Impact Location Dependence of Behind Armor Blunt Trauma Injury Assessed Using a Human Body Finite Element Model.

IF 1.7 4区 医学 Q4 BIOPHYSICS
Michael C Bustamante, Duane S Cronin
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引用次数: 0

Abstract

Behind armor blunt trauma (BABT), resulting from dynamic deformation of protective ballistic armor into the thorax, is currently assessed assuming a constant threshold of maximum backface deformation (BFDs) (44 mm). Although assessed for multiple impacts on the same armor, testing is focused on armor performance (shot-to-edge and shot-to-shot) without consideration of the underlying location on the thorax. Previous studies identified the importance of impacts on organs of animal surrogates wearing soft armor. However, the effect of impact location was not quantified outside the threshold of 44 mm. In the present study, a validated biofidelic advanced human thorax model (50th percentile male) was utilized to assess the BABT outcome from varying impact location. The thorax model was dynamically loaded using a method developed for recreating BABT impacts, and BABT events within the range of real-world impact severities and locations were simulated. It was found that thorax injury depended on impact location for the same BFDs. Generally, impacts over high compliance locations (anterolateral rib cage) yielded increased thoracic compression and loading on the lungs leading to pulmonary lung contusion (PLC). Impacts at low compliance locations (top of sternum) yielded hard tissue fractures. Injuries to the sternum, ribs, and lungs were predicted at BFDs lower than 44 mm for low compliance locations. Location-based injury risk curves demonstrated greater accuracy in injury prediction. This study quantifies the importance of impact location on BABT injury severity and demonstrates the need for consideration of location in future armor design and assessment.

使用人体有限元模型评估装甲后钝器创伤的撞击位置依赖性。
装甲后钝器创伤(BABT)是防护性弹道装甲向胸部的动态变形造成的,目前的评估假定最大后表面变形(BFDs)的阈值不变(44 毫米)。虽然对同一装甲的多次撞击进行了评估,但测试的重点是装甲的性能(射击到边缘和射击到射击),而没有考虑胸部的基本位置。先前的研究确定了撞击对穿着软装甲的动物代理器官的重要性。然而,在 44 毫米的临界值之外,撞击位置的影响并未得到量化。在本研究中,使用了经过验证的生物保真高级人体胸部模型(第 50 百分位男性)来评估不同撞击位置造成的 BABT 结果。该胸腔模型使用一种为重现 BABT 撞击而开发的方法进行动态加载,并模拟了真实世界撞击严重程度和位置范围内的 BABT 事件。结果发现,对于相同的 BFD,胸部伤害取决于撞击位置。一般来说,撞击高顺应性位置(肋骨前外侧)会增加胸部压缩和肺部负荷,导致肺挫伤(PLC)。低顺应性位置(胸骨顶部)的撞击导致硬组织骨折。在低顺应性位置,胸骨、肋骨和肺部受伤的预测BFD低于44毫米。基于位置的伤害风险曲线显示出更高的伤害预测准确性。这项研究量化了撞击位置对 BABT 损伤严重程度的重要性,并表明在未来的装甲设计和评估中需要考虑撞击位置。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.40
自引率
5.90%
发文量
169
审稿时长
4-8 weeks
期刊介绍: Artificial Organs and Prostheses; Bioinstrumentation and Measurements; Bioheat Transfer; Biomaterials; Biomechanics; Bioprocess Engineering; Cellular Mechanics; Design and Control of Biological Systems; Physiological Systems.
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