Experimental Investigation of Electro-Discharge Face Grinding of Metal Matrix Composite (Al/SiC)

Authors

  • Ram Singar Yadav Department of Mechanical Engineering, Motilal Nehru National Institute of Technology Allahabad, UP, India
  • Gyan Singh Department of Mechanical Engineering, Institute of Engineering and Rural Technology Allahabad Allahabad-211002, UP, India
  • Vinod Yadava Department of Mechanical Engineering, Motilal Nehru National Institute of Technology Allahabad Allahabad-211004, UP, India

DOI:

https://doi.org/10.51983/arme-2019.8.2.3065

Keywords:

Electro-Discharge Face Grinding (EDFG) process, Al/SiC MMC, Material Removal Rate (MRR), Surface Roughness (Ra)

Abstract

Surface quality and process productivity are the challenging performance measures in grinding of difficult-to machine materials these are measured in terms of Surface Roughness (Ra) and Material Removal Rate (MRR). Metal
Matrix composites are the materials having aggregate properties of constituents like higher strength to weight ratio, toughness, stiffness and hardness. Because of having these superior properties MMCs are highly desirable in applications ranging from commercial aircraft to sports equipment but still facing challenges in machining of MMCs. Machining of MMCs by conventional machining process results poor surface finish and frequent tool failure due to presence of ceramic particles. Grinding of MMCs by conventional grinding process produces poor surface finish and low material removal rate due to frequent wheel loading. Electro-Discharge Face Grinding (EDFG) process is used on work specimen of the material Al/SiC MMC to investigate the effects of Wheel speed, Gap current, Pulse on-time and Pulse off-time on Surface Roughness (Ra) and Material Removal Rate (MRR). Surface Roughness (Ra) increases with increase in Wheel RPM, Gap current and Pulse on-time. MRR also increases with increase in Gap current and Pulse on-time while it is almost constant on increasing Wheel RPM. SEM micrograph of machined surface is taken for analysis of surface texture.

References

K. P. Rajurkar and S. M. Pandit, “Formation and ejection of EDM debris,” Transaction of ASME-Journal of Engineering for Industry, vol. 108, pp. 22-26, 1986.

K. M. Shu and G. C. Tu, “Study of electrical discharge grinding using metal matrix composite electrodes,” International Journal of Machine Tools and Manufacture, vol. 43, pp. 845-854, 2003.

V. K. Jain, “Advanced Machining Processes,” Allied Publisher, New Delhi, 2005.

H. E. Hofy, “Advanced Machining Processes: Nontraditional and Hybrid Machining Processes,” McGraw-Hill Companies, New Delhi, 2005.

K. H. Ho, S. T. Newman, “State of the art electrical discharge machining (EDM),” International Journal of Machine Tools and Manufactures, vol. 43, pp. 1287-1300, 2003.

T. Sato, T. Mizutani, K. Yonemouchi and K. Kawata, “The development of an electro discharge machine for micro hole boring,” Precision Engineering, vol. 8, pp. 163-168, 1986.

T. B. Thoe, D.K. Aspinwall, M.L.H. Wise and I.A. Oxley, “Polycrystalline diamond edge quality and surface integrity of electrical discharge grinding,” Journal of Materials Processing Technology, vol. 56, pp. 773-785, 1996.

J. S. Soni and G. Chakraverti, “Machining characteristics of titanium with rotary electro-discharge machining,” Wear, vol. 171, pp. 51-58, 1994.

Y. H Guu and H. Hocheng, “Effects of workpiece rotation on machinability during electrical discharge machining,” Materials and Manufacturing Processes, vol. 16, pp. 91-101, 2001.

P. Koshy, V.K. Jain and G.K. Lal, “Experimental investigations into electrical discharge machining with a rotating disk electrode,” Precision Engineering, vol. 15, pp. 6-15, 1993.

H. M. Chow, B. H. Yan and F. Y. Huang, “Micro slit machining using electro-discharge machining with a modified rotary disk electrode (RDE),” Journal of Materials Processing Technology, vol. 91, pp. 161-166, 1999.

R. Fujun, H. Dechen and W. Dianjun, “Analysis of motion laws of machining non-sphere by EDM with rotary electrode,” Journal of Materials Processing Technology, vol. 149, pp. 323-327, 2004.

N. P. Hung, I. J. Yang and K.W. Leong, “Electrical discharge machining of cast metal matrix composites,” Journal of Material Processing Technology, vol. 44, pp. 229-236, 1994.

M. Ramulu, P.N. Rao and H. Kao, “Drilling of (Al2O3)p/6061 metal matrix composites,” Journal of Material Processing Technology, vol. 124, pp. 244-154, 2002.

B.H. Yan and C.C. Wang, The machining characteristics of Al/6061 metal matrix composites, Journal of Material Processing Technology, 124:244-154, 2002.

C.C. Wang and B.H. Yan, Blind-hole drilling of Al2O3 /6061Al composite using rotary electro-discharge machining, Journal of Materials Processing Technology, 102:90-102, 2000.

B. Mohan, A. Rajadurai and K.G. Satynarayana, Effect of SiC and rotation of electrode on electric discharge machining of Al-SiC composite, Journal of Material Processing Technology, 124:297-304, 2002.

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Published

05-11-2019

How to Cite

Yadav, R. S., Singh, G. ., & Yadava, V. . (2019). Experimental Investigation of Electro-Discharge Face Grinding of Metal Matrix Composite (Al/SiC). Asian Review of Mechanical Engineering, 8(2), 31–37. https://doi.org/10.51983/arme-2019.8.2.3065

Issue

Vol. 8 No. 2 (2019): July-December 2019

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Articles

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