatthe target will be overshot
by up to 37%(74Mt CO2) by 2010 (O’Leary et al, 2006).The EC Green
Paper on Energy Efficiency(EC, 2005), states that it is possible
forthe EU-25 Member States to achieveenergy savings of 20% by 2010,
and seesthe greatest proportion of these savings(32%) coming from
the built environ-ment.
In Ireland the residential sector accountsfor 26% of primary
energy consumption
and 27% of energy related CO2emissions (11,376 kt CO2), the
secondlargest sector after transport at 32%. Theaverage dwelling
emits approximately8.2 tonnes of CO2 emissions, 5 tonnesfrom direct
fuel use and 3.2 tonnes fromelectricity use (O’Leary et al, 2006)
andIrish dwellings have a higherconsumption of energy, electricity
andenergy related CO2 emissions perdwelling compared to the average
of theEU-15 (EC, 2005).
The Government White Paper ‘Deliveringa Sustainable Energy
Future for Ireland’(DCMNR, 2007) highlighted thatamendment to the
Building Regulationsin 2008 would bring a further 40%energy
reduction and related CO2emissions in new build construction.
Therecent Programme for Government hasbrought forward that
amendment to2007 and committed to a furtheramendment in 2010 to 60%
belowcurrent standards.
It is clear that the performance of bothnew build and existing
housing stockmust be addressed if we are to achievethe objectives
set out both at Europeanand national level. The energyrequirement
of a house built toPassivhaus Standard goes beyond theproposed 40%
energy reduction andrelated CO2 emissions in new
buildconstruction.
A study completed by UCD EnergyResearch Group quantified the
potentialreduction for space heating energy andCO2 emissions when
the PassivhausStandard for space heating of15kWh/m2year is applied
to the Irish newbuild residential construction market(Brophy et al.
2006). Five scenarios ofvarying levels of application
wereinvestigated. The tool used in this studywas a computer based
model,developed as part of the “Homes for the21st Century” study
(Brophy et al. 1999),which profiled the existing nationaldwelling
stock by dwelling form,insulation characteristics and heatingsystem
types. The model was used topredict the energy consumption andCO2
emissions of dwellings with a typicalfloor area of 100m2,
constructed to 2002building regulation standard. Thisprovided
national common practiceenergy consumption and CO2
emissionsfigures. It was found that a typical Irish
4
Passive house in Guenzburg, Germany (2006).Source: UCD Energy
Research Group.
Passivhaus Eusenstadt, Austria. Source: Construct Ireland Issue
2, Vol 3.
Multy family dwelling, ‘Hohe Strasse’, Hannover,Germany. Source:
UCD Energy Research Group.
Kronsberg Passivhaus Complex Hannover, Germany.Source: UCD
Energy Research Group.
-
dwelling consumes 9,722 kWh/year ofdelivered energy on space
heating andas a result releases 2,855 kgCO2/yearinto the
atmosphere. The space heatingrequirements for the same size
ofdwelling built to Passivhaus Standardswas found to be only 1,500
kWh/year ofdelivered energy which equates to 176kgCO2/year. (It was
assumed 50:50 splitbetween the use of gas and woodpellets for space
heating energy sourceas typically used in passive houses).
Thedifference in delivered energyconsumption and carbon
dioxideemissions between the two constructiontypes for a single
building over one yearwas therefore 8,222 kWh/year and
2,680kgCO2/year. Applying potential energyand CO2 emissions saving
rates to the 20year average new build dwellingconstruction rate of
40,000 homes peryear the following results werecalculated. The
results showed thatsubstantial savings are achievablethrough the
application of thePassivhaus Standard in Ireland (Table 2).
The Passivhaus Standard was firstintroduced in Ireland by the
Swedisharchitect Hans Eek at the ‘See the Light’conference
organised by SustainableEnergy Ireland (SEI) in June 2002.
TomásO’Leary of MosArt Architects, a delegateat the conference, was
so enthused byMr Eek’s presentation that he decided onthe spot to
sell his townhouse, buy a sitein the countryside in Co. Wicklow
andbuild a passive house. The O’Leary familyhas been living in the
“Out of the Blue”house since Spring 2005. This house isthe first
Irish passive house to becertified by the Passivhaus Institute
inGermany, and has been the focus of aresearch, demonstration and
energymonitoring project funded bySustainable Energy Ireland.
MosArtArchitects, the Passivhaus Institute of DrWolfgang Feist and
the UCD EnergyResearch Group are partners in theproject. The
project is instrumental inestablishing the basis for thedeployment
of the Passivhaus Standardin Ireland in different ways:
• it has provided a learning experiencefor professionals
involved in thedesign, specification, constructionand servicing
stages
• it will provide a scientific basis forperformance assessment
through
5
Percentage (and number) of new dwellings built to Passivhaus
Standard
Potential energy and CO2 emissions savings per
year
Potential energy and CO2emissions savings in
3.29 GWh 0.691 TWh 1% (400)
1.07 ktCO2 5.02 MtCO2
16.44 GWh 3.453 TWh 5% (2,000)
5.36 ktCO2 25.10 MtCO2
65.78 GWh 13.813 TWh 20% (8,000)
21.44 ktCO2 100.41 MtCO2
164.44 GWh 34.533 TWh 50% (20,000)
53.59 ktCO2 251.03 MtCO2
20 years
Table 2: Potential for space heating energy and carbon dioxide
savings.
Building Energy Rating Label. Source: Sustainable Energy
Ireland.
The EU Energy Performance of Buildings Directive (EPBD) was
transposed into Irishlaw on 4th January 2006. This states that when
a building is constructed, rented orsold a Building Energy Rating
(BER) certificate and label must be made available toprospective
buyers or tenants. The BER is expressed in terms of kWh of
primaryenergy/m2/year. A passive house would achieve an A2 rating
(UCD Energy ResearchGroup).
-
monitoring and evaluation
• it is an excellent demonstration tooland has been the focus of
manyvisits, presentations and journalarticles.
6
References
Brophy, V., Clinch, J.P., Convery, F.J.,Healy, J.D., King, C.
and Lewis, J.O., 1999“Homes for the 21st Century - The Costs&
Benefits of Comfortable Housing forIreland”. Dublin. Report
prepared forEnergy Action Ltd.
Brophy, V., Kondratenko, I., Hernandez,P., Burke, K., 2006
“Potential for Energyand CO2 Emission Savings throughapplication of
the Passive houseStandard in Ireland”. Published in thePassive
House Conference 2006 pp. 119-124. Hanover, Germany.
European Commission (EC), 2005.“Green Paper on Energy
Efficiency”.[Internet] EC. Available
at:http://ec.europa.eu/energy/efficiency/index_en.html
European Commission (EC), 2006.
“Promotion of European Passive Houses(PEP)". [Internet] PEP.
Available at: http://www.europeanpassivehouses.org/html
Government of Ireland, Department ofCommunications, Energy and
NaturalResources (DCMNR), 2007. Government"White Paper Delivering a
SustainableEnergy Future for Ireland". [Internet]DCERN. Available
at:http://w w
w.dcmnr.gov.ie/Energy/Energy+Planning+Division/Energy+White+Paper.html
O’Leary, F., Howley, M., and O’Gallagher,B., 2006. “Energy in
Ireland 1990-2004,Trends, issues, forecast and indicators”.Dublin.
