The Risk of Skin Injury Caused by High-Rate Blunt Impacts to the Human Thorax

Less-lethal weapons (LLWs) based on blunt impactors are seeing increased usage during crowd-control scenarios, and it is crucial that these devices do not inflict significant injuries when used. The guidelines for safe impactor design can be informed by rigorous biomechanical testing and injury risk...

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Bibliographic Details
Published inHuman factors and mechanical engineering for defense and safety Vol. 6; no. 1
Main Authors Shedd, D. F., Berthelson, P. R., Rifkin, J. A., McMahon, J., Giudice, J. S., Forman, J. L., Panzer, M. B.
Format Journal Article
LanguageEnglish
Published Singapore Springer Nature Singapore 01.12.2022
Subjects
Engineering
Mechanical Engineering
Original Paper
Security Science and Technology
Structural Materials
Textile Engineering
Survival analysis
Injury risk function
Less-lethal weapons
Skin injury
Human surrogate
Online AccessGet full text
ISSN2509-8004
2367-2544
DOI10.1007/s41314-022-00046-z

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Summary:Less-lethal weapons (LLWs) based on blunt impactors are seeing increased usage during crowd-control scenarios, and it is crucial that these devices do not inflict significant injuries when used. The guidelines for safe impactor design can be informed by rigorous biomechanical testing and injury risk analysis. In this study, high-rate blunt impact testing was conducted on five 50th percentile male post-mortem human surrogates to assess the tolerance of human skin to blunt impacts in situ. Six sectional-density matched cylindrical and spherical impactors ranging from 13 to 25 mm (0.5–1.0 in.) in diameter and 2.9–11.6 g in mass were used to impact four regions within the thorax at velocities ranging from 60 to 167 m/s. The free-flight impactor velocity was measured using high-speed video, and autopsies were performed to determine whether skin injury was induced at each impact site. Additionally, B-mode ultrasound imaging was employed to determine the tissue thickness at each impact location prior to test. Then, injury risk functions (IRFs) were developed to predict skin injury risk as a function of various test parameters. Regional anatomical differences were determined to have the greatest influence on the injury risk beyond velocity. Similarly, spherical impactors produced greater skin injury risk than the cylindrical impactors, and larger diameter impactors produced greater risk than smaller diameter impactors. The IRFs developed in this study will help guide future LLW design toward improved human safety and lower the risk of significant injury. Finally, this study will also help develop computational human body models capable of simulating skin injury response.
ISSN:2509-8004
2367-2544
DOI:10.1007/s41314-022-00046-z