Article: Occupant behaviour simulation using DADS and design of seat belt for occupant safety Journal: International Journal of Vehicle Design (IJVD) 1999 Vol.21 No.4/5 pp.402 - 423 Abstract: The occupant and seat belt restraint system were modelled mathematically using multi-body dynamics. The interactions between belt and dummy such as belt slip and energy dissipation were considered in three dimensional mathematical models of 50th percentile Hybrid111 dummy and 3-point seat belt system. In this study, the commercial software DADS (Dynamic Analysis and Design System) was used for dynamic simulation of occupant impact response in sled tests and barrier crash tests. Results from the sled test simulations were compared with those available in the literature in order to validate the mathematical model for occupant behaviour analysis. In order to simulate the occupant behaviour in barrier crash tests, simple models of car interior system and energy-absorbing steering system were also established. And the effect of seat belt systems on occupant protection was evaluated through the occupant behaviour simulation in barrier crash tests. Several factors, which were thought to be closely related to the performance of seat belt systems for occupant protection, were considered. Orthogonal array table was used for a systematic procedure to lay out the factors and conditions in the barrier crash test simulation. The various injury values were investigated in response to the change of seat belt variables such as shoulder belt slackness, lap belt slackness, belt stiffness, retractor performance, and outer D-ring position. The contribution of seat belt variables to occupant protection was analysed by ANOVA (analysis of variance). From this analysis, it was found that seat belt slackness had the most dominant effect on occupant injuries, and seat belt pretension can increase the occupant safety. Through the systematic applications of orthogonal array table and ANOVA to seat belt design, the modified combination of seat belt variables was obtained, and the initial occupant injury values could be decreased. Inderscience Publishers - linking academia, business and industry through research

Title: Occupant behaviour simulation using DADS and design of seat belt for occupant safety

Authors: Tae Seong Jang, Jung Ju Lee, Yong San Yoon

Addresses: Department of Mechanical Engineering, Korea Advanced Institute of Science and Technology, 373- 1, Kusong-dong, Yusong-gu, Taejon 305-701, Korea. ' Department of Mechanical Engineering, Korea Advanced Institute of Science and Technology, 373- 1, Kusong-dong, Yusong-gu, Taejon 305-701, Korea. ' Department of Mechanical Engineering, Korea Advanced Institute of Science and Technology, 373- 1, Kusong-dong, Yusong-gu, Taejon 305-701, Korea

Abstract: The occupant and seat belt restraint system were modelled mathematically using multi-body dynamics. The interactions between belt and dummy such as belt slip and energy dissipation were considered in three dimensional mathematical models of 50th percentile Hybrid111 dummy and 3-point seat belt system. In this study, the commercial software DADS (Dynamic Analysis and Design System) was used for dynamic simulation of occupant impact response in sled tests and barrier crash tests. Results from the sled test simulations were compared with those available in the literature in order to validate the mathematical model for occupant behaviour analysis. In order to simulate the occupant behaviour in barrier crash tests, simple models of car interior system and energy-absorbing steering system were also established. And the effect of seat belt systems on occupant protection was evaluated through the occupant behaviour simulation in barrier crash tests. Several factors, which were thought to be closely related to the performance of seat belt systems for occupant protection, were considered. Orthogonal array table was used for a systematic procedure to lay out the factors and conditions in the barrier crash test simulation. The various injury values were investigated in response to the change of seat belt variables such as shoulder belt slackness, lap belt slackness, belt stiffness, retractor performance, and outer D-ring position. The contribution of seat belt variables to occupant protection was analysed by ANOVA (analysis of variance). From this analysis, it was found that seat belt slackness had the most dominant effect on occupant injuries, and seat belt pretension can increase the occupant safety. Through the systematic applications of orthogonal array table and ANOVA to seat belt design, the modified combination of seat belt variables was obtained, and the initial occupant injury values could be decreased.

Keywords: ANOVA; analysis of variance; multi-body dynamics; occupant behaviour simulation; orthogonal array; seat belt design; mathematical modelling; belt slip; energy dissipation; sled tests; barrier crash tests; occupant impact response; vehicle occupant protection; occupant safety; vehicle safety; seat belt slackness; seat belt pretension; vehicle seat belts.

DOI: 10.1504/IJVD.1999.005593

International Journal of Vehicle Design, 1999 Vol.21 No.4/5, pp.402 - 423

Published online: 21 Oct 2004 *

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Title: Occupant behaviour simulation using DADS and design of seat belt for occupant safety

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