Sustainable Energy Ireland.
United Nations Framework Conventionon Climate Change (UNFCCC),
1997.The Kyoto Protocal. [Internet]. UNFCCC.Available at:
http://unfccc.int/resource/docs/convkp/kpeng.html
1 A passive house is a building, for whichthermal comfort
(ISO7730) can beachieved solely by post-heating or post-cooling of
the fresh airmass, which isrequired to fulfill sufficient indoor
airquality conditions (DIN 1946) - without aneed for recirculated
air. Source:http://w w w.passivhaustagung.de/P a s s i v e _ H o u
s e _ E / p a s s i v e h o u s e _definition.html
2 See http://www.passiv-on.org/
3 See http://www.passiv.de/07_eng/
news/CEPHEUS_final_short.pdf
Ireland’s first Passive House, Wicklow.Source: MosArt
Architecture.
The O’Leary’s embark on their passive house project.Source:
MosArt Architecture.
-
SECTION TWO
How to Design & Specify a Passive House in Ireland
-
This section introduces the passivehouse building design process
as well asexplaining the balance between energylosses and gains. It
also provides anoverview of the various building systemsand
technologies typically employed ina passive house and presents the
PHPPsoftware used for energy balancecalculations. The design
andspecification of the example prototypepassive house in the Irish
climatedeveloped as part of these guidelineswill be covered in
greater detail inSection 3.
2.1 Building Design Processfor a Passive House
Client’s BriefThe design of a passive house willtypically
commence with developing abrief with the Client, whether this is
afamily wishing to build a single ruraldwelling, a Local Authority
progressing ahousing scheme or a commercialdeveloper proposing a
mixed residentialproject. The brief would typically outlinethe
Client’s practical requirements interms of space functions and
densityand also their preferred image orconcept for the
building(s). Clientsinterested in building a passive housewill
often have carried out aconsiderable amount of research on
thesubject and so will already be relativelywell informed regarding
the benefits ofliving in a passive house.
Site VisitA site visit is important to (thus reducingthe
potential for achieving a glazedsouth facing façade) identify
thepresence of structures, landform orevergreen trees which might
castshadows on the house during the shortwinter days when the sun
is low in the
sky. It may happen that the best viewsfrom the site are to the
north suggestingthe placement of large glazing areas onthe northern
façade in order to optimisethe best view. All orientation
optionsmust be considered by the designer atthis stage - the house
must not onlyfunction well in terms of energyefficiency but also in
terms of optimisingthe potential of the site and
itssurroundings.
Sketch DesignThe next phase of the design process isto develop a
sketch design for the house.The basic principles of passive
housedesign will greatly inform thedevelopment of the initial
design. Anideal approach would be to have thelongest façade of the
house facingsouth, a bias of glazing towards thesouthern elevation
with reduced glazingarea on the northern elevation and acompact
form in order to minimisesurface to volume ratio. Shading
devicesmay be required in order to protectagainst the risk of
overheating insummer and the aesthetic integration ofthese are
essential. In terms of internallayout, it is preferable to
organise, wherepossible, family rooms and bedrooms onthe southern
elevation with utility roomand circulation spaces on the
northernelevation where availability of sunlight isnot so
critical.
Initial Evaluation of Energy PerformanceOnce the sketch design
has beenapproved by the client, it is important totest the energy
balance of the housedesign using the Passive House PlanningPackage
(PHPP). The essential elementsof the design are entered into
thespreadsheet U-values of walls, floors,roof and glazing as well
as orientation,
volume, and size of the house. This willprovide an early
indication of whetherthe Passivhaus Standard is beingachieved. If
the space heat requirementis significantly above the threshold
of15kWh/(m2year) then the building willhave to be modified whether
in terms ofimproved U-values, reorganisation ofglazing or
adjustment of form. Thedesigner should intuitively know
howimprovements can best be achievedwhile broadly remaining true to
theagreed sketch design. If the space heatrequirement is
significantly less than thethreshold level, then it might be
possibleto increase the U-values and thereforesave on insulation
costs. Care should betaken to note other performanceindicators
calculated by the software,such as frequency of overheating,
forexample.
Detailed Design and SpecificationThe design of the house is
nextdeveloped to the level of detail requiredto apply for planning
permission.Typically this would not require allconstruction details
but it is wise toconsider the various technologies at thisstage in
order to avoid difficulties lateron. The type of construction will
need tobe considered, whether timber frame,concrete, externally
insulated masonry,insulated concrete formwork, straw bale,etc as
well as the space required forservices such as solar panels,
largedomestic hot water tank, mechanicalventilation equipment with
supply andexhaust ducting. The specification ofsuch services might
be outside theexpertise of the house designer and itmay be required
to commission theservices of a Mechanical and ElectricalEngineer.
It is also critically important toplan ahead in terms of
airtightness and
9
How to Design & Specify a Passive House in Ireland
-
cold bridging detailing as these oftenrepresent the most
challenging aspectsof passive house design. The detaileddesign
should be re-tested in the PHPPsoftware to ensure that the
PassivhausStandard is achieved. At this stage all therequired data
fields have to becompleted as accurately as possible(details of the
PHPP tool datasheets isoutlined in section 2.3.1). This
mightrequire some minor redesign of theinitial house design. The
Client shouldbe kept informed at all times of thedecisions being
made by the designteam and have the opportunity tosuggest
alterations should the needarise.
Tender Documents and DrawingsOnce planning permission has
beengranted, a more detailed set of technicaldrawings will be
required in order toenable the construction of the house.
Ashighlighted above, the emphasis will beon detailing of junctions
betweendifferent elements of the building,practical requirements
for minimisingheat loss through cold bridging,planning for
airtightness and thelocation and routing of services. Thesizing of
the ventilation equipment,back-up space heating, solar domestichot
water system, as well as details ofcontrols for space and water
heating andventilation, will have to be specified atthis stage. The
detailed drawings andspecification can then be issued fortender to
competent contractors.
Site OperationsThe detailed design of the passive housemust now
be realised on-site and qualitycontrol is paramount to achieving
thestandard envisaged in the PHPPsoftware. The most challenging
aspectwill typically be achieving the required
level of airtightness, as this is greatlyaffected by the quality
of craftsmanshipon site. The challenge becomes all themore
difficult if the building contractorhas no prior experience of
building tothe Passivhaus Standard. Morechallenging again is the
commonpractice of the house built by ‘directlabour’ and without an
experiencedsupervisor with overall responsibility toachieve the
high standards set.
It will usually be necessary to engagespecialist Sub-Contractors
to supply andinstall such elements as the ventilationequipment,
solar system, back-upheating systems and controls.
Post Construction TestingThis is the final stage to
determinewhether the constructed dwellingactually meets the
air-tightnessrequirements of the PassivhausStandard. The
air-leakage must notexceed 0.6 air changes per hour using50Pa
overpressurisation andunderpressurisation testing. Anindependent
inspection and testingbody should conduct the testingactivities. It
is important to undertakethis test as soon as the airtight layer
iscomplete so that any leaks can berectified. When the house does
not meetthe requirements further testing may berequired.
