The aim of article is to provide development of a unified assessment methodology in relation to various technological processes and the actual conditions of their implementation. To carry the energy efficiency analysis of the technological processes through comparison of the established power and the power consumed by the actual technological process during its implementation using real technological equipment, i.e. upon determining the integral ecological quality index of the machine-building technological fabrication processes. This allows to determine the impact of technological processes on the environment due to the energy losses and to implement this process under excessive currents. In this case, the integral ecological quality index is determined by the ratio of the fabrication power set by the technologist and the power consumed by the actual technological process during its implementation using the real technological equipment. The integral ecological quality index is specific due to the fact that it is formed not on with regard to statistical data; it is based on the energy characteristics of the implemented technological process with regard to the real state of equipment and related factors, which are important for assessing the ecological performance of the real technological process.

Drogui, P., Blais, J. F., & Mercier, G. (2007). Review of electrochemical technologies for environmental applications. Recent patents on engineering, 1(3), 257-272.

Duflou, J. R., Sutherland, J. W., Dornfeld, D., Herrmann, C., Jeswiet, J., Kara, S., & Kellens, K. (2012). Towards energy and resource efficient manufacturing: A processes and systems approach. CIRP Annals-Manufacturing Technology, 61(2), 587-609.

Fisher, A. J. (2002). System and method for recovering energy from an air compressor. U.S. Patent, 6,360,535.

Fluga, M. A. (2013). Energy efficient building construction. U.S. Patent, 8,590,262.

Ginko, V. I. (2013). Ecological risk in the risk management system. The world of scientific discovery. 7(43), 301-312.

Golubkov, U. V., & Ermolaeva, N. V. (2012). Isoprenoids in oil-based lubricating-cooling liquids. Chemistry and technology of fuels and oils, 1, 41-43.

Gordeeva, O. V., & Astafieva, E. V. (2014). On consideration and management of environmental risks in assessing the quality of project solutions. Problems of Environment and nature resources, 1, 39-40.

Gvozdkova, S. I. (2015). Analysis of methods of environmental safety provision by minimization of energy losses by the example of industrial vibration and noise. Ecology and industry in Russia, 19(3), 14 – 17.

Hamed, H. H. Aly, M. M. El-Arini, & Youssef, M. T. (2013). Proposed Voltage Ride through Compensators for Improving Power System Performance. International Journal of Energy and Power Engineering, 2(2), 29-36.

Huang, Lee Lisheng (2014). Methods of making energy efficient cookware. U.S. Patent, 8,806,737.

Ivanova, N. A, Ryabov, S. A., & Shvartsburg, L. E. (2014a). The functioning algorithm of the automatic control system of thehydrocarbons concentration during turning. MSTU Bulletin “Stankin”, 2(29), 57-62.

Ivanova, N. A., Ryabov, S. A., & Shvartsburg, L. E. (2014b). Evaluation, analysis and professional risk management in the field of production. Chief mechanical engineer, 12, 21-26.

Ivanova, N. A. & Ryabov, S. A. (2015). Purification of atmospheric emissions during the operation of the extrusion line. Monthly scientific and technical journal. Ecology and industry in Russia, 19(3), 10–13.

Kaufman, P. J., Marcia E. W., Lombardi, S. A. (2013). Discrete energy assignments for manufacturing specifications. U.S. Patent Application No. 12/429,821.

Li, Jian-Guang, Lu, Yong, Zhao, Hang, Li, Peng, & Yao, Ying-Xue, (2014). Optimization of cutting parameters for energy saving. The International Journal of Advanced Manufacturing Technology, 70(4), 117-124.

Ma, J., Ge, X., Chang, S. I., & Lei, S. (2014). Assessment of cutting energy consumption and energy efficiency in machining of 4140 steel. The International Journal of Advanced Manufacturing Technology, 74(12), 1701-1708.

Parik, E., & Otto, T. (2012). Monitoring of Energy Efficiency in Industrial Pneumatic Machines. Annals of DAAAM for 2012 & Proceedings of the 23rd International DAAAM Symposium, 63-67.

Peng, T & Xu, X. (2014). Energy-efficient machining systems: a critical review. The International Journal of Advanced Manufacturing Technology, 72(12), 1389-1406.

Salonitis, K., & Ball, P. (2013). Energy efficient manufacturing from machine tools to manufacturing systems. Procedia, 7, 634-639.

Shvartsburg, L. E., Ivаnоvа, N. A., Ryabov, S. A., & Zaborowski, T. (2014). Chemical contaminations in a process of polishing with an implementation of liquid LCTS. Life science journal, 11(10), 228-230.

Taber, William (2001). Large scale procurement of energy efficiency resources. U.S. Patent Application, 09/964,133.

Wahl, E., Vincke, K., & Himmelsbach, M. (2011). Recovery of Energy from a Laser Machining System. US Patent Application publication, US2011/0024401.

Yevstratov, I. V. (2012). Energy Efficiency as a factor improving the competitiveness of engineering products. Innovations and Investments, 4, 114-117.