Vol. 27 No. 1 2025 3 EDITORIAL COUNCIL EDITORIAL BOARD EDITOR-IN-CHIEF: Anatoliy A. Bataev, D.Sc. (Engineering), Professor, Rector, Novosibirsk State Technical University, Novosibirsk, Russian Federation DEPUTIES EDITOR-IN-CHIEF: Vladimir V. Ivancivsky, D.Sc. (Engineering), Associate Professor, Department of Industrial Machinery Design, Novosibirsk State Technical University, Novosibirsk, Russian Federation Vadim Y. Skeeba, Ph.D. (Engineering), Associate Professor, Department of Industrial Machinery Design, Novosibirsk State Technical University, Novosibirsk, Russian Federation Editor of the English translation: Elena A. Lozhkina, Ph.D. (Engineering), Department of Material Science in Mechanical Engineering, Novosibirsk State Technical University, Novosibirsk, Russian Federation The journal is issued since 1999 Publication frequency – 4 numbers a year Data on the journal are published in «Ulrich's Periodical Directory» Journal “Obrabotka Metallov” (“Metal Working and Material Science”) has been Indexed in Clarivate Analytics Services. Novosibirsk State Technical University, Prospekt K. Marksa, 20, Novosibirsk, 630073, Russia Tel.: +7 (383) 346-17-75 http://journals.nstu.ru/obrabotka_metallov E-mail: metal_working@mail.ru; metal_working@corp.nstu.ru Journal “Obrabotka Metallov – Metal Working and Material Science” is indexed in the world's largest abstracting bibliographic and scientometric databases Web of Science and Scopus. Journal “Obrabotka Metallov” (“Metal Working & Material Science”) has entered into an electronic licensing relationship with EBSCO Publishing, the world's leading aggregator of full text journals, magazines and eBooks. The full text of JOURNAL can be found in the EBSCOhost™ databases.
OBRABOTKAMETALLOV Vol. 27 No. 1 2025 4 EDITORIAL COUNCIL EDITORIAL COUNCIL CHAIRMAN: Nikolai V. Pustovoy, D.Sc. (Engineering), Professor, President, Novosibirsk State Technical University, Novosibirsk, Russian Federation MEMBERS: The Federative Republic of Brazil: Alberto Moreira Jorge Junior, Dr.-Ing., Full Professor; Federal University of São Carlos, São Carlos The Federal Republic of Germany: Moniko Greif, Dr.-Ing., Professor, Hochschule RheinMain University of Applied Sciences, Russelsheim Florian Nürnberger, Dr.-Ing., Chief Engineer and Head of the Department “Technology of Materials”, Leibniz Universität Hannover, Garbsen; Thomas Hassel, Dr.-Ing., Head of Underwater Technology Center Hanover, Leibniz Universität Hannover, Garbsen The Spain: Andrey L. Chuvilin, Ph.D. (Physics and Mathematics), Ikerbasque Research Professor, Head of Electron Microscopy Laboratory “CIC nanoGUNE”, San Sebastian The Republic of Belarus: Fyodor I. Panteleenko, D.Sc. (Engineering), Professor, First Vice-Rector, Corresponding Member of National Academy of Sciences of Belarus, Belarusian National Technical University, Minsk The Ukraine: Sergiy V. Kovalevskyy, D.Sc. (Engineering), Professor, Vice Rector for Research and Academic Aff airs, Donbass State Engineering Academy, Kramatorsk The Russian Federation: Vladimir G. Atapin, D.Sc. (Engineering), Professor, Novosibirsk State Technical University, Novosibirsk; Victor P. Balkov, Deputy general director, Research and Development Tooling Institute “VNIIINSTRUMENT”, Moscow; Vladimir A. Bataev, D.Sc. (Engineering), Professor, Novosibirsk State Technical University, Novosibirsk; Vladimir G. Burov, D.Sc. (Engineering), Professor, Novosibirsk State Technical University, Novosibirsk; Aleksandr N. Korotkov, D.Sc. (Engineering), Professor, Kuzbass State Technical University, Kemerovo; Dmitry V. Lobanov, D.Sc. (Engineering), Associate Professor, I.N. Ulianov Chuvash State University, Cheboksary; Aleksey V. Makarov, D.Sc. (Engineering), Corresponding Member of RAS, Head of division, Head of laboratory (Laboratory of Mechanical Properties) M.N. Miheev Institute of Metal Physics, Russian Academy of Sciences (Ural Branch), Yekaterinburg; Aleksandr G. Ovcharenko, D.Sc. (Engineering), Professor, Biysk Technological Institute, Biysk; Yuriy N. Saraev, D.Sc. (Engineering), Professor, V.P. Larionov Institute of the Physical-Technical Problems of the North of the Siberian Branch of the RAS, Yakutsk; Alexander S. Yanyushkin, D.Sc. (Engineering), Professor, I.N. Ulianov Chuvash State University, Cheboksary