2.2 General Principles: HeatEnergy Losses & HeatEnergy
Gains
2.2.1 Passive House BuildingEnvelope
The building envelope consists of allelements of the
construction whichseparate the indoor climate from theoutdoor
climate. The aim of the passive
10
Roof Loss 30%-35%Flue Loss
Ventilation Loss 25%
Window Loss 15%
Floor Loss 7%-10%
Loss through Walls
25%-30%
Areas of Heat Loss in Homes
Comparison typical building fabric heat loss patternsin a
detached dwelling, excluding ventilation andinfiltration. Source:
SEI.
Figure depicting 2005 Building Regulation standard required for
insulation and required insulation to meet thePassivhaus Standard
in Ireland. Source: UCD Energy Research Group.
Thermographic image illustrating difference in heatloss through
building envelope in a conventional andpassive house
building.Source: UCD Energy Research Group.
0
0.05
0.1
0.15
0.2
0.25
0.3
321
U-v
alue
W/m
K
TGD Part L
Passive House
Walls RoofFloor
2
Thermal transmittance (U-value)relates to a building component
orstructure, and is a measure of the rateat which heat passes
through thatcomponent or structure when unittemperature difference
is maintainedbetween the ambient air temper-atures on each side. It
is expressed inunits of Watts per square metre perdegree of air
temperature difference(W/m2K).
Source: Building Regulations TechnicalGuidance Document, Part L
Conserv-ation of Fuel and Energy 2005.
-
house is to construct a buildingenvelope that will significantly
minimiseheat loss and optimise solar and internalheat gain to
reduce the space heatingrequirement to 15KWh/(m2year).
The following building envelopeparameters are fundamental in
thisprocess:
1. Well insulated building envelope2. High energy performing
windows
and doors3. Minimised heat loss through thermal
bridging 4. Significantly reduced structural air
infiltration 5. Optimal use of passive solar and
internal heat gains
Building Envelope InsulationMany building methods can be used
inthe construction of a passive house,including masonry,
lightweight frames(timber and steel), prefabricatedelements,
insulated concrete formwork,straw bale and combinations of
theabove. The prototype house presentedin this publication (details
in Section 2and 3) illustrates both masonry andtimber frame
construction asrepresentative of most typically usedbuilding
methods for dwellings inIreland.
Continuous insulation of the entirethermal envelope of a
building is themost effective measure to reduce heatlosses in order
to meet the PassivhausStandard.
A thermographic image is used toillustrate the difference
between thewell and poorly insulation levels in ahouse. Heat loss
through the buildingenvelope is highlighted by the green,yellow and
red colouring. The amount ofradiation emitted increases with
temperature, therefore warm objectsstand out well against
coolerbackgrounds. In the passive house someheat is lost through
windows but heatlost through the external wall is very low.In the
conventional building, on theother hand, there is heat loss from
theentire building envelope, especiallythrough windows.
Insulation of the building envelope canbe divided into four
distinct areas:external wall, floor, roof and windows.Existing
passive houses in Central andNorthern European countries have
beenachieved with U-values for walls, floorsand roofs ranging from
0.09 to 0.15W/(m2K) and average U-value forwindows (including
glazing and windowframes) in the region of 0.60 to 0.80W/(m2K).
These U-values far exceedthose currently required under the
IrishBuilding Regulations, with the mostmarked difference
pertaining towindows, wall and floor.
A sensitivity analysis using the PassiveHouse Planning Package
(PHPP), v2004,software was undertaken using a rangeof U-values for
the timber frame andmasonry constructions of the prototypehouse
using climate data for Dublin. Inall options tested the same data
wasinput into PHPP for air-tightness0.6ac/h@50Pa, ventilation
andminimised thermal bridging. Variousparameters were tested in
order todetermine, for example, the requiredlevel of U-values for
the buildingenvelope in the Irish climate, and toascertain whether
it would be possibleto use double glazing and still achievethe
Passivhaus Standard in Ireland. Theresults are: Option 1 being the
mostenergy efficient house and Option 8being the least energy
efficient. Anoutline description of each of the eight
11
Irish Building Regulations, ElementalHeat Loss Method
(BuildingRegulations Technical GuidanceDocument Part L,
Conservation ofFuel and Energy 2005).
Maximum average elemental U-valueW/(m2K)
• Pitched roof, insulation horizontalat ceiling level 0.16
• Pitched roof, insulation on slope0.20
• Flat roof 0.22• Walls 0.27 • Ground Floors 0.25 • Other
Exposed Floors 0.25 • Windows and roof lights 2.20*Regulations due
to be updated in 2008
Light filled room in a passive house.Source: MosArt
Architecture.
Light, bright and airy.Source: MosArt Architecture.
Windows on the northern elevation should ideally besmall.
Source: MosArt Architecture.
Comparison of the interior surface temperature depending on the
type of glazing.Source: Internorm, fenster–Lichtund Leben catalogue
2007/2008, pp.91.
-
options analysed is provided. Only thefirst four achieve the
PassivhausStandard set for space heating(delivered energy) of 15
kWh/(m2year)treated floor area:
• Option 1 - U-value 0.10 W(m2K) for allbuilding elements
combined withtriple gazed windows with averageU-value (including
glazing andwindow frames) of 0.80 W(m2K)results in space heating
requirementsignificantly below the standardrequired of 15 kWh/(m2
year).
• Option 2 - (This is the option that hasbeen used in the design
of theprototype passive house in Ireland aspart of these
Guidelines), with U-value 0.15 W(m2K) for all buildingenvelope
elements combined withtriple glazing. The results show spaceheating
requirement below thePassivhaus Standard.
• Option 3 - All building envelopeelements with U-value of
0.10W(m2K) combined with an efficientdouble glazed unit with low
U-value1.1 W/(m2K) achieves the PassivhausStandard.
• Option 4 - U-value 0.175 W(m2K) forexternal walls and U-value
0.15
W(m2K) for all other buildingenvelope elements, coupled
withtriple glazed windows. The result isexactly at the threshold of
thePassivhaus Standard but was notused for the prototype house as
thereis no margin in site operations.
• Option 5 - U-values for walls, roofand floor employed in the
IrishBuilding Regulations, Elemental HeatLoss Method (Building
RegulationsTGD Part L, Conservation of Fuel andEnergy 2005)
combined with tripleglazed windows, failing to achievethe required
standard.
• Option 6 - also a failure is thecombination of U-value
0.10W(m2K)for building fabric in combinationwith standard double
glazed units.
• Option 7 - U-values 0.15 W(m2K) forwalls, roof and floor as
the prototypehouse but with standard doubleglazing U-value 2.20
W(m2K) whichcomes way above the PassivhausStandard.
• Option 8 - U-values for walls, roofand floor employed in the
IrishBuilding Regulations, Elemental HeatLoss Method (Building
RegulationsTDG Part L, Conservation of Fuel andEnergy 2005) and
standard doubleglazed units underachieving thePassivhaus
Standard.
Thermal ConductivityThermal conductivity ( -value) relates toa
material or substance, and is a measureof the rate at which heat
passes througha uniform slab of unit thickness of thatmaterial or
substance, when unittemperature difference is maintainedbetween its
faces. It is expressed in unitsof Watts per metre per degree
(W/mK),(Building Regulations TechnicalGuidance Document Part
L,Conservation of Fuel and Energy 2005).Insulation materials for
walls, roofs andfloors vary in terms of thermalconductivity.
