Stochastic Diagnostics of Tool and Workpiece Interaction

• Autorzy: Bratan Sergey , Sága Milan , Yakimovich Boris , Bozek Pavol , Pokintelista Nikolay , Yakubov Chingiz

Identyfikatory

DOI

10.2478/mspe-2025-0004

• Języki publikacji: EN

Abstrakty

EN

Development is an integral part of research, since the study of specifics and characteristics in such a unique topic as the quality of processed products cannot be done without extraordinary equipment, fixtures and a laboratory. Laboratory equipment has been created that combines all hardware aspects of the development of the quality of processed products, where it analyzes the quality of workpieces that depend on the processing technology. However, this depends largely on the technological system used. The paper includes measurements, data acquisition and back-checking of the logic of the study of grinding operations. In the introduction, it must be shown that the correct selection and strength characteristics of the tool associated with the cutting mode of grinding determine the accuracy and quality of the surfaces of the ground part. The impact on the service life of the grinding tool was also monitored. The 4th partial result is also the knowledge that the correct selection of the tool characteristics and cutting mode predicts the quality of the workpiece surface. The operating conditions of the manufactured parts significantly affect the operating values of the production parameters. By appropriate diagnostics in the research process and precise measurements using sensitive sensors, deviations can be minimized. Without this apparatus, it is possible that deviations increase significantly during the operation of the technological system. The size of the deviation during grinding is explained in practice by the presence of vibrations in technological processes. They cause instability of the parameters of the technological system. To stabilize the quality indicators, a mathematical apparatus was also used, which takes into account changes in the technological regime. They are determined by designing adverse conditions, e.g. restoration of the cutting properties of a worn grinding wheel. Therefore, its replacement is logically carried out earlier than its replacement is planned.

Słowa kluczowe

EN

research; machining; grinding; quality; diagnostics; lifespan

• Wydawca: STE GROUP
• Czasopismo: Management Systems in Production Engineering
• Rocznik: 2025
• Tom: nr 1 (33)
• Strony: 39--45
• Opis fizyczny: Bibliogr. 20 poz., rys.

Twórcy

autor

Bratan Sergey

• Sevastopol State University 33 Universitetskaya St., 299053 Sevastopol

• https://orcid.org/0000-0002-9033-1174

autor

Sága Milan

• University of Zilina Univerzitná 8215/1, 010 26 Žilina, Slovakia

• https://orcid.org/0000-0002-0938-8772

autor

Yakimovich Boris

• Sevastopol State University 7 Kurchatova St., 299015 Sevastopol

• https://orcid.org/0000-0001-7363-1071

autor

Bozek Pavol

• University of Zilina Univerzitná 8215/1, 010 26 Žilina, Slovakia

• https://orcid.org/0000-0002-3891-3847

autor

Pokintelista Nikolay

• Sevastopol State University 33 Universitetskaya St., 299053 Sevastopol

• https://orcid.org/0000-0002-0277-8252

autor

Yakubov Chingiz

• Crimean Engineering and Pedagogical University Uchebniy side St. 8, 295055 Simferopol