Vol. 27 No. 1 2025 5 CONTENTS OBRABOTKAMETALLOV TECHNOLOGY Umerov E.D., Skakun V.V., Dzhemalyadinov R.M., Egorov Y.A. Investigation of the eff ect of oil-based MWFs with enhanced tribological properties on cutting forces and roughness of the processed surfaces.............................................. 6 Manikanta J.E., Ambhore N., Thellaputta G.R. Investigation of vegetable oil-based cutting fl uids enhanced with nanoparticle additions in turning operations........................................................................................................................ 20 Shlykov E.S., Ablyaz T.R., Blokhin V.B., Muratov K.R. Improvement the manufacturing quality of new generation heat-resistant nickel alloy products using wire electrical discharge machining................................................................... 34 Ablyaz T.R., Osinnikov I.V., Shlykov E.S., Kamenskikh A.A., Gorohov A.Yu., Kropanev N.A., Muratov K.R. Prediction of changes in the surface layer during copy-piercing electrical discharge machining....................................... 48 Martyushev N.V., Kozlov V.N., Boltrushevich A.E., Kuznetsova Yu.S., Bovkun A.S. Milling of Inconel 625 blanks fabricated by wire arc additive manufacturing (WAAM)..................................................................................................... 61 Fatyukhin D.S., Nigmetzyanov R.I., Prikhodko V.M., Sundukov S.K., Sukhov A.V. Infl uence of the oscillating systems inclination angle on the surface properties of steel 45 during ultrasonic surface plastic deformation................... 77 EQUIPMENT. INSTRUMENTS Borisov M.A., Lobanov D.V., Skeeba V.Y., Nadezhdina O.A. Development of a device for studying and simulating the electrochemical grinding process................................................................................................................................... 93 Lapshin V.P., Gubanova A.A., Dudinov I.O. Predicting machined surface quality under conditions of increasing tool wear............................................................................................................................................................................... 106 Podgornyj Y.I., Skeeba V.Y., Martynova T.G., Sadykin A.V., Martyushev N.V., Lobanov D.V., Pelemeshko A.K., Popkov A.S. Designing the homogenization mechanism.................................................................................................... 129 MATERIAL SCIENCE Usanova O.Yu., Ryazantseva A.V., Vakhrusheva M.Yu., Modina M.A., Kuznetsova Yu.S. Improving the performance characteristics of grey cast iron parts via ion implantation.......................................................................... 143 Abdelaziz K., Saber D. Fabrication and characterization of Al-7Si alloy matrix nanocomposite by stir casting technique using multi-wall thickness steel mold................................................................................................................ 155 Dama Y.B., Jogi B.F., Pawade R., Pal S., Gaikwad Y.M. DLP 3D printing and characterization of PEEK-acrylate composite biomaterials for hip-joint implants....................................................................................................................... 172 Prudnikov A.N., Galachieva S.V., Absadykov B.N., Sharipzyanova G.Kh., Tsyganko E.N., Ivancivsky V.V. Eff ect of deformation thermocyclic treatment and normalizing on the mechanical properties of sheet Steel 10.......................... 192 Bhanavase V., Jogi B.F., Dama Y.B. Wear behavior study of glass fi ber and organic clay reinforced poly-phenylenesulfi de (PPS) composites material........................................................................................................................................ 203 EDITORIALMATERIALS 218 FOUNDERS MATERIALS 227 CONTENTS
