Characterizing the effect of process variables on energy consumption in end milling
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Manufacturing processes, such as machining, transform raw materials into finished goods, and these processes consume significant energy. There is an increasing concern about the energy required for such processes and the environmental consequences attributable to the generation of the energy. Reducing the energy required to perform machining operations will not only reduce the environmental footprint, but also provide economic benefits. To that end, the effects of cutting conditions (e.g., feed and speed) and tool geometry (diameter and number of teeth) on the power required for an end milling operation are investigated experimentally. Experimental results are presented from a cutting mechanism perspective with the goal of understanding the role of the process variables. The specific cutting energy (SCE) is found decreasing when material removal rate increases, but there is substantial variation about the general trend. In essence, the cutting parameters and the tool geometry influenced the changes of average chip thickness and cutting speed, which cause the shear deformation energy changes and eventually collectively influence the SCE’s change. Based on the experiments, suggestions on selecting process parameters are provided to improve milling energy efficiency.
KeywordsSpecific cutting energy Average chip thickness Energy efficiency of milling Green manufacturing
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Magdalene Jackson is thanked for providing valuable insight and advice.
Research of this paper is supported by the National Natural Science Foundation of China (NO. 51675314) and Project from Ministry of Industry and Information Technology of China (No. NO.201656261-1-3).
- 1.International Energy Agency (IEA) (2016) World energy outlook special report 2016 : energy and air pollution. http://www.iea.org/publications/freepublications/publication/WorldEnergyOutlookSpecialReport2016EnergyandAirPollution.pdf. Accessed 23 Aug 2018
- 2.Gutowski T, Dahmus J, Thiriez A (2006) Electrical energy requirements for manufacturing processes. In: Proceedings of 13th CIRP international conference on life cycle engineering. Leuven, Belgium, pp 5–11Google Scholar
- 6.Cook NH (1966) Manufacturing analysis, 1st edn. Addison-Wesley Publishing Company, Boston, pp 36–38Google Scholar
- 8.Shaw MC (2004) Metal cutting principles, 2nd edn. Oxford University Press, OxfordGoogle Scholar
- 15.Martellotti ME (1945) An analysis of the milling process: part II-down milling. Trans Am Soc Mech Eng 67:223–251Google Scholar
- 20.Endres WJ, DeVor RE, Kapoor SG (1995). A dual-mechanism approach to the prediction of machining forces, part 1: Model development. J Manuf Sci E-T ASME 117(4):526–533Google Scholar
- 23.Shen Z, Sun X, Liu G, Chen M (2007) The milling mechanism of Ti6Al4V based on average cutting thickness. J Shanghai Jiaotong U 41(4):614–618 (in Chinese)Google Scholar
- 26.Johnson GR, Cook WH (1983) A constitutive model and data for metals subjected to large strains, high strain rates and high temperatures. In Proceedings of the 7th International Symposium on Ballistics 21(1):541–547Google Scholar