Typical conductivities fordifferent insulation materials
areincluded below as well as theapproximate thickness required in
orderto achieve a U-value of 0.15 W(m2K) and0.10W(m2K). (Table
4)
Typical insulation materials used inIreland include mineral
wool,polystyrene, polyurethane, polyiso-cyanurate, sheep wool and
hemp.Different insulation materials suitdifferent types of
construction
12
Note: Advantages and disadvantagesof using triple glazed windows
arediscussed in detail in section ‘Windows& Doors’)
Note: Results presented here areindicative only and should be
used asstarting point for specification of apassive house dwelling
in Ireland.Meeting the Passivhaus Standard mustbe tested and
verified with the PHPPsoftware for the specific dwellingdesign.
Option
U-Values of ext. wall
U-Values of roof
U-Values of
floor
AverageU-Value of
windows and doors
Space heating requirement
1 0.10 W(m2K) 0.10 W(m2K) 0.10 W(m2K) 0.80 W(m2K) 8 kWh/(
m2a)
2 0.15 W(m2K) 0.15 W(m2K) 0.15 W(m2K) 0.80 W(m2K) 13 kWh/(
m2a)
3 0.10 W(m2K) 0.10 W(m2K) 0.10 W(m2K) 1.10 W(m2K) 13 kWh/(
m2a)
4 0.175 W(m2K) 0.15 W(m2K) 0.15 W(m2K) 0.80 W(m2K) 15 kWh/(
m2a)
5 0.27 W(m2K) 0.16 W(m2K) 0.25 W(m2K) 0.80 W(m2K) 22 kWh/(
m2a)
6 0.10 W(m2K) 0.10 W(m2K) 0.10 W(m2K) 2.20 W(m2K) 28 kWh/(
m2a)
7 0.15 W(m2K) 0.15 W(m2K) 0.15 W(m2K) 2.20 W(m2K) 34 kWh/(
m2a)
8 0.27 W(m2K) 0.16 W(m2K) 0.25 W(m2K) 2.20 W(m2K) 45 kWh/(
m2a)
Table 3: Sensitivity analysis of the passive house prototype
house in Ireland outline test results for eight options. Source:
MosArt Architecture.
-
application and it is important to use thematerial best suited
for the situation. Forexample, cellulose insulation is suitablefor
use in an open attic space where itwill fill completely between
ceiling joistsin comparison with rigid insulationwhere there is a
high risk of thermalbridging unless cut perfectly to fitsnuggly
between the joists. Conversely,a high density rigid insulation is
bettersuited under a floor slab compared withinsulation that easily
compress or areaffected by moisture.
The U-value of the construction isdetermined by the conductivity
ofmaterials and components used fromthe internal surface to the
externalsurface of the thermal envelope.Examples of typical
constructionmethods and materials used for theprototype passive
house in Ireland areillustrated later in Section 3.
Windows & DoorsThe recommended approach to thedesign of a
passive house is to haveavoid excessive area of north facingglazing
and place relatively largewindows facing south or due south. Thisis
in order to minimise heat lossesthrough the north facing
elevation,which receives no direct sunlight, whilemaximising ‘free’
solar heat gains on thesouth. An advantage of large windows isan
increase in interior day light levelswhich in turn reduces the need
for use ofelectricity for artificial lighting and alsoensures a
more pleasant natural light-filled living environment.
There is, however, a balance to beachieved between heat losses
throughthe glazing and solar heat gains throughthe south/east/west
facing windows.When designing a passive house, PHPPsoftware should
be used to calculate theheat losses and heat gains taking
intoaccount building orientation, areas ofglazing and specific
types of glazing so
the optimum balance of glazing for eachpassive house design can
be reached.
It has been illustrated above that the useof windows and doors
with average U-values of 0.8 W/(m²K) can be combinedwith U-values
for opaque elements of0.15 W/(m²K) to comfortably achieve
thePassivhaus Standard in Ireland. There area number of advantages
in usingwindows with average U-values of 0.8W/(m²K) as well as
highly insulateddoors, principally the assurance of acomfortable
indoor climate due to thelower cold radiation heat transfer at
thesurface of the glass. One will not sense adrop in temperature
standingimmediately adjacent to this standard ofwindow, unlike the
experience ofstanding next to a conventional doubleglazed unit with
U-value, for example of2.2 W/(m2K). An added benefit of usinghighly
energy efficient windows anddoors includes significant
draughtreduction due to the fact that they havetypically two seals
or gaskets (comparedwith conventional double glazed unitswhich
often have only one) as well asexcellent sound insulation.
Finally,natural convection which is driven bytemperature difference
between theinside face of the glass and the roominterior is much
reduced with which inturn will reduce cold air flows andthermal
discomfort.
The sensitivity analysis for a passivehouse dwelling in Ireland
(showed inOption 3), achieves the PassivhausStandard yearly space
heatingrequirement with extremely efficientdouble glazed windows
with a U-valueno greater than 1.1 W/(m²K). When usedin a passive
house, however, they mustbe used in conjunction with very low
U-values for all other elements of thebuilding envelope. This may
negate anyfinancial saving in not using moreefficient glazing as
well as compromise
the thermal comfort level in the house.
Typically triple glazed window units areused in passive houses
in Central andNorthern Europe. The Passivhaus Instituthas certified
a range of glazing and doorunits suitable for use in passive
housebuildings. Although it is not aprerequisite to use certified
passivehouse products (http://www.passiv.de) ina passive house,
choosing approvedproducts means the validity of technicaldata has
been tested and verified by anindependent certifier. The
principlecharacteristics and advantages of usingtriple glazed
windows in a passive houseare listed below, for both windowglazing
and frames:
Glazing• Three panes of glass separated by
special low-conductivity spacerseliminates the risk of
condensation atthe bottom of the glass in coldweather (which may
lead to rottingof timber frames over time).
• High solar energy transmittance (g50) which allows solar
radiation to
penetrate the glass and contributetowards heating of the
dwelling.
• A low emissivity (low-e) coating onthe inside of the outer two
paneswhich reduces solar re-radiation backout through the glass. It
should benoted that a ‘soft coat’ has slightlybetter U-value but a
‘hard coat’glazing has higher solar trans-mittances.
• Insulating gases between the glasspanes, typically argon or
krypton,which help to reduce heat escapingthrough the glass.
Frame• The frame must be well insulated and
also be thermally broken. Even woodconducts heat and a
thermallybroken timber window frame willresult in much lower heat
losses thana solid one.
• There will typically be two weathergaskets on triple glazed
windowsused in a passive house dwelling, theprimary function of the
outer onebeing for weathering with the innerone serving to improve
airtightness.The majority of these types ofwindows open outwards
which iscommon place in Continental Europe
13
Insulation Material Type
Thermal conductivity W/mK
Thickness for U-Value of 0.15
W(m2K)
Thickness for U-Value of 0.10
W(m2K)
Polyisocyuranate or polyurethane 0.023 145mm 220mm
Polystyrene, sheep wool 0.035 220mm 340mm
Cellulose, Hemp and Rockwool
0.04 250mm 400mm
Wood 0.13 825mm 1,250mm
Table 4: Conductivity of insulation materials and approximate
thickness to achieve specific U-value for externalwalls. Source:
MosArt Architecture.
