Analysis of Kerf Taper Angle in Abrasive Water Jet Cutting of Makrana White Marble

Authors

  • Vishal Gupta Research Scholar, Indian Institute of Technology Delhi
  • M. P. Garg Department of Mechanical Engineering, M.M.University, Mullana (Ambala), India
  • R. Khanna Department of Mechanical Engineering, M.M.University, Mullana (Ambala), India
  • R. Khanna Department of Mechanical Engineering, M.M.University, Mullana (Ambala), India

DOI:

https://doi.org/10.51983/ajeat-2013.2.2.682

Keywords:

Abrasive water jet machining,, Kerf taper angle, Taguchi method, ANOVA

Abstract

Abrasive water jet cutting (AWJ) process is used to experimental investigations parameters on kerf taper angles of makrana white marble. Marble is having a wide application in domestic, commercial and industrial construction so there is a need to investigate the AWJ cutting of marble. Three different process parameters were undertaken for this study; water pressure, nozzle transverse speed and abrasive flow rate. Experiments were conducted in varying these parameters for the cutting of marble. The design philosophy of Taguchi was followed to conduct the experiments. Analysis of variance (ANOVA) was used to evaluate the data obtained to determine the major significant process factors statistically affecting the kerf taper angle. The results revealed that the nozzle transverse speed was the most significant factor affecting on the kerf taper angle.

References

Fredin Johan and Jönsson Anders (2011), “Experimentation on Piercing with Abrasive Waterjet”, World Academy of Science, Engineering and Technology, Vol 59, pp 2611-2617.

El-Hofy Hassan (2005), Advanced Machining Process, New York, McGraw-Hill Book Company, pp 44.

Van Lutter and Ir. C. A. (1989) “On the Selection of Manufacturing Methods Illustrated by an Overview of Separation Techniques for Sheet Materials”, Annals of the CIRP, Vol. 38, pp 587-607.

Wang J. and Guo D.M. (2003) “The cutting performance in multipass abrasive waterjet machining of industrial ceramics”, Journal of Materials Processing Technology, Vol. 133/3, pp 371-377.

Palleda and Mahabalesh (2007), “A study of taper angles and material removal rates of drilled holes in the abrasive water jet machining process “, Journal of Materials Processing Technology, Vol. 189, pp 292–295.

Wang J., Kuriyagawa T. and Huang C. Z. (2003), “ An Experimental Study to Enhance the Cutting Performance in Abrasive Water jet Machining” , Machining Science and Technology, Vol 7(2), pp 191– 207.

http://www.scribd.com/doc/7370772/Marble1 access on January, 2012.

Kantha Babu M. and Krishnaiah Chetty O.V. (2006), “A study on the use of single mesh size abrasives in abrasive waterjet machining”, International Journal Advance Manufacturing Technology, Vol. 29, pp 532-540.

Jegaraj J. J.R and N. Ramesh Babu (2005), “A strategy for efficient and quality cutting of materials with abrasive water jets considering the variation in orifice and focusing nozzle diameter”, International Journal of Machine Tools & Manufacture, Vol. 45, pp 1443–1450.

Pi Vu Ngoc (2007), “An introduction to Abrasive Water jet (AWJ) machining”, History Studies Science and Engineering Technology, Vol. 4, pp 91-96.

Arola D. and Ramulu M. (1996), “A study of kerf characteristics in abrasive waterjet machining of graphite/epoxy composite”, Journal of Engineering Materials and Technology, Vol. 118, pp 256–265.

Rahmah A., Khan A.A. and Ramulu M. (2003), “A study of abrasive waterjet machining of Kevlar composite”, In: Proceedings of the 12th U.S. Water Jet Conference, 4-F.

Schwetz K.A., Sigl L.S., Greim J. and Knoch H. (1995), “Wear of boron carbide ceramics by abrasive waterjets”, 10th International Conference on Wear of Materials, Vol. 181-183, pp 148-155.

Conner I., Hashish M. and Ramulu M. (2003), “Abrasive waterjet machining of aerospace structural sheet and thin plate materials”. In: Proceedings of the 12th U.S. Water Jet Conference, 1-G.

Wang J. and Wong W.C.K. (1999), “A study of abrasive water jet cutting of metallic coated sheet steels”, International Journal of Machine Tools & Manufacture, Vol. 39, pp 855–870.

Hocheng H., Tsai H.Y., Shiue J.J. and Wang B. (1997), “Feasibility study of abrasive-waterjet milling of fibre-reinforced plastics”. Journal of Manufacturing Science and Engineering, Vol. 119, pp 133– 142.

Selvan M. Chithirai Pon, Raju and N. Mohana Sundara (2012), “Analysis of surface roughness in abrasive waterjet cutting of cast iron”, International Journal of Science, Environment and Technology, Vol. 1, pp 174-182.

Wang Jun (1999), “A machinability study of polymer matrix composites using abrasive water jet cutting technology”, Journal of Materials Processing Technology, Vol. 94, pp 30–35.

Azmira M.A. and Ahsan A.K. (2009), “A study of abrasive water jet machining process on glass/epoxy composite laminate”, Journal of Materials Processing Technology, Vol. 209, pp 6168–6173.

Downloads

Published

05-11-2013

How to Cite

Gupta, V., Garg, M. P., Khanna, R., & Khanna, R. (2013). Analysis of Kerf Taper Angle in Abrasive Water Jet Cutting of Makrana White Marble. Asian Journal of Engineering and Applied Technology, 2(2), 35–39. https://doi.org/10.51983/ajeat-2013.2.2.682

Issue

Vol. 2 No. 2 (2013): July-December 2013

Section

Articles

License

Copyright (c) 2013 The Research Publication

Creative Commons License

This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.