1. What is air tightness?
2. Why is air tightness important?
3. What impact does air tightness have on carbon emission rates calculated using SAP or SBEM?
4. Is air tightness testing mandatory?
5. Which buildings need to be tested?
6. Do I need to test every building unit?
7. Who selects which buildings to test and when?
8. What are the most common air leakage/infiltration paths?
9. Who can carry out the testing?
10. When does testing take place in the construction process?
11. What information is required to produce a quote for air tightness testing?
12. What preparation needs to take place in advance of testing?
13. What does air tightness testing involve?
14. What is the envelope area?
15. How long does an air tightness test take?
16. How is air tightness calculated?
17. When will I get the results?
18. What test evidence is required?
19. What happens if the building fails?

1. What is air tightness?

Air tightness, air leakage or air permeability all refer to the leakage of ‘conditioned air’ (heated or cooled) through ‘unplanned/unintentional ventilation’ (gaps, holes, cracks, etc).

By limiting the loss of this conditioned air, which requires the consumption of energy to produce and replace, it is possible to more efficiently maintain the temperatures of our buildings.

Also, the infiltration of colder/hotter air from outside requires heating/cooling systems to work harder and consume more energy.

FAQ list

2. Why is air tightness important?

Air tightness plays a significant role in the energy efficiency of buildings.

Because:

• a link has been established between carbon emissions and global warming
• the production of energy emits carbon
• the built environment contributes about 50% of carbon emissions
• heated/conditioned air leaking from buildings requires the use of additional energy to maintain temperatures

By limiting the leakage of heated/conditioned air from buildings, it is possible to reduce energy consumption and costs.

The government has made commitments to reduce carbon emissions through the European Energy Performance of Buildings Directive (EPBD) and the Kyoto Agreement. Part L is their method for addressing the conservation of fuel and power in buildings and as such places requirements on air tightness.

FAQ list

3. What impact does air tightness have on carbon emission rates calculated using SAP or SBEM?

Air permeability is an important factor in assessing the overall carbon emission of a building via the appropriate calculation methodology:

• Standard Assessment Procedure (SAP) for dwellings under 450m² floor area – accredited software has been developed to make calculation easier.
• Simplified Building Energy Model (SBEM) for buildings other than dwellings – software still under development

Before construction:
SAP or SBEM is used to calculate a Target Emission Rate (TER) in advance of starting building work. This is based on a range of factors including orientation, glazing, insulation, heating system/fuel and air permeability. The details of the above are entered into the software along with a ‘Design Air Permeability’ (what you hope the building will achieve under testing) which must be under 10m³/h/m²)or 15 m³/h/m² if an assumed value can be used.

The TER is effectively the performance the building would have achieved under 2002 regulations, with a 20% improvement factor applied, in line with wider government targets for reducing carbon emissions.

To achieve the TER, you may need to change the specification of products, orientation of buildings, heating system or commit to achieve air permeability lower than the basic regulatory requirement.

If you want to view how you might achieve the TER using your existing methods and products you can do so at www.playtheregs.com

After construction:
The building is then constructed and the specification and configuration of the building may change over the course of the process. The actual details and tested air permeability figure are entered into the software again to give a Dwelling or Building Emission Rate (DER or BER)

The actual DER or BER must be lower or equal to TER.

This is a regulatory requirement under Approved Document L.

FAQ list

4. Is air tightness testing mandatory? 

Yes, buildings need to demonstrate a minimum level of air permeability (10m³/h/m²) and in the majority of cases this is done through an on-site, pre-completion test.

This is not an onerous requirement in itself but the design air permeability for a particular building may be lower to achieve the overall carbon emission rate for the building and/or client specification.

FAQ list

5. Which buildings need to be tested?

1. All new dwellings (based on a sampling rate)
2. All new buildings other than dwellings
3. ‘Large’ Extensions to buildings other than dwellings

There are some exceptions to the above where buildings may be able to assume a poorer air permeability rather than undertake a test. The exceptions are explained below

1. Dwellings
Approved Document L1A - Conservation of Fuel & Power (for England & Wales) requires air tightness testing of new houses and flats to achieve building control approval.

Refurbishments of and extensions to existing residential buildings do not require testing.