-
however, there are models of inwardopening windows being
developedwhich will soon be available in theIrish market. One
advantage ofoutward opening windows is thatthey don’t intrude in
the room spacewhich may be important in morecompact dwellings.
• Triple glazing window frames aretypically much wider and
strongerconstruction than their conventionaldouble glazing
counterparts.
• Triple glazed windows with low-emissivity coating and
insulatedwindow frames will have improvedU-values compared to
double glazedwindows, resulting in less heat loss.However with
triple glazing the solarenergy transmittance (gs), that is,
theamount of solar energy enteringthrough that glazing, is
somewhatreduced compared to double glazingdue to the effect of the
additionallayer of glass. The requirements ofthe Passivhaus
Standard is to useglazing with minimum solartransmittance of 50% or
higher.
The use of larger areas of glazing on thesouth elevation is
helpful in maximisingthe amount of sunlight available in theshort
days of winter. It must beremembered, however, that highlyenergy
efficient windows allow lessdaylight (visible light transmittance)
intoa building than a normal double glazedwindows without
e-coating. Lighttransmittance is an optical property thatindicates
the amount of visible lightbeing transmitted through the glazing.It
varies between 0 and 1 (0 to 100%light transmitted) with the higher
thelight transmittance value the more lightis transmitted. A double
glazed windowwith low-e coating will transmit 72% ofvisible light.
A triple glazed energyefficient window will transmit 65% ofvisible
transmittance (these areindicative values only - actual
valuesdepend on the manufacturer’s specific-ation).
In a conventionally constructed house inIreland radiators are
typically positionedunder windows in order to heat the coldair
entering through the single ordouble glazing. In a passive
houselocating radiators beneath windows issimply not required as
the heat load is
transferred throughout the house viathe mechanical ventilation
system. Thishas the added benefit of enablingunobstructed use for
placing furnitureagainst all external walls.
Thermal BridgingThermal bridging (i.e. un-insulated
jointsbetween walls, floors/walls, ceilings/adjacent walls,
windows/walls etc) areweak points of the building envelopeand cause
unwanted losses of energywhich should be eliminated orsignificantly
reduced to a degree thatthe associated heat losses
becomenegligible.
A thermal bridge increases heat lossthrough the structure, and
in someextreme cases this may cause surfacecondensation or
interstitial conden-sation in the structure. Surface mouldgrowth or
wood rot may be theconsequences of a thermal bridge.Typical effects
of thermal bridges are:
• Significantly increased heat losses.
• Decreased interior surface temper-ature which may result in
highhumidity in parts of the construction.
• Mould growth cause by warminternal air condensing on
coldsurfaces.
All of the above situations can beavoided in houses built to
thePassivhaus Standard. The PassivhausStandard for linear thermal
trans-mittance (ψ) should not exceed 0.01W/(mK). This requires the
buildingdesigner to identify and locate allpotential thermal
bridging in theconstruction, careful specification anddetailing of
those elements providingwhere possible a continous layer
ofinsulation, as well as care being taken toexecute those elements
on site as perdesign details.
Designing and building a passive housein Ireland requires the
development ofconstruction details that go far beyondguidance
provided (to avoid excessiveheat losses and local condensation)
inBuilding Regulations Technical GuidanceDocument Part L,
Conservation of Fueland Energy 2005. Building practitionerscould
refer to the accredited con-struction details specifically
developedfor passive house building published inGermany “Thermal
Bridge-Free Con-struction” (PHPP 2007, pp.96). Thermal
14
Cross section though a triple glazed insulated windowand frame.
Source: MosArt Architecture.
The risk of internal condensation is dramaticallyreduced.
Source: MosArt Architecture.
The quantity which describes the heatloss associated with a
thermal bridge isits’ linear thermal transmittance (ψ).This is a
property of a thermal bridgeand is the rate of heat flow per
degreeper unit length of bridge that is notaccounted for in the
U-values of theplane building elements containingthe thermal
bridge.
Source: SEI, Dwelling Energy Assess-ment Procedure (DEAP) 2005
edition,version 2, pp.55
-
bridging can be tested and verified inthe PHPP software as the
design of thepassive house building is beingdeveloped.
Structural Air-Tightness and Draught-Proofing Building an
airtight or leak-free structureis imperative to achieving the
PassivhausStandard. If there are gaps in thebuilding structure then
uncontrolledamounts of cold external air caninfiltrate the
building. Achieving a highlevel of air-tightness eliminates
colddraughts and associated comfort losses.It also prevents
condensation of indoormoist, warm air penetrating thestructure, and
possible structuraldamages due to decay, corrosion andfrost.
Air-tightness is achieved by carefulapplication of appropriate
membranesand tapes or wet plastering in concreteconstruction within
the buildingenvelope. A great deal of attention mustbe paid to
detailing and workmanship inorder to ensure that the airtight layer
iscontinuous all round the building,especially around junctions
betweenwalls and floors, roof, windows, doors,etc. Penetrations of
the airtight layer bymechanical and electrical services mustbe
properly sealed.
The air-tightness of a building can beaccurately measured by
carrying out ablower-door test. The test involvesplacing a powerful
fan suspended in acanvas sheet within a door opening andoperating
the fan at very high speedsthereby creating either negative
orpositive pressure within the house. Bysucking air out of the
house, forexample, a negative pressure is createdwith the result
that external air will besucked in through any gaps or cracks inthe
building envelope. The pressureused for such tests is 50 Pascal
which canbe accurately set by the blower doorequipment.
When undertaking the test it is usuallyquite easy to identify
major leaks due tothe presence of a strong draught whichcan be felt
by the hand or, for smallerleaks, can be detected by athermographic
camera. The cause ofthese draughts can then be sealed
withappropriate materials as the test is beingundertaken. It may
also happen that the
leaks in the envelope are very minor andtherefore difficult to
locate. In thesesituations it is typical to reverse thedirection of
the fan and suck air into thehouse putting it under positive
pressure.Odorless smoke can then be releasedinto the building and
leaks can beobserved from the outside where thesmoke appears
through the envelope. Itis important to notify the fire service
ifyou are carrying out such a test in case itis mistakenly reported
as a house fire bypassers by.
The Passivhaus Standard is reachedwhen there are less than or
equal to 0.6air changes per hour @50Pa pressure.
The most critical issue regarding testingfor airtightness is
timing during thebuilding process. It is important thatremedial
measures can be carried out inorder to remedy any leaks or cracks.
Thetest should be carried out before secondfix carpentry, for
example, when thereare no skirting boards or window boardsfitted
and where the junctions coveredby such materials are still
accessible andcan be sealed. The test should also becarried out
after all mechanical andelectrical services, that need topenetrate
the building envelope, havebeen installed. Otherwise,
installingsuch services after the test couldseverely compromise the
airtightness ofthe building.
