Assessing impacts of summertime overheating: some adaptation strategies

Tillson, Amy-Alys; Oreszczyn, Tadj; Palmer, Jason

doi:10.1080/09613218.2013.808864

Cited by 32 publications

(21 citation statements)

References 8 publications

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“…For instance, Orme, Palmer and Irving [7] concluded that night time purging was the most effective single intervention to reduce overheating. Tillson et al [8] showed that using a combination of window shutters or overhangs and ventilation can greatly reduce overheating. Mavrogianni et al [9] investigated the effectiveness of thermal mass and insulation in reducing overheating.…”

Section: The Passivhaus Standard and Literature Reviewmentioning

confidence: 99%

Summer Thermal Comfort and Self-Shading Geometries in Passivhaus Dwellings: A Pilot Study Using Future UK Climates

Lavafpour

Sharples

2015

Buildings

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This study uses numerical thermal simulation to investigate the potential use of building geometry to eliminate or reduce current and future thermal discomfort overheating risk in UK Passivhaus dwellings. The study focused on the optimum inclination of a south façade to make use of the building shape to self-protect itself. Dynamic simulation modelling software was used to test a range of different inclined façades with regards to their effectiveness in reducing overheating risk. The research found that implementing a tilted façade could completely eliminate the risk of overheating for current UK climates, but with some consequences for natural ventilation and daylighting. Future overheating was significantly reduced by the tilted façade. However, geometric considerations could not eradicate completely the risk of thermal discomfort overheating, particularly by the 2080s.

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Section: The Passivhaus Standard and Literature Reviewmentioning

confidence: 99%

Summer Thermal Comfort and Self-Shading Geometries in Passivhaus Dwellings: A Pilot Study Using Future UK Climates

Lavafpour

Sharples

2015

Buildings

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“…A plethora of studies have used dynamic thermal simulation in order to see how different energy refurbishments might affect building overheating in current and future weather scenarios (Mavrogianni et al, 2012;Tillson et al, 2013;Porritt et al, 2011;Porritt et al, 2012;McLeod et al, 2013;Oikonomou et al, 2012;Ji et al, 2014;Barbosa et al, 2015). However, most of these studies use simple statements of ventilation patterns, for example, ventilation commencing when the room operative temperature reaches an assumed threshold temperature (Mavrogianni et al, 2012;Tillson et al, 2013;Porritt et al, 2011;Porritt et al, 2012). This is not representative of how windows are used in reality by occupants in homes, since it is based on studies in offices.…”

Section: Introductionmentioning

confidence: 99%

Overheating in vulnerable and non-vulnerable households

Vellei

2016

Building Research & Information

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As the 2003 European heat wave demonstrated, overheating in homes can cause wide scale fatalities. With temperatures and heat wave frequency predicted to increase due to climate change, such events can be expected to become more common. Thus, investigating the risk of overheating in buildings is key to understanding the scale of the problem and in designing solutions. Most work on this topic has been theoretical and based on lightweight dwellings that might be expected to overheat. By contrast, in this study temperature and air quality data were collected over two years in vulnerable and non-vulnerable UK homes where overheating would not be expected to be common. Overheating was found to be occurring, and disproportionally so in households with vulnerable occupants. Since the summers in question were not extreme and contained no prolonged heat waves this is a significant and worrying finding. The vulnerable homes were also found to have worse air quality and this suggests that some of the problem might be solved by enhancing indoor ventilation. Finally, the collected thermal comfort survey data were validated against the European adaptive model. Results suggest that the model underestimates discomfort in warm conditions, having implications for both vulnerable and non-vulnerable homes.

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“…Barriers to uptake have led to an energy efficiency gap [87], which policy has not adequately addressed [88]. In addition to this range of non-cost factors, modelling needs to account for a range of other factors, such as rebound effects [89], the specificity of measures to building type, the degree of interaction with other aspects of the heating system, linkages with preventing winter mortality [90] and energy poverty [91], other risks such as over-heating [92,93], and broader supply chain issues relating to scaling up the deployment of energy efficiency measures. Appendix A.1.…”

Section: Discussionmentioning

confidence: 99%

Heat Decarbonisation Modelling Approaches in the UK: An Energy System Architecture Perspective

et al. 2020

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Energy models have been widely applied to the analysis of energy system decarbonisation to assess the options and costs of a transition to a low carbon supply. However, questions persist as to whether they are able to effectively represent and assess heat decarbonisation pathways for the buildings sector. A range of limitations have been identified, including a poor spatio-temporal resolution, limited representation of behaviour, and restricted representation of the full technical option set. This paper undertakes a review of existing energy models for heat decarbonisation in the UK, applying the novel perspective of energy system architecture (ESA). A set of ESA-related features are identified (including evolvability, flexibility, robustness, and feasibility), and models are reviewed against these features. The review finds that a range of models exist that have strengths across different features of ESA, suggesting that multiple modelling approaches are needed in order to adequately address the heat decarbonisation challenge. However, opportunities to improve existing models and develop new approaches also exist, and a research agenda is therefore proposed.

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Assessing impacts of summertime overheating: some adaptation strategies

Cited by 32 publications

References 8 publications

Summer Thermal Comfort and Self-Shading Geometries in Passivhaus Dwellings: A Pilot Study Using Future UK Climates

Summer Thermal Comfort and Self-Shading Geometries in Passivhaus Dwellings: A Pilot Study Using Future UK Climates

Overheating in vulnerable and non-vulnerable households

Heat Decarbonisation Modelling Approaches in the UK: An Energy System Architecture Perspective

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