ON THE FORCES AND TEMPERATURES DUE TO FLANK WEAR IN HARD TURNING

ASME International Mechanical Engineering Congress and Exposition, Proceedings (IMECE)

Volumn 1998-R, Issue , 1998, Pages 161-169

  Wang, J Y ^a   Liu, C R ^a  

^a SCHOOL OF INDUSTRIAL ENGINEERING   (United States)

Author keywords

[No Author keywords available]

Indexed keywords

CUTTING; CUTTING TOOLS; GAS TURBINES;

CHIP FORMATIONS; CONDITION; CUTTING TEMPERATURE; FLANK WEAR; FORMATION PROCESS; HARD TURNING; HEAT PARTITIONS; THERMAL MODEL; TOOL/CHIP INTERFACE; WEAR FORMATION;

THERMOGRAPHY (TEMPERATURE MEASUREMENT);

EID: 85124353274     PISSN: None     EISSN: None     Source Type: Conference Proceeding    
DOI: 10.1115/IMECE1998-1026     Document Type: Conference Paper

References (25)

1. J. F. Archard and R. A. Rowntree. Metallurgical phase transformation in the rubbing of steels. Proc. R. Soc. Lond., A 418:405-424, 1988.
2. J. V. Beck, K. D. Cole, A. Haji-Sheikh, and B. Litkouhi. Heat Conduction Using Green’s Functions. Hemisphere, 1992.
3. G. Boothroyd, J. M. Eagle, and A. W. J. Chisholm. Effect of tool flank wear on the temperature generated during metal cutting. In Proceedings of the MTDR, pages 667-680, 1967.
4. B. T. Chao and K. J. Trigger. Temperature distribution at tool-chip and tool-work interface in metal cutting. Transactions of the ASME, pages 311-320, Feb. 1958.
5. A. G. Harris. An investigation to derive a method of predicting the contribution of tool flank wear to tool forces in orthogonal machining, report, IE, UNSW, 1981.
6. J. C. Jaeger. Moving sources of heat and the temperature at sliding contacts. J. Proc. Roy. Soc., 76:203-224, 1942. New South Wales.
7. NV. Konig, A. Berktold, and K. F. Koch. Turning versus grinding - a comparison of surface integrity aspects and attainable accuracies. Annals of the CIRP, 42(l):39-43, 1993.
8. X. Li, E. M. Kopalinsky, and P. L. B. Oxley. A numerical method for determining temperature distributions in machining with coolant part 1: Modeling the process. Proc. Instn. Meeh. Engrs., 209:33-43, 1995.
9. Z. C. Lin and W. C. Pan. A thermoelastic-plastic large deformation model for orthogonal cutting with tool flank wear - part i: Computation procedures. International Journal of Mechanical Science, 35(10):829-840, 1993.
10. C. R. Liu. An Investigation of the Surface Condition in a Steel Component Machined by Chip Removal Process. PhD thesis, Purdue University, August 1973.
11. C. R. Liu and M. M. Barash. The mechanical state of the sublayer of a surface generated by chip-removal process, part 1: Cutting with a sharp tool. Journal of Engineering for Industry, pages 1193-1201, Nov. 1976.
12. C. R. Liu and M. M. Barash. The mechanical state of the sublayer of a surface generated by chip-removal process, part 2: Cutting with a tool with flank wear. Journal of Engineering for Industry, pages 1203-1208, Nov. 1976.
13. C. R. Liu and S. Mittal. Single-step superfinishing using hard machining resulting in superior surface integrity. Journal of Manufacturing Systems, 14(2): 129—133, 1995.
14. C. R. Liu and S. Mittal. Single-step superfinish hard machining: Feasibility and feasible cutting conditions. Robotics & Computer-Integrated Manufacturing, 12(l):15-27, 1996.
15. Y. Matsumoto, M. M. Barash, and C. R. Liu. Residual Stress in the Machined Suface of Hardened Steel, pages 193-204. American Society of Mechanical Engineers, New Orleans, Louisiana, 1984.
16. P. D. Muraka, G. Barrow, and S. Hinduja. Influence of the process variables on the temperature distribution in orthogonal machining using the finite element method. International Journal of Mechanic Science, 21:445-456, 1979.
17. K. Nakayama. The formation of saw-toothed chip in metal cutting. In Proceedings of the International Conference on Production Engineering, pages 572-577, Tokyo, 1974.
18. K. Nakayama, M. Arai, and T. Kanda. Machining characteristics of hard materials. Annals of the CIRP, 37(1):89—92, 1988.
19. J. Orlich. The austenization process during rapid heating and impulse heating of steel. Traitment Therm., 90:69-75, 1974.
20. M. C. Shaw and A. Vyas. Chip formation in the machining of hardened steel, annals of the CIRP, 41(1):29-33, 1993.
21. H. K. Tonshoff, D. Brandt, and H. G. Wobker. Potential and limitation of hard turning. In 1st International Machining and Grinding Conference, pages 965-978, Dearborn, Michigan, Sept. 1995a.
22. H. K. Tonshoff, H. G. Wobker, and D. Brandt. Tribological aspects of hard turning with ceramic tools. Journal of the Society of Tribologists and Lubrication Engineers, 51(2):163-168,1995b.
23. J. Y. Wang and C. R. Liu. A new concept for decoupling the cutting forces due to flank wear and due to chip formation in hard turning. To Appear in Journal of Machining Science and Technology, June 1998.
24. P. K. Wright and E. M. Trent. Metallographic methods of determining temperature gradients in cutting tools. Journal of the Iron and Steel Institute, pages 364-368, May 1973.
25. N. N. Zorev. Metal Cutting Mechanics. Pergamon Press, New York, 1966.