The Development of a Feeding Device for a Cooling Lubricant Technological Tool with Automatic Temperature Control System
| Authors: Yakovlev А.А., Shostenko S.V., Borisko S.N., Postupaeva S.G. | Published: 14.08.2019 |
| Published in issue: #8(713)/2019 | |
| Category: Mechanical Engineering and Machine Science | Chapter: Technology and Equipment for Mechanical and Physico-Technical Processing | |
| Keywords: cooling lubricant technological tool, physical principle of action, technical solution, expert review, control system, cooling device |
The article presents a feeding device designed for a cooling lubricant technological tool and an automatic control system for controlling the temperature mode of parts when milling. The device implements a new method of separate cooling and lubrication of the cutting area with sprayed liquid and ionized gas. To develop the device, an engineering-physical search design method is used, which makes it possible to obtain a set of possible options of technical solutions for the desired device and determine the most promising options for the design implementation. The method is based on constructing a model of the physical principle of operation using application software. The design of the new device is developed, mathematical modeling is performed, and the parameters of the transfer function of the automatic temperature control system are calculated. The proposed device can increase the efficiency of machining when milling workpieces and make a significant improvement to working conditions by reducing the content of harmful impurities in the air.
References
[1] Sakayeva E.Kh., Rudakova L.V., Shchuklina L.M. Microbiological Assessment of the Level of Potting Soil Contamination in Urban Areas of Metal Cutting Oils. Ecology and Industry of Russia, 2018, vol. 22, no. 10, pp. 34–37 (in Russ.).
[2] Grigor’yev L.N., Shanova O.A., Orevinina A.E. Assessment of Resource and Energy Conservation Level for Technologies related to Emissions and Emptying Treatment, and Waste Handling. Safety in Technosphere, 2017, vol. 6, no. 6, pp. 54–60 (in Russ.), doi: https://doi.org/10.12737/article_5af029c462cd67.51343889
[3] Mel’nikova D.V., Volkov D.A. Analysis of toxicological influence of lubricoolants in industrial enterprises on human organism and environment. Fundamental research, 2014, no. 11–7, pp. 1555–1559 (in Russ.). Available at: http://www.fundamental-research.ru/ru/article/view?id=35806 (accessed 02 December 2019).
[4] Vasenina I.V., Sushko V.A. Industrial Ecology of the Region and Quality of Life of the Local Population. Ecology and Industry of Russia, 2018, vol. 22, no. 11, pp. 66–71 (in Russ.).
[5] Khudobin L.V., Babichev A.P., Bulyzhev E.M. Smazochno-okhlazhdayushchiye tekhnologicheskiye sredstva i ikh primeneniye pri obrabotke rezaniyem: spravochnik [Lubricating and cooling technological tools and their use in cutting: a reference book]. Moscow, Mashinostroyeniye publ., 2006. 543 p.
[6] Kirillov A.K., Mosiychuk M.M. Development of high efficiency technology of dry turning products from special materials. Vestnik MSTU Stankin, 2017, no. 4(43), pp. 28–32 (in Russ.).
[7] Yakovlev A.A., Trukhanov V.M., Yakovleva E.V. Sposob podachi smazochno-okhlazhdayushchikh tekhnologicheskikh sredstv [The method of supplying coolant technology]. Patent RF no. 2367556, 2009. 5 p.
[8] Norenkov I.P. Osnovy avtomatizirovannogo proyektirovaniya [Basics of computer aided design]. Moscow, Bauman Press, 2009. 430 p.
[9] Korobeynikov A.G., Fedosovsky M.E., Zharinov I.O., Shukalov A.V., Gurjanov A.V., Zharinov I.O., Shukalov A.V. Development of conceptual modeling method to solve the tasks of computer-aided design of difficult technical complexes on the basis of category theory. International Journal of Applied Engineering Research, 2017, vol. 12, no. 6, pp. 1114–1122.
[10] Khabarov V.V., Shutaleva N.S., Kostin V.I. Information System for Design Enterprises. Information technologies, 2018, vol. 24, no. 4, pp. 256–265 (in Russ.), doi: 10.17587/it.24.256-265
[11] Sobolev A.N., Nekrasov A.Y. CAD/CAE modeling of Maltese cross mechanisms in machine tools. Russian Engineering Research, 2016, vol. 36, no. 4, pp. 300–302, doi: 10.3103/S1068798X16040183
[12] Papageorgiou E., Hakki Eres M., Scanlan J. Value modelling for multi-stakeholder and multi-objective optimization in engineering design. Journal of Engineering Design, 2016, vol. 27, iss. 10, pp. 697–724, doi: 10.1080/09544828.2016.1214693
[13] Nam G., Park J., Kim S. Conceptual design of passive containment cooling system for APR-1400 using multipod heat pipe. Nuclear Technology, 2015, vol. 189, no. 3, pp. 278–293, doi: 10.13182/NT13-121
[14] Yakovlev A.A. Razrabotka mnozhestv tekhnicheskikh resheniy ustanovok dlya preobrazovaniya energii [Development of a set of technical solutions for energy conversion plants]. Moscow, Mashinostroyeniye-1 publ., 2007. 128 p.
[15] Yakovlev A.A. Development of the matrix of technical solutions for energy converters and the algorithm for generating lists of functionally compatible structural elements. Handbook. An Engineering journal with appendix, 2007, no. 10, pp. 34–39 (in Russ.).
[16] Yakovlev A.A., Yakovleva E.V. Avtomatizatsiya sinteza i vybora tekhnicheskikh resheniy preobrazovateley energii. Informatsionnyye tekhnologii, 2010, no. 11, pp. 71–78.
[17] Yakovlev A.A., Kamayev V.A., Sorokin V.S., Mishuchstina S.N. Search Engine Design Systems Cooling Based Engineering and Physical Approach. Information technologies, 2016, vol. 22, no. 11, pp. 819–826 (in Russ.).
[18] Yakovlev A.A., Mishuchstina S.N., Sorokin V.S., Mishuchstin O.A. Ustroystvo dlya podachi smazochno-okhlazhdayushchego tekhnologicheskogo sredstva [Device for supplying coolant technology]. Patent RF no. 154326, 2015. 9 p.
[19] Kim D.P. Teoriya avtomaticheskogo upravleniya. T. 1. Lineynyye sistemy [The theory of automatic control. Vol. 1. Linear systems]. Moscow, FIZMATLIT publ., 2007. 312 p.
[20] Teoriya avtomaticheskogo upravleniya [Automatic control theory]. Ed. Savin M.M., Elsukov V.S., Pyatina O.N., Lachin V.I. Rostov-on-Done, Feniks publ., 2007. 469 p.