Small developments (1 or 2 houses) may avoid the need to test by accepting an assumed poor value for air permeability of 15m³/h/m² but this may add costs to other aspects of the building specification in order that the building meets overall targets for emissions. Alternatively it may be possible to re-use existing test evidence where building designs have been repeated within 12 months of conducting the original test.

2. Buildings other than dwellings
Approved Document L2A - Conservation of Fuel & Power (for England & Wales) requires air tightness testing of new commercial buildings to achieve building control approval.

‘Small’ commercial buildings (with a floor area less than 500m²) may avoid the need to test by accepting an assumed poor value for air permeability (15m³/h/m²) but this may add costs to other aspects of the building specification in order that the building meets overall targets for emissions.   

3. ‘Large’ extensions to buildings other than dwelling
Approved Document L2B - Conservation of Fuel & Power (for England & Wales) requires air tightness testing of ‘large’ extensions to commercial buildings to achieve building control approval.

‘Large’ is defined as greater than 100m² AND greater than 25% of the useful floor area of the existing building.

FAQ list

6. Do I need to test every building? 

• Yes for commercial buildings
• No for dwellings

For commercial developments, where testing is required, each individual building unit will need to be tested ie if the ‘unit’ is not connected to adjoining units and intended to be occupied/operated separately.

However, in practice we have seen similar units being covered by a sample.

On residential developments a sampling rate applies depending on:

1. Dwelling Types
2. Adoption of ‘Accredited Construction Details

1. Dwelling Type

For housing developments, a sample of units from different ‘dwelling types’ are tested to prove compliance. Separate blocks of flats are considered as different developments.

Dwelling types are defined based on:

1.  Position – this is likely to be:

• Detached house (no party walls)
• End terrace/sem-detached house (1 party wall)
• Mid terrace house (2 party walls)
• Ground/bottom floor flat (party floor below - may be over car parking, drive through, etc.)
• Intermediate floor flat (2 party floors)
• Top floor flat (party floor below)

2.  Construction type – where there is variation in floor, wall and roof construction details and/or construction method. For simplicity it is likely that this would be based on whether there is variation in those aspects covered by the Accredited Construction Details. This is likley to relate most obviously to variation in storey height ie duplex rather than single storey flats or 2.5 storey (warm roof) rather than 2 or 3 storey (cold roof). Plus whether similar units are being built using different methods ie traditional/masonry, timber frame, steel frame, etc.

Other factors may also effect dwelling types based on ATTMA TS1:

• Size: Part L makes reference to size but fairly vaguely: ‘small changes in ground floor area do not constitute a change in dwelling type’. ‘Small’ is not defined so is open to interpretation. Ultimately, Building Control will define what constitutes a significant change in size but as a basis for estimating it is safe to assume this will not effect the dwelling types.  ATTMA suggest 15% variation although in practice 50% to 100% variation is more likely to be considered 'significant'.
• Significant penetrations: ie number of windows, doors and flues.

2.   Accredited Construction Details

Part L1A refers to Accredited Construction Details (ACD), these can be found on the Planning Portal website (http://www.planningportal.gov.uk/england/professionals/en/1115314255826.html).

The details refer to insulation as well as air permeability and are divided into construction types:

• Timber frame
• Steel frame
• Masonry (cavity insulation)
• Masonry (internal insulation)
• Masonry (external insulation)

They include details for the important elements of the dwelling, including:

• Ground floor to wall
• Wall to ceiling
• Party walls and floors to external walls
• Eaves
• Windows and Doors

The details take the form of a site checklist.

Adoption of these details will need to be verified by Building Control or the Approved Inspector.

Sampling for Dwellings

FAQ list

7. Who selects which buildings to test and when?

In theory, it is the responsibility of Building Control or the Approved Inspector to randomly select which units to test. The aim is to prevent certain building units being constructed specifically for testing and therefore not necessarily reflecting the air tightness of similar units.

Approved Document L encourages the testing of units as early in the construction process as possible to allow any problem identified under test to be addressed on future units, rather than completed units of the same type having to undergo costly and disruptive remedial work.

These two factors are a little contradictory in so much that if you test the first completed unit of a dwelling type the sample will not be random (as there is only one to choose from).

