Passenger car-body crashworthiness based on the force transmission path of frontal impact

doi:10.3969/j.issn.1674-8484.2011.04.005

Journal of Automotive Safety and Energy ›› 2011, Vol. 2 ›› Issue (4): 317-322.DOI: 10.3969/j.issn.1674-8484.2011.04.005

• Automotive Safety • Previous Articles Next Articles

Passenger car-body crashworthiness based on the force transmission path of frontal impact

LIU Zhao, ZHU Ping, YU Ming, LU Jiahai

Shanghai Jiao Tong University, Shanghai Key Laboratory of Digital Auto Body Engineering, Shanghai 200240, China

Received:2011-10-10 Online:2011-12-26 Published:2011-12-26
Contact: 朱平，教授。E-mail ：pzhu@sjtu.edu.cn E-mail:kakalz@163.com
About author:刘钊（1988—），男（汉），山东，硕士研究生。E-mail ：kakalz@163.com

Abstract

Abstract: Structural crashworthiness was investigated for a passenger car-body to improve vehicle safety. The
auto-body structure was analyzed based on the force transmission path of frontal impact, with the auto-body
finite element model being built using the HyperWorks program and some key parts being improved including
the front side rail, front cross rail and crash box for a passenger car-body structure. Two front impacts were
numerically simulated using LS-DYNA program according to the crash regulation by China New Car Assessment
Program, CNCAP, in which one is full front impact with rigid barrier (RGB) and the other is 40% offset front
impact with offset deformable barrier (ODB). The results show that owing to car-body structure improvements,
the intrusion capacities obviously decrease with accelerations of both the left and right “B” pillars decreasing in
the two front impacts, and with increased impact energy absorption of 9.8 kJ for the 100% RGB and 3.3 kJ for
the 40% ODB.

Key words: vehicle safety, structural crashworthiness, force transmission path, passenger car-body, finite element method (FEM), offset deformable barrier (ODB)

CLC Number:

U 491.6

LIU Zhao, ZHU Ping, YU Ming, LU Jiahai. Passenger car-body crashworthiness based on the force transmission path of frontal impact[J]. Journal of Automotive Safety and Energy, 2011, 2(4): 317-322.

[1]	BIAN Jiang, WANG Xiaoying, GUI Liangjin, FAN Zijie. Experiments and simulations of bimetal drum brakes at high temperature conditions [J]. Journal of Automotive Safety and Energy, 2021, 12(2): 173-179.
[2]	LI Wenli, ZHANG Yousong, HAN Di, QIAN Hong, SHI Xiaohui. Vehicle autonomous collision avoidance decision control model based on deep reinforcement learning [J]. Journal of Automotive Safety and Energy, 2021, 12(2): 201-209.
[3]	LI Xueyun, ZHANG Ju. Design of AFS variable steering ratio considering road adhesion coefficient and vehicle speed [J]. Journal of Automotive Safety and Energy, 2020, 11(3): 329-336.
[4]	HUANG Jie, LIU Xi, HU Yuanzhi，et al. Protection effect on rear seat female occupant by airbag-belt [J]. Journal Of Automotive Safety And Energy, 2019, 10(1): 74-81.
[5]	CHEN Changliang, ZHOU Chi, WANG Qi, et al. Loaded tooth contact analysis of spur gear considering edge relaxation effect [J]. Journal Of Automotive Safety And Energy, 2018, 9(4): 370-378.
[6]	XIAO Huipeng, CHEN Tao, DUAN Libin, et al. Vehicle tire finite-element modelling and simulation based on parameter reverse by computer [J]. Journal Of Automotive Safety And Energy, 2018, 9(3): 258-264.
[7]	QU Xian, YU Feng, Zhao Yue. Identification of dangerous state of fatigue driving based on entropy weight grey incidence and D-S theory evidence [J]. Journal Of Automotive Safety And Energy, 2018, 9(2): 164-170.
[8]	CAO Libo, CHEN Long, WU Jun, WU Junting, SHI Xianyao. Small test device of inter-collision sled without fixed barrier and its absorption characteristics [J]. Journal Of Automotive Safety And Energy, 2018, 9(01): 48-56.
[9]	DU Feng, GUAN Zhiwei, GAO Bolin, DAI Jingang, WEI Lang. Vehicle stability control based on synergistic effect of active steering and differential braking [J]. Journal Of Automotive Safety And Energy, 2018, 9(01): 65-73.
[10]	ZHOU Qing, JI Peijun, HUANG Yi, et al. Challenges and opportunities of smart occupant protection against motor vehicle collision accidents in future traffic environment [J]. Journal Of Automotive Safety And Energy, 2017, 08(04): 333-350.
[11]	HAN Yong, HE Wei, LI Quan, et al. Analysis of two-wheelers kinematics before/during/after vehicle collisions based on video records [J]. Journal Of Automotive Safety And Energy, 2017, 08(04): 381-387.
[12]	HU Yuanzhi,HU Yuanyuan,JIANG Chengyue, LIU Xi,LIAO Gaojian. Neck injury comparison between BioRID II and THUMS model in whiplash test [J]. Journal Of Automotive Safety And Energy, 2017, 08(03): 239-245.
[13]	HU Yuanzhi, LV Zhangjie, LIU Xi. Algorithm and simulation verification of longitudinal collision avoidance for autonomous emergency break (AEB) system based on PreScan [J]. Journal Of Automotive Safety And Energy, 2017, 08(02): 136-142.
[14]	WANG Xiaoyuan, LIU Yaqi， ZHANG Jinglei. Dynamic identification method of driver and vehicle features based on travel time [J]. Journal Of Automotive Safety And Energy, 2017, 08(01): 38-45.
[15]	NIE Bingbing, ZHOU Qing, XIA Yong. Multi-phase impact pulse and structure design for pedestrian headform impact on vehicle hood [J]. Journal Of Automotive Safety And Energy, 2017, 08(01): 65-71.

Passenger car-body crashworthiness based on the force transmission path of frontal impact

PDF

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments

Journal information

Online journal

Author center

Review center

Contact us