AN EXPERIMENTAL STUDY OF KERF PROPERTIES OF LEAD ZIRCONATE TITANATE CERAMIC MACHINED BY ABRASIVE WATER JET MACHINING

Authors

  • Ravi Prakash Upadhyai S. V. National Institute of Technology, Surat, India
  • Ajit Dhanawade S. V. National Institute of Technology, Surat, India
  • Shailendra Kumar S. V. National Institute of Technology, Surat, India
  • Raj Kalmekar Naval Materials Research Laboratory, Ambernath, Mumbai, India

Keywords:

Abrasive water jet Machining, lead zirconate titanate ceramics, kerf properties, optimization

Abstract

The present paper describes the experimental study of kerf properties in abrasive water jet machining of lead zirconate titanate ceramic material. Process parameters namely traverse rate, water pressure and stand-off distance are considered in the present study. Design of experiments is performed on the basis of response surface methodology to investigate the influence of process parameters on kerf taper. Further, analysis of variance is performed in order to identify significance and influence of process parameters on kerf taper.  It is found that traverse rate and water pressure are most significant parameters followed by stand-off distance. On the basis of experimental analysis, a second order mathematical model is developed to predict kerf taper. Model predictions and experimental results are found in reasonable agreement. Lastly optimization of process parameters is performed to minimize kerf taper.

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References

Carter C B and Norton M G (2013), “Ceramic Materials Science and Engineering”, Springer Science + Business Media, New York, 4-31.

Jaffe B Cook W R and Jaffe H (1971), “Piezoelectric Ceramics”, Academic press London and New York, 1-6.

Kiso H Taguchi T Fukuhara M and T Kimora (1987), “Machining of Advanced Ceramics by Turning Sintered Polycrystalline Diamond Tool”, Bull. Jpn. & w. Prec. Eng.

Dhanawade A and Kumar S (2014), “Abrasive Water Jet Machining Of Composites: A Review, Journal of Manufacturing Engineering”, Vol. 9(3), 136-142.

Wang J and Guo D M (2003), “The Cutting Performance in Multipass Abrasive Water Jet Machining of Industrial Ceramics”, journal of Materials Processing Technology, Vol. 133, 371-377.

Hocheng H and Chang K R (1994), “Material Removal Analysis in Abrasive Water jet Cutting of Ceramic Plates”, Journal of Materials Processing Technology, Vol. 40, 287-304.

Chen L Siores E and Wong W C K (1996), “Kerfs Characteristics in Abrasive Water jet Cutting of Ceramic Materials”, International Journal of Machine Tools and Manufacture, Vol. 36, 1201-1206.

Momber A W Eusch I and Kovacevlc R. (1996), “Machining Refractory Ceramics with Abrasive Water Jets”, journal of materials science, Vol. 31, 6485-6493.

Gudimetla P Wang J and Wong W (2002) “Kerfs Formation Analysis in the Abrasive Water jet Cutting of Industrial Ceramics”, journal of Materials Processing Technology, Vol. 128, 123–129.

Wang J and Guo D M (2003), “The Cutting Performance in Multipass Abrasive Water Jet Machining of Industrial Ceramics”, journal of Materials Processing Technology, Vol. 133, 371-377.

Wang J and Liu H (2006), “Profile Cutting on Alumina Ceramics by Abrasive Water jet Part 1 & 2 : Cutting Performance Models”, Proceedings of the Institution of Mechanical Engineers, Vol. 220, 715-725.

Shanmugam D K and Masood S H (2009), “Minimization of Kerfs Tapers in Abrasive Water jet Machining of Alumina Ceramics Using A Compensation Technique, International Journal of Machine Tools Manufacturing, Vol. 48, 1527-1534.

Srinivasu D S and Axinte D A (2010), “An Analytical Model for Top Width of Jet Footprint in Abrasive Water Jet Milling: A Case Study on SiC Ceramics”, Proc. I Mech, Part B: J. Engineering Manufacture, Vol. 225, 317-335.

Annoni M Arleo F and Milano P (2012), “Fine Abrasive Water Jet Machining Of Piezoelectric Ceramics: Cutting Parameters Optimization”, 21st International Conference on Water Jetting: Looking to the Future, Learning from the Past, Ottawa, Canada, 67-80.

Huang C Lv Z Wang J Zhu H Yao P and Liu Z (2013), “An Experimental Research on Abrasive Water Jet Polishing of the Hard Brittle Ceramics”, Advanced Materials Research, Vol. 797, 15-20.

Ghosh D Das P K Doloi B (2014), “Parametric Studies of Abrasive Water Jet Cutting on Surface Roughness of Silicon Nitride Materials”, 5th International and 26th All India Manufacturing Technology, Design and Research Conference (AIMTDR, 2014), IIT Guwahati, Vol. 422(1-5).

Dittrich M Dix M Kuhl M Palumbo B and Tagliaferri F (2014), “Process Analysis of Water Abrasive Fine Jet Structuring of Ceramic Surfaces via Design of Experiment”, Procedia CIRP, Vol. 14, 442 – 447.

Chithirai P S M Sampath S S Shetty S and Shivamurty B (2015), “Investigation of Abrasive Water Jet Cutting Surface of Alumina Ceramic”, International journal of emerging technology and advance engineering, Vol. 5(1), 402-407.

Dhanawade A and Kumar S (2016), “An Experimental Study of Surface Roughness in Abrasive Water jet Machining of Carbon Fiber Reinforced Polymer Using Orthogonal Array With Grey Relational Analysis”, Journal of Manufacturing Engineering, Vol. 11(1), 001-006.

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Published

2017-03-01

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Articles

How to Cite

[1]
“AN EXPERIMENTAL STUDY OF KERF PROPERTIES OF LEAD ZIRCONATE TITANATE CERAMIC MACHINED BY ABRASIVE WATER JET MACHINING”, JME, vol. 12, no. 1, pp. 006–011, Mar. 2017, Accessed: Nov. 22, 2024. [Online]. Available: https://smenec.org/index.php/1/article/view/180

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