OBRABOTKAMETALLOV Vol. 23 No. 3 2021 MATERIAL SCIENCE EQUIPMENT. INSTRUMENTS 7 1 5 Development of a device for studying and simulating the electrochemical grinding process Mikhail Borisov 1, а, Dmitry Lobanov 1, b, *, Vadim Skeeba 2, c, Oksana Nadezhdina 1, d 1 I.N. Ulianov Chuvash State University, 15 Moskovsky Prospekt, Cheboksary, 428015, Russian Federation 2 Novosibirsk State Technical University, 20 Prospekt K. Marksa, Novosibirsk, 630073, Russian Federation a https://orcid.org/0000-0001-9084-1820, borisovmgou@mail.ru; b https://orcid.org/0000-0002-4273-5107, lobanovdv@list.ru; c https://orcid.org/0000-0002-8242-2295, skeeba_vadim@mail.ru; d https://orcid.org/0009-0006-3656-394X, nadezhdina_oksana@mail.ru Obrabotka metallov - Metal Working and Material Science Journal homepage: http://journals.nstu.ru/obrabotka_metallov Obrabotka metallov (tekhnologiya, oborudovanie, instrumenty) = Metal Working and Material Science. 2025 vol. 27 no. 1 pp. 93–105 ISSN: 1994-6309 (print) / 2541-819X (online) DOI: 10.17212/1994-6309-2025-27.1-93-105 ART I CLE I NFO Article history: Received: 26 November 2024 Revised: 12 December 2024 Accepted: 28 December 2024 Available online: 15 March 2025 Keywords: Electrochemical grinding Combined processing Modeling Abrasive tool Hybrid technology Funding This study was supported by a NSTU grant (project No. TP-PTM-1_25). Acknowledgements The research was carried out at the equipment of the Engineering Center “Design and Production of High-Tech Equipment” and the shared research facility “Structure, mechanical and physical properties of materials”. ABSTRACT Introduction. When manufacturing critical parts from high-strength and difficult-to-process steels in various industries, the final quality is usually formed during finishing operations. The efficiency of the process is significantly higher when using combined, hybrid methods of influencing the surface being processed. When processing some complex-shaped parts, more attention in finishing operations is usually paid to reducing roughness while maintaining previously achieved dimensional accuracy indicators. For this purpose, abrasive tools on a rigid base are often used, placing it in a less rigid technological system. To increase the efficiency of the process, it is necessary to establish optimal modes of mechanical and electrochemical processing of parts. In the absence of the possibility of using industrial equipment for hybrid technologies at the initial stage, taking into account the need to modernize existing technological equipment for the implementation of the electrochemical grinding process, it is advisable to study this process by simulating it on simulator devices. The purpose of the work is to develop a device for studying and simulating the process of electrochemical grinding of conductive parts with abrasive heads on a metal bond. Research methodology. To simulate the process of electrochemical grinding of conductive parts using abrasive heads on a metal bond, we have developed a special device. It allows for the basing of the workpiece and the tool, implementation the electrochemical grinding process, its kinematic and electrical conditions: main motion, linear displacement of working bodies, mechanical and electrical modes, ensuring the necessary conditions for the implementation of the technology, and implementing a control system. Results and discussion. To determine the influence of mechanical cutting modes on the roughness of the machined surface of a part made of corrosion-resistant steel 0.12 C-18Cr-10 Ni-Ti, empirical studies were carried out on the designed device. Planning and processing of experimental results were carried out using standard methodology for preparing and conducting a full factorial experiment. The resulting model makes it possible to determine rational mechanical cutting conditions and evaluate its influence on the quality of the surface being processed. For citation: Borisov M.A., Lobanov D.V., Skeeba V.Y., Nadezhdina O.A. Development of a device for studying and simulating the electrochemical grinding process. Obrabotka metallov (tekhnologiya, oborudovanie, instrumenty) = Metal Working and Material Science, 2025, vol. 27, no. 1, pp. 93–105. DOI: 10.17212/1994-6309-2025-27.1-93-105. (In Russian). ______ * Corresponding author Lobanov Dmitry V., D.Sc. (Engineering), Associate Professor I.N. Ulyanov Chuvash State University, 15 Moskovsky Ave, 428015, Cheboksary, Russian Federation Тел.: +7 908 303-47-45, e-mail: lobanovdv@list.ru Introduction When manufacturing critical parts from high-strength and hard-to-machine steels in various industries, the final quality is typically achieved during finishing operations. These parts often operate under specific operating conditions. Consequently, they are made of hard-to-machine, corrosion-resistant, and heatresistant steels and alloys based on titanium and nickel. If there is a requirement to minimize the mass of products, many parts are thin-walled and have a complex profile.
