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Research of Thermal Conductivity and Tensile Strength of Carbon Black-Filled Nature Rubber

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Abstract:

Through measuring the thermal conductivities and tensile strength of nature rubbers filled with carbon black and comparing with each other, it is shown that the difference of carbon black particle size and the structure affects on the thermal conductivity and tensile strength of nature rubber. Thermal conductivities of carbon black-filled nature rubber are enhanced with the increase of volume fraction of filler; tensile strength of composite increases first and then decreases with the increase of carbon black volume fraction.

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Advanced Polymer Processing View Preview

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Periodical:

Advanced Materials Research (Volumes 87-88)

Pages:

200-205

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.87-88.200

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Online since:

December 2009

Authors:

Yan He, Zhong Yin, Lian Xiang Ma, Jun Ping Song

Keywords:

Carbon, Rubber, Tensile Strength, Thermal Conductivity (TC)

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© 2010 Trans Tech Publications Ltd. All Rights Reserved

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References

[1] J.J. Wang and X.S. Yi: Composites Science and Technology Vol. 64(2004), p.1623.

Google Scholar

[2] Julia A King, Michael G. Miller and Rodwick L. Barton: Journal of Applied Polymer Science Vol. 99(2006), p.1552.

Google Scholar

[3] Bernd Weidenfeller, Michael Hofer and Frank Schilling: Composites. Part A Vol. 33(2002), p.1041.

Google Scholar

[4] J.R. Gaier, Y. Yodevandenberg and S. Berkebile: Carbon Vol. 41(2003), p.2187.

Google Scholar

[5] Y.A. Kim, T. Hayashi and M. Endo: Scripta Materialia Vol. 54(2006), p.31.

Google Scholar

[6] L.C. Sim and S.R. Ramanan: Thermochimica Acta Vol. 430(2005), p.155.

Google Scholar

[7] D. Kumlutas and I.H. Tavman: Composites Science and Technology Vol. 63(2003), p.113.

Google Scholar

[8] P. Giuseppe and K. Ikuko: Journal of the European Ceramic Society Vol. 20(2000), p.1197.

Google Scholar

[9] P.H. Kang and Y.C. Nho, J. Ind. Eng. Chem. Vol. 7(2001), p.199.

Google Scholar

[10] S. Luo and C.P. Wong: IEEE Trans Compon Pack Technol Vol. 23(2000), p.151.

Google Scholar

[11] W.Y. Zhou, C.F. Wang, and Q.L. An: Journal of Composite Materials Vol. 42 (2008), p.173.

Google Scholar

[12] R.S. Prasher: Journal of Heat Transfer Vol. 123(2001), p.969.

Google Scholar

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