EFFECTS OF SLIDING DISTANCE SPEED AND LOAD ON WEAR AND TEMPERATURE IN DIFFERENT MATRIX AND FIBER-REINFORCED COMPOSITE MATERIALS

Year 2021, Volume: 11 Issue: 1, 47 - 52, 01.06.2021

Haşim Pıhtılı

https://doi.org/10.36222/ejt.813718

Cited By: 1

Abstract

In this study, wear behaviours of fiber-reinforced and matrix composite materials are experimentally investigated under different speeds, loads and temperature. Composite materials were made of Kevlar-epoxy resin, glass fibre-epoxy resin and glass fibre -polyester resin materials. Tests were conducted for speeds of 0,390 and 0,557 m/s , at two different loads of 5N and 10N, respectively. Wear in the experiments was determined as lost in mass. In addition, the photographs of specimens were taken under the SEM and wear behaviours on these photographs were investigated. As a result of this study, it is shown that the applied load on the specimens has more effect on the wear than that of speed. The surface temperature plays an important role in the friction and wear of polymers and increases at higher sliding speeds and loads. The temperature of the specimens increased more with the increasing sliding speed and applied load, so the wear increases more with the temperature.

Keywords

Wear, ,Composite Materials, ,Woven Fabric Polyesetr resin

References

• [1] Vinson, J.R., Chou, T., Composite Materials and their use in structures, London, (1975).
• [2] Kishore, Sampathkumaran P., Seetharamu S., Murali A. and Kumar R.K. Journal of Reinforced Plastics and Composites.; 18(1): 55–62 (1999).
• [3] Kishore, Sampathkumaran P., Seetharamu S., Vynatheya S., Murali A. and Kumar R.K. “SEM Observations of The Effects Of Velocity and Load on The Sliding Wear Characteristics of Glass Fabric–Epoxy Composites with Different Fillers”, Wear.; 237: 20–27(2000).
• [4] A.A. Collyer, “Rubber Toughened Engineering Materials”, Chapman & Hall, London, (1994).
• [5] Pihtili, H., Tosun,N., “Effect of load and speed on the wear behaviour of woven glass fabrics and aramid fibre-reinforced composites” , Wear 252 ,; 979 -984, Elsevier (2002).
• [6] Pihtili, H., Tosun,N., “Investigation of the wear behaviour of a glass-.fibre-reinforced composite and polyester resin Composites”, Science and Technology 62; 367–370, Elsevier ( 2002).
• [7] N.S. El-Tayep, R.M. Gadelrap, “Friction and wear properties of E-glass fiber reinforced epoksi composites under different sliding contact conditions”, Wear 192,; 112-117 (1996).
• [8] N. Chand, A. Naik, S. Neogi, “Three-body abrasive wear of short glass fibre polyester composite”, Wear 242; 38–46. (2000).
• [9] M.R. Piggot, “Load-Bearing Fibre Composite”, Pergamon Press, Oxford,(1980).
• [10] S.N. Kukureka, C.J. Hooke, M. Rao, P. Liao, Y.K. Chen, “The effect of fibre reinforcement on the friction and wear af polyamide 66 under dry rolling–sliding contact”, Tribol. Int. 32,; 107–116. (1999).
• [11] V.K. Srivastava, J.P. Pathak, “Friction and wear properties of bushing bearing of graphite filled short glass fibre composite in dry sliding”, Wear 197 ,; 145–150. (1996).
• [12] ASM Handbook, ASM International. Materials Park. USA. 1992; 18.
• [13] R.Ramesh, Kishore, Rao R.M.V.G.K, “Dry sliding wear studies in glass fiber reinforced epoxy composites”, Wear, 89: 131. (1983).
• [14] Bolvari AE, Gleen SB. Eng Plast, 9:205 –15. (1996).
• [15] Halling J, ASM J. Lubr Technol, 105:212. (1983).
• [16] J. Halling, “Toward a mechanical wear equation”, J. Lubricat. Technol. Trans. ASME 105 (2) , 212–220. (1983).
• [17] K.H. Zum Gahr, “Microstructure and wear of materials”, Tribology Series, Vol. 10,Elsevier, Amsterdam, (1987).
• [18] B. Vishwanath, A.P. Verma, C.V.S. Kameswara Rao, Composite Sci. Technol. 44 (1), 77–86. (1992).
• [19] Bahadur, “Wear research and development”, J. Lubricat. Technol. Trans. ASME 100 (4),; 449–454 (1978).
• [20] N. Chand, M. Fahim, S.G. Hussain, “Effect of 60Co gamma-irradiation on interface and abrasive wear of glass-reinforced polyester composite”, J. Mater. Sci. Lett., 12,; 1603–1605. (1993).