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本文引用的文献

1
Thoracic injury metrics with side air bag: stationary and dynamic occupants.胸部损伤指标与侧面安全气囊:静止和动态乘客。
Traffic Inj Prev. 2010 Aug;11(4):433-42. doi: 10.1080/15389581003753017.
2
Splenic trauma as an adverse effect of torso-protecting side airbags: biomechanical and case evidence.脾脏创伤作为躯干保护侧气囊的一种不良反应:生物力学及病例证据
Ann Adv Automot Med. 2009 Oct;53:13-24.
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The effect of angle on the chest injury outcome in side loading.
Stapp Car Crash J. 2009 Nov;53:403-19. doi: 10.4271/2009-22-0014.
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Characterization of torso side airbag aggressivity - biomed 2009.躯干侧面安全气囊攻击性的特征描述——生物医学2009年
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Rib cage strain pattern as a function of chest loading configuration.肋骨应变模式作为胸部负荷配置的函数。
Stapp Car Crash J. 2008 Nov;52:205-31. doi: 10.4271/2008-22-0009.
6
Deflections from two types of human surrogates in oblique side impacts.两种人体代用物在斜侧碰撞中的偏移
Ann Adv Automot Med. 2008 Oct;52:301-13.
7
Chest deflections and injuries in oblique lateral impacts.斜侧撞击中的胸部变形与损伤
Traffic Inj Prev. 2008 Jun;9(2):162-7. doi: 10.1080/15389580701775942.
8
Injury patterns in side pole crashes.侧面柱碰撞中的损伤模式。
Annu Proc Assoc Adv Automot Med. 2007;51:419-33.
9
Oblique and lateral impact response of the PMHS thorax.人体志愿者胸部的斜向和侧向撞击响应
Stapp Car Crash J. 2006 Nov;50:147-67. doi: 10.4271/2006-22-0007.
10
Development of Side Impact Thoracic Injury Criteria and Their Application to the Modified ES-2 Dummy with Rib Extensions (ES-2re).侧面碰撞胸部损伤标准的制定及其在带肋骨延伸装置的改进型ES-2假人(ES-2re)上的应用。
Stapp Car Crash J. 2003 Oct;47:189-210. doi: 10.4271/2003-22-0010.

躯干侧面安全气囊后外侧加载的生物力学及损伤反应

Biomechanical and injury response to posterolateral loading from torso side airbags.

作者信息

Hallman Jason J, Yoganandan Narayan, Pintar Frank A

机构信息

Department of Biomedical Engineering, Marquette University 9200 W. Wisconsin Avenue, Milwaukee, WI 53226, USA.

出版信息

Stapp Car Crash J. 2010 Nov;54:227-57. doi: 10.4271/2010-22-0012.

DOI:10.4271/2010-22-0012
PMID:21512911
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3820120/
Abstract

This study characterized thoracoabdominal response to posterolateral loading from a seat-mounted side airbag. Seven unembalmed post-mortem human subjects were exposed to ten airbag deployments. Subjects were positioned such that the deploying airbag first contacted the posterolateral thorax between T6 and L1 while stationary (n = 3 x 2 aspects) or while subjected to left lateral sled impact at ΔV = 6.7 m/s (n = 4). Chestband contours were analyzed to quantify deformation direction in the thoracic x-y plane (zero degrees indicating anterior and 180° indicating posterior), magnitude, rate, and viscous response. Skeletal injuries were consistent with posterolateral contact; visceral injuries consisted of renal (n = 1) or splenic (n = 3) lacerations. Deformation direction was transient during sled impact, progressing from 122 ± 5° at deformation onset to 90° following maximum deflection. Angles from stationary subjects progressed from 141 ± 9° to 120°. Peak normalized deflections, peak rates, and VCmax ranges were 0.075 - 0.171, 3.7 - 12.7 m/s, and 0.3 - 0.6 m/s with stationary airbag, respectively; ranges were 0.167 - 0.297, 7.4 - 18.3 m/s, and 0.7 - 3.0 m/s with airbag sled impact, respectively. Peak deflections were measured at angles between 99° - 135° and 98° - 125° for stationary and dynamic conditions, respectively. Because of deflection angle transience and localized injury response, both posterolateral and lateral injury metrics may be required for this boundary condition. Contrasted with flat rigid or anterolateral loading, biomechanical response to side airbag interaction may be augmented by peak normalized deflection or VCmax at 130°.

摘要

本研究描述了坐姿侧面安全气囊后外侧加载时胸腹的反应。七具未防腐处理的尸体被暴露于十次安全气囊展开试验中。受试者的姿势使得展开的安全气囊首先在静止状态下(n = 3×2个方位)或在以ΔV = 6.7 m/s的速度进行左侧滑板撞击时(n = 4)接触T6和L1之间的后外侧胸部。分析胸带轮廓以量化胸部x-y平面内的变形方向(0度表示前方,180°表示后方)、大小、速率和粘性反应。骨骼损伤与后外侧接触一致;内脏损伤包括肾裂伤(n = 1)或脾裂伤(n = 3)。在滑板撞击过程中变形方向是短暂的,从变形开始时的122±5°发展到最大偏转后的90°。静止受试者的角度从141±9°发展到120°。静止安全气囊时的峰值归一化偏转、峰值速率和VCmax范围分别为0.075 - 0.171、3.7 - 12.7 m/s和0.3 - 0.6 m/s;安全气囊滑板撞击时的范围分别为0.167 - 0.297、7.4 - 18.3 m/s和0.7 - 3.0 m/s。静止和动态条件下的峰值偏转分别在99° - 135°和98° - 125°的角度处测量。由于偏转角的短暂性和局部损伤反应,对于这种边界条件可能需要后外侧和外侧损伤指标。与平坦刚性或前外侧加载相比,侧面安全气囊相互作用的生物力学反应可能在130°时通过峰值归一化偏转或VCmax而增强。

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