Investigating the Effect of Cutting Condition on the Plastic Energy in Turning Process of AISI 1050
الموضوعات :
Mohammad Meghdad Fallah
1
,
Seyyed Reza Hamzeloo
2
1 - Mechanical Engineering Department, Shahid Rajaee Teacher Training University, Tehran, Iran
2 - Department of Mechanical Engineering,
Shahid Rajaee Teacher Training University, Iran
الکلمات المفتاحية: AISI, Tool Geometry, Turning Process, FE Simulation, Cutting Parameters, Plastic Energy,
ملخص المقالة :
Reducing energy consumption is a demanding issue considering the limited available energy resources and increasing environmental pollution. On the other hand, industry consumes a huge amount of energy, and manufacturing processes are the most energy consuming portions of the industry. Machining issues including cutting tool geometry and process parameters affect the cutting forces and also production consuming energy. By increasing cutting forces, the tool life would be reduced and therewith cost of machining process increases. In this work, the effect of machining condition on cutting force and energy consumption studied in turning process during validated FE analysis using ALE method. So, the effect of rake angle, tool edge radius and cutting speed was investigated on the cutting force, plastic strain and plastic consuming energy. Results proved that these parameters are effective on plastic energy consumption in turning process among them cutting speed has more effect on the plastic energy. By increasing the cutting speed, the plastic energy decreases considerably. Rake angle is also effective on process energy consumption and the combination of increasing the rake angle and cutting speed, and choosing the optimal edge radius leads to the minimized plastic energy.
[1] Duflou, J. R., et al., Towards Energy and Resource Efficient Manufacturing: A Processes and Systems Approach, CIRPAnn Manuf Technol, Vol. 61. No.2, 2012, pp. 587-609.
[2] Yuan C, Zhai Q and Dornfeld D. A three dimensional system approach for environmentally sustainable manufacturing. CIRPAnn Manuf Technol, Vol. 61, No. 1, 2012, pp. 39-42.
[3] Neugebauer, R., et al., Influence Exerted by Tool Properties on the Energy Efficiency During Drilling and Turning Operations, CIRP J. Manuf Sci. Technol, Vol. 4, 2011, pp. 161-169.
[4] Oda, Y., et al., Study of Optimal Cutting Condition for Energy Efficiency Improvement in Ball End Milling with Tool-Workpiece Inclination, CIRPAnn Manuf Technol, Vol. 61, 2012, pp. 119-122.
[5] Rajemi, M. F., Mativenga, P. T., and Aramcharoen, A., Sustainable Machining: Selection of Optimum Turning Conditions Based on Minimum Energy Considerations, Journal of Cleaner Production, Vol. 18, 2010, pp. 1059-1065.
[6] Zhao, G., et al., Energy Consumption Characteristics Evaluation Method in Turning, Advances in Mechanical Engineering, Vol. 8, No. 11, 2016, pp. 1-8.
[7] Riefa, M., Karpuschewskib, B., and Kalhöfera, E., Evaluation and Modeling of the Energy Demand During Machining, CIRP Journal of Manufacturing Science and Technology, Available Online 20 June 2017, In Press, Corrected Proof.
[8] Balogun, V. A., Edemb, I. F., Optimum Swept Angle Estimation Based on the Specific Cutting Energy in Milling AISI 1045 Steel Alloy, International Journal of Engineering, Vol. 30, No. 4, 2017, pp. 591-596.
[9] Davim, J. P., Maranhão, C., A Study of Plastic Strain and Plastic Strain Rate in Machining of Steel AISI 1045 Using FEM Analysis, Materials and Design, Vol. 30, 2009, pp. 160-165.
[10] Grzesik, W., Advanced Machining Processes of Metallic Materials: Theory, Modelling and Applications, Elsevier Science 2008, Oxford.
[11] Ma, J., Ge, X., Chang, S. I., and Lei, S., Assessment of Cutting Energy Consumption and Energy Efficiency in Machining of 4140 Steel, Int J. Adv Manuf Technol, Vol. 74, 2014, pp. 1701-1708.
[12] Tuğrul, Ö., Erol, Z., Finite Element Analysis of the Influence of Edge Roundness on the Stress and Temperature Fields Induced by High-Speed Machining, Int. J. Adv. Manuf. Technol., Vol. 35, No. 3-4, 2007, pp. 255-267.
[13] Duan, C. Z., et al., Finite Element Simulation and Experiment of Chip Formation Process During High Speed, Int. J. of Recent Trends in Engineering, Vol. 1, No. 5, 2010, pp. 46-50.
[14] Seshadri, R., et al., Finite Element Simulation of the Orthogonal Machining Process with Al 2024 T351 Aerospace Alloy, Procedia Engineering, Vol. 64, 2013, pp. 1454-1463.
[15] Umbrello, D., Finite Element Simulation of Conventional and High Speed Machining of Ti6Al4V Alloy, Journal of Materials Processing Technology, Vol. 196, No. 1-3, 2008, pp. 79-87.
[16] Erick, O., et al., Mechinery's Handbook, 28th Edition, Industrial Press Inc. 2008, New York.
[17] Sandeep, B., Survase, P., Darade, D., and Ganesh, K., Numerical and Experimental Analysis of Tool Wear in Orthogonal Cutting, International Engineering Research Journal, Vol. 2, 2015, pp. 2895-2899.
[18] Asad, M., Mabrouki, T., Ijaz, H., Aurangzeb Khan, M., and Saleem, W., On the Turning Modeling and Simulation: 2D and 3D FEM Approaches, Mechanics & Industry, Vol. 15, 2014, pp. 427-434.
[19] Abdelali, H. B., et al., Identification of a Friction Model at the Tool-Chip-Workpiece Interface in Dry Machining of a AISI 1045 Steel with a TiN Coated Carbide Tool, Journal of Tribology, Vol. 133, No. 4, 2011, pp. 042201.
[20] Rech, J., et al., Characterisation of Friction and Heat Partition Coefficients at the Tool-Work Material Interface in Cutting, CIRP Annals, Vol. 62, No. 1, 2013, pp. 79-82.
[21] Chowdhury, M. A., et al., Estimation of the Friction Coefficient in Turning Process of Metals Through Model Experiment, Proceedings of the Institution of Mechanical Engineers, Part J: Journal of Engineering Tribology, Vol. 232, No. 6, 2018, pp. 685-692.
[22] Zhou, L., et al., Energy Consumption Model and Energy Efficiency of Machine Tools: A Comprehensive Literature Review, J. Clean Prod., Vol. 112, No. 5, 2016, pp. 3721-3734.
[23] Gutowski, T., et al., Electrical Energy Requirements for Manufacturing Process. Proceedings of 13th CIRP International Conference on Life Cycle Engineering, 2006, pp. 623-627.
