Abstract
The analysis of equations for determining the grinding temperature taking into account the curvature of the grinding profile, is performed. Mathematical models of the temperature field were proposed, which makes it possible to identify the influence of the curvature radius of the surface to be ground on the grinding temperature in the range from a semicircular profile to a linear one as the radius of the semicircular profile tends to infinity. The variation range of the curvature radius is established, in which the curvature of the profile being ground can be neglected when calculating the grinding temperature. The influence of the profile curvature radius on the maximum grinding temperature was established using both direct calculating and computer simulating of the temperature field by the analytical model and the finite element method (FEM), respectively. Grinding temperature FEM simulation results differ by no more than 0.5% compared to the analytical model under otherwise similar conditions. It is established that the FEM simulation is more suitable due to its greater sophistication, which makes it possible considering the individual geometric features of the surface to be ground as well as any instantaneous distribution of the heat flux in the grinding zone. At the same time, an analytical model for direct calculating of the grinding temperature takes much less time to get a result and can be used in computer monitoring and grinding diagnosing of subsystems on CNC machines.
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References
Larshin, V., Lishchenko, N.: Gear grinding system adapting to higher CNC grinder throughput. MATEC Web Conf. 226, 04033 (2018)
Larshin, V., Lishchenko, N.: Adaptive profile gear grinding boosts productivity of this operation on the CNC machine tools. In: Ivanov, V., et al. (eds.) CONFERENCE 2019, LNME, pp. 79–88. Springer, Cham (2019)
Deivanathan, R., Vijayaraghavan, L.: Theoretical analysis of thermal profile and heat transfer in grinding. Int. J. Mech. Mater. Eng. (IJMME) 8(1), 21–31 (2013)
Tan, J., Jun, Y., Siwei, P.: Determination of burn thresholds of precision gears in form grinding based on complex thermal modelling and Barkhausen noise measurements. Int. J. Adv. Manuf. Technol. 88(1–4), 789–800 (2017)
Jun, Y., Ping, L.: Temperature distributions in form grinding of involute gears. Int. J. Adv. Manuf. Technol. 88(9–12), 2609–2620 (2017)
González-Santander, J.L.: Maximum temperature in dry surface grinding for high Peclet number and arbitrary heat flux profile. Hindawi Publishing Corporation Mathematical Problems in Engineering, pp. 1–9 (2016)
Foeckerer, T., Zaeh, M., Zhang, O.: A three-dimensional analytical model to predict the thermo-metallurgical effects within the surface layer during grinding and grind-hardening. Int. J. Heat Mass Transf. 56, 223–237 (2013)
Lishchenko, N., Larshin, V.: Comparison of measured surface layer quality parameters with simulated results. Appl. Aspects Inf. Technol. 2(4), 304–316 (2019)
Zhang, L.: Numerical analysis and experimental investigation of energy partition and heat transfer in grinding. In: Salim Newaz Kazi, M. (eds.) Heat Transfer Phenomena and Applications, Sense Publishers, Rotterdam, The Netherlands (2012)
Tahvilian, A.M., Champliaud, H., Liu, Z., Hazel, B.: Study of workpiece temperature distribution in the contact zone during robotic grinding process using finite element analysis. In: 8th CIRP Conference on Intelligent Computation in Manufacturing Engineering, Ischia, Italy, pp. 205–210 (2013)
Li Hao, N., Axinte, D.: On a stochastically grain-discretised model for 2D/3D temperature mapping prediction in grinding. Int. J. Mach. Tools Manuf 116, 1–27 (2017)
Jermolajev, S., Epp, J., Heinzel, C., Brinksmeier, E.: Material modifications caused by thermal and mechanical load during grinding. In: 3rd CIRP Conference on Surface Integrity (CIRP CSI) (2016). Procedia CIRP 45, 43–46
Jermolajev, S., Brinksmeier, E., Heinzel, C.: Surface layer modification charts for gear grinding. CIRP Ann. Manuf. Technol. 67(1), 333–336 (2018)
Heinzel, C., Sölter, J., Jermolajev, S., Kolkwitz, B., Brinksmeier, E.: A versatile method to determine thermal limits in grinding. In: 2nd CIRP Conference on Surface Integrity (CSI) (2014). Procedia CIRP, vol. 13, pp. 131–136
Vrkoslavová, L., Louda, P., Malec, J.: Analysis of surface integrity of grinded gears using Barkhausen noise analysis and X-ray diffraction. In: 40th Annual Review of Progress in Quantitative Nondestructive Evaluation APP Conference Proceedings, vol. 1581, pp. 1280–1281 (2014)
Crow, J.R., Michael, A.: Pershing standard samples for grinder burn etch testing. Gear Technology, pp. 54–56 (2018)
Zaborowski, T., Ochenduszko, R.: Grinding burns in the technological surface of the gear teeth of the cylindrical gears. MECHANIK NR 90, 880–884 (2017)
de Lima, A., Gâmbaro, L.S., Junior, M.V., Baptista, E.B.: The use of cylindrical grinding to produce a martensitic structure on the surface of 4340 steel. J. Braz. Soc. Mech. Sci. Eng. 33, 34–40 (2011)
Rena, X., Hu, H.: Analysis on the temperature field of gear form grinding. Appl. Mech. Mater. 633–634, 809–812 (2014)
Beizhi, L., Dahu, Z., Zhenxin, Z., Qiang, Z., Yichu, Y.: Research on workpiece surface temperature and surface quality in high-speed cylindrical grinding and its inspiration. Adv. Mater. Res. 325, 19–27 (2011)
Lishchenko, N., Larshin, V.: Gear-grinding temperature modeling and simulation. In: Radionov, A., et al. (eds.) Proceedings of the 5th International Conference on Industrial Engineering (ICIE 2019), vol. 2, pp. 289–297. Springer (2019)
Yadav, R.K.: Analysis of grinding process by the use of finite element methods. ELK Asia Pacific J. Manuf. Sci. Eng. 1(1), 35–42 (2014)
Linke, B., Duscha, M., Vu, A.T., Klocke, F.: FEM-based simulation of temperature in speed stroke grinding with 3D transient moving heat sources. Adv. Mater. Res. 223, 733–742 (2011)
Sharma, C., Ghosh, S., Talukdar, P.: Finite element analysis of workpiece temperature during surface grinding of inconel 718 alloy. In: 5th International & 26th All India Manufacturing Technology, Design and Research Conference, IIT Guwahati, Assam, India, pp. 420-1–420-6 (2014)
Patil, P., Patil, C.: FEM simulation and analysis of temperature field of environmental friendly MQL grinding. In: Proceedings of the International Conference on Communication and Signal Processing 2016 (ICCASP 2016), pp. 182–186 (2017)
Lishchenko, N., Larshin, V.: Temperature models for grinding system state monitoring. Appl. Aspects Inf. Technol. 2(3), 216–229 (2019)
Chen, X., Öpöz, T.: Effect of different parameters on grinding efficiency and its monitoring by acoustic emission. Prod. Manuf. Res. Open Access J. 4(1), 190–208 (2016)
Carslaw, H.S., Jaeger, J.C.: Conduction of Heat in Solids, 2nd edn. Oxford University Press, Oxford (1959)
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Lishchenko, N., Larshin, V., Uminsky, S. (2020). Finite Element Analysis of Profile Grinding Temperature. In: Ivanov, V., Trojanowska, J., Pavlenko, I., Zajac, J., Peraković, D. (eds) Advances in Design, Simulation and Manufacturing III. DSMIE 2020. Lecture Notes in Mechanical Engineering. Springer, Cham. https://doi.org/10.1007/978-3-030-50794-7_41
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