International Journal of Automotive Technology

The Korean Society of Automotive Engineers (한국자동차공학회)
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MEASUREMENT AND CHARACTERIZATION OF FRICTION IN AUTOMOTIVE DRIVESHAFT JOINTS

  • Lee, C.H. (Department of Mechanical Engineering, Inha University)
  • Published : 2007.12.01
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Abstract

The typical design of automotive driveshafts generally utilizes Constant Velocity(CV) joints as a solution to NVH. CV joints are an integral part of vehicles and significantly affect steering, suspension, and vehicle vibration comfort levels. Thus, CV joints have been favored over universal joints due to the constant velocity torque transfer and plunging capability. Although CV joints are common in vehicle applications, current research works on modeling CV joint friction and assumes constant empirical friction coefficient values. However, such models are long known to be inaccurate, especially under dynamic conditions, which is the case for CV joints. In this paper, an instrumented advanced CV joint friction apparatus was developed to measure the internal friction behavior of CV joints using actual tripod-type joint assemblies. The setup is capable of measuring key performance of friction under different realistic operating conditions of oscillatory speeds, torque and joint installation angles. The apparatus incorporates a custom-installed triaxial force sensor inside of the joint to measure the internal CV joint forces(including friction). Using the designed test setup, the intrinsic interfacial parameters of CV joints were investigated in order to understand their contact and friction mechanisms. The results provide a better understanding of CV joint friction characteristics in developing improved automotive driveshafts.

Keywords

References

  1. Bierman, J. (1999). Measurement system for CV joint efficiency. SAE Paper No.1999-01-0936, 203-209
  2. Gao, H., Barber, G. C. and Chu, H. (2002). Friction characteristics of a paper-based friction material. Int. J. Automotive Technology 3, 4, 171−176
  3. Jia, X., Jin, D., Ji, L. and Zhang, J. (2002). Investigation on the dynamic performance of the tripod-ball sliding joint with clearance in a clank-slider mechanism, Part1, Theoretical and experimental results. J. Sound and Vibration 252, 5, 919−933
  4. Kernizan, C., Jacobs, R. P. and Whitticar, D. J. (2002). Development of a constant velocity joint, CVJ, test stand to assess the performance of a series of greases. NLGI Spokesman 66, 4, 26−32
  5. Kochersberger, K. B. (2002). Apparatus for Testing a Constant Velocity Joint and a Method Thereof. United States Patent, 6,378,374 B2
  6. Philpott, M. L., Welcher, B. P., Pankow, D. R. and Vandenberg, D. (1996). Two phase circular regression algorithm for quantifying wear in CV joint ball race tracks. Wear 199, 2, 160−168
  7. Schmelz, F., Seherr-Thoss, C. H.-C. and Aucktor, E. (1992). Universal Joints and Driveshafts: Dnalysis, Design, Applications (Translated by S.J. Hill and J.A. Tipper). Springer-Verlag. New York
  8. Wagner, E. R. (1979). Universal Joint and Driveshaft Design Manual: Advances in Engineering, Series No. 7. Society of Automotive Engineers, Inc.. Warrendale. PA