Assessing uncertainty in housing stock infiltration rates and associated heat loss: English and UK case studies

Jones, Benjamin; Das, Payel; Chalabi, Zaid; Davies, Martin; Hamilton, Ian; Lowe, Robert; Mavrogianni, Anna; Robinson, Darren; Taylor, Jonathon

doi:10.1016/j.buildenv.2015.05.033

Cited by 49 publications

(55 citation statements)

References 26 publications

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“…Studies have found that there is little difference in airtightness between naturally and mechanically ventilated dwellings in the UK [16]. The infiltration rate in an UK dwelling vary between 0.02 and 2.77 h −1 , and probably less than 1.13 h −1 for a detached house [17].…”

Section: Introductionmentioning

confidence: 99%

Energy Modelling and Calibration of Building Simulations: A Case Study of a Domestic Building with Natural Ventilation

et al. 2019

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In this paper, the building energy performance modelling tools TRNSYS (TRaNsient SYstem Simulation program) and TRNFlow (TRaNsient Flow) have been used to obtain the energy demand of a domestic building that includes the air infiltration rate and the effect of natural ventilation by using window operation data. An initial model has been fitted to monitoring data from the case study, building over a period when there were no heat gains in the building in order to obtain the building infiltration air change rate. After this calibration, a constant air-change rate model was established alongside two further models developed in the calibration process. Air change rate has been explored in order to determine air infiltrations caused by natural ventilation due to windows being opened. These results were compared to estimates gained through a previously published method and were found to be in good agreement. The main conclusion from the work was that the modelling ventilation rate in naturally ventilated residential buildings using TRNSYS and TRNSFlow can improve the simulation-based energy assessment.

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Section: Introductionmentioning

confidence: 99%

Energy Modelling and Calibration of Building Simulations: A Case Study of a Domestic Building with Natural Ventilation

et al. 2019

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“…The impact of infiltration as a consequence of poor airtightness can be considerable; research by Jones (Jones, 2015) predicts that unintended infiltration across the UK housing stock may be responsible for as much as 5% of total UK energy demand. However, the standard blowerdoor method used to measure airtightness, in some cases to predict infiltration, could arguably be considered a compromise and concerns about this technique have led to numerous attempts to find alternative ways of determining building airtightness; a partial selection of these attempts include AC techniques (repeated sinusoidal building volume change) by Sharples (Sharples, 1996), Siren (Siren, 1997), Sherman (Sherman, 1986), Watanabe (Watanabe, 1999), Nishioka (Nishioka, 2003) and Modera (Modera, 1989), gradual decay techniques by Granne (Granne, 2001) and Mattsson (Mattsson, 2007), acoustic techniques by Varshney (Varshney, 2013) and Card (Card, 1978), and pulse techniques by Carey (Carey, 2001), and Cooper (Cooper, 2004.…”

Section: Introductionmentioning

confidence: 99%

Field trialling of a pulse airtightness tester in a range of UK homes

Cooper

Zheng

Wood

et al. 2016

International Journal of Ventilation

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A note on versions:The version presented here may differ from the published version or from the version of record. If you wish to cite this item you are advised to consult the publisher's version. Please see the repository url above for details on accessing the published version and note that access may require a subscription.For more information, please contact eprints@nottingham.ac.uk Field trialling of a new airtightness tester in a range of UK homes ABSTRACTA low pressure 'quasi-steady' pulse technique for determining the airtightness of buildings has been developed and compared with the standard blower-door technique for field-testing a range of UK homes. The reported low pressure air pulse unit (APU) for determining the airtightness of buildings, through several development stages related to optimizing the algorithm, pressure reference and system construction, has been trialled under various testing and environmental conditions to assess its repeatability and accuracy. The houses, representative of the UK housing stock, mostly have high levels of air leakage; resulting in poor energy performance and imbalanced indoor environments. The results of the pulse techniques are also compared with the standard blower door technique. A comparison between the results obtained using the two techniques is presented, which indicates that the pulse technique is reliable for determining building leakage at low pressure. Repeatability of consecutive tests in identical conditions is found to be within ± 5% of the mean, and within ± 8% when tested under different environment conditions. It has also been shown that the correct tank/valve combination is necessary to achieve the required quasi-steady flow. Tests for accuracy using the addition of known openings have been conducted and shown that uncertainties are hard to eliminate for a clean comparison when testing conditions are not controlled.

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“…It is desirable to minimize adventitious openings to minimize a building's energy demand and to ensure the satisfactory operation of a system of PPOs (Jones et al, 2015). When designing a ventilation strategy that comprises a system of PPOs, a fundamental objective is to establish their location and size.…”

Section: Introductionmentioning

confidence: 99%

A review of ventilation opening area terminology

Jones

Cook

Fitzgerald

et al. 2016

Energy and Buildings

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The design of a natural ventilation strategy requires the establishment of the location and size of a series of purpose provided ventilation openings (PPOs). The success of the design is dependent on knowledge of the aerodynamic performance of the PPOs often described by their geometry (normally an area) and resistance to airflow. The incorrect interpretation of this information can lead inappropriate ventilation strategies and buildings that overheat and have an excessive energy demand.Many definitions of PPO area are used by standards, guidelines, text books, and software tools. Each can be assigned multiple terms and a single term can be assigned to different definitions. There is evidence that this leads to errors in practice. An effective area of a PPO, defined as the product of its discharge coefficient and its free area, is proposed as a standard description because it is unambiguous and its measurement is governed by recognised standards. It is hoped that PPO manufacturers will provide an effective area as standard and that its use will be recognised as best practice. It is intended that these steps will reduce design errors and lead to successful natural ventilation strategies and better buildings. HIGHLIGHTS Definitions of free, effective, and equivalent ventilation opening areas are given  A review of current definitions highlight contradictions in national standards and guidelines  The contradictions are shown to lead to unintended design errors  An unambiguous term that describes ventilation opening performance is proposed  This will help to mitigate against design errors in ventilation strategies KEYWORDS Natural Ventilation; Design; Standards; Effective area; Equivalent area; Free area; Policy. 3 INTRODUCTIONOpenings located in the thermal envelope of a building comprise those that are intentional, known as purposeprovided openings (PPOs), and those that are unintentional, known as adventitious openings (Etheridge, 2012).It is desirable to minimize adventitious openings to minimize a building's energy demand and to ensure the satisfactory operation of a system of PPOs (Jones et al., 2015). When designing a ventilation strategy that comprises a system of PPOs, a fundamental objective is to establish their location and size. Both factors depend on the airflow rates required through each PPO for a given pressure drop in order to maintain adequate indoor air quality (IAQ) and to dissipate heat gains under limiting conditions (CIBSE, 2005). Accordingly, a description of the geometry of each PPO and its resistance to airflow are required in order to enable a designer to establish the performance of a system using envelope flow models (CIBSE, 2005;Etheridge, 2012). The same information can also be used when working with more complex simulation tools to ensure that a building meets relevant energy and indoor environment quality (IEQ) criteria, such as indoor air quality (IAQ), thermal comfort, overheating, and noise levels. The geometrical information and resistance to airflow of a specific P...

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Assessing uncertainty in housing stock infiltration rates and associated heat loss: English and UK case studies

Cited by 49 publications

References 26 publications

Energy Modelling and Calibration of Building Simulations: A Case Study of a Domestic Building with Natural Ventilation

Energy Modelling and Calibration of Building Simulations: A Case Study of a Domestic Building with Natural Ventilation

Field trialling of a pulse airtightness tester in a range of UK homes

A review of ventilation opening area terminology

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