Development of an Experimental Procedure for Thermal Contact Resistance Estimation at the Glass/Metal Contact Interface

Author:

Abdulhay B.12,Bourouga B.3,Alzetto F.4,Challita C.5

Affiliation:

1. School of Engineering, Energy, and Thermo-Fluids Research Group, Lebanese International University, P. O. Box 146404, Mazraa, Beirut, Lebanon;

2. LTN, UMR CNRS 6607, BP 50609, La Chantrerie, 44306 Nantes Cedex 3, France e-mail:

3. LTN, UMR CNRS 6607, BP 50609, La Chantrerie, 44306 Nantes Cedex 3, France

4. Saint Gobain, R&D – 39 quai Lucien Lefranc, Aubervilliers Cedex 93303, France

5. School of Engineering, Energy and Thermo-Fluids Research Group, Lebanese International University, P. O. Box 146404, Mazraa, Beirut, Lebanon

Abstract

In this paper, an experimental device is designed and developed in order to estimate thermal conditions at the glass/metal contact interface. This device is made of two parts: The upper part contains the tool (piston) made of bronze and a heating device to raise the temperature of the piston to 700 °C. The lower part is composed of a lead crucible and a glass sample. The assembly is provided with a heating system, an induction furnace of 6 kW for heating the glass up to 950 °C. The developed experimental procedure has permitted the estimation of the thermal contact resistance (TCR) using a developed measurement principle based on the inverse technique developed by Beck et al. (1985, Inverse Heat Conduction: III Posed Problems, Wiley Inter-science, New York). The semitransparent character of the glass has been taken into account by an additional radiative heat flux and an equivalent thermal conductivity. After the set-up tests, reproducibility experiments for a specific contact pressure have been carried out. Results show a good repeatability of the registered and estimated parameters such as the piston surface temperature, heat flux density, and TCR. The estimated value of TCR reaches 2 × 10−3 K m2/W with a maximum dispersion that does not exceed 6%.

Publisher

ASME International

Subject

Fluid Flow and Transfer Processes,General Engineering,Condensed Matter Physics,General Materials Science

Reference14 articles.

1. Pietrzyk, M., and Lenard, J. G., 1988, Proceeding National Heat Transfer Conference, Houston, TX, pp. 47–53.

2. Pietrzyk, M., Kusiak, H., Lenard, J. G., and Malinowski, Z., 1994, “Heat Exchange Between the Workpieced and the Tool in the Metal Forming Processes,” Proceedings Conference Formability, Ostrava, Czech Republic, pp. 329–338.

3. Influence of the Lubricant on Temperature Distribution in the Forging Dies;Steel Res.,1995

4. Sadok, L., Pietrzyk, M., Packo, M., and Lenard, J. G., 1992, “A Study of the Interface Heat Transfer Coefficient in Metal-Forming Processes,” Proceedings 1st International Conference Transport Phenomena in Processing, Honolulu, HI, Vol. 1, pp. 515–523.

5. A Study of the Heat Transfer Coefficient as a Function of Temperature and Pressure;J. Mater. Process. Technol.,1994

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