使用真实的车辆和详细的人体模型了解汽车与行人碰撞过程中的头部伤害风险。

Q2 Medicine Stapp car crash journal Pub Date : 2022-11-01 DOI:10.4271/2022-22-0006
Kalish Gunasekaran, Sakib Ul Islam, Haojie Mao
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引用次数: 0

摘要

创伤性脑损伤(TBI)是道路交通事故中死亡和长期残疾的主要原因。研究人员研究了车辆前部形状和行人体型对行人头部受伤风险的影响。另一方面,涉及不同体型的不同人群的车辆前部形状参数与行人TBI风险之间的关系尚待研究。因此,本研究的目的是全面研究车辆前部形状参数和从第95百分位男性(AM95)到6岁(YO)儿童的各种行人身体对头部动态反应和初次(车辆)碰撞期间TBI风险的影响。在三种不同的碰撞速度(30、40和50 km/h)下,使用三种不同车型(亚紧凑型乘用车、中型轿车和运动型多用途车(SUV))和四种不同的THUMS行人有限元(FE)模型(AM50、AM95、AF05和6YO),共重建了36起车-人碰撞(CPC)。除了头部线性和旋转运动学外,我们还评估了颅骨应力和大脑应变。我们的研究结果表明,车辆形状参数,特别是发动机罩前缘高度(BLEH),当除以人体重心高度时,与头部运动学呈正相关。使用真实的车辆结构和详细的人体模型进行的这项研究的数据表明,较小的BLEH/CG比率降低了汽车中心到中站步行行人碰撞的头部损伤标准(HIC)和脑损伤标准(BrIC)值,但低到中等的R平方值在0.2到0.5之间。较小的BLEH/CG降低了所有冲击速度下的头部横向弯曲速度,R平方值为0.57至0.63,并降低了50km/h情况下的HIC,R平方为0.62。未来,具有逼真汽车结构和详细人体模型的模拟将进一步用于模拟不同位置和不同体型/姿势的碰撞。
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Understanding Head Injury Risks During Car-to-Pedestrian Collisions Using Realistic Vehicle and Detailed Human Body Models.

Traumatic brain injury (TBI) is the leading cause of death and long-term disability in road traffic accidents (RTAs). Researchers have examined the effect of vehicle front shape and pedestrian body size on the risk of pedestrian head injury. On the other hand, the relationship between vehicle front shape parameters and pedestrian TBI risks involving a diverse population with varying body sizes has yet to be investigated. Thus, the purpose of this study was to comprehensively study the effect of vehicle front shape parameters and various pedestrian bodies ranging from 95th percentile male (AM95) to 6 years old (YO) child on the dynamic response of the head and the risk of TBIs during primary (vehicle) impact. At three different collision speeds (30, 40, and 50 km/h), a total of 36 car-to-pedestrian collisions (CPCs) were reconstructed using three different vehicle types (Subcompact passenger sedan, mid-sedan, and sports utility vehicle (SUV)) and four distinct THUMS pedestrian finite element (FE) models (AM50, AM95, AF05, and 6YO). We assessed skull stress and brain strains besides head linear and rotational kinematics. Our findings indicate that vehicle shape parameters especially bonnet leading edge height (BLEH), when being divided by the height of the Center of Gravity of the human body, correlated positively to head kinematics. The data from this study using realistic vehicle structures and detailed human body models showed that smaller BLEH/CG ratios reduced head injury criteria (HIC) and brain injury criteria (BrIC) values for the car center to mid-stance walking pedestrian impacts but with low-to-moderate R squared values between 0.2 to 0.5. Smaller BLEH/CG reduced head lateral bending velocities with R squared values of 0.57 to 0.63 for all impact velocities, and reduced HIC with R squared value of 0.62 for 50 km/h cases. In the future, simulations with realistic car structures and detailed human body models will be further used to simulate impacts at different locations and with various body shapes/postures.

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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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