Journal of The Korea Institute of Healthcare Architecture (의료ㆍ복지 건축 : 한국의료복지건축학회 논문집)

Korea Institute of Healthcare Architecture (한국의료복지건축학회)
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Review of Environmental Characteristics and Building Finishes Controlling the Spread of SARS-CoV-2 - Focused on overseas literature related to antiviral experiments

코로나 바이러스 확산억제를 위한 환경 및 건축마감재료 고찰 - 항바이러스 재료 관련 해외 문헌을 중심으로

  • 박용현 (건축학과, 아주대학교) ;
  • 이현진 (의료공간디자인학과, 건양대학교) ;
  • 권순정 (건축학과, 아주대학교)
  • Received : 2023.10.17
  • Accepted : 2023.11.22
  • Published : 2023.12.15
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Abstract

Purpose: Currently, research on environmental conditions and finishing materials for medical facilities with proven antiviral performance is poor in Korea. Through this study, we have explored environmental characteristics and finishing materials that can be used to control cross-infection when constructing medical facilities. Methods: Experiments in overseas papers related to antiviral effects of environmental conditions, spatial compartments, and interior finishes have been analyzed. Results: The higher the temperature, the higher the humidity, and the higher the illuminance of sunlight, the lower the viability of the corona-virus. The proliferation of viruses was suppressed on the surface of the copper alloy. Materials such as brushed steel are the ones that maintain the strongest viability. Among the characteristics of the surface, survival and propagation power differ depending on whether it is porous or hydrophilic. In the case of infection ward actually operated in Italy, the presence of airborne viruses in contaminated and non-contaminated spaces differed significantly. Corona-virus has been identified in reachable parts such as door handles and medical shelves in quasi-contaminated spaces, which are spaces between contaminated and non-contaminated spaces, but the corona-virus has not been identified in cases of out-of-touch walls. Implications: It is necessary to evaluate the performance by testing the construction finishing materials of infection control facilities according to domestic conditions.

Keywords

Acknowledgement

본 연구는 보건복지부의 재원으로 감염병의료안전강화 기술개발사업 지원에 의하여 이루어진 것임(과제고유번호 : HG22C0017)

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