There is also a practical consideration when scheduling the testing, it will be significantly cheaper and less disruptive to test 4 dwelling types on a single day rather than over 4 separate days.

It is yet to be seen quite how selection of units and timing of their testing will take place but I would suspect that common sense would dictate a balance of the above considerations.

This might affect the build programme such that an example of each dwelling type is completed early in the construction of the whole development so testing can be completed early enough to address any issues but multiple tests can be conducted.

There will need to be discussion between the contractor, testing body and controlling authority to achieve a pragmatic solution.

In practice, It is likely that the air tightness testing body will propose a test regime based on information provided by the building contractor and the building inspector will approve this.

The units to be tested are most likely to be the first completions of each type.

FAQ list

8. What are the most common air leakage/infiltration paths? 

In essence achieving an air tight building should not be too difficult. Identifying potential air paths is fairly straightforward and addressing them is often not complicated or may be already dealt with by measures to achieve acoustic or fire requirements, as well as achieving the basic finish that is likely to be expected by the occupants.

Basically, the objective is to create a continuous air barrier between:

• Inside and outside
• Conditioned and unconditioned spaces ie apply the same principles to barriers between heated and unheated areas eg plant rooms, stair wells
• Adjacent units eg flats or attached houses are tested individually so, as far as the test is concerned, air leakage into neighbouring units is still leakage.

Creating this air barrier is the SHARED responsibility of:

• The designer
• The contractor – namely the construction manager and/or the site manager
• The subcontractors – notably those that are responsible for creating the air barrier eg plasterers, timber frame erectors and those that may penetrate it eg plumbers and electricians

Therefore communication is important. Ensure workers and sub-contractors are aware of the important areas and the impact of their work. Place responsibility on ‘subbies’ to maintain the air barrier and require them to pay remedial or re-test costs if found to be their responsibility. It may be helpful, having established the air barrier, to identify it on drawings so the site manager is made aware of critical areas and therefore operations.

Areas to focus on:

1. Where elements of the air barrier meet eg wall to floor, wall to structural ceiling (suspended ceilings are permeable), cladding to roofing, eaves details, etc. For dwellings these details comprise the ACD and are focussed on achieving a good internal finish. In more complex constructions it may be helpful to identify the air barrier – which must be continuous. Typically the air barrier will be external or party walls, ceilings and floors plus elements bordering ‘unconditioned areas’ (eg plant rooms, garages and cold roof spaces). Sometimes detailing around partition walls and floors may also present an air path into cavities or voids that link to an external space. Extensions can create particular difficulties where contractors are trying to seal against the external face of an existing building as well as running services and allowing access between the new and old areas.
2. Where components meet eg block work joints, joints between beam and block flooring, where cladding systems overlap or meet blockwork.
3. Where penetrations interrupt the air barrier:

• Doors and windows - ensure door and window fitters produce a good seal between the building and the product (ensuring air cannot escape outside or into the cavity) – eg board out the aperture.
• Loft hatches – some of the plastic hatches may distort; preferably they would close against a lip rather than be suspended so that gravity helps to seal them.
• Piping – especially soil piping, sealing where pipes enter boxing and/or where they exit eg into unconditioned loft spaces.
• Electrical fittings – resealing behind sockets and switches is preferable on external/party walls eg taping or putty pads in extreme cases. Down-lighters in party ceilings can present a problem.
• Trickle vents – these are closed but not sealed during testing so it is important they create a good seal and are not damaged/distorted.
• Ventilation – although the face of vents for extraction and air supply systems are sealed during testing, you still need to make sure they are well fitted

Generally, air should not escape in great quantities through walls, floors and ceilings themselves (plaster is an excellent seal) but it is worth checking the permeability of certain materials eg:

• the density of block work effects its permeability (large expanses may need painting)
• mineral wool is permeable and therefore continuity of insulation does not necessarily guarantee air tightness
• perforated acoustic products obviously will not provide an air barrier on their own

Finally, be aware of concealed areas to avoid an ‘out of sight, out of mind’ mentality, eg:

• Above suspended ceilings
• Below raised floors
• Behind bath panels and shower trays

These may mask unsealed penetrations or other problems so site managers and agents will need to be vigilant when signing off sub-contract work

On site, basically:

1. Can you see any holes?
2. Are they supposed to be there?
3. If not, where would air go that passes through them?
4. If it is likely to escape outside, seal it at one end or the other.

