Journal of the Korean Society for Precision Engineering (한국정밀공학회지)

Korean Society for Precision Engineering (한국정밀공학회)
권호 표지

Optimum Evaluation of Reinforcement Cord of Air Spring for the Vehicle Suspension System

자동차 현가장치를 위한 에어스프링 보강코드의 최적 성능평가

  • Kim, Byeong-Soo (Department of Mechanical and Automotive Engineering, High Safety Vehcle Cafe Technology Research Center, Inje Univ.) ;
  • Moon, Byung-Young (Department of Naval Architecture, Kunsan Univ.)
  • 김병수 (인제대학교 기계자동차공학부 고안전차량핵심기술연구소) ;
  • 문병영 (군산대학교 조선공학과)
  • Received : 2010.05.25
  • Accepted : 2010.12.13
  • Published : 2011.03.01
Download PDF
⟨ Previous Next ⟩

Abstract

Air springs are prevalently used as suspension in train. However, air springs are seldom used in automobiles where they improve stability and comfort by enhancing the impact-relief, breaking, and cornering performance. Thus, this study proposed a new method to analyze air springs and obtained some reliable design parameter which can be utilized in vehicle suspension system in contrast to conventional method. Among air spring types of suspension, this study focused on sleeve type of air spring as an analysis model since it has potential for ameliorating the quality of automobiles, specifically in its stability and comfort improvement by decreasing the shock through rubber sleeve. As a methodology, this study used MARC, as a nonlinear finite element analysis program, in order to find out maximum stress and maximum strain depending on reinforcement cord's angle variation in sleeves. The properties were found through uniaxial tension and pure shear test, and they were developed using Ogden Foam which is an input program of MARC. As a result, the internal maximum stresses and deformation according to the changes of cord angle are obtained. Also, the results showed that the Young's modulus becomes smaller, then maximum stresses decrease. It is believed that these studies can be contributed in automobile suspension system.

Keywords

References

  1. Woo, C. S., Kim, W. D. and Choi, K. J., "Reliability evaluation of air spring for railway vehicle," J. of the Korean Society for Railway, Vol. 8, No. 2, pp. 182-187, 2005.
  2. Kim, I. S., Hwang, S. H., Han, M. S. and Koh, C. S., "The study on the improvement of dynamic characteristics with multi-orifice in air spring," Proc. of the Korean Society for Noise and Vibration Engineering Spring Conference, pp. 97-103, 2002.
  3. MSC MARC, "MSC. MARC User's Guide," 2005.
  4. Kim, B. S., Moon, B. and Kim, K., "A study on contact deformation of automotive door weatherstrip using non-linear finite element method," Trans. of KSAE, Vol. 13, No. 4, pp. 1-7, 2005.
  5. Kim, W. D., Hur, S., Lee, H. J., Kim, S. W. and Kim, Y. G., "Evaluation of characteristics of cord reinforced air spring for railroad vehicle," J. of the Korean Society for Railway, Vol. 3, No. 3, pp. 84-91, 2000.
  6. Kim, W. D., Kim, D. J., Kim, W. S. and Lee, Y. S., "A study on the equi-biaxial tension test of rubber material," Trans. of KSAE, Vol. 11, No. 5, pp. 95-104, 2003.
  7. KS M6518, "Physical test methods for vulcanized rubber," 2006.
  8. ASTM D412, "Standard test methods for vulcanized rubber and thermoplastic elastomers-tension," 2006.
  9. Miller, K., "Laboratory characterization of elastomers for finite element analysis," Axel Physical Testing Service Conference, pp. 146-151, 2001.
  10. ASTM E143-02, "Standard Test Method for Shear Modulus at Room Temperature," 2008.
  11. KS K 0860, "Textiles-test methods for nonwovenspart 3 : Determination of tensile strength and elongation : Cut strip method," 2006.
  12. Huh, S., Woo, C., Han, H., Kim, W. and Kim, S., "Performance test and finite element analysis of air spring for automobile," Trans. of KSME A, Vol. 31, No. 7, pp. 725-731, 2007.
  13. Yang, W., Chen, C., Chen, Y. and Ren, Y., "Finite element analysis of an air spring for automobile suspension," Journal of Beijing University of Chemical Technology, Vol. 31, No. 3, pp. 105-109. 2004.