[논문]수소충전소 폭발위험장소 완화를 위한 확산차단벽 최적화 설계

안승효; 오세현; 김은희; 이준서; 마병철

doi:10.7316/jhne.2023.34.6.734

수소충전소 폭발위험장소 완화를 위한 확산차단벽 최적화 설계
Optimization of Designing Barrier to Mitigate Hazardous Area in Hydrogen Refueling Stations 원문보기

한국수소 및 신에너지학회 논문집 = Transactions of the Korean Hydrogen and New Energy Society, v.34 no.6, 2023년, pp.734 - 740

안승효 (전남대학교 화학공학과) , 오세현 (전남대학교 화학공학과) , 김은희 (전남대학교 화학공학과) , 이준서 (전남대학교 공정혁신 시뮬레이션센터) , 마병철 (전남대학교 화학공학과)

Abstract ▼ AI-Helper

Hydrogen emphasis on safety management due to its high potential for accidents from wide explosive limits and low ignition energy. To prevent accidents, appropriate explosion-proof electrical equipment with installed to safe management of ignition sources. However, designing all facilities with explosion-proof structures can significantly increase costs and impose limitations. In this study, we optimize the barrier to effectively control the initial momentum in case of hydrogen release and form the control room as a non-hazardous area. We employed response surface method (RSM), the barrier distance, width and height of the barrier were set as variables. The Box-Behnken design method the selection of 15 cases, and FLACS assessed the presence of hazardous area. Analysis of variance (ANOVA) analysis resulting in an optimized barrier area. Through this methodology, the workplace can optimize the barrier according to the actual workplace conditions and classify reasonable hazardous area, which is believed to secure safety in hydrogen facilities and minimize economic burden.

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참고문헌 (18)

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수소충전소 폭발위험장소 완화를 위한 확산차단벽 최적화 설계
Optimization of Designing Barrier to Mitigate Hazardous Area in Hydrogen Refueling Stations 원문보기

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수소충전소 폭발위험장소 완화를 위한 확산차단벽 최적화 설계 Optimization of Designing Barrier to Mitigate Hazardous Area in Hydrogen Refueling Stations 원문보기

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수소충전소 폭발위험장소 완화를 위한 확산차단벽 최적화 설계
Optimization of Designing Barrier to Mitigate Hazardous Area in Hydrogen Refueling Stations 원문보기