Role of Cryogenic Cooling on Cutting Temperature in Turning Steel

[+] Author and Article Information
N. R. Dhar

Technical Teacher’s Training College, Tejgaon Industrial Area, Dhaka 1208, Bangladesh

S. Paul, A. B. Chattopadhyay

Department of Mechanical Engineering, Indian Institute of Technology, Kharagpur, West Bengal 721 302, India

J. Manuf. Sci. Eng 124(1), 146-154 (Apr 01, 2001) (9 pages) doi:10.1115/1.1413774 History: Received March 01, 2000; Revised April 01, 2001
Copyright © 2002 by ASME
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Shaw,  M. C., Pigott,  J. D., and Richardson,  L. P., 1951, “The Effect of Cutting Fluid upon Chip-Tool Interface Temperature,” Trans. ASME, 71, pp. 45–56.
Merchant, M. E., 1958, “The Physical Chemistry of Cutting Fluid Action,” Am. Chem. Soc., Div. Petrol Chem., Preprint 3, No. 4A, pp. 179–189.
Cassin,  C., and Boothroyed,  G., 1965, “Lubrication Action of Cutting Fluids,” J. Mech. Eng. Sci., 7(1), pp. 67–81.
Kitagawa,  T., Kubo,  A., and Maekawa,  K., 1997, “Temperature and Wear of Cutting Tools in High Speed Machining of Inconel 718 and Ti-6V-2Sn,” Wear, 202, pp. 142–148.
Mazurkiewicz,  M., 1989, “Metal Machining with High-Pressure Water-Jet Cooling Assistance—A New Possibility,” ASME J. Eng. Ind., 111, pp. 7–12.
Singamneni, S. B., 1993, “Role of Controlled Contact Cutting on the Mechanism and Mechanics of Chip Formation and the Induced Stresses in Turning Carbide Inserts,” Doctoral Dissertation, Mech. Eng. Dept., IIT Kharagpur.
Grabner, T., and Tonshoff, H. K., 1984, Proc. 5th ICPE, Tokyo, pp. 326–343.
Ecologically Improved Manufacturing Processes at home page http://www.ifw.uni-hannover.de/BEREICH3/Forschen/310_2e.htm
Farook, A., Varadarajan, A. S., and Philip, P. K., 1998, “Machinability Studies on Steel Using Hard Metal Inserts with Soft Material Deposit,” Proc. 18th All India Conf. MTDR, pp. 152–155.
Alaxender, A., Varadarajan, A. S., and Philip. P. K., 1998, “Hard Turning with Minimum Cutting Fluid: A Viable Green Alternative on the Shop Floor,” Proc. 18th All India Conf. MTDR, pp. 152–155.
Thoors, H., and Chandrasekaran, H., 1994, “Influence of the Cutting Medium on Tool Wear during Turning,” Swedish Institute for Metal Research, Report No IM-3118.
Chattopadhyay,  A. B., Bose,  A., and Chattopadhyay,  A. K., 1985, “Improvements in Grinding Steels by Cryogenic Cooling,” Precis. Eng., 7, No 2, pp. 93.
Banerjee, A., and Chattopadhyay, A. B., 1985, “Control of Residual Stress in Grinding by Cryogenic Cooling,” Proceedings of INCONCRYO’85, pp. 78–48.
Paul, S., 1994, “Performance of Cryogenic Grinding over Conventional Grinding,” Doctoral Dissertation, Dept. of Mech. Eng., IIT, Kharagpur, India.
Bhattacharya, A., Roy, T. K., and Chattopadhyay, A. B., 1972, “Application of Cryogenic in Metal Machining,” J. of Institution of Engs, India.
Uhera,  K., and Kumagai,  S., 1968, “Chip Formation, Surface Roughness, Cutting Forces and Tool Wear in Cryogenic Machining,” CIRP Ann., 17(1), pp. 409–416.
Uhera,  K., and Kumagai,  S., 1969, “Mechanisms of Tool Wear,” J. of Japanese Society of Precision Eng., 35(9), pp. 43–49.
Fillippi,  A. D., and Ippolito,  R., 1970, “Face Milling at 180°C,” CIRP Ann., 19(1), pp. 399–406.
Evans,  C., 1991, “Cryogenic Diamond Turning of Stainless Steel,” CIRP Ann., 40/1, pp. 571–575.
Bhattacharya,  S. K., and Moffatt,  V. L., 1976, “Characteristics of Micro Wheel Wear in Grinding,” Int. J. MTDR., 16, pp. 325.
