Advancement on Thermal Comfort in Educational Buildings: Current Issues and Way Forward

The thermal environment in educational buildings is crucial to improve students’ health and productivity, as they spend a considerable amount of time in classrooms. Due to the complexity of educational buildings, research performed has been heterogeneous and standards for thermal comfort are based o...

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Veröffentlicht in:	Sustainability 2021-09, Vol.13 (18), p.10315
Hauptverfasser:	Lamberti, Giulia, Salvadori, Giacomo, Leccese, Francesco, Fantozzi, Fabio, Bluyssen, Philomena M.
Format:	Artikel
Sprache:	eng
Schlagworte:	Adults Building envelopes Buildings Classrooms Dose-response effects Education Energy consumption Energy efficiency Environmental education Environmental factors Humidity HVAC equipment Indoor air quality Indoor environments Keywords Learning Metabolism Perception Physiology Preferences Questionnaires Students Sustainability Temperature Thermal environments Visual effects
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creator	Lamberti, Giulia Salvadori, Giacomo Leccese, Francesco Fantozzi, Fabio Bluyssen, Philomena M.
description	The thermal environment in educational buildings is crucial to improve students’ health and productivity, as they spend a considerable amount of time in classrooms. Due to the complexity of educational buildings, research performed has been heterogeneous and standards for thermal comfort are based on office studies with adults. Moreover, they rely on single dose-response models that do not account for interactions with other environmental factors, or students’ individual preferences and needs. A literature study was performed on thermal comfort in educational buildings comprising of 143 field studies, to identify all possible confounding parameters involved in thermal perception. Educational stage, climate zone, model adopted to investigate comfort, and operation mode were then selected as confounding parameters and discussed to delineate the priorities for future research. Results showed that children often present with different thermal sensations than adults, which should be considered in the design of energy-efficient and comfortable educational environments. Furthermore, the use of different models to analyse comfort can influence field studies’ outcomes and should be carefully investigated. It is concluded that future studies should focus on a more rational evaluation of thermal comfort, also considering the effect that local discomfort can have on the perception of an environment. Moreover, it is important to carefully assess possible relationships between HVAC systems, building envelope, and thermal comfort, including their effect on energy consumption. Since several studies showed that the perception of the environment does not concern thermal comfort only, but it involves the aspects of indoor air, acoustic, and visual quality, their effect on the health and performance of the students should be assessed. This paper provides a way forward for researchers, which should aim to have an integrated approach through considering the positive effects of indoor exposure while considering possible individual differences.
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subjects	Adults Building envelopes Buildings Classrooms Dose-response effects Education Energy consumption Energy efficiency Environmental education Environmental factors Humidity HVAC equipment Indoor air quality Indoor environments Keywords Learning Metabolism Perception Physiology Preferences Questionnaires Students Sustainability Temperature Thermal environments Visual effects
title	Advancement on Thermal Comfort in Educational Buildings: Current Issues and Way Forward
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