In a typical Irish house built inaccordance with building
regulationsTGD Part F 2002 the method in whichhabitable rooms are
ventilated is usuallyvia a hole in the wall or ventilator in
thewindows of 6,500mm2 fitted with acontrollable grille. Such means
ofventilation can result in large amounts ofcool external air
infiltrating the buildingdepending on wind speed and pressure.In a
passive house, on the other hand,the supply of fresh air is
provided by awhole house mechanical ventilationsystem with heat
recovery whichnegates the necessity for openings inthe wall or
windows. Thereby draughtsare eliminated and structural
air-tightness is not compromised.
In developing the building design it isvery important to
anticipate differentialmovement and decay of adhesives andchemical
bonds by detailing junctionswhich will assist in maintaining an
15
Infrared image of the interior of a passive housewindow. All
surfaces (wall structure, window frame,and the glazing) are
pleasantly warm (over 17°C). Evenat the glass edge, the temperature
does not fall below15°C (light green area).Source: Passivhaus
Institut, http://www.passiv.de fromthe passive house
Kranichstein).
For comparison, a typical older double glazed windowis shown.
The centre of glass surface temperature isbelow 14°C. In addition,
there are large thermalbridges, particularly where the window meets
theexternal wall. The consequences are significant
radianttemperature asymmetry, drafts, and pooling of cold airin the
room. IR-photography: Passivhaus Institut.Source: Passivhaus
Institut, http://www.passiv.de fromthe passive house
Kranichstein).
Timber Frame I-Beam construction reducing thermalbridging.
Source: Passivhaus Institut, Germany.
-
airtight layer for the life of the building.Many excellent
details, for example, canbe found at the website of the
ScottishEcological Design Association(www.seda2.org/dfa/index.htm).
It is alsoimportant to use membranes andplasters that are both
airtight but alsovapour diffusing which allow moisturewithin the
structure to escape to theoutside thereby reducing the risk
ofinterstitial moisture and the threat of rotand decay over
time.
Passive Heat GainsPassive heat gains in a passive house area
result of the combination of solar gainsand internal gains.
Solar Heat GainsPassive solar gain is optimised byproviding an
east-west alignment to thebuilding, if possible on the site,
resultingin the longest façade facing south, andby placing the
majority of the glazingtowards the south. Very high qualitywindows
(average U-value 0.8W/m2K)facing south will have a positive
thermalbalance - it will have more heat gainthan heat loss
throughout the year.Results of a recent parametric study by
J.Schnieders of the Passivhaus Institut“Climate Data for
Determination ofPassive House Heat Loads in NorthwestEurope”
illustrates the relationshipbetween the area of south facing
glazingand the space heat demand for a passivehouse dwelling
located in Ireland(measured climate data for Birr used).The
parametric study uses the firstpassive house built by Dr. Wolfgang
Feistof the Passivhaus Institut as a case studybuilding, shown
below. It can be seenthat the space heating demand
initiallydecreases quite steeply with increasingsouth facing
glazing. There arediminishing returns from increasing thearea of
south facing glass, however, andthere eventually comes a point
wherethere is little or no benefit in providingmore south facing
glass as the net heatloss is greater than the heat gains overthe
year.
There is no optimal ratio of glazing tofloor area that can be
used as a rule ofthumb in deciding what proportion of agiven façade
should be glazed. The areaof glass has to be determined as part
ofthe design verification procedure usingthe PHPP software.
Internal Heat GainsA passive house is very efficient atutilising
‘free’ internal heat gains fromdomestic household appliances,
kitchenand utility equipment, electronicequipment, artificial
lighting, andoccupants. Heat losses from stoves orboilers also
contribute towards theoverall space heating requirement aslong as
they are positioned within thebuilding envelope. Occupants of
thebuilding also contribute to the heat load- a human continuously
emits 100W ofheat when stationary. A family of fivepersons,
therefore, can emit 0.5KW ofheat. This may seem like a small
amountbut it equates to approximately onethird of the total space
heat load for theprototype passive house presented inSection 3.
Risk of OverheatingPlacing extensive areas of glass on thesouth
facing façade in a well insulatedand air-tight dwelling may lead
tooverheating in warm sunny days. ThePHPP software will alert the
designer toany risk of overheating by calculatingthe frequency of
overheating expressingthis as a percentage of the year in whichthe
internal temperature in the houserises above 25oC. If frequency
oftemperatures over the comfort limit of25oC exceeds 10% of the
year, additionalmeasures for reducing overheatingshould be included
in the dwelling. Toprevent uncomfortable indoortemperature in a
passive house dwellingit is recommended to specify shadingdevices
(blinds, overhangs or awnings,etc.) which allow low sun to enter
thehome in winter but prevent the high sunentering in summer.
In the first Irish passive house in Wicklowshading was not in
place on the southfacing glazing during the first summerand the
house did overheat. A balconywas installed ahead of the
secondsummer, which significantly reduced thefrequency of
overheating. In mid-summer when the daylight hours arelong the sun
only enters the buildinglater in the day while during winterwhen
the daylight hours are short thelow sun completely illuminates
theentire interior of the building.
In the temperate climate in Irelandwhere external temperature
rarelyexceeds 25oC, the risk of overheating
16
Correctly insulated house avoiding thermal brid.Source:
Passivhaus Institut, Germany.
Timber frame house pre-cladding fitted airtightmembrane. Source:
Passivhaus Institut, Germany.
Continuous Airtight Membrane. Source: IG Passivhaus Osterreich
Innovative Passivhausprojekte.
There are two measurements used todefine airtightness, namely
cubicmetres of air per square metre ofexternal envelope per hour
(m3/m2h) orair changes per hour (ac/h). While themeasured result
for the former isgenerally 20% greater than that of thelatter, the
difference is practice greatlydepends on the building form.
-
should be avoided by carefulconsideration of shading
devices,provision of openings for naturalventilation in combination
with thermalmass inside the dwelling (exposedconcrete floor;
masonry wall, etc.). Insome cases the mechanical ventilationsystem
could be used to distribute freshair throughout the building by
switchingto a ‘summer bypass’ setting. Thishowever should be
avoided wherepossible as the ventilation system willconsume
electricity resulting inincreased primary energy. The
dwellingdesigner should employ ‘passive’ coolingstrategies to
minimise overheating.
2.2.2 Passive House BuildingSystems
As explained earlier a passive housedoes not need a conventional
spaceheating system of radiators orunderfloor heating to maintain
acomfortable indoor climate. Instead,typically, the following
building servicesare required in a passive house:
• Mechanical ventilation system withheat recovery which provides
most ofthe space heat requirement.
• Back-up system capable of heatingthe air passing through the
dwellingvia mechanical ventilation. Typicalfuel sources for the
back-up systeminclude biomass, gas, and in someinstances
electricity (for example‘green electricity’ from renewablesources).
Since the demand for spaceheating in a passive house dwelling
isvery low, the back-up system is usedto provide hot water,
either
throughout the year or during winterif a solar water heating
system is usedduring summer.
Each of these items is dealt withseparately in greater detail
below.
