Analysis of Unsteady State Heat Conduction Performance in Anisotropic Materials

Shun Yu Su; Qin Huang; Jian Chen

doi:10.4028/www.scientific.net/AMM.217-219.2484

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 217-219Analysis of Unsteady State Heat Conduction...

Analysis of Unsteady State Heat Conduction Performance in Anisotropic Materials

Abstract:

The magnitudes of heat flux for both isotropic materials and anisotropic materials can be determined from Fourier’s law. But the mechanism of heat transfer in anisotropic materials is quite different from that in isotropic materials. The thermal conductivities at one point are not equal in all directions for anisotropic materials. The magnitude of heat transfer rate of anisotropic material in one direction is not only relevant to the temperature gradient in this direction, but also relevant to the temperature gradient which is normal to the direction. Basing on one-dimensional unsteady state heat conduction problem in isotropic materials which can be solved by separation-of-variables method, the performance of unsteady state heat conduction in anisotropic materials was analyzed. And the unsteady state temperature field of the anisotropic plane wall was obtained. The results will provide help for the energy conservation of anisotropic materials.

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Periodical:

Applied Mechanics and Materials (Volumes 217-219)

Pages:

2484-2487

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.217-219.2484

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Online since:

November 2012

Authors:

Shun Yu Su, Qin Huang, Jian Chen

Keywords:

Anisotropic Material, Heat Conduction, Separation-of-Variables Method, Unsteady State

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References

[1] T. S. Komatsu, N. Nakagawa, S. I. Sasa and H. Tasaki: Phys. Rev. Lett. Vol. 100 (2008), p.1

Google Scholar

[2] D. Gang, Z. Z. Liu and J. Luo: Phys. Rev. A. Vol. 80 (2009), p.1

Google Scholar

[3] Y. A. Cengel: Heat transfer: a practical approach (Second edition) (McGraw-Hill, New York 2003).

Google Scholar

[4] D. X. Sun: Advanced heat transfer: mathematical analysis of heat conduction and convection (China Architecture & Building Press, Beijing, 2005) (In Chinese).

Google Scholar

[5] Q. Gu: Mathematical methods for physics (Science Press, Beijing, 2012) (In Chinese).

Google Scholar

[6] Q. S. Yang and B. Y. Pu: Advanced heat transfer (Second edition) (Shanghai Jiao Tong University Press, Shanghai, 2001) (In Chinese).

Google Scholar

[7] S. Y. Su, J. Chen, C. Z. Zhang: Adv. Mater. Res. Vol. 194-196, No. 2 (2011), p.829

Google Scholar