Early Intervention Mechanism for Preventing Electrical Shocks During Construction Projects: Portable Electrical Equipment

To prevent electrical shock accidents in construction sites, the present researchers used portable electrical equipment as an example to plan a preconstruction early intervention mechanism that can be used to conduct various inspections of portable electrical devices. This study used narrative text analysis for data collection and compilation. The researchers analyzed 41 real electrocution death cases involving portable electric equipment as the electrocution medium in the Taiwanese construction industry and identified hazard factors that cause electrocution from the case summaries. Then, the IDEF3 was used to integrate and construct a model for the portable electrical equipment inspection flowchart of the early intervention mechanism as a safety inspection system to prevent electrocution in construction engineering units. This study revealed hazard factors and management omissions related to electrocutions caused by portable electrical equipment. To protect workers and strengthen the safety of the construction site, this study proposed of an electric shock prevention early intervention mechanism for portable electric equipment in construction projects. Various inspections should be conducted before equipment is brought on site for construction operations to ensure the safety of electrical equipment and reduce electrocution risks. This study also established a visualization mechanism for the visual qualification label of portable electrical equipment. This mechanism is conducive to strengthening safety management.

[1]  Bong-Huan Jun,et al.  Study on Identification Procedure for Unidentified Underwater Targets Using Small ROV Based on IDEF Method , 2019 .

[2]  Alistair G.F. Gibb,et al.  Accident precursors and near misses on construction sites: An investigative tool to derive information from accident databases , 2010 .

[3]  P. K. Marhavilas,et al.  Risk analysis and assessment in the worksites using the fuzzy-analytical hierarchy process and a quantitative technique – A case study for the Greek construction sector , 2019, Safety Science.

[4]  Raja R. A. Issa,et al.  Safety implementation framework for Pakistani construction industry , 2016 .

[5]  Weisheng Lu,et al.  Towards the “third wave”: An SCO-enabled occupational health and safety management system for construction , 2019, Safety Science.

[6]  P. Davis,et al.  The psychological contract: A missing link between safety climate and safety behaviour on construction sites , 2019, Safety Science.

[7]  Gabor Mezei,et al.  Injuries among electric power industry workers, 1995-2013. , 2017, Journal of safety research.

[8]  Chimay J. Anumba,et al.  Cyber-physical systems for temporary structure monitoring , 2016 .

[9]  Weisheng Lu,et al.  Auto ID Bridging the physical and the digital on construction projects , 2014 .

[10]  M. Suárez-Cebador,et al.  Quality evaluation of official accident reports conducted by Labour Authorities in Andalusia (Spain). , 2018, Work.

[11]  An analysis of fatal and non-fatal injuries and injury severity factors among electric power industry workers. , 2016, American journal of industrial medicine.

[12]  Matthew R. Hallowell,et al.  Construction-Safety Best Practices and Relationships to Safety Performance , 2013 .

[13]  A. Colantonio,et al.  Construction fatality due to electrical contact in Ontario, Canada, 1997-2007. , 2016, Work.