Erosive wear response of SiCp reinforced aluminium based metal matrix composite: Effects of test environments

Authors

  • M.M. Khan Mechanical Engineering Department, Maulana Azad National Institute of Technology, Link Road No. 3, Bhopal, 462003, India.
  • Gajendra Dixit Mechanical Engineering Department, Maulana Azad National Institute of Technology, Link Road No. 3, Bhopal, 462003, India.

DOI:

https://doi.org/10.15282/jmes.11.1.2017.1.0222

Keywords:

Slurry erosion tester (TR-40); SEM; AMCs; Aluminium-Silicon Alloy; SiC particulate.

Abstract

In the present investigation, the erosive wear behaviour of a 10 wt.% SiC particles reinforced aluminium based metal matrix composite has been studied. The composite was fabricated by dispersing SiC particles of size 50-100 µm into the matrix alloy. The resulting material cast was characterised in terms of microstructure, hardness and erosive wear behaviour. The wear response was examined by the sample rotation technique using the slurry pot erosion tester. The effects of speed, sand content and slurry environment on the slurry wear behaviour have been studied. It was observed from the microstructural studies that the interfacial bonding strength between the aluminium matrix and the SiC particles was good and the particles were distributed uniformly. Moreover, in basic medium matrix alloy exhibited a minimum wear rate compared to the composite whereas in the case of an acidic and saline medium, an improved wear resistance was obtained in the case of the composite. The rate of material loss is found to be higher with the increased sand concentration due to the increased impinging action of the sand particles. Also, the rotational speed has a mixed effect on the wear rate. It can be concluded that the material loss was caused by the synergistic effect of corrosive, erosive and abrasive actions of the slurry medium although in the acidic medium, erosion was the dominant mode of material removal whereas corrosion was dominant in the case of a basic medium.

References

Selvam JDR, Smart DR, Dinaharan I. Microstructure and some mechanical properties of fly ash particulate reinforced AA6061 aluminum alloy composites prepared by compocasting. Materials & Design. 2013;49:28-34.

Chawla KK. Composite materials: science and engineering: Springer Science & Business Media; 1999.

Tavoosi M, Karimzadeh F, Enayati M. Fabrication of Al–Zn/α-Al2O3 nanocomposite by mechanical alloying. Materials Letters. 2008;62:282-5.

Kalaiselvan K, Murugan N, Parameswaran S. Production and characterization of AA6061–B4C stir cast composite. Materials & Design. 2011;32:4004-9.

Xiu Z, Yang W, Chen G, Jiang L, Ma K, Wu G. Microstructure and tensile properties of Si3N4p/2024Al composite fabricated by pressure infiltration method. Materials & Design. 2012;33:350-5.

Amirkhanlou S, Rezaei MR, Niroumand B, Toroghinejad MR. High-strength and highly-uniform composites produced by compocasting and cold rolling processes. Materials & Design. 2011;32:2085-90.

Srivastava V, Ojha S. Microstructure and electrical conductivity of Al-SiCp composites produced by spray forming process. Bulletin of Materials Science. 2005;28:125-30.

Rahimian M, Ehsani N, Parvin N, reza Baharvandi H. The effect of particle size, sintering temperature and sintering time on the properties of Al–Al2O3 composites, made by powder metallurgy. Journal of Materials Processing Technology. 2009;209:5387-93.

Srinivasarao B, Suryanarayana C, Oh-Ishi K, Hono K. Microstructure and mechanical properties of Al–Zr nanocomposite materials. Materials Science and Engineering: A. 2009;518:100-7.

Kok M. Production and mechanical properties of Al2O3 particle-reinforced 2024 aluminium alloy composites. Journal of Materials Processing Technology. 2005;161:381-7.

Das S, Mondal D, Dasgupta R, Prasad B. Mechanisms of material removal during erosion–corrosion of an Al–SiC particle composite. Wear. 1999;236:295-302.

Tu J, Li C, Zhao H, Matsumura M. Slurry erosion‐corrosion characteristics of squeeze cast aluminum alloy‐aluminum borate composite. Materials and Corrosion. 1999;50:205-12.

Jha A, Batham R, Ahmed M, Majumder A, Modi O, Chaturvedi S, et al. Effect of impinging angle and rotating speed on erosion behavior of aluminum. Transactions of Nonferrous Metals Society of China. 2011;21:32-8.

Ramesh C, Keshavamurthy R, Channabasappa B, Pramod S. Influence of heat treatment on slurry erosive wear resistance of Al6061 alloy. Materials & Design. 2009;30:3713-22.

Yu S, Ishii H, Chuang T. Corrosive wear of SiC whisker-and particulate-reinforced 6061 aluminum alloy composites. Metallurgical and Materials Transactions A. 1996;27:2653-62.

Saraswathi Y, Das S, Mondal D. Influence of microstructure and experimental parameters on the erosion–corrosion behavior of Al alloy composites. Materials Science and Engineering: A. 2006;425:244-54.