OBRABOTKAMETALLOV MATERIAL SCIENCE Том 23 № 3 2021 EQUIPMEN . INSTRUM TS Vol. 7 No. 1 2025 At the final stage of the technological process of machining, it is necessary to minimize the force and heat generation in the contact zone between the workpiece and the abrasive tool in order to achieve the required quality of the processed surfaces. Such requirements impose restrictions on the choice of finishing methods and conditions. Process efficiency is significantly increased when using combined, or hybrid, methods to affect the surface being processed [1‑19]. When machining complex shaped parts, increased attention is given to finishing operations, particularly to reducing roughness while maintaining previously achieved dimensional accuracy indicators. For this purpose, rigid-base abrasive tools (abrasive heads on a metal bond) are often used and integrated into a less rigid technological system are often used, and integrated into a less rigid technological system. The tool can be edited electrochemically, continuously with the use of an additional electrical circuit or intermittently without its use. Feed alternating with a certain interval of reverse polarity current pulses is made directly to the operating circuit. To increase the efficiency of the process, it is necessary to establish optimal modes of mechanical and electrochemical processing of parts [20‑27]. If there is no possibility to use industrial equipment for hybrid technologies at the initial stage, and considering the need to modernize existing technological equipment for performing the electrochemical grinding process, it is advisable to study this process by modelling it on simulators [28‑31]. The aim of the work is to develop a device to study and simulate the process of electrochemical grinding of conductive parts with abrasive heads on a metal bond. To achieve this goal, the following tasks were formulated: 1) to identify, based on modeling, the operating parameters of the system under study and the applicability of the device for studying the roughness of processed parts in the process of electrochemical grinding with abrasive heads on a metal bond. 2) to conduct empirical studies of the roughness of the processed surfaces depending on the modes of electrochemical grinding. 3) to substantiate the possibility of using the developed device to study the process of electrochemical grinding of conductive parts with abrasive heads on a metal bond. Methods To simulate the process of electrochemical grinding of conductive parts with abrasive heads on a metal bond, a special device was developed. The block diagram of this device is shown in Fig. 1. The proposed device allows positioning theworkpiece and tool, implement the process of electrochemical grinding, its kinematic and electrical conditions: the primary motion, linear motion of working elements, mechanical and electrical modes, provide the necessary conditions for the implementation of the technology (electrolyte and its supply to the processing zone), and implement a control system. To determine the model of the engraver that gives the rotary motion of the abrasive head and the drive for linear motion of the abrasive head, the cutting forces and cutting power were calculated. The abrasive grinding modes were selected in accordance with the modes used in the study of hybrid technology for electrochemical processing of 0.12C-18Cr-10Ni-Ti stainless steel with a diamond cylindrical head with a working part diameter of 3 mm and a shank diameter of 2 mm. Cutting speed ranged from 4.7 m/s to 6.05 m/s, cutting depth from 0.04 mm to 0.06 mm, longitudinal feed rate from 230 mm/min to 250 mm/min [32]. As a result, the maximum cutting power values of 0.128 kW were obtained. Tool deformation calculations were performed additionally using the ANSYS software. The model with boundary conditions for the study is shown in Fig. 2. Table 1 shows the calculation examples. The tool deformation ranged from 0.14 to 0.23 mm. Fig. 3 shows a general view of the linear drive of the working body. It serves to provide a longitudinal feed of the tool and consists of a DC motor, a screw-nut transmission, and a slider. Table 2 shows the technical characteristics of the linear drive. The Zubr ZG-160EK engraver is used to give the main cutting motion to the abrasive head. Technical characteristics of the engraver Zubr ZG-160EK are given in Table 3.
