The effect of thermal conductivity and friction coefficient on the contact temperature of polyimide composites: Experimental and finite element simulation

Liwen Mu; Yijun Shi; Xin Feng; Jiahua Zhu; Xiaohua Lu

doi:10.1016/j.triboint.2012.04.003

The effect of thermal conductivity and friction coefficient on the contact temperature of polyimide composites: Experimental and finite element simulation

Liwen Mu, Yijun Shi, Xin Feng, Jiahua Zhu, Xiaohua Lu

College of Chemical Engineering

Research output: Contribution to journal › Article › peer-review

63 Scopus citations

Abstract

In this work, the Finite Element Method is used to simulate and visualize the maximum contact temperature of polymer composites under ring-on-block tribolgical test. The simulated temperatures are in good agreement with the experimental results under all testing conditions. The error values between the experimental and simulated temperature are less than 10%. The contact temperature is decreased to nearly 72°C just by reduction of the friction coefficient by 40%, which is about 18 times higher than the 40% increase of thermal conductivity. The results indicate that the friction coefficient plays a more important role in the contact temperature than the thermal conductivity.

Original language	English
Pages (from-to)	45-52
Number of pages	8
Journal	Tribology International
Volume	53
DOIs	https://doi.org/10.1016/j.triboint.2012.04.003
State	Published - Sep 2012

Keywords

Contact temperature
Finite-element method
Friction coefficient
Polyimide composites

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10.1016/j.triboint.2012.04.003

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title = "The effect of thermal conductivity and friction coefficient on the contact temperature of polyimide composites: Experimental and finite element simulation",

abstract = "In this work, the Finite Element Method is used to simulate and visualize the maximum contact temperature of polymer composites under ring-on-block tribolgical test. The simulated temperatures are in good agreement with the experimental results under all testing conditions. The error values between the experimental and simulated temperature are less than 10%. The contact temperature is decreased to nearly 72°C just by reduction of the friction coefficient by 40%, which is about 18 times higher than the 40% increase of thermal conductivity. The results indicate that the friction coefficient plays a more important role in the contact temperature than the thermal conductivity.",

keywords = "Contact temperature, Finite-element method, Friction coefficient, Polyimide composites",

author = "Liwen Mu and Yijun Shi and Xin Feng and Jiahua Zhu and Xiaohua Lu",

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T1 - The effect of thermal conductivity and friction coefficient on the contact temperature of polyimide composites

T2 - Experimental and finite element simulation

AU - Mu, Liwen

AU - Shi, Yijun

AU - Feng, Xin

AU - Zhu, Jiahua

AU - Lu, Xiaohua

PY - 2012/9

Y1 - 2012/9

N2 - In this work, the Finite Element Method is used to simulate and visualize the maximum contact temperature of polymer composites under ring-on-block tribolgical test. The simulated temperatures are in good agreement with the experimental results under all testing conditions. The error values between the experimental and simulated temperature are less than 10%. The contact temperature is decreased to nearly 72°C just by reduction of the friction coefficient by 40%, which is about 18 times higher than the 40% increase of thermal conductivity. The results indicate that the friction coefficient plays a more important role in the contact temperature than the thermal conductivity.

AB - In this work, the Finite Element Method is used to simulate and visualize the maximum contact temperature of polymer composites under ring-on-block tribolgical test. The simulated temperatures are in good agreement with the experimental results under all testing conditions. The error values between the experimental and simulated temperature are less than 10%. The contact temperature is decreased to nearly 72°C just by reduction of the friction coefficient by 40%, which is about 18 times higher than the 40% increase of thermal conductivity. The results indicate that the friction coefficient plays a more important role in the contact temperature than the thermal conductivity.

KW - Contact temperature

KW - Finite-element method

KW - Friction coefficient

KW - Polyimide composites

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SN - 0301-679X

VL - 53

SP - 45

EP - 52

JO - Tribology International

JF - Tribology International

ER -

The effect of thermal conductivity and friction coefficient on the contact temperature of polyimide composites: Experimental and finite element simulation

Abstract

Keywords

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