A review on the effects of micro-nano particle size and volume fraction on microstructure and mechanical properties of metal matrix composites manufactured via mechanical alloying

The major challenge for the production of the composites which are reinforced with nano and micro-sized particles is to obtain uniform distribution of reinforcement particles in microstructure. Powder metallurgy method can be used in order to obtain a homogeneous distribution of reinforcement particles. This method has three steps: 1) mixing and/or alloying of powders, 2) pressing, and 3) sintering. Mechanical alloying is a complex process which involves optimization of many parameters such as milling time, process control agent, particle size, ball to powder weight ratio, milling speed, milling atmosphere, mill types, etc. The main aim of the present study is to explain the roles of volume fraction and size of reinforcement particle on the microstructural properties and how these parameters affect the mechanical properties of aluminum based metal matrix composites with micro and nano-sized reinforcement particles produced by mechanical alloying.

Keywords:

Mechanical alloying, Mechanical properties, Metal matrix composites, Microstructure Reinforcement particle size, Volume fraction,

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1. Mazahary A., and M.O. Shabani, Mechanical properties of A356 matrix composites reinforced with nano SiC particles, Strength of Materials, 2012. 44(6): p. 146-155.
2. Amal E.N., and E.E. Nassar, Properties of Al matrix nano composites prepared by powder metallurgy processing, Journal of King Saud University- Engineering Science, 2017. 29(3): p. 295-299.
3. Dongshuai Z., F. Qiu, H. Wang, and Q. Jiang, Manufacture of nano-sized particle-reinforced metal matrix composites: A Review, Acta Metall. Sin.(Eng. Lett.), 2014. 27(5): p. 798-805.
4. Murthy N.V., A.P. Reddy, N. Selvaraj, and C.S.P. Rao, Aluminium metal matrix nano composites- manufacturing methods: A Review, International Journal of Mechanical Engineering, 2015, 4(4): p.24-44.
5. Sajjadi S.A, H.R. Ezatpour, and H. Beygi, Microstructure and mechanical properties of Al-Al2O3 micro and nano composites fabricated via stir casting, Materials Science and Engineering A, 2011. 528: p. 8765-8771.
6. Jose J.G., R. Catalin, G.V. Picu, M. Nithin, S. Thomas, A. Lopes, and C. Buchheim, Mechanical behaviour of Al-SiC nanocomposites produced by ball milling and spark plasma sintering, Metallurgical and Materials Transactions A, 2013. 44 A: p. 5259-5269
7. Endalkachew M., V.Y. Bazhin, and S. Savchenkow, Review on nano particle reinforced aluminum metal matrix composites, Research Journal of Applied Sciences, 2016. 11(5): 188-196.
8. Aizadeh A., M. Khademian, and A. Abdollahi, Investigation of fabrication method effects on microstructure and mechanical properties of Al-2wt %B4C nanocomposite, [cited 2017 29 August]; Avaliable from:http://www.ias.ac.in/public/Volumes/boms/forthcoming/BOMS-D-15-00636.pdf
9. Sherif M.E., Mechanical Alloying, Nanotechnology, Materials Science and Powder Metallurgy. 2015, Elsevier.
10. Prabhu B., C. Suryanarayana, L. Ana, and R. Vaidyanathan, Synthesis and characterization of high volume fraction Al-Al2O3 nanocomposite powders by high energy milling, Materials Science and Engineering A, 2006. 425: p.192-200.
11. Suryanarayana C., Mechanical milling and alloying, Progress In Materials Science, 2001. 46: p. 1-184.
12. Mahboob H., S.A. Sajjadi, and S.M. Zebarjad, Synthesis of Al-Al2O3 nanocomposites by mechanical alloying and evaluation of the effect of ball milling time on the microstructure and mechanical properties, in ICMM’08: Kuala Lumpur. p. 240-245.
13. Razavi Z.H., A. Simchi and S.M. Reihani, Structural evolution during mechanical milling of nanometric and micrometric Al2O3 reinforced Al matrix composite, Materials Science and Engineering A, 2006. 428: p. 159-168.
14. Paksereht A.H., A. Baghbaderani and R. Yazdani, Role of different fractions of nano sized SiC and milling time on the microstructure and mechanical properties of Al-SiC nanocomposites, Transactions of the Indian Institute of Metals, 2016. 69(5): p. 1007-1014.
15. Carlton C.E., and P.J. Ferreira, What is behind the inverse Hall-Petch effect in nanocrystalline materials? ActaMaterialia, 2007. 55: p. 3749-3756.
16. Allalhesabi S., S.A. Manafi and E. Borhani, The structural and mechanical properties of Al-2.5%wt. B4C metal matrix nano composite fabricated by mechanical alloying, Mechanics of Advanced Composites Structures, 2015. 2: p. 39-44.
17. Zhang Z., and D.L. Chen, Contribution of Orowan strengthening effect in particulate-reinforced metal matrix nanocomposite, Materials Science and Engineering A, 2008. 483-484: p. 148-152.
18. Kamrani S., A. Simchi, R. Riedel and S.M.S. Reihani, Effect of reinforcement volume fraction on mechanical alloying of Al-SiC nanocomposite powders, Powder Metallurg, 2007. 50(3): p. 276-282.
19. Kamrani S., R. Riedel, S.M.S. Reihani, and H.J. Kleebe, Effect of reinforcement volume fraction on the mechanical properties of Al-SiC nanocomposites produced by mechanical alloying and consolidation, Journal of Composite Materials, 2010. 44: p. 313-326.
20. Suryanarayana C., Synthesis of nanocomposites by mechanical alloying, Journal of Alloys and Compounds, 2001. 509: p. 229-234.

International Advanced Researches and Engineering Journal-Cover

Yayın Aralığı: Yılda 3 Sayı
Başlangıç: 2017
Yayıncı: Dr. Ceyhun YILMAZ

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