FAQ list

9. Who can carry out the testing?

Part L requires testing to be conducted test engineers/bodies registered by the British Institute of Non Destructive Testing (BINDT).

BINDT registration for Part L1 testing is based on training of individuals and calibration of their equipment or membership of the Air Tightness Testing & Measurement Association (ATTMA).

Registration for Part L2 requires ATTMA membership.

ATTMA membership requires technical review of training, reports and procedures and accreditation by the United Kingdom Accreditation Service (UKAS).

UKAS accreditation verifies:

• that the testing body works to appropriate procedures 
• test engineers have the necessary training and competency levels
• equipment is correctly calibrated within defined parameters to ensure the accuracy of readings through annual site inspection and system audits.

Testing can be carried out by a ‘suitably competent person’ but in the absence of a third party checking the accuracy and consistency of testing, the building inspector will need to take additional responsibility to ensure testing has been completed correctly. This should include checking the report especially the calculations and/or witnessing testing.

FAQ list

10. When does testing take place in the construction process? 

Basically when the building is completed, typically everything has been finished apart from the carpets being laid. But before handover.

Inviting the test body to site too early is likely to jeopardise the result, mean testing is impossible or not satisfy the building inspector.

This does place extra pressure on getting things right first time, remedial works at this stage may be awkward and cause expensive delays.

It is important that the air barrier is complete and any penetrations have been fitted and finished.

For dwellings we have produced a checklist to gauge whether the units are sufficiently complete.

FAQ list

11. What information is required to produce a quote for air tightness testing?

For dwellings, sufficient information is required to identify the different dwelling types and the number of each eg General Arrangement/Site Plan and Schedule (including other important details such as variation in storey height or construction method).

For buildings other than dwellings, the approximate envelope area is the key factor for quoting. It is required to establish the necessary fan arrangement. This affects the time on site and potentially the number of people. This can be calculated from drawings – floor plans AND elevations.

The testing body may also need to identify the potential aperture(s) for the test equipment to be installed into, in some circumstances this may require additional time on site, extra people or bespoke templates to be made.

The SAP/SBEM assessor or architect may have already calculated (NB should be verified for final result).

FAQ list

12. What preparation needs to take place in advance of testing? 

We provide a simple checklist of building preparation. This needs to go to site. The preparation would ideally be undertaken by the contractor n advance of the test body arriving on site to maximise the testing time in a day.

For dwellings it may also be necessary to agree the test programme with the building inspector before arriving on site.

Where possible, it is helpful to accurately calculate the envelope area and confirm the fan installation arrangements based on architectural drawings before coming to site.

• The building should be ‘completed’
• All external doors and windows closed
• All internal doors wedged open
• All fire dampers, ventilation louvres and trickle vents closed but not sealed
• Mechanical ventilation turned off with inlet/outlet grilles sealed
• All combustion appliances switched off
• Drainage traps must contain water

FAQ list

13. What does air tightness testing involve?

The objective is to measure the volume of conditioned air escaping through the building envelope via uncontrolled ventilation at an induced pressure difference of 50Pa.

The following basic steps are typical:

1. Check site preparation / Prepare site – including temporary sealing
2. Calculate the envelope area if not done previously
3. Explain the process to relevant staff and sub-contractors working on or near the building
4. Take environmental condition measurements – wind speed, temperatures, barometric pressures
5. Install template(s) into suitable aperture(s)
6. Install fan(s) into template(s)
7. Connect monitoring equipment
8. Check the static pressure
9. Take multiple pressure difference readings and record fan flow rate(s) – allowing sufficient time for the pressure readings to stabilise
10. Check the static pressure
11. Check site preparation / Prepare site – including temporary sealing
12. Take environmental condition measurements – wind speed, temperatures
13. Process the readings through appropriate software – check that readings fulfil the requirements of the standard
14. If the building fails, attempt to identify/quantify air leakage/infiltration paths
15. Disconnect measurement equipment
16. Remove the fan(s)
17. Remove the template(s)

FAQ list

14. What is the envelope area?

The envelope area is the total internal surface area of the conditioned areas of the building ie the sum of floor area, wall areas and roof area (of the heated space).

