Abstract
The friction in cutting is considered in terms of thermodynamics and self-organization. The mean frictional coefficient in cutting depends significantly on the phase and structural transformations in the secondary chip-deformation zone. Those transformations affect the contact length and the shrinkage and load capacity of the chip. In terms self-organization, the friction in cutting must be regarded as storage of the elastic deformational energy in the boundary layer and its dissipation by different means, producing wear and self-oscillation of the cutting tool.
REFERENCES
Kabaldin, Yu.G., Shatagin, D.A., and Kolchin, P.V., Upravlenie kiberfizicheskimi mekhanoobrabatyvayushchimi sistemami v tsifrovom proizvodstve na osnove iskusstvennogo intellekta i oblachnykh tekhnologii (Management of Cyberphysical Machining Systems in Digital Manufacturing Based on Artificial Intelligence and Cloud Technologies), Kabaldin, Yu.G., Ed., Moscow: Innovats. Mashinostr., 2019.
Zorev, N.N., Voprosy mekhaniki protsessa rezaniya metallov (Mechanics of Metal Cutting), Moscow: Mashgiz, 1956.
Poletika, M.F., Kontaktnye nagruzki na rezhushchikh poverkhnostyakh instrumenta (Contact Loads on Cutting Surfaces of the Tool), Moscow: Mashinostroenie, 1969.
Gordon, M.B., Research on friction and lubrication in metal cutting, in Trenie i smazka pri rezanii metallov (Friction and Lubrication in Metal Cutting), Cheboksary: Chuvash State Univ., 1972, pp. 7–23.
Zharkov, I.G., Vibratsii pri rezanii lezviinym instrumentom (Vibration in Blade Cutting), Leningrad: Mashinostroenie, 1986.
Nikolis, G. and Prigozhin, I., Self-Organization in Nonequilibrium Systems: From Dissipative Structures to Order through Fluctuations, New York: Wiley, 1977.
Kabaldin, Yu.G., Oleinikov, A.I., Shpilev, A.M., and Burkov, A.A., Matematicheskoe modelirovanie samoorganizuyushchikhsya protsessov v tekhnologicheskikh sistemakh obrabotki rezaniem (Mathematical Modeling of Self-Organizing Processes in Technological Machining Systems), Vladivostok: Dal’nauka, 2000.
Pavlov, V.A., Amorphization of the structure of metals and alloys with an extremely high degree of deformation, Fiz. Met. Materialoved., 1985, vol. 59, no. 4, pp. 629–649.
Panin, V.E., Likhachev, V.A., and Grinyaev, Yu.V., Strukturnye urovni deformatsii tverdykh tel (Structural Levels of Solids Deformation), Novosibirsk: Nauka, 1985.
Krasulin, Yu.L., Dislocations as active centers in topochemical reactions, Teor. Eksp. Khim., 1967, vol. 3, no. 1, pp. 58–62.
Kolbasnikov, N.G., Theory of metal processing by pressure, in Soprotivlenie deformatsii i plastichnost’ (Deformation Resistance and Plasticity), St. Petersburg: S.-Peterb. Gos. Tekhnol. Univ., 2000.
Kabaldin, Yu.G. and Seryi, S.V., Optimizing the composition and properties of nanostructural coatings for cutting tools on the basis of the electron-density functional, Russ. Eng. Res., 2011, vol. 31, pp. 458–464. https://doi.org/10.3103/S1068798X11050078
Kabaldin, Yu.G., Shatagin, D.A., Kolchin, P.V., and Anosov, M.S., Iskusstvennyi intellekt, internet veshchei, oblachnye tekhnologii i tsifrovye dvoiniki v sovremennom mekhanoobrabatyvayushchem proizvodstve: Monografiya (Artificial Intelligence, Internet of Things, Cloud Technologies, and Digital Doubles in Modern Machining: Monograph), Kabaldin, Yu.G., Ed., Nizhny Novgorod: Nizhegorodsk. Gos. Tekh. Univ. im. A.A. Alekseeva, 2019.
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Translated by B. Gilbert
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Kabaldin, Y.G., Bashkov, A.A. Self-Organization and Friction in Cutting. Russ. Engin. Res. 43, 451–456 (2023). https://doi.org/10.3103/S1068798X23050088
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DOI: https://doi.org/10.3103/S1068798X23050088