An empirical surface roughness model of titanium alloys cut with abrasive water jet

Advanced Materials Research

Volumn 189-193, Issue , 2011, Pages 4231-4244

  Zhang, Shi Jin ^a   Wu, Yu Qiang ^a   Wang, Yan Li ^a  

^a CHONGQING UNIVERSITY   (China)

Author keywords

Abrasive water jet (AWJ); Modeling; Surface roughness; Titanium alloy

Indexed keywords

ABRASIVE WATER JET; AEROSPACE AND AUTOMOTIVE INDUSTRIES; BEAM CUTTING; CUTTING PROCESS; EMPIRICAL MODEL; HIGH COSTS; HIGH QUALITY; MANUFACTURING PROCESS; MODELING; SURFACE ROUGHNESS MODEL;

ABRASIVE CUTTING; ABRASIVES; ALLOYS; CUTTING TOOLS; ENERGY DISSIPATION; INDUSTRIAL ENGINEERING; JETS; MANUFACTURE; METAL ANALYSIS; PRODUCTION ENGINEERING; SURFACE PROPERTIES; TITANIUM; TITANIUM ALLOYS;

SURFACE ROUGHNESS;

EID: 79952491888     PISSN: 10226680     EISSN: None     Source Type: Book Series    
DOI: 10.4028/www.scientific.net/AMR.189-193.4231     Document Type: Conference Paper

References (13)

1. Jaffery, S. I. and Mativerga, P. T., Assessment of the machinability of Ti-6Al-4V alloy using the wear map approach, International Journal of Advanced Manufacturing Technology, Vol. 40, 2009, p. 687;.
2. Lutjering, G. and Williams, J. C., Titanium, Springer-Verlag, Berlin, 2003;.
3. Ezugwu, E. O. and Wang, Z. M., Titanium alloys and their machinability - a review, Journal of Materials Processing Technology, Vol. 68, 1997, pp.262;.
4. Sun, S., Harris, J. and Durandet, Y., Brandt, M., effect of laser beam on machining titanium alloys, PICALO 2008 Conference Proceedings, Beijin, China, 2008;.
5. Zhang, S. and Nambiath, P. et. al, Accurate Hole Drilling Using an Abrasive Waterjet in Titanium, Proceedings of the 13th American Waterjet Conference, Houston, Texas, 2005;.
6. Kong, M. C. and Axinte, D., Response of titanium aluminide alloy to abrasive waterjet cutting: geometrical accuracy and surface integrity issues versus process parameters, Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, Vol. 223, Number 1/2009, p. 019;.
7. Zhang, S., Liao, Z. and Chen, D., Accurate titanium machining using abrasive water jet, 9th Pacific Rim International Conference on Water Jetting Technology, Nov. 20-23, 2009, Japan, pp.87;.
8. Momber, A. W., Principles of Abrasive Water Jet Machining, 1997, pp. 217;.
9. Singh, P. J., Chen, W. and Munoz, J., Comprehensive evaluation of abrasive waterjet cut surface quality, Proc. 6th American Waterjet Conference, 1991,Houston, USA, pp. 139;.
10. Blickwedel, H., Guo, N. S., and Haferkamp, H. et al, Prediction of Abrasive Jet Cutting Performance and Quality, Jet Cutting Technol., Elsevier, London, 1991, pp. 163;.
11. Guo, N. S., Louis, H. and Meier, G., Surface structure and kerf geometry in abrasive waterjet cutting: formation and optimization, Proc. 7th American Waterjet Conference, Seattle, USA, 1993, pp.1;.
12. Zhang, S., Li, X. and Gu, Y., Optimum abrasive flow rate modeling for titanium alloy cutting using abrasive water jet, International Journal of Abrasive Technology, Vol.2(4), 2009, pp.400;.
13. Zeng, J., Mechanisms of Brittle Material Erosion Associated with High Pressure AWJ Processing - A Modeling and Application Study, 1992, Dissertation.