0
TECHNICAL PAPERS

Influence of Carbon Fabric on Fretting Wear Performance of Polyetherimide Composite

[+] Author and Article Information
Jayashree Bijwe

Industrial Tribology, Machine Dynamics and Maintenance Engineering Center (ITMMEC), Indian Institute of Technology, Delhi, Hauz Khas, New Delhi 110016, Indiae-mail: jbijwe@hotmail.com

J. Indumathi

GE India Technology Centre, Bangalore, Karnataka, 560066, India

Bhabani K. Satapathy

Industrial Tribology, Machine Dynamics and Maintenance Engineering Center (ITMMEC), Indian Institute of Technology, Delhi, Hauz Khas, New Delhi 110016, India

Anup K. Ghosh

Center for Polymer Science and Engineering (CPSE), Indian Institute of Technology, Delhi, Hauz Khas, New Delhi 110016, India

J. Tribol 124(4), 834-839 (Sep 24, 2002) (6 pages) doi:10.1115/1.1456088 History: Received March 20, 2001; Revised August 23, 2001; Online September 24, 2002
Copyright © 2002 by ASME
Your Session has timed out. Please sign back in to continue.

References

Bill,  R. C., 1985, “Selected Fretting Wear Resistant Coatings for Ti-6 percent Al-4 percent V Alloy,” Wear, 106, pp. 283–301.
Jacobs,  O., Friedrich,  K., and Schulte,  K., 1991, “Fretting Fatigue of Continuous Carbon Fibre Reinforced Polymer Composites,” Wear, 145, pp. 167–188.
Ohmae,  N., Kobayashi,  K., and Tsukizoe,  T., 1974, “Characteristics of Fretting of Carbon Fibre Reinforced Plastics,” Wear, 29, pp. 345–353.
Iwabuchi,  A., Hori,  K., and Sugawara,  Y., 1988, “Effects of Temperature and Ambient Pressure on Fretting Properties of Polyimide,” Wear, 125, pp. 67–81.
Jacobs,  O., Friedrich,  K., Marom,  G., and Schulte,  K., 1990, “Fretting Wear Performance of Glass, Carbon and Aramid Fibre/Epoxy and PEEK Composites,” Wear, 135, pp. 207–216.
Rehbin,  P., and Wallaschek,  J., 1998, “Friction and Wear Behavior of Polymer/Steel and Alumina/Alumina Under High Frequency Fretting Conditions,” Wear, 216, pp. 97–105.
Renicke,  R., Haupert,  F., and Friedrich,  K., 1998, “On the Tribological Behaviour of Selected Injection Moulded Thermoplastic Composites,” Composites Part A, 29A, pp. 763–771.
Schulte, K., Friedrich, K., and Jacobs, O., 1993, “Fretting and Fretting Fatigue of Advanced Composite Laminates,” Chap. 18, Advances in Composite Tribology, Composite Materials Series, Vol. 8, K. Friedrich, ed., Elsevier, The Netherlands.
Tewari, U. S., and Bijwe, J., 1996, “Tribological Behaviour of Polyimides,” in Polyimides Fundamentals and Applications, Chap. 19, M. K. Ghosh and K. L. Mittal, eds., Marcel Dekker Inc., USA.
Bijwe, J., and Sharma, S. K., 2001, “Fretting Wear Studies on Solid Lubricated Polyimide Composite,” 12th LAWPSP Symposium, Indian Institute of Technology, Mumbai, Vol. 12, No. 12, pp. SOL-04.1–04.4.
Sen, S., Bijwe, J., Ghosh, A. K., Mishra, A., Parida, T., and Trivedi, P. D., “Role of PTFE, A Solid Lubricant on Wear Behaviour of Polyetheretherketone,” ibid., pp. SOL-05.1–05.4.
Rajesh, J. J., and Bijwe, J., 2002, “Influence of Fillers and Short Fibres on Fretting Wear Behaviour of PA11 Composites,” submitted to WOM 2003 Conference, Washington D.C.
Bijwe, J., and Fahim, M., 2001, “Tribology of High Performance Polymers—State of Art,” in Handbook of Advanced Functional Molecules and Polymers, chpt. 8, H. S. Nalwa, ed., Gordon and Breach Publishers, The Netherlands, pp. 265–321.

Figures

Grahic Jump Location
Schematic of the SRV optimol tester
Grahic Jump Location
Friction coefficient for PEI and CFC as a function of fretting time (a) under various loads at 25°C and (b) at various temperatures under 100 N; A−1 mm, ν−50 Hz. (For PEI μ was constant at all the loads and temperatures. Hence, shown by continuous lines.)
Grahic Jump Location
Friction coefficient for PEI and CFC as a function of (a) load at constant temperature (25°C) and (b) temperature at constant load of 100 N: t−1 hr,A−1 mm, ν−50 Hz.
Grahic Jump Location
Specific wear rate for PEI and CFC as a function of (a) load at constant temperature (25°C) and (b) temperature at constant load of 100 N: t−1 hr,A−1 mm, ν−50 Hz.
Grahic Jump Location
Wear volume for PEI a function of (a) amplitude (t−1 hr, ν−50 Hz, L−100 N,T−25 °C) (b) frequency (ν) (A−1 mm,L−100 N,t−1 hr,T−25 °C)
Grahic Jump Location
Micrographs of worn surfaces of CFC fretted under high temperature (200°C, 100 N) showing (a) general view of the crater, (b) edge of the crater showing brittle fracture of fibers in the direction anti-parallel to fretting, (c) surface in the center of crater indicating extensive melting of matrix due to very high temperature in the center; back transfer of molten material (extreme right), (d) adjacent part of crater indicating fiber damage, wear thinning and embedment of debris, (e) center of crater showing chipping off of molten material, and (f) corresponding Fe dot mapping with EDAX showing less dot density of Fe in the center of the crater.

Tables

Errata

Discussions

Some tools below are only available to our subscribers or users with an online account.

Related Content

Customize your page view by dragging and repositioning the boxes below.

Related Journal Articles
Related eBook Content
Topic Collections

Sorry! You do not have access to this content. For assistance or to subscribe, please contact us:

  • TELEPHONE: 1-800-843-2763 (Toll-free in the USA)
  • EMAIL: asmedigitalcollection@asme.org
Sign In