Ding,  Y., and Hong,  S. Y., 1998, “Improvement of Chip Breaking in Machining Low Carbon Steel by Cryogenically Precooling the Workpiece,” Trans. ASME, 120, pp. 76–83.
Hong, S., Qu, X., and Lee, A., “Economical Cryogenic Milling for Environmentally Safe Manufacturing,” Technical Papers of the North American Manufacturing Research Institute of SME at home page http://www.columbia.edu/∼ahl21/index2.html.
Wang,  Z. Y., and Rajurkar,  K. P., 1997, “Wear of CBN Tool in Turning of Silicon Nitride With Cryogenic Cooling,” Int. J. Mach. Tools Manuf., 37, pp. 319–326.
Wang,  Z. Y., Rajurkar,  K. P., and Murugappan,  M., 1996, “Cryogenic PCBN Turning of Ceramic (Si3N4),” Wear, 195, pp. 1–6.
Jawahir,  I. S., and van Luttervelt,  C. A., 1993, “Recent Development in Chip Control Research and Application,” CIRP Ann., 42/2, pp. 659–693.
Shore,  H., 1925, “Thermoelectric Measurement of Cutting Tool Temperature,” J. Wash. Acad. Sci., 15, pp. 85–88.
Bus, C., Tuuwen, A. L., Veenstra, P. C., and Van Der Wolf, A. C. H., 1971, “Thermoelectric Characteristics of Carbides,” Proc. of the 12th Int. Machine Tool Design and Research Conference, pp. 397–400.
Byrne,  G., 1987, “Thermoelectric Signal Characteristics and Average Interfacial Temperature in the Machining of Metals under Geometrically Defined Conditions,” Int. J. Mach. Tools Manuf., 27, pp. 215–224.
Alvelid,  B., 1970, “Cutting Temperature Thermo-electric Measurements,” CIRP Ann., 18, pp. 547–554.
Barrow,  G., 1973, “A Review of Experimental and Theoretical Techniques for Assessing Cutting Temperatures,” CIRP Ann., 22, pp. 203–211.
Braiden, P. M., 1967, “The Calibration of Tool-work Thermocouples,” Proc. of the 8th Int. MTDR Conf., pp. 653–666.
Shaw, M. C., 1984, Metal Cutting Principles, Clarendon Press, Oxford University Press, pp. 284–287.
Leshock,  C. E., and Shin,  Y. C., 1997, “Investigation on Cutting Temperature in Turning by a Tool-work Thermocouple Technique,” Trans. ASME, 119, pp. 502–508.
Chow,  J. G., and Wright,  P. K., 1988, “On-line Estimation of Tool/Chip Interface Temperatures for a Turning Operations,” ASME J. Eng. Ind., 110, pp. 56–64.
Hahn, R. S., 1951, “On the Temperature Developed at the Shear Plane in the Metal Cutting Processes,” Proc. U. S. Nat. Congress of Applied Mechanics, ASME, pp. 661.
Loewen,  E. G., and Shaw,  M. C., 1954, “On the Analysis of Cutting Tool Temperature,” Trans. ASME, 76, pp. 217–231.
Weiner,  J. H., 1955, “Shear-Plane Temperature Distribution in Orthogonal Cutting,” Trans. ASME, 77, pp. 1331.
Tay,  A. O., Stevenson,  M. G., and Davis,  G. V., 1974, “Using the Finite Element Method to Determine Temperature Distribution in Orthogonal Machining,” Proc. Inst. Mech. Eng., 188, pp. 627–638.
Tay,  A. O., Stevenson,  M. G., Davis,  G. V., and Oxley,  P. L. B., 1976, “A Numerical Method for Calculating Temperature Distribution in Machining from Force and Shear Angle Measurements,” Int. J. Mach. Tool Des. Res., 16, pp. 335–349.
Stevenson,  M. G., Wright,  P. K., and Chow,  J. G., 1983, “Further Developments in Applying the Finite Element Method to the Calculation of Temperature Distributions in Machining and Comparisons with Experiment,” ASME J. Eng. Ind., 105, pp. 149–154.
Muraka,  P. D., Barrow,  G., and Hinduja,  S., 1979, “Influence of the Process Variables on the Temperature Distribution in Orthogonal Machining using the Finite Element Method,” Int. J. Mach. Tool Des. Res., 21, pp. 445.
Strenskovski,  J. S., and Kyung-jin,  Moon, 1990, “Finite Element Prediction of Chip Geometry and Tool and Workpiece Temperature Distributions in Orthogonal Cutting,” ASME J. Eng. Ind., 112, pp. 313–318.