This should be calculated or verified by the air tightness test body as the accuracy of the envelope area has a significant impact on the final air permeability result.

The building inspector should check this is being done correctly and/or approximately verify the area.

FAQ list

15. How long does an air tightness test take? 

Depending on:

1. The size/complexity of the building which affects the pre-test checks, equipment installation and test time
2. The amount of preparation that needs to take place
3. The access to the site which affects set up times,

Assuming the second 2 factors are within reasonable limits the 1st factor tends to mean a test time of between 1 and 4 hours:

• dwellings typically take 30 to 90 minutes for each unit
• industrial units typically take between 90 minutes and 3 hours
• hospitals, schools, large office blocks, etc typically taking up to 4 hours.

FAQ list

16. How is air tightness calculated?

Air permeability is essentially a function of the pressure difference between the inside and outside of the building and air flow rate through the fan(s) to produce that pressure difference.

This is averaged out over the envelope area.

The result takes account of environmental conditions.

The final air permeability at 50Pa is based on a logarithmic graph of pressure difference and flow rate, the graph should:

• Have at least 5 points (ideally 10 or more)
• The highest figure should be at least 35Pa but preferably would be in excess of 50Pa and ideally higher than 60Pa
• The lowest figure should be at least 10Pa or 5 times the ‘static pressure’ (the pressure difference between inside and outside without the fans) – which in itself MUST be less than 5Pa to limit uncertainty
• The readings should be no more than 10Pa apart
• The correlation of the graph should be at least 98%
• The gradient of the graph (n) should be between 0.5 and 1.0

These are aspects that the BCB should be checking carefully if choosing to accept air permeability results from non-accredited testing bodies.

FAQ list

17. When will I get the results?

An indicative result is available immediately.

Certificates can usually be issued on the same day, where required.

Reports will certificates are typically sent within 5 working days.

FAQ list

18. What test evidence is required?

A test certificate from a test engineer and/or test body that is registered with the British Institute of Non-destructive Testing (BINDT).

The test certificate should include sufficient information to describe the building tested eg location, type and size (the envelope area is an important component in calculating the air permeability and must be accurate) plus the design air permeability as well as the actual result.

I would also expect the certificate to refer to BINDT registration and/or membership of the Air Tightness Testing & Measurement Association (ATTMA). This can be cross-referenced via their respective websites eg www.attma.org

ATTMA membership requires accreditation by the United Kingdom Accreditation Service (UKAS) to check test engineer competency, accuracy of equipment and consistency/appropriateness of procedures, plus a technical review of training, procedures and evidence.

The test engineer/body should also produce a full test report that meets the requirements of ATTMA Technical Standard 1. This will include the building pre-test preparations as well as full test data and should be available from the contractor if required.

FAQ list

19. What happens if the building fails? 

At Chiltern Dynamics, we will endeavour to help you identify the probable air leakage/infiltration paths.

There are number of methods we employ to do this of increasing complexity:

• Depressurise the building – we tend to pressurise the building under testing which forces air out, by reversing the fans and depressurising the building air is drawn in and normally can be felt or even seen as ‘draughts’
• Smoke testing – if the air paths are less direct it may be necessary to use smoke puffers and/or fill the building with smoke and pressurise/depressurise again. Points of air ingress and egress should be identifiable.
• Thermography – if it is still not apparent where air is escaping, infra-red cameras can be used to identify hot spots and cold spots on the internal and external surfaces of the building. This requires a temperature difference between inside and outside and usually done at night.

In the vast majority of cases the first method is sufficient to identify air leakage paths. These can be temporarily or permanently sealed and the test repeated to quantify the effect of addressing these areas.

The building will need to be re-tested, sometimes on the same day but usually at a later date.

For buildings other than dwellings, the same unit is tested and must achieve the air permeability require to achieve the Target Emission Rate or for buildings less than 1000m², until October 2007, a significant improvement.

For dwellings, the same unit should be tested, plus another example of the same dwelling type (assuming one exists).

FAQ list