Abstract
With the help of building diagnostics, the causes and solutions to complex problems in buildings can be determined. In central and greater London, an increasing number of cases of chronic, year-round, overheating in buildings have been reported. We present three cases of unexpected temperatures in multi-storey residential buildings. Detailed analysis and modelling of these scenarios have led to an investigation of whether the way in which infiltration is currently modelled in building performance simulation may be exerting a pronounced effect on the results of overheating studies. An EnergyPlus model, of one of the dwellings in a multi-residential building in London, was created to investigate the influence of infiltration and exfiltration pathway assumptions on the prediction of overheating. The simulation results were compared to empirical data and show that the predicted indoor temperatures are highly sensitive to how the infiltration airflow network is modelled. The findings of this study have been used to provide practical guidance for modellers and building designers on critical aspects to consider when creating building performance simulation models to ensure more reliable outcomes. Overheating in buildings is an emerging topic of critical importance to the future of the built environment. The importance of understanding infiltration pathways in assessing and modelling overheating risks in flats and multi-residential buildings has been hitherto underestimated or simply ignored. In this paper, examples are given which highlight the need for a fuller understanding of internal air movement where accurate predictions of internal temperatures are required. At present, common building simulation practices and existing technical memorandum (TM) standards are masking the problem and do not provide a basis from which typical or worst-case scenarios can be adequately considered.
Highlights
As part of a building diagnostic study that took place in 2015, a number of cases of chronic overheating were investigated in greater London.[1]
There is a gap between the EnergyPlus simulations and reality where the monitored indoor temperatures are considerably higher than the simulated ones
This study has demonstrated the importance of modelling both infiltration and exfiltration pathways, between adjacent zones, in order to capture the mass transfer of heat, in complex multi-storey, multi-residential buildings
Summary
As part of a building diagnostic study that took place in 2015, a number of cases of chronic (i.e. year-round) overheating were investigated in greater London.[1] It is notable that the climate of 2015 does not rank amongst the hottest 10years in the UK record. Whilst 10 of the hottest years ever recorded in the UK have all occurred since 2002.2 The year 2015 can be considered a relatively cool year during this recent period. We address a critical and neglected aspect of current practice in relation to overheating risk assessments carried out in multiresidential buildings. Three case study examples from three flats located in two adjacent multistorey buildings in central London, UK are used to provide empirical evidence of the problem of correctly accounting for inter-zonal air flow pathways in the assessment of overheating risks. Opening a window when the outside temperature is cooler than the inside temperature does not necessarily lead to cooling of the internal temperature of the space
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