OBRABOTKAMETALLOV Vol. 23 No. 3 2021 MATERIAL SCIENCE EQUIPMENT. INSTRUMENTS 7 1 5 Fig. 1. Structural diagram of the device for simulating the electrochemical grinding process: 1 – device housing; 2 – collet mechanism of the engraver; 3 – abrasive head; 4 – part holding device; 5 – container for electrolyte; 6 – engraver; 7 – engraver stand; 8 – DC source; 9 – container for electrolyte; 10 – time relay; 11 – thermometer, 12 – surge protector; 13 – terminal block; 14 – filter electrical network; 15 – engraver electrical network; 16 – electric heater electrical network; 17 – linear motion drive motor electrical network; 18 – DC source electrical network; 19 – time relay electrical network; 20 – electrical network for supplying current to the part; 21 – DC source electrical network for a time relay; 22 – electrical network for supplying current to the abrasive head; 23 – electrical network for connecting a DC source to a time relay; 24 – electric pump; 25 – electrolyte supply line; 26 – flexible engraver shaft Fig. 2. Tool deformation model with boundary conditions for analysis
OBRABOTKAMETALLOV MATERIAL SCIENCE Том 23 № 3 2021 EQUIPMEN . INSTRUM TS Vol. 7 No. 1 2025 Ta b l e 1 Tool deformation calculation results Cutting modes Tool deformation, mm Shear stress, MPa V = 4.7 m s-1, t = 0.04 mm, S = 230 mm/min 0.148 59.551 V = 6.05 m s-1, t = 0.06 mm, S = 250 mm/min 0.230 92.426 Fig. 3. Linear drive: C = 700 mm, A = 160 mm, S = 500 mm Ta b l e 2 Linear drive specifications Name Meaning Input voltage, V 12 Load capacity, N 1,500 Minimum slider travel speed, mm s−1 4 Maximum slider travel speed, mm s−1 36 Stroke motion, mm 500
OBRABOTKAMETALLOV Vol. 23 No. 3 2021 MATERIAL SCIENCE EQUIPMENT. INSTRUMENTS 7 1 5 Ta b l e 3 Engraver Specifications Name Meaning Supply voltage, V 220 Frequency, Hz 50 Power consumption, W 160 Rotation speed, rpm 15,000‑35,000 Collet diameter, mm 2.4; 3.2 Weight, kg 2.1 For mounting the abrasive head, a collet chuck, modified for combined processing, is used. Special equipment is used to mount the processed sample; this equipment allows for cross-feed of the sample. The working area of the installation is shown in Fig. 4. Fig. 4. External view of the working area of the installation: 1 – upgraded collet chuck; 2 – electrolyte feed tube; 3 – sample being processed; 4 – sample basing and feed equipment; 5 – abrasive head The cartridge is isolated from the engraver and mounted on the slider of the feed motion drive. Aflexible shaft transmits the primary motion from the engraver to the chuck. Specially designed tooling, isolated from the main body of the device, is used to position the processed experimental sample and enable transverse feed (cutting depth t). The device used to study and simulate the electrochemical grinding process is shown in Fig. 5. Results and Discussion Empirical studies were conducted using the designed device to determine the effect of mechanical cutting modes on the surface roughness of a part sample made of corrosion-resistant 0.12C-18Cr-10Ni-Ti steel. Electrical modes and experimental conditions for studying the electrochemical grinding process were selected based on prior experiments [32]. These included a voltage of 12 V at the process current source, a n etching current density of 1.5 A/cm², and a water-based electrolyte (NaNO₃ – 3 %, NaNO₂ – 1 %, Na₂CO₃ – 0.5 %).
