Investigation of transient and heterogeneous micro-climate around a human body in an enclosed personalized work environment

Chong Wang, Sung Jun Yoo, Shin ichi Tanabe, Kazuhide Ito*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

2 Citations (Scopus)

Abstract

Heterogeneous distribution of indoor environmental quality is known to have a great impact on human health, comfort, and productivity. A personalized work environment, that creates a localized and independent environment with capsules or partitions, is being developed worldwide to provide workers with a space that enables undisturbed concentration on studying and working. However, the minimized interior space of a personalized work environment can immediately cause adverse health impacts for occupant if the air quality and thermal environment in the personalized work environment is not controlled appropriately. Particularly, constant breathing can sharply increase the CO2 concentrations in an interior space with an insufficient ventilation rate. In order to design a healthy and comfortable indoor environment, especially in a personalized work environment, it is important to predict precisely and comprehensively the transient and heterogeneous structure of the indoor environment formed around a human body. With this background, we have developed an in silico human model that integrates a computational human model (virtual manikin combined with thermoregulation models) and respiratory model (virtual airway) for estimating indoor environmental quality, targeting the microclimate around a human body and breathing zone with high accuracy. In this study, we report the applicability of a comprehensive in silico human model to estimate the environmental quality in a personalized work environment. A coupled analysis of heat and contaminant transfer with computational fluid dynamics was conducted targeting the space around the in silico human model installed in a virtual personalized work environment. The informative data including human thermal comfort and breathing air quality were obtained, potentially forming the basis for the development of a digital twin of the personalized work environment and contributing to the design of a healthy, comfortable, and productive personalized work environment.

Original languageEnglish
Pages (from-to)423-431
Number of pages9
JournalEnergy and Built Environment
Volume1
Issue number4
DOIs
Publication statusPublished - 2020 Oct

Keywords

  • Computational fluid dynamics
  • Digital twin
  • in silico human model
  • Indoor environment
  • Microclimate
  • Personalized work environment

ASJC Scopus subject areas

  • Building and Construction
  • Civil and Structural Engineering
  • Renewable Energy, Sustainability and the Environment
  • Transportation

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