A hybrid approach based on the HFACS-FBN for identifying and analysing human factors for fire and explosion accidents in the laboratory

Fire and explosion accidents are the most important crises in the lab at colleges and universities, and human factors (HFs) are widely regarded as the highly contributing factors to the occurrence of lab accidents. Therefore, it is necessary to use efficient and reliable methods to identify and monitor the key HFs that cause and affect lab fire and explosion accidents. In this paper, to identify the most critical and highly contributing HFs exposed in the lab fire and explosion accidents, a hybrid method integrating Human Factors Analysis and Classification System (HFACS), Fuzzy set theory (FST), and Bayesian network (BN) is applied, which can compensate for the static nature of conventional methods in HFs analysis and its inability to deal with uncertainty. The hybrid model was tested on 39 lab fire and explosion accidents from 2008 to 2020 in China and the United States, and the sensitivity analysis was also conducted to recognize the top 10 most critical root events associated with HFs leading to lab fire and explosion accidents. The results demonstrated that organizational influences are the leading contributors to the top 10 most highly contributing root events for lab accidents.

Automated summary

In this study, a hybrid method integrating Human Factors Analysis and Classification System (HFACS), Fuzzy set theory (FST), and Bayesian network (BN) was applied to identify the most critical and highly contributing human factors in lab fire and explosion accidents. The results showed that organizational influences played a significant role in the top 10 most critical root events associated with human factors leading to lab accidents.