OBRABOTKAMETALLOV MATERIAL SCIENCE Том 23 № 3 2021 EQUIPMEN . INSTRUM TS Vol. 7 No. 1 2025 Fig. 5. External view of the device for studying and simulating the electrochemical grinding process: 1 – current source for electrochemical process; 2 – engraver; 3 – linear drive; 4 – electrolyte container; 5 – sample basing and feeding equipment; 6 – upgraded collet chuck; 7 – time relay; 8 – current source for linear drive electric motor Ta b l e 4 Initial data for planning and processing experimental results Factors Levels Variation interval Upper Xi = +1 Primary (Zero) Xi = 0 Lower Xi = −1 X1 – cutting depth, t (mm) 0.06 0.05 0.04 0.01 X2 – feed rate, S (mm/min) 250 240 230 10 X3 – cutting speed, V (m/s) 6 5 4 1 The planning and processing of experimental results were performed using the standard methodology for preparing and conducting a full factorial experiment. The initial data for planning and processing experimental results are presented in Table 4. The regression equation obtained from the analysis of experimental data reflects the dependence of surface roughness on mechanical processing modes and is expressed as follows: 2.67 106.17 0.43 19,55 0.013 0.004 0.94 0.08 . t tS tV S SV V tSV = − + − − + − + + Ra The resulting model enables the determination of optimal mechanical cutting conditions and the assessment of their impact on the quality of the machined surface. Specific cases of the system response surfaces with constant cutting parameters at the zero level of variation are shown in Figs. 6–8. The obtainedmodel and response surfaces enable the prediction of surface roughness variation depending on grinding modes and represent an empirical model of the system under consideration.
OBRABOTKAMETALLOV Vol. 23 No. 3 2021 MATERIAL SCIENCE EQUIPMENT. INSTRUMENTS 7 1 5 Fig. 6. Graphs of the influence of feed rate and depth of cut on the surface roughness Ra of the machined 0.12C-18Cr-10Ni-Ti steel at V = 5 m/sec Fig. 7. Graphs of the influence of cutting speed and depth of cut on the surface roughness Ra of the machined 0.12C-18Cr-10Ni-Ti steel at S = 240 mm/min Fig. 8. Graphs of the influence of cutting speed and feed rate on the surface roughness Ra of the machined 0.12C-18Cr-10Ni-Ti steel at t = 0.05 mm Conclusions 1. Calculations have established that when modeling the machining of 0.12C-18Cr-10Ni-Ti stainless steel parts with a diameter of 10 mm using a diamond cylindrical head with a 3 mm working diameter, the maximum cutting power reached 0.128 kW, and the maximum tool deformation was 0.23 mm, with
OBRABOTKAMETALLOV MATERIAL SCIENCE Том 23 № 3 2021 EQUIPMEN . INSTRUM TS Vol. 7 No. 1 2025 the cutting speed varying from 4.7 m/s to 6.05 m/s, the cutting depth from 0.04 mm to 0.06 mm, and the longitudinal feed rate from 230 mm/min to 250 mm/min. Therefore, the developed device is suitable for investigating the relationship between the quality indicators of the machined surface and the cutting modes. To further investigate machining accuracy, the system rigidity should be increased. 2. Studies of the electrochemical grinding process of 0.12C-18Cr-10Ni-Ti stainless steel parts with a diameter of 10 mm, conducted using the developed device with a diamond cylindrical head with a 3 mm working diameter under the specified cutting parameters, have enabled the construction of an empirical model that predicts surface roughness variation as a function of electrochemical grinding modes. 