Given the lengths to which the designerand builder go to in
terms of ensuring ahighly insulated building envelope,excellent
air-tightness and minimalthermal bridging, it is important that
thebuilding services in a passive house areas energy efficient as
possible. This isespecially critical in the case of themechanical
ventilation heat recoverysystem. Therefore, the requiredefficiency
of the mechanical ventilationsystem with heat recovery for a
passivehouse dwelling is 75%. It is also veryimportant to consider
comfort, healthand safety issues in the design of thebuilding
services for a passive house,ensuring for example that the
back-upheating system is adequately sized todeal with extreme
weather conditions;that filters in the ventilation equipmentare
replaced regularly and that there is afresh air supply for any
combustiondevices such as a boiler. These and otherissues are dealt
with in greater detailbelow.
Mechanical Heat Recovery Ventilation(MHRV)An airtight house
requires a well-designed mechanical ventilation systemto provide
good indoor air quality. Apassive house is ventilated using
amechanical system which incorporatesair to air heat recovery
(mechanicalventilation heat recovery, or MVHR).
17
Climate Data for the Determination of Passive House Heat Loads
in Northwest Europe.Source: J. Schnieders, Passivhaus Institut.
No more than 0.6 air changes/hour at 50 Pascalpressure should be
observed in accordance with thePassivhaus Standard. This should be
checked forcompliance with a blowerdoor test which willimmediately
highlight leaky areas. Air-tightness can beachieved through the use
of membranes, roofing feltsand plasters combined with sealants and
vapourdiffusing resistant materials.Source: UCD Energy Research
Group.
Location of overhang and balcony. Source: MosArt
Architecture.
Lighting contributes towards internal heat gains.Source: MosArt
Architecture.
02468
1012141618202224
0 10 20 30 40 50 60
Area South Facing Windows [m2]
Spac
e H
eat D
eman
d / H
eat L
oad
Space Heat Demand [kWh/(m2a)]
Heat Load [W/m2]
Ireland - Birr
U-Value Wall = 0.175 W/(m2K)U-Value Window = 0.85 W/(m2K)
Deep roof overhang shadesupstairs windows
Balcony shades downstairs windows
-
Exhaust air is extracted from rooms thattypically produce heat,
moisture andunwanted smells such as kitchens andbathrooms. Before
this air is expelled tothe outside it passes through a
heatexchanger where the heat is transferredto the incoming fresh
air, therebyeliminating the need to completely heatthe fresh air as
it enters the building. It isimportant to highlight that the
staleexhaust air and clean fresh air do not mixin the heat
exchanger and thereforethere is no risk whatsoever of whatmight be
referred to as ‘sick buildingsyndrome’. Rather, the stale air and
cleanair is channelled through closely spacedbut separate narrow
sleeves in the coreof the heat exchanger.
The benefits of having a whole-housemechanical heat recovery
ventilationsystem (MHRV) are many, including:
• Constant supply of the correctamount of fresh air to all
habitablerooms thereby reducing CO2 levelsand removing the cause of
stuffinessand tiredness.
• Simultaneous extraction of moisture-laden air from bathrooms,
utilityrooms and kitchens as well asventilating noxious gases
andunwanted smells if present.
• A lowering in humidity levelsreducing mould and fungus that
mayappear over time and decreasingdust mite levels.
System EfficiencyThe efficiency of the heat exchanger inthe MHRV
determines the amount ofheat that can be recovered from theexhaust
air and, therefore, has a verysignificant influence on the
additional
space heating that may be required in apassive house. The aim is
to use thewarm exhaust air to raise the temper-ature of the cool
fresh air to provide forthermal comfort all around the house.On a
night where outside temperaturesare below freezing, the fresh air
shouldbe raised to, for example, 18oC, havingpassed through the
MVHR. Theefficiency of sensible heat recoveryshould exceed 75% for
the nominalrange of flow rates specified for the unitwhen measured
in terms of the supply-air side temperature ratio as described inEN
13141-7:2004.1 Specifiers anddesigners should be wary of
productsclaiming extraordinary efficiency rates of95% or higher.
The safest route is toinstall equipment that has beenindependently
tested and verified bysuch bodies as the Passivhaus Institute.
The graph above is based on actualtesting of the first Irish
passive house inWicklow. It illustrates, for example, howmechanical
ventilation ensures goodindoor air quality by removing the
highconcentrations of a tracer gas that wasdeliberately released
into the house aspart of the test procedure. In less than1.5 hours
the air quality in the house hadreturned to normal.
Recommended Ventilation RateAccording to the Passivhaus
Institut, theappropriate air change rate for dwellingsis between
0.3 and 0.4 times the volumeof the building per hour, with a
generalrecommendation of leaning toward thelower rate. This
maintains high indoor airquality while ensuring a comfortablelevel
of humidity and maximizingenergy savings.
18
Photo depicting how the low winter sun enters theroom below the
overhang/awning/balcony. Source: MosArt Architecture.
Schematic of the supply air ducts, the extract air ductsand the
heat exchanger within mechanicallyventilated house. Source:
Passivhaus Institut.
The sommer-bypass can be used for cooling in thesummer if
needed. Source: MosArt Architecture.
Photo depicting how the house is shaded from the highsummer sun
by the overhang/awning/balcony.Source: MosArt Architecture.
Graph depicting how mechanical ventilation ensures a good indoor
air quality by removing the high concentrationsof tracer gas that
were inserted into the house under test conditions. Source: UCD
Energy Research Group.
IR C
once
ntra
tion
Hours
-
The PHPP software suggests that 30m3
per person per hour should be providedto dwellings to ensure
good air quality.These two measurements can be used tochoose an
appropriately sized machinefor different dwelling designs. Taking
theprototype house presented later inSection 3 as an example, an
occupancyof 5 persons would require 150m3 offresh air delivered to
the house per hour.In terms of extract, the PHPP softwareuses the
following rates for differentroom types as default values, kitchen
=60m3h, bathroom = 40m3h, shower =20m3h and WC = 20m3h. In the
prototypehouse these total 140 m3h which is closeto the supply
volume which will ensurethat the whole house system will
bebalanced. The supply and extractvolumes can be accurately set by
using adigital anemometer and adjusting thevalves on the vents in
each room asrequired.
Adjustment of Fan Speed and ExchangeRateMost MVHR machines have
differentsettings for different circumstances.These are often
referred to as a ‘party’setting, where there are a lot of peoplein
the house and where additional freshair is required, and ‘holiday’
setting,where the house is being left vacant andthe flow of air is
reduced. The former ofthese settings will use more energy andalso
decrease the level of humiditywhereas the latter will use less
energyand perhaps lead to an increase inhumidity.
It is not advisable to constantly run theequipment on the lower
setting just tosave energy when the house isoccupied. MHRV machines
usessurprisingly little energy given theimportant role that they
play in thepassive house. The PHPP software usesstandard value
0.45Wh for every m3
transported air software in thecalculation of electricity due to
MHRV.When designing a passive house inIreland the specific fan
power should becarefully considered as the electricityconsumed for
fans has direct impact interms of primary energy performanceand
energy labelling, the BuildingEnergy Rating (BER), recently
introducedto Ireland. Therefore, specific fan powerfor fans should
be less than 1w/l/s.
Winter and Summer ModeThere are generally two ventilationmodes
in a passive house: SummerMode and Winter Mode. In winter, theMHRV
uses the heat in the exhausted airto warm the incoming fresh air.
Insummer, a bypass in the equipment canbe set to open automatically
(controlledby thermostats) such that the incomingfresh air is not
heated. Alternatively insummer natural cross ventilation may beused
and the MHRV system can beswitched off.
