Analysis of Temperature in Metal Cutting and Its Measurement Methods
Keywords:
Cutting parameters, metal cutting, measurement, thermocouple, temperature.
Abstract
In this paper, traditional and novel technologies of measuring the heat generated in metal cutting process are studied. Analysing the literature about the cutting temperature, conclusions on the influence of temperature in metal cutting zone are given. Moreover, popular methods of measuring the temperature while conducting a machining process are presented, and their advantages, limitations are discussed. The paper is prepared using reviews of the literatures.
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References
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Shi, H. (2018). Metal Cutting Theory. New Perspectives and New Approaches.
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De Chiffre, L. (1977). Mechanics of metal cutting and cutting fluid action. International Journal of Machine Tool Design and Research, 17(4), 225-234.
O‘ktamov, O. B., & Mardonov, U. T. (2023). Metal kesish jarayonida hosil bo ‘ladigan kesish harorati va uning hosil bo ‘lish sabablari [Cutting temperature and reasons for its formation during metal cutting]. Innovations in Technology and Science Education, 2(11), 212-217.
Umarov, E. O., & Mardonov, U. T. (2020). General characteristic of technological lubricating cooling liquids in metal cutting process. International Journal of Research in Advanced Engineering and Technology, 6(2), 01-03.
Pereira Guimaraes, B. M., da Silva Fernandes, C. M., Amaral de Figueiredo, D., Correia Pereira da Silva, F. S., & Macedo Miranda, M. G. (2022). Cutting temperature measurement and prediction in machining processes: comprehensive review and future perspectives. The International Journal of Advanced Manufacturing Technology, 120(5), 2849-2878.
Cichosz, P., Karolczak, P., & Waszczuk, K. (2023). Review of Cutting Temperature Measurement Methods. Materials, 16(19), 6365.
Abhang, L. B., and M. Hameedullah. "Chip-tool interface temperature prediction model for turning process." International Journal of Engineering Science and Technology 2.4 (2010): 382-393.
Korkut, Ihsan, Adem Acır, and Mehmet Boy. “Application of regression and artificial neural network analysis in modelling of tool–chip interface temperature in machining”. Expert Systems with Applications 38.9 (2011): 11651-11656.
O’Sullivan, D., and M. Cotterell. “Workpiece temperature measurement in machining” Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture 216.1 (2002): 135-139.
Bogdan P. Nedic, Milan D. Eric. “Cutting Temperature Measurement and Material Machinability”, Thermal Science, 18(1), 2014, pp. 259-268.
Umarov, E. O., & Mardonov, U. T. (2021). Methods for increasing the wear resistance of cutting tools. In Техника и технологии машиностроения (pp. 83-86).
Mardonov, U., Tuyboyov, O., Abdirakhmonov, K., & Tursunbaev, S. (2023). Mathematical approach to the flank wear of high-speed steel turning tool in diverse external cutting environments. International Journal, (14), 19.
Bjerke, A., Hrechuk, A., Lenrick, F., Markström, A., Larsson, H., Norgren, S., ... & Bushlya, V. (2021). Thermodynamic modeling framework for prediction of tool wear and tool protection phenomena in machining. Wear, 484, 203991.
Maruda, R. W., Krolczyk, G. M., Nieslony, P., Wojciechowski, S., Michalski, M., & Legutko, S. (2016). The influence of the cooling conditions on the cutting tool wear and the chip formation mechanism. Journal of Manufacturing processes, 24, 107-115.
Haddag, B., & Nouari, M. (2013). Tool wear and heat transfer analyses in dry machining based on multi-steps numerical modelling and experimental validation. Wear, 302(1-2), 1158-1170.
Figueiredo, A. A., Guimaraes, G., & Pereira, I. C. (2022). Heat flux in machining processes: a review. The International Journal of Advanced Manufacturing Technology, 120(5), 2827-2848.
Abukhshim, N. A., Mativenga, P. T., & Sheikh, M. A. (2006). Heat generation and temperature prediction in metal cutting: A review and implications for high speed machining. International Journal of Machine Tools and Manufacture, 46(7-8), 782-800.
Han, S., Faverjon, P., Valiorgue, F., & Joël, R. (2017). Heat flux density distribution differences in four machining processes of AlSi7 block: MQL drilling, tapping, reaming and dry milling. Procedia CIRP, 58, 61-66.
Umarov, E.O. (2019). Kesish nazariyasi va kesuvchi asboblar [Cutting theory and tools]. Fan va texnologiya, Tashkent, 302p.
Leonidas, E., Ayvar-Soberanis, S., Laalej, H., Fitzpatrick, S., & Willmott, J. R. (2022). A comparative review of thermocouple and infrared radiation temperature measurement methods during the machining of metals. Sensors, 22(13), 4693.
Astakhov, V. P., & Outeiro, J. (2019). Importance of temperature in metal cutting and its proper measurement/modeling. measurement in machining and tribology, 1-47.
Umarov, E. O., Mardonov, U. T., & Turonov, M. Z. (2021, January). Measurement of dynamic viscosity coefficient of fluids. In Euro-Asia Conferences (Vol. 1, No. 1, pp. 37-40).
Santos, M. C., Araújo Filho, J. S., Barrozo, M. A. S., Jackson, M. J., & Machado, A. R. (2017). Development and application of a temperature measurement device using the tool-workpiece thermocouple method in turning at high cutting speeds. The International Journal of Advanced Manufacturing Technology, 89, 2287-2298.
Shi, H. (2018). Metal Cutting Theory. New Perspectives and New Approaches.