Ramachandra M, Radhakrishna K. Effect of reinforcement of flyash on sliding wear, slurry erosive wear and corrosive behavior of aluminium matrix composite. Wear. 2007;262:1450-62.

Desale GR, Gandhi BK, Jain S. Particle size effects on the slurry erosion of aluminium alloy (AA 6063). Wear. 2009;266:1066-71.

Gupta A, Prasad B, Pajnoo R, Das S. Effects of T6 heat treatment on mechanical, abrasive and erosive-corrosive wear properties of eutectic Al–Si alloy. Transactions of Nonferrous Metals Society of China. 2012;22:1041-50.

Krabay S. the effect of heat treatments on the Solid-particle erosion behavior of the Aluminum alloy AA2014. Materiali in Tehnologije. 2014;48:141-7.

RamakoteswaraRao V, Ramanaiah N, Srinivasa Rao M, Sarcar MMM, Kartheek G. Optimisation of process parameters for minimum volumetric wear rate on AA7075-TiC metal matrix composite. International Journal of Automotive and Mechanical Engineering. 2016;13:3669-80.

Mohanty S, Routara BC. A review on machining of metal matrix composites using nanoparticle mixed dielectric in electro-discharge machining. International Journal of Automotive and Mechanical Engineering. 2016;13:3518-39.

Fatchurrohman N, Sulaiman S, Sapuan SM, Ariffin MKA, Baharuddin BTHT. Analysis of a metal matrix composites automotive component. International Journal of Automotive and Mechanical Engineering. 2015;11:2531-40.

Asif Iqbal AKM, Arai Y. Study on low-cycle fatigue behavior of cast hybrid metal matrix composites. International Journal of Automotive and Mechanical Engineering. 2015;11:2504-14.

Maleque MA, Radhi M, Rahman MM. Wear study of Mg-SiCp reinforcement aluminium metal matrix composite. Journal of Mechanical Engineering and Sciences. 2016;10:1758-64.

Abu Bakar MH, Raja Abdullah RI, Md. Ali MA, Kasim MS, Sulaiman MA, Ahmad SSN, et al. Surface integrity of LM6 aluminum metal matrix composite when machined with high speed steel and uncoated carbide cutting tools. Journal of Mechanical Engineering and Sciences. 2014;6:854-62.

Khan MAR, Rahman M, Kadirgama K, Maleque M, Ishak M. Prediction of surface roughness of Ti-6Al-4V in electrical discharge machining: A regression model. Journal of Mechanical Engineering and Sciences. 2011;1:16-24.

Bhandare RG, Sonawane PM. Preparation of aluminium matrix composite by using stir casting method. Int J Eng Adv Technol. 2013;3:2249-8958.

Ding Z, Fan Y, Qi H, Ren D, Guo J. Study on the SiC_p./Al-Alloy composite automotive brake rotors. Acta Metallurgica Sinica (English Letters). 2009;13:974-80.

Mishra AK, Sheokand R, Srivastava R. Tribological behaviour of Al 6061/SiC metal matrix composite by Taguchi’s Techniques. International Journal of Scientific and Research Publications. 2012;2:1-8.

Taufik R, Adibah M, Muhamad M, Hasib H. Feasibility study of natural fiber composite material for engineering application. Journal of Mechanical Engineering and Sciences. 2014;6:940-8.

Adebisi A, Maleque M, Rahman M. Metal matrix composite brake rotor: historical development and product life cycle analysis. International Journal of Automotive and Mechanical Engineering. 2011;4:471-80.

Seah K, Sharma S, Girish B, Lim S. Wear characteristics of as-cast ZA-27/graphite particulate composites. Materials & Design. 1996;17:63-7.

Singh M, Mondal D, Modi O, Jha A. Two-body abrasive wear behaviour of aluminium alloy–sillimanite particle reinforced composite. Wear. 2002;253:357-68.

Dixit G, Khan MM. Sliding Wear Response of an Aluminium Metal Matrix Composite: Effect of Solid Lubricant Particle Size. Jordan Journal of Mechanical & Industrial Engineering. 2014;8.

Khan MM, Gurupanchayan V, Dixit G. Abrasive Wear Response of SiCp reinforced ZA-43 alloy metal matrix composite. Indian Journal of Science and Technology. 2016;9.

Bhaskar HB, Sharief A. Effect of Solutionizing on Dry Sliding Wear of Al2024-Beryl Metal Matrix Composite. Journal of Mechanical Engineering and Sciences. 2012;3:281-90.

Bertolini L, Brunella M, Candiani S. Corrosion behavior of a particulate metal-matrix composite. Corrosion. 1999;55:422-31.

Saraswathi Y, Das S, Mondal D. A comparative study of corrosion behavior of Al/SiCp composite with cast iron. Corrosion. 2001;57:643-53.

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Published

2017-03-31

How to Cite

[1]
M. Khan and G. . Dixit, “Erosive wear response of SiCp reinforced aluminium based metal matrix composite: Effects of test environments”, J. Mech. Eng. Sci., vol. 11, no. 1, pp. 2401–2414, Mar. 2017.

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