Sustainable development will become importance issues for many fields, including production, industry, and
manufacturing. In order to achieve sustainable development, industry should be able to perform of sustainable
production processes and environmentally friendly. Therefore, there is need to minimize the energy demand in the
machining process. This paper presents a calculation method of energy consumption in the machining process,
especially turning process which calculated by summing the number of energy consumption, such as the electric energy
consumed during the machining preparation, the electrical energy during the cutting processes, and the electrical energy
to produce a cutting tool. A case study was performed on dry turning of AISI 1045 steel using uncoated carbide. This
approach can be used to determine the total amount of electrical energy consumed and material removal rate (MRR) in
the specific machining process. It concluded that the energy consumption will be an increase for using the high cutting
speed as well as for the feed rate was increased.

Hanafi, I., Khamlichi, A., Cabrera, F. M., Almansa, E., & Jabbouri, 2012. Optimization of cutting conditions for

sustainable machining of peek cf30 using tin tools, Journal of Cleaner Production, No. 28.

Park, C.-W., Kwon, K.-S., Kim, W.-B., Min, B.-K., Park, S.-J., Sung, I.-H., et al., 2009. Energy consumption reduction

technology in manufacturing — A selective review of policies, standards, and research," International Journal of

Precision Engineering and Manufacturing, Vol. 10, hal 151-173

Rajemi, M. F., Mativenga, P. T., & Aramcharoen, A., 2010. Sustainable machining: selection of optimum turning

conditions based on minimum energy considerations, Journal of Cleaner Production, Vol. 18, hal. 1059-1065.

P. F. Chapman, 1974. Energy costs: A review of methods, Energy Policy, Vol. 2, hal. 91-103.

He, Y., Liu, B., Zhang, X., Gao, H., & Liu, X., 2012. A modeling method of task-oriented energy consumption for

machining manufacturing system, Journal of Cleaner Production, No. 23, hal. 167-174.

Sarwar, M., Persson, M., Hellbergh, H., & Haider, J., 2009 Measurement of specific cutting energy for evaluating the

efficiency of bandsawing different workpiece materials, International Journal of Machine Tools and Manufacture, No.

, hal. 958-965.

Mori, M., Fujishima, M., Inamasu, Y., & Oda, Y., 2011. A study on energy efficiency improvement for machine tools,

CIRP Annals - Manufacturing Technology, No. 60, hal. 145-148.

Diaz, N., Redelsheimer, E., & Dornfeld, D., 2011. Energy Consumption Characterization and Reduction Strategies for

Milling Machine Tool Use, Proceeding of the 18th CIRP International Conference on Life Cycle Engineering, hal.

-267.

P. T. Mativenga and M. F. Rajemi, 2011. Calculation of optimum cutting parameters based on minimum energy

footprint, CIRP Annals - Manufacturing Technology, No.60, hal. 149-152.

R. Nur, M.Y. Noordin , S.Izman, D. Kurniawan, 2014. The Effect of Cutting Parameters on Power Consumption during

Turning Nickel Based Alloy, Advanced Materials Research, Vol. 845, hal. 799-802.

Gutowski, T., Dahmus, J., & Thiriez, A., 2006. Electrical Energy Requirements for Manufacturing Processes, 13th

CIRP International Conference on Life Cycle Engineering, 31 May – 2 June 2006.

R. A. Walsh, 2001. Handbook of Machining and Metalworking Calculations: McGraw-Hill Professional.

Calvanese M, Albertelli P, Matta A, Taisch M., 2013.Analysis of Energy Consumption in CNC Machining Centers and

Determination of Optimal Cutting Conditions. In: Nee AYC, Song B, Ong S-K, editors. Re-engineering

Manufacturing for Sustainability: Springer Singapore, hal. 227-232.

Camposeco-Negrete C., 2013. Optimization of cutting parameters for minimizing energy consumption in turning of AISI

T6 using Taguchi methodology and ANOVA. Journal of Cleaner Production, hal. 1- 9.

Nur, R., Noordin, M., Izman, S., & Kurniawan, D. 2015. Machining parameters effect in dry turning of AISI 316L

stainless steel using coated carbide tools. Proceedings of the Institution of Mechanical Engineers, Part E: Journal of

Process Mechanical Engineering, hal. 1-8.