Insulation and Positioning of Duct Workand VentsIit is very
important to adequatelyinsulate the supply air ducting so thatthere
is minimal loss of temperature indelivering warm air around the
house.The thickness of insulation generallyused in passive houses
is between 6cmand 10cm for ductwork. It is alsopreferable to locate
the ducting withinthe thermal envelope and to keep piperuns as
short as possible by ideallypositioning the MVHR unit in the
centreof the house. This requires carefulplanning at a very early
stage of buildingdesign.
Vents are normally placed in the ceilingbut can also be placed
in the wall ifnecessary. The air inlets are typicallydesigned to
spread the air horizontallyacross the ceiling, minimizing down-ward
drafts. There should be a gap eitherunder or over the door of each
room toenable the easy movement of air fromone room to the next. If
doors are fittedtight without such a gap, rooms withexhaust vents
would be under negativepressure and rooms with supply airunder
positive pressure.
Noise Fan and valve noises can be almostcompletely eliminated by
sound controlmeasures (e.g. vibration isolationmounts, low air
speed and acousticlining in ducts). The grilles on ventsgenerally
guide incoming air along theceiling from where it uniformly
diffusesthroughout the room at velocities thatare barely
perceptible. If the ventilationequipment is operating on a
highsetting (‘Party Mode’) the noise of theequipment and the air
flow may be morenoticeable. MVHR machines aregenerally housed in a
well insulated
19
A pellet stove is at the hearth of an Irish passive
house.Source: MosArt Architecture.
The ventilation system can be used in a sealed closet todry
clothes. Source: MosArt Architecture.
Supply air ducts should be well insulated.Source: MosArt
Architecture.
Ceiling air supply vent. Source: MosArt Architecture.
-
casing and noise should not be a criticalissue.
Maintaining Good Air QualityIt is important that attention is
paid toregular replacement of air-filters for bothincoming and
exhaust air. Filters areused not only to provide clean air for
theoccupants but also to ensure that theheat exchanger is not
clogged with dustand other matter. If the filters are notregularly
replaced (for example every sixto twelve months) and they
themselvesbecome clogged with dirt the MHRV willhave to work harder
to provide the samevolume of air to the house, therebyincreasing
the speeds of the fans and,ultimately, using more energy.
Incountries where this system is relativelynew, occupants may not
be aware of thismaintenance need and indoor air qualitymay suffer
as a consequence. Equipmentdiffers with respect to the types of
filtersused, some have to be replaced whileothers can be washed and
reused.
Sometimes the extractor hood in thekitchen is connected to the
MHRVequipment to extract kitchen smells andto use the waste heat
from cooking towarm the incoming fresh air. In suchinstances, it is
very important that thehood is fitted with a high quality
filterthat can easily be cleaned or replaced inorder to prevent the
built up of grease inthe ducting system which could be a
firehazard.
What happens in the event of a powerfailure?If there is a loss
of electricity (and thedwelling has no back-up generator)
theventilation system will stop working andthe supply of fresh air
will be cut off. Ifpower is lost for a short while (forexample a
few hours), then there is likelyto be no noticeable difference in
indoorair quality. If the loss of power isprolonged, the simple
solution is toopen the windows and to create naturalcross flow
ventilation through thebuilding.
Back-up Heating SystemAs previously highlighted in
theseguidelines, space heating requirementin a passive house is so
low that there isno need for a traditional space heatingsystem. The
optimal way to transfer thesmall amount of required heat
through-out the house is through the mechanical
ventilation system. This section of theguidelines will provide
an overview ofthe typical back-up heating systemsused in passive
houses to providethermal comfort .
Space heating demand in a passivehouse is typically met through
passivesolar gains (40–60%), internal heat gains(20–30%) and the
remainder (10–40%)needs to be provided from buildingsystems.
The PHPP software will accuratelypredict the following two
measure-ments for each passive house design:
• Annual Space Heat Requirement -this measures the amount of
energythat is needed to maintain acomfortable indoor
temperature,specified in kilowatt hours per squaremetre of treated
floor area per year,or kWh/(m2year).
• Heat Load - this measures thecapacity of the space heating
systemrequired to maintain comfortableindoor temperatures at any
one time,specified in Watts per square metre oftreated floor area,
or W/m2.
For the prototype house the annualspace heat requirement
is15kWh/(m2year) equating to approx-imately 1,650 KWh over an
entire year(the house measures 110m2 in treatedfloor area). This
would equate to 155litres/year of oil, 160m3/year of mains gasor
350kg/year of wood pellets (in bags)at a cost of approximately
€92/yearwhen using oil, €55/year when using gas(without standing
charges for gas or€345/year with standing charges) or€97/year when
using wood pellets. Unitprice: heating oil 5.62c/kWh; mains
gas3.39c/kWh standing charges €256/year;wood pellets - in bags
5.92c/kWh.Source: SEI, Dwelling Energy AssessmentProcedure (DEAP)
2005 edition, version2, Manual pp. 84.
The heat load, on the other hand, isapproximately 1,800 W, or
just 1.8 kW.This amount of energy could beprovided by a very small
stove / heater /boiler compared to what might betypically required
in a family home.
The most common method of 'heating'in a passive house is by
post-heating thefresh air after it has already beenwarmed by the
exhaust air in the MVHR.
20
Used air filter. Source: MosArt Architecture.
What a clean filter looks like. Source: MosArt Architecture.
Water to air heat exchanger unit. Source: MosArt
Architecture.
Compact unit including ventilation heat recovery andair to water
heat pump. Source: Drexel und Weiss.
-
There are a number of ways in which thetemperature of the air
can be boosted,including those listed below:
• Water to air heat exchanger.
• Compact unit with electrical heatpump.
• Compact unit with natural gas.
The first two of these is explored inoutline below. The compact
unit withnatural gas, while used in Central Europeis virtually
unheard of in Ireland andwould have to be approved for use bythe
appropriate authorities.
Water to Air Heat ExchangerThis method involves using a
heatingdevice placed immediately on the freshair supply outlet of
the MVHR. There is asmall radiator inside this device and it
isheated by hot water connected to thedomestic hot water tank. If
the houseneeds additional heat (which isdetermined by a thermostat)
then hotwater is circulated through the device,hence the
appropriate title of ‘water toair heat exchanger’. Once the house
hasreached the programmed temperature,the hot water stops
circulating and theair is no longer heated. The water in
thedomestic hot water (DHW) tank isheated, in turn, by using a
number ofenergy sources including a stove orboiler (for a larger
house) in combinationwith solar hot water panels. Theprinciple
advantage of this system overthe compact unit system describedbelow
is that when fueled by acombination of firewood and sunshine itis
carbon neutral.
Compact Unit with Electrical Heat PumpThis system is so-named as
itincorporates all of the technologyrequired for a passive house in
arelatively small unit, namely the MVHR,the DHW and the heating
power for thehome, in this case powered by anelectrically powered
heat pump. It istherefore very suited to smaller homeswhere space
might be limited for largetanks, stoves and storage for
wood.Compact units are becoming morewidespread in use in passive
housesbuilt in Central and Northern Europe.
Integrated controls for heating in aPassive HouseHeating systems
in Irel
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