Abukhshim, N. A., Mativenga, P. T., & Sheikh, M. A. (2006). Heat generation and temperature prediction in metal cutting: A review and implications for high speed machining. International Journal of Machine Tools and Manufacture, 46(7-8), 782-800.
De Chiffre, L. (1977). Mechanics of metal cutting and cutting fluid action. International Journal of Machine Tool Design and Research, 17(4), 225-234.
O‘ktamov, O. B., & Mardonov, U. T. (2023). Metal kesish jarayonida hosil bo ‘ladigan kesish harorati va uning hosil bo ‘lish sabablari [Cutting temperature and reasons for its formation during metal cutting]. Innovations in Technology and Science Education, 2(11), 212-217.
Umarov, E. O., & Mardonov, U. T. (2020). General characteristic of technological lubricating cooling liquids in metal cutting process. International Journal of Research in Advanced Engineering and Technology, 6(2), 01-03.
Pereira Guimaraes, B. M., da Silva Fernandes, C. M., Amaral de Figueiredo, D., Correia Pereira da Silva, F. S., & Macedo Miranda, M. G. (2022). Cutting temperature measurement and prediction in machining processes: comprehensive review and future perspectives. The International Journal of Advanced Manufacturing Technology, 120(5), 2849-2878.
Cichosz, P., Karolczak, P., & Waszczuk, K. (2023). Review of Cutting Temperature Measurement Methods. Materials, 16(19), 6365.
Abhang, L. B., and M. Hameedullah. "Chip-tool interface temperature prediction model for turning process." International Journal of Engineering Science and Technology 2.4 (2010): 382-393.
Korkut, Ihsan, Adem Acır, and Mehmet Boy. “Application of regression and artificial neural network analysis in modelling of tool–chip interface temperature in machining”. Expert Systems with Applications 38.9 (2011): 11651-11656.
O’Sullivan, D., and M. Cotterell. “Workpiece temperature measurement in machining” Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture 216.1 (2002): 135-139.
Bogdan P. Nedic, Milan D. Eric. “Cutting Temperature Measurement and Material Machinability”, Thermal Science, 18(1), 2014, pp. 259-268.
Umarov, E. O., & Mardonov, U. T. (2021). Methods for increasing the wear resistance of cutting tools. In Техника и технологии машиностроения (pp. 83-86).
Mardonov, U., Tuyboyov, O., Abdirakhmonov, K., & Tursunbaev, S. (2023). Mathematical approach to the flank wear of high-speed steel turning tool in diverse external cutting environments. International Journal, (14), 19.
Bjerke, A., Hrechuk, A., Lenrick, F., Markström, A., Larsson, H., Norgren, S., ... & Bushlya, V. (2021). Thermodynamic modeling framework for prediction of tool wear and tool protection phenomena in machining. Wear, 484, 203991.
Maruda, R. W., Krolczyk, G. M., Nieslony, P., Wojciechowski, S., Michalski, M., & Legutko, S. (2016). The influence of the cooling conditions on the cutting tool wear and the chip formation mechanism. Journal of Manufacturing processes, 24, 107-115.
Haddag, B., & Nouari, M. (2013). Tool wear and heat transfer analyses in dry machining based on multi-steps numerical modelling and experimental validation. Wear, 302(1-2), 1158-1170.
Figueiredo, A. A., Guimaraes, G., & Pereira, I. C. (2022). Heat flux in machining processes: a review. The International Journal of Advanced Manufacturing Technology, 120(5), 2827-2848.
Abukhshim, N. A., Mativenga, P. T., & Sheikh, M. A. (2006). Heat generation and temperature prediction in metal cutting: A review and implications for high speed machining. International Journal of Machine Tools and Manufacture, 46(7-8), 782-800.
Han, S., Faverjon, P., Valiorgue, F., & Joël, R. (2017). Heat flux density distribution differences in four machining processes of AlSi7 block: MQL drilling, tapping, reaming and dry milling. Procedia CIRP, 58, 61-66.
Umarov, E.O. (2019). Kesish nazariyasi va kesuvchi asboblar [Cutting theory and tools]. Fan va texnologiya, Tashkent, 302p.
Leonidas, E., Ayvar-Soberanis, S., Laalej, H., Fitzpatrick, S., & Willmott, J. R. (2022). A comparative review of thermocouple and infrared radiation temperature measurement methods during the machining of metals. Sensors, 22(13), 4693.
Astakhov, V. P., & Outeiro, J. (2019). Importance of temperature in metal cutting and its proper measurement/modeling. measurement in machining and tribology, 1-47.
Umarov, E. O., Mardonov, U. T., & Turonov, M. Z. (2021, January). Measurement of dynamic viscosity coefficient of fluids. In Euro-Asia Conferences (Vol. 1, No. 1, pp. 37-40).
Santos, M. C., Araújo Filho, J. S., Barrozo, M. A. S., Jackson, M. J., & Machado, A. R. (2017). Development and application of a temperature measurement device using the tool-workpiece thermocouple method in turning at high cutting speeds. The International Journal of Advanced Manufacturing Technology, 89, 2287-2298.
Published
2024-05-30
How to Cite
Ogabek Uktamov, Umidjon Mardonov, & Erkin Umarov. (2024). Analysis of Temperature in Metal Cutting and Its Measurement Methods. Central Asian Journal of Theoretical and Applied Science, 5(3), 118-121. Retrieved from https://cajotas.centralasianstudies.org/index.php/CAJOTAS/article/view/1460
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