Crystal Structures and Thermal Properties of Bamboo Nanofiber Reinforced-Composite Friction Materials of Glass and Metal Wastes

Sutikno Sutikno; Sukiswo Supeni Edi; Dany Sigit Saputra

doi:10.4028/www.scientific.net/AMR.789.49

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HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 789Crystal Structures and Thermal Properties of...

Crystal Structures and Thermal Properties of Bamboo Nanofiber Reinforced-Composite Friction Materials of Glass and Metal Wastes

Abstract:

In Indonesia, a lot of wastes of glasses and metals have potency to be one of brake raw materials. For example, little bottles of used food packages are usually directly thrown into environment. The scraps of metal machining wastes are usually collected to be manufactured into other products. In this research, both wastes are used as fillers for brake friction materials, the effects of them on the thermal properties are studied in details. The glass wastes are crushed, grinded and filtered to simplify the mixing process with other raw materials when the fabrication of brake fiction materials done. During fabrication, samples are cured at 190°C for 3 hours. The samples are characterized using x-ray diffractometer and thermogravimetric analysis. Based on these characterizations, the increase of glass powders content plays role in increasing the percentage of crystalllinities. This is suspected the glass used as ingredient of friction material has crystalline structure. The glass waste quantity does not influence significantly on the thermal properties. During heating up to 1200°C, the mass loss occurs due to epoxy, bamboo fiber and styrene butadiene rubber decompose. The optimum composition is found at sample B2, a sample with lowest total mass loss (2 mg).

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Periodical:

Advanced Materials Research (Volume 789)

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49-55

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https://doi.org/10.4028/www.scientific.net/AMR.789.49

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September 2013

Authors:

Sutikno Sutikno, Sukiswo Supeni Edi, Dany Sigit Saputra

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Crystalline, Friction Material, Glass, Metal, Thermal Property

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References

[1] Sutikno: Profesional, Jurnal Ilmiah Populer dan Teknologi Terapan Vol. 6 No. 2 (2009), p.893.

Google Scholar

[2] D. Kiswiranti, Sugianto, N. Hindarto, dan Sutikno: Jurnal Pendidikan Fisika Indonesia (JPFI), Vol. 9 No. 1 (2009) p.87.

Google Scholar

[3] A. Podratzky & H. Bansemir: Aerospace Sci Technol 11 (2007), p.360.

Google Scholar

[4] Sutikno, N. Hindarto, P. Marwoto, and S. Rustad: Pembuatan bahan gesek kampas rem menggunakan serbuk tempurung kelapa sebagai pemodifikasi gesek, " Proceedings of National Seminar VIII Engineering dan Application of Mechanical Engineering in Industry, Bandung, Indonesia 24-25 November, (2009(a).

Google Scholar

[5] Atzeni & Luliano: J Mater Proces Tech 196 (2008), p.184.

Google Scholar

[6] Sutikno, N. Hindarto, P. Marwoto, and S. Rustad: Effect of content of coconut char powders on mechanical and physical properties of brake friction materials, Proceedings of Regional Conference on Solid State Science and Technology, Bayview Beach Resort, Penang, Malaysia, 21st-23rd December, (2009(b).

DOI: 10.1016/j.carbon.2010.06.015

Google Scholar

[7] S. Fan, L. Zhang, Y. Xu, L. Cheng, J. Lou, J. Zhang, and L. Yu: Compos Sci Technol 67 (2007), p.2390.

Google Scholar

[8] St. Louis: U.S. Survey Shows Imports of Asbestos Brake Materials Increasing, St. Louis: Legal News Watch (2004).

Google Scholar

[9] M.G. Jacko, P.H.S. Tsang, and S.K. Rhee: Automative friction materials evaluation during the past decade, Troy: Allied Automotive Technical Center (2003).

Google Scholar

[10] J.W. Cherie, H. Gibson, C. McIntosh, W.M. Maclaren, and G. Linchae: Exposure to fire airborne dust amongst processor of para-aramid, Edinburgh: Institute of Occupational Medicine (2000).

Google Scholar

[11] S. Mohanthy, & Y.P. Chugh: Tribology Int 40 (2007), p.1217.

Google Scholar

[12] Z. Weiss, J.C. Crelling, G.S. Martynková, M. Valášková, and P. Filip: Carbon 44(4) (2006), p.792.

DOI: 10.1016/j.carbon.2005.06.048

Google Scholar

[13] Subiyakto, E. Hermiati, and DHY Yanto: Berita Selulosa Vol. 44 No. 2 (2009), p.57.

Google Scholar

[14] A. Shojaei, M. Fahimian, and B. Derakhshandeh: Compos Sci Technol 67, (2007), p.2665.

Google Scholar

[15] K.H. Cho, H. Jang, Y.S. Hong, S.J. Kim, R. H, Basch, and J.W. Fash: Wear, 264(3-4), 2008, p.291.

Google Scholar