IJBTT

Studying Methods of Estimating Heat Generation at Three Different Zones in Metal Cutting: A Review of Analytical models

	International Journal of Engineering Trends and Technology (IJETT)
	© 2014 by IJETT Journal
	Volume-8 Number-10
	Year of Publication : 2014
	Authors : Ajay Goyal , Shailendra Kumar , Suresh Dhiman , Rajesh Kumar Sharma
	10.14445/22315381/IJETT-V8P296

Citation 

Ajay Goyal , Shailendra Kumar , Suresh Dhiman , Rajesh Kumar Sharma. "Studying Methods of Estimating Heat Generation at Three Different Zones in Metal Cutting: A Review of Analytical models", International Journal of Engineering Trends and Technology(IJETT), V8(10),532-545 February 2014. ISSN:2231-5381. www.ijettjournal.org. published by seventh sense research group

Abstract

The temperature rise during machining would severely affects the quality of work as well as tool life, if goes beyond a limit. Prior estimation and control of this temperature rise have always being a thrust area for machinists in adopting the optimum machining parameters. Though the temperature rise can be measured experimentally but reliable and time tested mathematical model(s) will serve the purpose in a better way. Mathematical model(s) is handy and economic as compared to experimental methods for set of machining parameters. A number of mathematical methods are developed, and the results have been compared with reality. In this paper efforts have been made to review and systemize the study of all such major analytical methods developed in past to identify the future scope of research. Further, a Comparative study of merits and demerits of experimental methods for measurement of temperature rise developed, in past is tabulated.