3. Theoretical calculations and practical experiments have confirmed that the developed device is applicable for studying and modeling the electrochemical grinding of conductive parts using abrasive heads on a metallic bond. References 1. Borisov M.A., Lobanov D.V., Yanyushkin A.S., Skeeba V.Yu. Investigation of the process of automatic control of current polarity reversal in the conditions of hybrid technology of electrochemical processing of corrosion-resistant steels. Obrabotka metallov (tekhnologiya, oborudovanie, instrumenty) = Metal Working and Material Science, 2020, vol. 22, no. 1, pp. 6–15. DOI: 10.17212/1994-6309-2020-22.1-6-15. (In Russian). 2. Lobanov D.V., Arkhipov P.V., Yanyushkin A.S., Skeeba V.Yu. The research into the effect of conditions of combined electric powered diamond processing on cutting power. Key Engineering Materials, 2017, vol. 736, pp. 81–85. DOI: 10.4028/www.scientific.net/KEM.736.81. 3. Bratan S.M., Kharchenko A.O., Vladetskaya E.A., Kharchenko A.A. Analysis and synthesis of vibration isolation system of a grinding machine with account of the operational reliability of its elements. Obrabotka metallov (tekhnologiya, oborudovanie, instrumenty) = Metal Working and Material Science, 2019, vol. 21, no. 1, pp. 35–49. DOI: 10.17212/1994-6309-2019-21.1-35-49. (In Russian). 4. Kharchenko A., Chasovitina A., Bratan S. Modeling of regularities of change in profile sizes and wear areas of abrasive wheel grains during grinding. Materials Today: Proceedings, 2021, vol. 38 (4), pp. 2088–2091. DOI: 10.1016/j.matpr.2020.10.154. 5. Nosenko S.V., Nosenko V.A., Kremenetskii L.L. The condition of machined surface of titanium alloy in dry grinding. International Conference on Industrial Engineering, ICIE 2017, Saint-Petersburg, 16–19 May 2017, pp. 115–120. DOI: 10.1016/j.proeng.2017.10.446. 6. Gusev V.V., Roshchupkin S.I., Moiseev D.A., Melnikova E.P. Analysis of grinding process with the use of field theory. IOPConference Series: Materials Science and Engineering, 2019, vol. 709 (2), p. 022001. DOI: 10.1088/1757899X/709/2/022001. 7. Rechenko D.S. The study of the process of difficult-to-machine materials cutting at the micro-level. Obrabotka metallov (tekhnologiya, oborudovanie, instrumenty) = Metal Working and Material Science, 2019, vol. 21, no. 2, pp. 18–25. DOI: 10.17212/1994-6309-2019-21.2-18-25. (In Russian). 8. Rechenko D.S., Popov A.Y., Titov Y.V., Balova D.G., Gritsenko B.P. Ultra-high-speed sharpening and hardening the coating of carbide metal-cutting tools for finishing aircraft parts made of titanium alloys. Journal of Physics: Conference Series, 2019, vol. 1260 (6), p. 062020. DOI: 10.1088/1742-6596/1260/6/062020. 9. Kozlov A.M., Kozlov A.A. Shaping the surface topology of cylindrical components by means of an abrasive tool. Russian Engineering Research, 2009, vol. 29 (7), pp. 743–746. DOI: 10.3103/S1068798X09070223. 10. Soler Ya.I., Kazimirov Yu.D. Predicting the supporting area of microrelief in machine parts of variable rigidity during plane grinding. Journal of Machinery Manufacture and Reliability, 2006, vol. 35 (3), pp. 260–265. 11. Niu L., Jin Z., Zhou Z., Dong Z., Zhu X. Study on electrochemical effect in electrochemical grinding of tungsten alloy. ISAAT 2018 – 21st International Symposium on Advances in Abrasive Technology, Toronto, 14– 16 October 2018. 12. Bratan S.M., Sidorov D.E., Bogutskii V.B. [Synthesis of a Kalman-Bussy filter for assessing the state of a grinding operation]. Sovremennye napravleniya i perspektivy razvitiya tekhnologii obrabotki i oborudovaniya v mashinostroenii [Modern directions and prospects for the development of processing technologies and equipment in mechanical engineering]. Materials of the International Scientific and technical conference, Sevastopol, September 14–15, 2015, pp. 87–91. (In Russian). 13. Nosenko V.A., Belukhin R.A., Fetisov A.V., Morozova L.K. Ispytatel’nyi kompleks na baze pretsizionnogo profileshlifoval’nogo stanka s ChPU CHEVALIER modeli smart-B1224 III [Test complex based on a precision
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