Development of a digital model for cooling efficiency of metal working fluids in machining

Umidjon Mardonov; O. A. Khasanov; D. D. Norkhurozov; A. A. Khushmuhammadov

Authors

Umidjon Mardonov Tashkent State Technical University named after Islam Karimov https://orcid.org/0000-0003-3327-1846
O. A. Khasanov Tashkent State Technical University named after Islam Karimov
D. D. Norkhurozov Tashkent State Technical University named after Islam Karimov
A. A. Khushmuhammadov Tashkent State Technical University named after Islam Karimov

Keywords:

cutting temperature, digital model, heart dissipation, heat transfer, machining, metal working fluid, process digitalization

Abstract

In this manuscript, cutting temperature generated in machining process, it’s sources and dissipation directions are studied. Energy consumption in metal cutting process and metal working fluids have taken as an object of the study. Moreover, the effect of metal working fluids in heat dissipation process and the importance of their cooling capacity is theoretically researched. As a result of the study, dependence model of temperature gradient between cutting face and fluid on fluid’s density and viscosity is mathematically developed. The developed digital model gives an easy way to predict metal working fluid’s cooling capacity before it’s use. It can be concluded that the reduction cutting fluids’ viscosity causes an increase in the cooling capacity of the fluids while high dense fluids show a better cooling capacity.

References

[1] Reznikov AN, Reznikov LA, Teplovыe protsessы v texnologicheskix sistemax [Thermal processes and technological systems]. Moscow: Mashinastroeniya; 1990, 288p.

[2] Özel T. The influence of friction models on finite element simulations of machining. International journal of machine tools and manufacture. 2006; 46(5): pp. 518-530. https://doi.org/10.1016/j.ijmachtools.2005.07.001

[3] Kuram E, Simsek BT, Ozcelik B, Demirbas E, Askin S, Optimization of the Cutting Fluids and Parameters Using Taguchi and ANOVA in Milling. Proceedings of the World Congress on Engineering, Vol II, 2010.

[4] Usmonov KB. Metall kesish asoslari [Metal cutting theory]. Toshkent, Oqituvchi, 2004, 160p.

[5] Kuntoğlu M. Tool Flank Wear Analysis for MQL Assisted Milling of Strenx 1100 Structural Steel. Avrupa Bilim Teknol. Derg. 2021, pp. 629–635. https://doi.org/10.31590/ejosat.938234

[6] Tóth, M., Brown, A., Cross, E., Rogers, T., & Sims, N. D. (2023). Resource-efficient machining through physics-informed machine learning. Procedia CIRP, 117, 347-352. https://doi.org/10.1016/j.procir.2023.03.059

[7] Du Preez, A., & Oosthuizen, G. A. (2019). Machine learning in cutting processes as enabler for smart sustainable manufacturing. Procedia Manufacturing, 33, 810-817. https://doi.org/10.1016/j.promfg.2019.04.102

[8] Soori, M., Behrooz, A., & Dastre, R. (2023). Machine Learning and Artificial Intelligence in CNC Machine Tools: A Review. Sustainable Manufacturing and Service Economics, 2, Article ID: 100009. https://doi.org/10.1016/j.smse.2023.100009

[9] Yıldırım, ÇV. Experimental comparison of the performance of nanofluids, cryogenic and hybrid cooling in turning of Inconel 625. Tribol. Int. 2019, 137, pp. 366–378. https://doi.org/10.1016/j.triboint.2019.05.014

[10] Sun Y, Ma L, Jia J, Tan Y, Qi S, Tang B, ... & Zhou Y. The generation mechanism of cutting heat and the theoretical prediction model for temperature on the rake face of the cutting tool in Zirconia ceramics. Journal of Manufacturing Processes. 2024; 132: pp. 584-597. https://doi.org/10.1016/j.jmapro.2024.11.013

[11] Astakhov VP, Outeiro J. (2019). Importance of Temperature in Metal Cutting and Its Proper Measurement/Modeling. In: Davim, J. (eds) Measurement in Machining and Tribology. Materials Forming, Machining and Tribology. Springer, Cham. https://doi.org/10.1007/978-3-030-03822-9_1

[12] Reznikov AN. Teoreticheskie osnovы aktivnogo oxlajdeniya instrumentov [Theoretical foundations of active cooling of instruments]. In: Kuybishev KAI, Machinability of heat-resistant and titanium alloys//Proceedings of the All-Union Inter-university Conference, 1962, pp. 247-260.

[13] Erkin U., Umidjon M., Umida S. Application of Magnetic Field on Lubricating Cooling Technological Condition in Metal Cutting Process // In International Conference on Reliable Systems Engineering. Springer, Cham, 2021, September. - pp. 100-106.

[14] Pastunova VA, Sladkova TA, Shpinkov VA. Opit vnedreniya novix smazochno-oxlajdayushix jidkostey [Experience of implementation of new cutting fluids]//Obrabotka konstruksionnix materialov rezaniem s primeneniem SOJ; MDNTP, 1978; pp. 34-38.

[15] Umarov TU, Mardonov UT. General characteristic of technological lubricating cooling liquids in metal cutting process. International Journal of Research in Advanced Engineering and Technology, 2020, 6(2), pp. 01-03.

[16] Erkin U, Umidjon M, & Umida S. Application of Magnetic Field on Lubricating Cooling Technological Condition in Metal Cutting Process. In International Conference on Reliable Systems Engineering. Springer, Cham, 2021, September, pp. 100-106. https://doi.org/10.1007/978-3-030-83368-8_10

[17] Kiselyov YeS, Unyashin AN, Kurganova SZ. Texnologicheskaya effektivnost sovremennыx SOJ dlya lezviynoy obrabotki [Technological efficiency of modern cutting fluids for blade processing]. STIN. 1995; 1: pp. 22-25.

[18] Entelisa ST, Berlinera EM. Smazochno-oxlajdayuщie texnologicheskie sredstva dlya obrabotki metallov rezaniem [Lubricating and cooling technological means for metal cutting]. handbook, 2nd ed. Moscow: Mashinostroenie; 1995. 496p.

Development of a digital model for cooling efficiency of metal working fluids in machining

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