• https://orcid.org/0000-0003-4029-8553

Bibliografia

• [1] Bratan, S.M. Identification of parameters of the joint in combined grinding of tokopass ceramic materials. Progressive technologies and systems of mass engineering: International collection of scientific works. Doneck: DonGTU, 2000. Issue 9, pp. 24–32.
• [2] Bratan, S.M. Synthesis of a subsystem of the population for the operation of shallow grinding. High technologies in mass production. Proceedings of scientific works HDPU. Harkіv, 2020, Issue 1(3), pp. 22–31.
• [3] Bratan, S.M. Control of the operation of flat grinding with dynamic stabilization of technological cycle parameters. Cutting and instrument in technological systems. International collection of scientific works. Har’kov: HGPU, 2000. Issue 57, pp. 17–23.
• [4] Gantmaher, F.R. Theori matrix, Scientific, 1998, p. 552.
• [5] Denkena, B.; Krödel, A.; Wilckens, M. High performance peel grinding of steel shafts using coarse electroplated CBN grinding wheels. Production Engineering-Research and Development, 2021, Volume 15, Issue 5, pp. 717–724. DOI10.1007/s11740-021-01047-1.
• [6] Hu, J.; Zhang, H.; Sfarra, S.; Pivarciová, E.; Yao, Y.; Duan, YX.; Ibarra-Castanedo, C;. Tian, GY.; Maldague, X. Autonomous dynamic line-scan continuous-wave terahertz nondestructive inspection system combined with unsupervised exposure fusion. NDT & E INTERNATIONAL 2022, Page 132.
• [7] Hung, L.X.; Pi, V.N.; Tung, L.A.; Tu, H.X.; Jun, G.; Long, B.T. Determination of Optimal Exchanged Grinding Wheel Diameter when Internally Grinding Alloy Tool Steel 9CrSi. 5th International Conference on Mechanics and Mechatronics Research (ICMMR 2018), Volume 417, DOI 10.1088/1757-899X/417/1/012026.
• [8] Perkins, AT.; Dragsdorf, RD. Decomposition of bentonite as affected by h grinding, ca grinding, mg grinding, and dry grinding. Soil Science Society of America Proceedings. Volume 16, Issue 3, pp. 312–312. DOI10.2136/sssaj1952.03615995001600030023x.
• [9] Saga, M.; Vasko, M.; Handrik, M.; Kopas P. Contribution to random vibration numerical simulation and optimisation of nonlinear mechanical systems. Scientific Journal of Silesian University of Technology-series Transport, Vol. 103, pp. 143–154. DOI 10.20858/sjsutst. 2019.103.11, 2019.
• [10] Ji, K.K.; Zhang, X.Q.; Yang, S.B.; Shi, L.P.; Wang, S,Y.; Wu, Y.G. Surface integrity of quenched steel 1045 machined by CBN grinding wheel and SiC grinding wheel. International Journal of Structural Integrity, Volume 8, Issue 2, pp. 179–187. DOI 10.1108/IJSI-03-2016-0011.
• [11] Józwik, J.; Semotiuk, L.; Kuric, I. Diagnostic of cnc lathe with qc 20 ballbar system. Advances in Science and Technology Research Journal. Volume 9, Issue 28, pp. 96–102. DOI 10.12913/22998624/60793.
• [12] Korchak, S.N. Production by grinding of steel details. Mechanical Engineering. 1974, 280 pages.
• [13] Ryzhov, J.V.; Sagarda, A.A.; Il’iccij, V.B.; Chepoveckij, I.H. Credibility of the lubricant-abrasive treatment. Kiev, Nauk. dumka, 1979, p. 224.
• [14] Kuric, I.; Zajacko, Císar, M. Analytical intelligence tools for multicriterial diagnostics of CNC machines. Advances in Science and Technology Research Journal, 2016, Volume 10, Issue 32, pp. 59–64. DOI 10.12913/22998624/65105.
• [15] Larshin, V.P. Statistical check of the operability of technological systems according to the stability criterion. Physical and computer technologies in the national economy. Proceedings of the 5th International Scientific and Technical Conference HNPK Har’kov, 2002, pp. 31–32.
• [16] Novoselov Ju.K. Dynamics of forming of superstructures in abrasive machining. Izd-vo Saratov, 1979. p. 232.
• [17] Mihelkevich, V.N. Automatic grinding control. Mechanical engineering, 1975, 204 pages.
• [18] Qazizada, M.E.; Pivarciová, E. Reliability of parallel and serial centrifugal pumps for dewatering in mining process. Acta Montanistica Slovaca 2018, 23 (2), pp 141–152.
• [19] Rowe, W.B. Grinding Wheel Dressing. Principles of Modern Grinding Technology, 2019. pp 59–78.
• [20] Biały W. Podstawy maszynoznawstwa. Wydawnictwo WNT Warszawa 2017.

Uwagi

1. Nikolay Pokintelista- błędny nr ORCID w pdf'ie.

2. Chingiz Yakubov - w Orcid zmienione nazwisko Chigiz.

3. Opracowanie rekordu ze środków MNiSW, umowa nr POPUL/SP/0154/2024/02 w ramach programu "Społeczna odpowiedzialność nauki II" - moduł: Popularyzacja nauki i promocja sportu (2025).