Development of Finite Element Model of Hybrid III 5th Percentile Female Dummy

Hybrid III 5% 성인 여성 더미의 유한요소 모델 개발

  • 이상일 (한양대학교 대학원 기계공학과) ;
  • ;
  • ;
  • 박경진 (한양대학교 기계공학과)
  • Received : 2009.04.07
  • Accepted : 2010.01.22
  • Published : 2010.07.01

Abstract

As the automobile industry is developing, the number of deaths and injuries has increased. To reduce the damages from automobile accidents, the government of each country proposes experimental conditions for reproducing the accident and establishes the vehicle safety regulations. Automotive manufacturers are trying to make safer vehicles by satisfying the requirements. The Hybrid III crash test dummy is a standard Anthropomorphic Test Device (ATD) used for measuring the occupant's injuries in a frontal impact test. Since a real crash test using a vehicle is fairly expensive, a computer simulation using the Finite Element Method (F.E.M.) is widely used. Therefore, a detailed and robust F.E. dummy model is needed to acquire more accurate occupant injury data and behavior during the crash test. To achieve this goal, a detailed F.E. model of the Hybrid III 5th percentile female dummy is constructed by using the reverse engineering technique in this research. A modeling process is proposed to construct the F.E. model. The proposed modeling process starts from disassembling the physical dummy. Computer Aided Design (CAD) geometry data is constructed by three-dimensional (3-D) scanning of the disassembled physical dummy model. Based on the geometry data, finite elements of each part are generated. After mesh generation, each part is assembled with other parts using the joints and rigid connection elements. The developed F.E. model of dummy is simulated based on the FMVSS 572 validation regulations. The results of simulation are compared with the results of physical tests.

Keywords

References

  1. National Highway Traffic Safety Administration, Federal Motor Vehicle Safety Standards; Occupant Crash Protection, Code of Federal Regulations under Title 208, Part 571.
  2. National Highway Traffic Safety Administration, Federal Motor Vehicle Safety Standards; Anthropomorphic Test Devices, Code of Federal Regulations under Title 49, Part 572.
  3. R. Cook, D. Malkus, M. Plesha and R. Witt, Concepts and Applications of Finite Element Analysis, 4th Edn, Wiley, 2001.
  4. A. Noureddine, A. Eskandarian and K. Digges, "Computer Modeling and Validation of a Hybrid III Dummy for Crashworthiness Simulation," Mathematical and Computer Modeling, Vol.25, pp.885-893, 2002.
  5. J. B. Ennies, D. Marzougui, A. Eskandarian and E. Bedewi, "Finite Element Modeling of Anthropomorphic Test Devices for Vehicle Crashworthiness Evaluation," International Journal of Crashworthiness, Vol.6, No.4, pp.511-524, 2001. https://doi.org/10.1533/cras.2001.0194
  6. P. Mohan, D. Marzougui, R. V. Velde and C. D. Kan, Development of Detailed Finite Element Dummy Models, LS-DYNA Users Conference, Frankenthal, Germany, 2007.
  7. T. Varady, R. R. Martin and J. Coxt, "Reverse Engineering of Geometric Models - An Introduction," Computer-Aided Design, Vol.29, No.4, pp.255-268, 1997. https://doi.org/10.1016/S0010-4485(96)00054-1
  8. S. Motavalli, V. Suharitdamrong and A. Alrashdan, "Design Model Generation for Reverse Engineering Using Multi-sensors," IIE Transactions, Vol.30, pp.357-366, 1998.
  9. Livermore Software Technology Corporation, LS-DYNA Version 971 User's Manual, 2006.
  10. Altair Corporate, HyperWorks Version 9.0 User's Manual, 2008.
  11. Livermore Software Technology Corporation, LS-DYNA Theoretical Manual, 1998.