Friction and Wear Studies on Polyphenylene Sulfide Filled with a Complex Mixture

Li Guo; Huan Qin Zhu; Yuan Bao Sun

doi:10.4028/www.scientific.net/AMM.184-185.1400

Paper Titles

Tribological Behavior of PTFE Nanocomposites Reinforced with PBA Grafted Alumina Nanoparticles
p.1380

A New Method to Study the Thermal Fatigue Resistance of Molybdenum by High Power Laser Irradiation
p.1384

Development of Knitting Protective Sleeve
p.1389

Experimental Study on Infrared Spectrum Characteristics of Coal in Low Temperature Oxidation
p.1394

Friction and Wear Studies on Polyphenylene Sulfide Filled with a Complex Mixture
p.1400

Manufacturing Technique of the Biocompatible Polymer Nanofiber Membrane by Electrospinning
p.1404

Kinetic Compensation Effect of Kinetic Parameters of Thermal Explosion Test
p.1408

Numerical Simulation of the Temperature Field in Multi-Layer Powder-Feeding Laser Cladding Forming
p.1418

Preliminary Study of Manufacturing Technique Using Three Dimensions Stain Steel Braid for Bone Scaffold
p.1424

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 184-185Friction and Wear Studies on Polyphenylene Sulfide...

Friction and Wear Studies on Polyphenylene Sulfide Filled with a Complex Mixture

Abstract:

The tribological behavior of PPS filled with molybdenum-concentrate (MC) deposit from Armenia was studied. The deposit MC was a complex mixture of compounds such as MoS2, SO2, CuS, Al2O3, and others. Whereas MC as the filler in particulate form reduced the steady state wear rate of PPS, the optimum reduction in wear was found to occur with the addition of PTFE along with PPS. The behavior of PPS composites made with MC and PTFE sliding against a steel counterface was investigated as a function of the MC and PTFE proportions, sliding speed, and counterface roughness. Of all the above factors, the change in MC proportion, while PTFE was also present, had the greatest effect on the reduction in wear rate. The variation of the coefficient of friction was found to be in the narrow range of 0.27-0.33. The lowest wear rate was found in the case of PPS+ 17vol.%MC+10vol.%PTFE composite sliding at 1.5 m/s against a counterface roughness of 0.1 μm Ra.