분말시스압연법에 의한 5 vol%CNT/Al 복합재료의 제조 및 평가

홍동민; 김우진; 이성희; Dongmin Hong; Woo-Jin Kim; Seong-Hee Lee

Korean Journal of Materials Research, Vol.23, No.11, 607-612, November, 2013

DOI10.3740/MRSK.2013.23.11.607 Export Citation

분말시스압연법에 의한 5 vol%CNT/Al 복합재료의 제조 및 평가

Fabrication and Evaluation of 5 vol%CNT/Al Composite Material by a Powder in Sheath Rolling Method

홍동민, 김우진¹, 이성희^†

국립목포대학교 신소재공학과
¹홍익대학교 신소재공학과

Dongmin Hong, Woo-Jin Kim¹, and Seong-Hee Lee^†

Department of Advanced Materials Science and Engineering, Mokpo National University, Muan-gun, Chonnam 534-729, Korea
¹Department of Materials Science and Engineering, Hongik University, Sangsu-dong, Seoul 121-791, Korea

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A powder in sheath rolling method was applied to the fabrication of a carbon nano tube (CNT) reinforced aluminum composite. A 6061 aluminum alloy tube with outer diameter of 31 mm and wall thickness of 2 mm was used as a sheath material. A mixture of pure aluminum powder and CNTs with a volume content of 5% was filled in the tube by tap filling and then processed to an 85% reduction using multi-pass rolling after heating for 0.5 h at 400 oC. The specimen was then further processed at 400 oC by multi-pass hot rolling. The specimen was then annealed for 1 h at various temperatures that ranged from 100 to 500 oC. The relative density of the 5vol%CNT/Al composite fabricated using powder in sheath rolling increased with increasing of the rolling reduction, becoming about 97% after hot rolling under 96 % total reduction. The relative density of the composite hardly changed regardless of the increasing of the annealing temperature. The average hardness also had only slight dependence on the annealing temperature. However, the tensile strength of the composite containing the 6061 aluminum sheath decreased and the fracture elongation increased with increasing of the annealing temperature. It is concluded that the powder in sheath rolling method is an effective process for fabrication of CNT reinforced Al matrix composites.

Keywords:powder in sheath rolling;carbon nano tube;aluminum matrix composite;mechanical property;microstructure

[References]

I. J. Palmear, Light Alloys, Arnold, Butterworthheinemann Press, London 325. (1995)
Genma Y, Tsunekawa Y, Okumiya M, Mohri N, Mater. Trans. JIM., 38, 232 (1997)
Ohori K, Watanabe H, Takeuchi Y, Mater. Sci. Tech., 3, 57 (1987)
Kothari NC, Int. of Powder Metall., 18, 321 (1986)
Hong SH, Chung KH, Mater. Sci. Eng., A194, 165 (1995)
Wang WF, Powder Metall., 38, 289 (1995)
Lee SH, Lee CH, J. Kor. Powder Metall. Inst., 10(2), 103 (2003)
Lee SH, Lee CH, J. Kor. Powder Metall. Inst., 11(3), 259 (2004)
Lee JC, Subramanian KN, Mater. Sci. Eng., A159, 43 (1992)
Joo SH, Kim HS, Trans. Mater. Proces., 19(7), 423 (2010)
Lim JK, Choi SY, Choe KH, Kim SS, Cho GS, Kor. J. Met. Mater., 51(5), 385 (2013)

[Referenced By]

[1] I. J. Palmear, Light Alloys, Arnold, Butterworthheinemann Press, London 325. (1995)

[2] Genma Y, Tsunekawa Y, Okumiya M, Mohri N, Mater. Trans. JIM., 38, 232 (1997)

[3] Ohori K, Watanabe H, Takeuchi Y, Mater. Sci. Tech., 3, 57 (1987)

[4] Kothari NC, Int. of Powder Metall., 18, 321 (1986)

[5] Hong SH, Chung KH, Mater. Sci. Eng., A194, 165 (1995)

[6] Wang WF, Powder Metall., 38, 289 (1995)

[7] Lee SH, Lee CH, J. Kor. Powder Metall. Inst., 10(2), 103 (2003)

[8] Lee SH, Lee CH, J. Kor. Powder Metall. Inst., 11(3), 259 (2004)

[9] Lee JC, Subramanian KN, Mater. Sci. Eng., A159, 43 (1992)

[10] Joo SH, Kim HS, Trans. Mater. Proces., 19(7), 423 (2010)

[11] Lim JK, Choi SY, Choe KH, Kim SS, Cho GS, Kor. J. Met. Mater., 51(5), 385 (2013)