References

[1] Thompson B. Count Rumford, 1798, An inquiry concerning the source of heat which is excited by friction, Philosophical Transactions of the Royal Society of London; 18:278-87.
[2] Joule JP., 1850, Mechanical equivalent of heat, Philosophical Transactions of the Royal Society of London; 61-81
[3] Taylor, G.I. and Quinney, H., 1934, The Latent Energy Remaining in a Metal after Cold Working, Proc. Roy. Soc. A, 143, 307-326
[4] A.B. Chattopadhyay, Cutting temperature causes effects, assessment and control. MHRD NEPTEL Manufacturing Science II, Lecture 11, IIT Kharagpur Version 2.
[5] Lei Pang, 2012, Analytical modeling and simulation of metal cutting forces for engineering alloys: Ph.D. thesis, department of Engineering and Applied Science, University of Ontario Institute of Technology, page 8
[6] Rosenthal D., 1946, The theory of moving sources of heat and its application to metal treatments, Transactions of ASME; 68: 849-66
[7] Blok H., 1938, Theoretical study of temperature rise at surfaces of actual contact under oiliness lubricating conditions. Proceedings of General Discussion on Lubrication and Lubricants, Institute of Mechanical Engineers London,. pg. 222-235.
[8] Jaeger JC., 1942, Moving sources of heat and the temperature at sliding contacts. Proceedings of the Royal Society of NSW; 76 : 203-24
[9] Carlsaw HS, Jaeger JC., 1959, Conduction of heat in solids. Oxford, UK: Oxford University Press. [10] Loewen EG, Shaw MC., 1954, On the analysis of cutting tool temperatures, Transactions of ASME; 71: 217-31
[11] Cook NH et al., 1954, Discontinuous chip formation. Transactions of the ASME; 76: 153–62
[12] Leone WC., 1954, Distribution of shear-zone heat in metal cutting, Transactions of ASME; 76: 121-5
[13] Weiner JH., 1955, Shear plane temperature distribution in orthogonal machining, Transactions of ASME; 77: 1331-41
[14] Hahn RS., 1951, On the temperature developed at the shear plane in the metal cutting process. Proceedings of First U.S. National Congress of Applied Mechanics pg. 661-6
[15] Dutt RP, Brewer RC., 1964, On the theoretical determination of the temperature field in orthogonal machining. International Journal of Production Research; 4:91-114
[16] Dawson PR, Malkin S., 1984, Inclined moving heat source model for calculating metal cutting temperatures. Transactions of ASME; 106: 179-86
[17] Chao BT, Trigger KJ., 1953, The significance of thermal number in metal machining, Transactions of ASME; 75: 109-20
[18] Trigger KJ, Chao BT., 1951, An analytical evaluation of metal cutting temperature, Transactions of ASME; 73: 57-68
[19] R. Komanduri, Z.B. Hou, 2005, Thermal modeling of the metal cutting process Part I - Temperature rise distribution due to shear plane heat source, International Journal of Mechanical Sciences 2000; 42: 1715-52
[20] Y. Huang, S. Liang, Cutting temperature modeling based on non-uniform heat intensity and partition ratio, Taylor and Francis, Machining Science and Technology, 9: 301–323
[21] Y. Huang and S. Liang, Modelling of the cutting temperature distribution under the tool flank wear effect
[22] Chao BT, Trigger KJ., 1955, Temperature distribution at the tool-chip interface in metal cutting, Transactions of the ASME; 72: 1107-21
[23] Chao BT, Trigger KJ., 1958, Temperature distribution at the tool-chip and tool-work interface in metal cutting, Transactions of the ASME; 80: 311-20
[24]Nakayama K., 1956, Temperature rise of work piece during metal cutting, Bulletin of the Faculty of Engineering,Yokohama National University, Yokohama, Japan; 5: 1
[25] R. Komanduri, Z.B. Hou, 2001, Thermal modeling of the metal cutting process - Part II: temperature rise distribution due to frictional heat source at the tool-chip interface, International Journal of Mechanical Sciences; 43: 57-88
[26] R. Komanduri, Z.B. Hou, 2001, Thermal modeling of the metal cutting process - Part III: temperature rise distribution due to the combined effects of shear plane heat source and the tool-chip interface frictional heat source, International Journal of Mechanical Sciences;43: 89-107
[27] Schallbroach H, Lang M. , 1943, Messung der SchnittemperaturmittelsTemperaturanzeigenderFarbanstriche. Zeitschrift des VereinesDeutscherIngenieure ;87:15–9.
[28] Bickel E, Widmer W. 1954, Die Temperaturenan der Werkzeugschneide. Zurich, Switzerland: Industrielle Organization.
[29] L.B.Abhang and M. Hameedullah. , 2010, Chip-tool interface temperature prediction model for turning process.International Journal of Engineering Science and Technology Vol. 2(4), 382-393
[30] Kraemer G. 1936, Neitragzur Erkenntnis der beim Drehenauftretended Temperaturen und deren Messungmiteinem Gesamtstrahlungsempfanger. Dissertation, Hannover.
[31] A.B. Chattopadhyay, Cutting temperature causes, effects, assessment and control. MHRD NEPTEL Manufacturing Science II, Lecture 11, IIT Kharagpur Version 2. Page 9
[32] Schwerd F., 1933, UeberdieBestimmung des TemperaturfeldesbeimSpanablauf (Determination of the Temperature Distribution During Cutting). Z VDI; 9:211.
[33] Kraemer G., 1936., NeitragzurErkenntnis der beimDrehenauftretendedTemperaturen und derenMessungmiteinemGesamtstrahlungsempfanger. Dissertation, Hannover,
[34] Lenz E. , 1963, Der Einfluss der Schnittempertur auf die standzeit der keramischenSchneidstoffen. Maschinenmarkt;28:30.
[35] Friedman MY, Lenz E. , 1971, Determination of temperature field on upper chip surface. Annals of CIRP;19:395–8.
[36] Ueda T, Hosokawa A, Yamamoto A. , 1985, Studies on temperarature of abrasive grains in grinding — application of infrared radiation pyrometer. Trans ASME, J of Engg for Ind;107:127–33.
[37] Boothroyd G., 1961, Photographic techniques for the determination of metal cutting temperatures.Brit J of Appl Physics;12:238–42.
[38] Jeelani S., 1981, Measurement of temperature distribution in machining using IR photography. Wear;68:191–202.
[39] Kato S, Yamaguchi K, Watanabe Y, Hiraiwa Y., 1976, Measurement of temperature distribution within tool using powders of constant melting point. Trans ASME, J of Engg for Ind;108:607–13.
[40] Wright PK, Trent EM., 1973, Metallographic methods of determining temperature gradients in cutting tools.J Iron and Steel Institute;211:364–88.

Keywords
Analytical models, experimental methods, temperature rise, metal cutting, primary deformation zone, secondary deformation zone, tertiary deformation zone