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Citation |
Hallowell MR, Alexander D, Gambatese JA. Constr. Manag. Econ. 2017; 35(1-2): 64-77. |
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Copyright |
(Copyright © 2017, Informa - Taylor and Francis Group) |
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DOI |
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PMID |
unavailable |
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Abstract |
Although the quantity and quality of safety risk data have improved in recent years, available data do not link directly to natural principles and are, therefore, limited in their application and scientific extension. The present study aims to test the hypothesis that the quantity and intensity of energy observable prior to an incident predicts the severity of the incident. The hypothesis is built upon the theory that energy is translated to an injury through uncontrolled release of the energy, transfer of the energy to the human body and the vulnerability of the body and associated protective equipment. To test the hypothesis, a multi-phase experiment was conducted. First, over 500 injury reports were gathered from national databases and private companies. For each report, the leading information describing the work operations and environment and the lagging information describing the injury were extracted, separated and isolated. Second, the magnitude of the energy was estimated using only leading information. Once energy magnitude was quantified, the distribution was compared across injury severity levels using analysis of variance tests. As hypothesized, energy magnitude is a strong predictor of injury severity. Although computationally intensive, energy intensity, defined as the magnitude of energy divided by the area of contact between an object and the human body, showed strong predictive validity. This research indicates that energy-based safety risk analysis has predictive validity and is a promising line of scientific inquiry with the potential to increase our understanding of the natural phenomena that contribute to injuries. Language: en |
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Keywords |
Accident; injury; occupational health and safety; risk analysis; safety |