Ostafiev,  V. A., and Noschenko,  A. N, 1985, “Numerical Analysis of Three Dimensional Heat Exchange in Oblique Cutting,” CIRP Ann., 34, pp. 137–140.
Kagiwada, T., and Canonic, T., 1988, “Numerical Analysis of Cutting Temperature and Flowing Ratios of Generated Heat,” ASME Int. Thermal, Series III, Vol. 31, No. 3, pp. 624.
Nashchokin, V. V., 1979, Engineering Thermodynamics and Heat Transfer, MIR Publisher, Moscow, USSR.
Barron, R. F., 1985, Monographs on Cryogenic 3: Cryogenics System, 2nd Ed., Oxford Univ. Press, N. Y., USA.
Rothman, M. F., 1988, High Temperature Property Data: Ferrous Alloy, Metal Park, OH 44073, USA.
Kato, S., Yamaguchi, K., and Yamada, M., 1972, “Stress Distribution at the Interface Between Tool and Chip in Machining,” ASME J. Eng. Ind., pp. 683.
Barrow,  G., Graham,  W., Kurimoto,  T., and Leong,  Y. F., 1982, “Determination of Rake Face Stress Distribution in Orthogonal Machining,” Int. J. Mach. Tool Des. Res., 22, pp. 75.
Chen,  N. N. S., and Pun,  W. K., 1988, “Stresses at the Cutting Tool Wear Land,” Int. J. Mach. Tools Manuf., 28, No. 2, pp. 79.
Childs,  T. H. C., Mahdi,  M. I., and Barrow,  G., 1989, “On the Stresses Between the Chip and Tool During Metal Turning,” CIRP Ann., 38, 1, pp. 55.
Stephenson, D. A., and Agapiou, J. S., 1997, Metal Cutting Theory and Practice, New York, pp. 425.
Bhattacharyya, A., 1965, “On the Friction Process in Metal Cutting,” Proc. 6th Int. Conf. on MTDR, Manchester, UK, pp. 491–505.
Lo Casto,  S., Lo Valvo,  E., and Micari,  F., 1989, “Measurement of Temperature Distribution within Tools in Metal Cutting. Experimental Tests and Numerical Results,” J. Mech. Work. Technol., 20, pp. 35.
“NISA/3D-FLUID (Incompressible) User’s Manual,” 1995, Eng. Mechanics Res. Corporation, Michigan, USA.
Chao,  B. T., and Trigger,  K. J., 1955, “Temperature Distribution at the Chip-tool Interface in Metal Cutting,” Trans. ASME, 77, pp. 1107.


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Schematic layout of the experimental set-up
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Schematic diagram of tool-work thermocouple
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Scheme of calibration of present tool-work thermocouple
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Thermocouple calibration for the C-40 steel/WC tool material combination
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Stress distribution along the chip-tool and work-tool interface
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Comparison of measured and predicted average chip-tool interface temperature
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Distribution of temperature obtained by FEM analysis under (a) dry and (b) cryogenic machining by SNMG insert
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Distribution of temperature obtained by FEM analysis under (a) dry and (b) cryogenic machining by SNMM insert
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Variation in average chip-tool interface temperature with increase in cutting velocity, Vc for different feeds in machining by SNMG insert under (a) dry and (b) cryogenic cooling environment
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Variation in average chip-tool interface temperature with increase in cutting velocity, Vc for different feeds in machining by SNMM insert under (a) dry and (b) cryogenic cooling environment




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