Contact Temperature Calibration of PPS Thrust Bearings under Dry Condition

Hiroya Nihon’yanagi; Takahiro Matsueda; Katsuyuki Kida; Yuji Kashima

doi:10.4028/www.scientific.net/MSF.1020.131

Paper Titles

Analysis of the Influence of Different Construction Joints on the Ductility of Cast-in-Place Frame Structure
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Friction Coefficient and Wear of PEEK-PTFE Hybrid Radial Ball Bearings under Dry Conditions
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Observation of Surface and Subsurface Crack Propagation in PPS Thrust Bearings under Rolling Contact Fatigue in Water
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Crack Growth Evaluation of Induction Quenched JIS-S45C Steel Based on Stress Intensity Factor Simulation
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Contact Temperature Calibration of PPS Thrust Bearings under Dry Condition
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Computational Analysis of Laser Cladding of Preset MCrAlY Coating Based on ANSYS I-Temperature Field
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Computational Analysis of Laser Cladding of Preset MCrAlY Coating Based on ANSYS Ii-Stress Field
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Effects of Heat Accumulation on Temperature Field during Multi-Track Laser Cladding of Preset MCrAlY Coating
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Effect of Different Carbon Materials on the Conductivity of Epoxy Resin Conductive Coatings
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HomeMaterials Science ForumMaterials Science Forum Vol. 1020Contact Temperature Calibration of PPS Thrust...

Contact Temperature Calibration of PPS Thrust Bearings under Dry Condition

Abstract:

In the present study, Rolling Contact Fatigue (RCF) tests of Poly-phenylene-sulfide (PPS) thrust bearings under dry condition were carried out and the relationship between fatigue life of bearings and temperature was studied. Furthermore, in order to investigate maximum temperature of PPS thrust bearings in service, in order to obtain the calibration data, the temperatures of rolling contact element and Infrared (IR) temperature on the side of top race were measured and correlated. It is concluded that the contact temperature of failure PPS bearing was higher than the glass transition point but lower than a melting point of PPS.

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Periodical:

Materials Science Forum (Volume 1020)

Pages:

131-135

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.1020.131

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Online since:

February 2021

Authors:

Hiroya Nihon’yanagi, Takahiro Matsueda, Katsuyuki Kida*, Yuji Kashima

Keywords:

Polymer Thrust Bearing, PPS, Temperature Measurement

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