人体死后在不同后排座椅配置下的生物力学反应和损伤评估。

Q2 Medicine Stapp car crash journal Pub Date : 2020-11-01 DOI:10.4271/2020-22-0005
Yun-Seok Kang, Jason Stammen, Rakshit Ramachandra, Amanda M Agnew, Alena Hagedorn, Colton Thomas, Hyun Jung Kwon, Kevin Moorhouse, John H Bolte
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引用次数: 8

摘要

本研究的目的是在56公里/小时的滑橇试验中,模拟车辆正面撞击时朝后的乘员在两种不同的椅背倾斜角度下的死后人体(PMHS)产生生物力学走廊。PMHS被放置在一个生产座椅,其中包括一个集成的安全带。为了实现可重复的配置,座椅在后方向上使用加强框架进行刚性化,从而允许椅背倾斜角度和头部约束位置的可调性。该框架包含仪器测量乘员负载应用于头部约束和座椅靠背。为了测量PMHS的运动学,在头部、脊柱、骨盆和下肢安装加速度计和角速率传感器。应变计附着在肋骨的前后侧面,以及股骨和胫骨的中轴,以确定骨折时间。在胸骨中部安装胸带以量化胸部变形。为每个倾斜角度生成每个身体和座位位置的生物力学走廊,为定量评估ATDs和HBMs的生物保真度提供数据。损伤包括上肢损伤、肋骨骨折、骨盆骨折和下肢损伤。45度俯卧的病例比25度俯卧的病例有更多的受伤记录。这些伤害很可能是由于过度加速和相应的PMHS运动学。本研究提供的生物力学走廊和损伤信息可以指导高速正面碰撞中刚性、后仰座椅配置的HBMs和atd的设计。
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Biomechanical Responses and Injury Assessment of Post Mortem Human Subjects in Various Rear-facing Seating Configurations.

The objective of this study was to generate biomechanical corridors from post-mortem human subjects (PMHS) in two different seatback recline angles in 56 km/h sled tests simulating a rear-facing occupant during a frontal vehicle impact. PMHS were placed in a production seat which included an integrated seat belt. To achieve a repeatable configuration, the seat was rigidized in the rearward direction using a reinforcing frame that allowed for adjustability in both seatback recline angle and head restraint position. The frame contained instrumentation to measure occupant loads applied to the head restraint and seatback. To measure PMHS kinematics, the head, spine, pelvis, and lower extremities were instrumented with accelerometers and angular rate sensors. Strain gages were attached to anterior and posterior aspects of the ribs, as well as the mid-shaft of the femora and tibiae, to determine fracture timing. A chestband was installed at the mid sternum to quantify chest deformation. Biomechanical corridors for each body and seat location were generated for each recline angle to provide data for quantitatively evaluating the biofidelity of ATDs and HBMs. Injuries included upper extremity injuries, rib fractures, pelvis fractures, and lower extremity injuries. More injuries were documented in the 45-degree recline case than in the 25-degree recline case. These injuries are likely due to the excessive ramping up and corresponding kinematics of the PMHS. Biomechanical corridors and injury information presented in this study could guide the design of HBMs and ATDs in rigid, reclined, rear-facing seating configurations during a high-speed frontal impact.

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来源期刊
Stapp car crash journal
Stapp car crash journal Medicine-Medicine (all)
CiteScore
3.20
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期刊最新文献
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