Physical and strength properties of Fe/SiC composites under microwave hybrid sintering method

Authors

  • Siti Nurul Adura Daud Faculty of Engineering, Universiti Putra Malaysia https://orcid.org/0000-0002-7824-4633
  • Suraya Mohd Tahir Faculty of Engineering, Universiti Putra Malaysia
  • Mohd Shamsul Anuar Faculty of Engineering, Universiti Putra Malaysia
  • Che Nor Aiza Jaafar Faculty of Engineering, Universiti Putra Malaysia
  • Mohd Zuhri Mohamed Yusoff Faculty of Engineering, Universiti Putra Malaysia

Keywords:

Fe/SiC, Microwave hybrid sintering, Tensile strength, Shrinkage, Relative density

Abstract

Two different methods for the sintering of Fe/SiC composite prepared via uniaxial powder compaction are investigated in this work; the conventional furnace sintering and the microwave hybrid sintering methods. The important variables considered are the compositions of SiC in the Fe/SiC composite and the sintering temperatures used. The compositions of the SiC in the Fe/SiC used are 0, 10 and 20 wt. % and the sintering temperatures used are 1000°C, 1050°C, 1100°C and 1200°C. Damaged samples are obtained at the sintering temperatures of 1100°C and 1200°C for microwave hybrid method. For the undamaged samples obtained at 1000°C and 1050°C sintering temperatures, the physical and strength properties are studied. The physical properties of the sintered samples studied are the occurrence of shrinkage and swelling, the relative density and also their microstructure. The results show that the samples sintered under microwave hybrid process exhibit relatively higher shrinkage and swelling. The addition of SiC leads to the decrease in the relative densities of the sintered Fe/SiC samples. In addition, the tensile strengths of the Fe/SiC samples decrease with increasing SiC content. Microwave hybrid sintering produces relatively stronger samples by having relatively higher tensile strength values, especially for pure Fe and at 10 wt% SiC at 1050°C sintering temperature.

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References

S. H. Thauri, T. F. Ariff, and A. N. Mustafizul Karim, “Study of TiC Cutting Tool Insert Using Microwave Synthesis,” Applied Mechanics and Materials, vol. 52–54, pp. 2116–2121, 2011.

P. Leonelli, P. Veronesi, L. Denti, and L. Juliano, “Microwave Assisted Sintering of Green Metal Parts,” Journal Material Process Technology, vol. 5(1-3), pp. 489-496, 2008

S. Chaktin, M. Morakotjinda, T. Yodkaew, N. Torasngtum, R. Krataithong, P. Siriphol, N, Coovattanachai, B. Vetayanugul, N. Thavarungkul, N. Poolthong, and R. Tongsri, “Influence of Carbides on Properties of Sintered Fe-Base Composites,” Journal of Metals, Materials and Minerals, vol. 18(2), pp. 67-70, 2008.

T. Yodkaew, M. Morakotjinda, N. Tosangthum, O. Coovattanachai, R. Krataitong, P. Siriphol, B. Vetayanugul, S. Chaktin, N. Poolthong and R. Tongsri, “Sintered Fe-Al2O3 and Fe-SiC Composites,” Journal of Metals, Materials and Minerals, vol. 18(1), pp. 57-61, 2008

S. Pitakrattanayothin, S. Naknaka, M. Morakotjinda, T. Yodkaew, B. Vetayanugul, R. Krataitong, N. Torsangthum, and R. Tongsri, “Preparation of PM Fe-FeAl and Fe2Al5 Composites,” The 25th Conference of the Mechanical Engineering Network of Thailand, 2011

K. S Sreenivasan, S. Kathiresan, and C. Nandakumar, “Fabrication and Testing of Hybridal/SiC/Flyash using Powder Metallurgy Technique through Microwave Sintering,” IOSR Journal of Mechanical and Civil Engineering (IOSR-JMCE), pp. 54-65, 2014

K. Feng, Y. Yang, M. Hong, J. Wu, and S. Lan, “Intensified Sintering of Iron Powders Under The Action of An Electric Field: Effect of Technologic Parameter on Sintering Densification,” Journal of Materials Processing Technology, vol. 208(1-3), pp. 264- 269, 2008.

D. Agrawal, “Microwave Sintering of Ceramics, Composites and Metallic Materials and Melting of Glasses,” Transactions of the Indian Ceramic Society, vol. 65(3) pp. 129- 144, 2006.

R. M. Anklekar, D. K. Agrawal, and R. Roy, “Microwave Sintering and Mechanical Properties of PM Copper Steel,” Powder Metal, vol. 44(4), pp. 355-362, 2001.

W. L. E. Wong, and M. Gupta, “Simultaneously Improving Strength and Ductility of Magnesium using Nano-Size SiC Particulates and Microwaves,” Advanced Engineering Materials, vol. 8(8), pp. 735-740, 2006.

E. T. Thostenson, and T. W. Chou, “Microwave Processing: Fundamentals and Applications,” Composites Part A: Applied Science and Manufacturing, vol 30(9), pp 1055-1071, 1999.

D. K. Agrawal, “Microwave Sintering Brazing and Melting of Metallic Materials,” NonFerrous Material Extrusion Process, vol. 4, pp. 183-192, 2006.

K. Venkateswarlu, S. Saurabh, S. K. Rajinikanth, and A. K. Ray, “Synthesis of TiN Reinforced Aluminium Metal Matrix Composites through Microwave Sintering,” Journal Material Engineering Performance, vol. 19(2), pp. 231-236, 2010.

C. Zhao, J. Vleugels, C. Groffils, P. J. Luypaert, and O. Van der Diest, “Hybrid Sintering with a Tubular Susceptor in A Cylindrical Single-Mode Microwave Furnace,” Acta Materialia, vol. 48(14), pp. 379-3801, 2000.

J. Vleugels, I. Volders, S. Put, C. Zhao, O. Van der Biest, C. Groffils, P. J. Luypaert, G. Barbies, and L. Bourgeois, “HybridMicrowave Sintering of Hard metals and Graded Oxide Composites,” International Plansee Seminar, vol. 2, pp. 204-215, 2001.

K. Rajkumar, and S. Aravindan, “Microwave Sintering of Copper-Graphite Composites. Journal of Materials Processing Technology,” vol. 209 (15-16), pp. 5601-5605, 2009

S. N. A. Daud, S. M. Tahir, C. N. A. Jaafar, M. Y. M. Zuhri, “Preliminary comparison of Fe/SiC sintered using microwave hybrid and conventional sintering,” AIP Conference Proceedings, vol. 1885, pp. 1-7. 2018

Z. S. Liu, G. Shao, D. Chen, and R. Zhang, “Preparation and Characterization of Fe/SiC Ceramic-Metal Composites,” Key Engineering Materials, vol. 434-435, pp. 66-68, 2010.

G. Prabhu, A. Chakraborty, and B. Sarma, “Microwave Sintering of Tungsten,” International Journal of Refractory Metals and Hard Materials, vol. 27(3), pp. 545-548, 2009.

C. S. Ramesh, C. K. Srinivas, and B. H. Channabasappa, “Abrasive Wear Behavior of Laser Sintered Iron-SiC Composites,” Wear, vol. 267 (11), pp. 1777-1783, 2009.

C. Srinivasa, C. Ramesh, and S. Prabhakan, “Blending of Iron and Silicon Carbide Powders for Producing Metal Matrix Composites by Laser Sintering Process,” Rapid Prototyping Journal, vol. 16, pp. 258-267, 2010.

S. Chaktin, N. Poolthong, and R. Tongsri, “Effect of Reaction between Fe and Carbide Particles on Mechanical Properties of Fe-Base Composite,” Advanced Materials Research, vol. 55-57, pp. 357-360, 2008.

N, Ozkan, “Compaction and Sintering of Ceramics,” Imperial College of Science, Technology and Medicine, 1994.

K. Saitou, “Microwave Sintering of Iron, Cobalt, Nickel, Copper and Stainless Steel Powders,” Scripta Materialia, vol. 54(5), pp. 875-879, 2006.

D. Li, and L. N. Y. Wong, “The Brazillian Disc Test for Rock Mechanics Applications Review and New Insight,” Rock Mechanics and Rock Engineering, vol. 46(2), pp. 269-287, 2013.

Z. S. Liu, G. Shao, D. Chen, and R. Zhuang, “Preparation and Characterization of Fe/SiC Ceramic-Metal Composites,” Key Engineering Materials, vol. 434-435, pp. 66-68, 2010.

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Published

2019-06-29

How to Cite

[1]
S. N. A. Daud, S. M. Tahir, M. S. Anuar, C. N. A. Jaafar, and M. Z. M. Yusoff, “Physical and strength properties of Fe/SiC composites under microwave hybrid sintering method”, J Met Mater Miner, vol. 29, no. 2, Jun. 2019.

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Original Research Articles