Empirical mathematical models of plasticity, strength and wear resistance of materials on the example of P18 steel

The paper analyzes the results of laboratory experimental studies of parameters that
characterize the plasticity, strength and wear resistance of P18 tool steel obtained during
material science examinations. New empirical mathematical expert models have been developed
for the dependence of P18 steel ductility and strength on temperature. Empirical mathematical
expert models of the dependence of mechanical properties and wear resistance of P18 steel on
various factors are obtained. The possibility of analytical representation of complex experimental
graphical dependencies of mechanical and tribological properties of P18 steel on various factors
for use in forensic practice is shown.

1. }Gvozdev A.E., Chernykh D.P., Breki A.D., Moiseev V.V., Starikov N.E., Pustovgar A.S., Averyanov R.V. 2006, \textit{Superplasticity of ledeburite-class steels}. Tula, Tula state University Press, 75 p.

2. }Vinogradov V.N., Sorokin G.M. 1994, \textit{Wear Resistance of steels and alloys}. Moscow, Oil and gas, 417 p.

3. }Chumachenko E.N., Tsepin M.A., Chekin A.V., Panina O.N. 2001, «Analysis of the influence of structure on the shaping of the workpiece during sheet superplastic molding», \textit{Forging and stamping production}, No.7, pp. 3–7.

4. }Enikeev F.U. 2001, «Determination of the parameters of the sigmoidal superplastic curve», \textit{Forging and stamping production}, No.4, pp. 18–22.

5. }Gulyaev A.P. 1969, «Technological plasticity of high-speed steels», \textit{Metal Science and heat treatment of metals}, No.7, pp. 2–9.

6. }Breki A.D., Gvozdev A.E., Kolmakov A.G. 2019, «Semiempirical mathematical models of the friction of twisting steel SHX15 on steel P6M5, according to the ball – plane scheme with wear», \textit{Material Science}, No.2, pp. 43–48.

7. }Chulkin S.G., Steshenkov A.L., Breki A.D., Lysenkov P.M. 2019, «Mathematical modeling of the process of running in propeller shafts», \textit{Marine intelligent technologies}, No.1-3(43), pp. 76–86.

8. }Breki A.D. 2018, «On the functional contour of a finite triangular array of numbers», \textit{Algebra, number theory and discrete geometry: modern problems and applications Materials of the XV International conference dedicated to the centenary of the birth of Professor Nikolai Mikhailovich Korobov}, pp. 166–169.

9. }Breki A.D., Alexandrov S.E., Tyurikov K.S., Kolmakov A.G., Gvozdev A.E., Kalinin A.A. 2018, «Antifriction properties of plasma-chemical coatings based on SiO2 with $MoS_2$ nanoparticles under conditions of torsion friction on steel SHX15», \textit{Material Science}, No.1, pp. 31–35.

10. }Breki A.D., Medvedeva V.V., Krylov N.A., Aleksandrov S.E., Kolmakov A.G., Gvozdev A.E., Sergeev N.N., Provotorov D.A., Fadin Y.A. 2018, «Antiwear properties of composite greases «LITOL-24–magnesium hydrosilicate particles»», \textit{Inorganic Materials: Applied Research}, Vol.9, No.1, pp. 21–25.

11. }Breki A.D., Gvozdev A.E., Kolmakov A.G., Sergeyev N.N. 2018, «Investigation of the friction of twisting steel SHX15 on P6M5 and 10R6M5-MP steels using mathematical modeling», \textit{Material Science}, No.12, pp. 40–45.

12. }Koltsova T.S., Breki A.D., Larionova T.V., Tolochko O.V. 2018, «Operational characteristics of the composite aluminum–carbon nanofibers», \textit{Materials Physics and Mechanics}, Vol.38, No.1, pp. 11–15.

13. }Breki A., Nosonovsky M. 2018, «Ultraslow frictional sliding and the stick-slip transition», \textit{Applied Physics Letters}, Vol.113, No.24, pp. 241602.

14. }Breki A., Nosonovsky M. 2018, «Einstein's viscosity equation for nanolubricated friction», \textit{Langmuir: the ACS journal of surfaces and colloids}, Vol.34, No.43, pp. 12968–12973.

15. }Breki A.D., Semenov S.A., Starikov N.E., Gvozdev A.E., Lavrushin A.V. 2018, «Influence of microscopic Aspergillus niger fungi on tribotechnical properties of LITA brand plastic lubricant», \textit{Izvestiya Tula state University. Technical science}, No.7, pp. 108–117.

16. }Chechulin K.N., Breki A.D., Molokov I.E., Gvozdev A.E., Kutepov S.N., Pantyukhin O.V. 2018, «Influence of changes in the suitability of M-8DM engine oil in the internal combustion engine D-245. 7E3 of the GAZ-3309 car on the cycles of its delivery within the technical support», \textit{Izvestiya Tula state University. Technical science}, No.7, pp. 137–150.

17. }Breki A.D., Gvozdev A.E., Minaev I.V., Kutepov S.N., Kalinin A.A. 2018, «Mathematical models of characteristics of the process of friction interaction of heterophase metal systems», \textit{Izvestiya Tula state University. Technical science}, No.7, pp. 39–53.

18. }Chechulin K.N., Breki A.D., Molokov I.E., Gvozdev A.E., Kutepov S.N., Pantyukhin O.V. 2018, «Influence of changes in the properties of M10G2K engine oil in the internal combustion engine YAMZ-236 of the URAL-4320 car on the cycles of its delivery within the boundaries of technical support», \textit{Izvestiya Tula state University. Technical science}, No.8, pp. 127–140.

19. }Chechulin K.N., Breki A.D., Molokov I.E., Gvozdev A.E., Kutepov S.N., Pantyukhin O.V. 2018, «Influence of diagnostics of M10G2K engine oil in the KAMAZ-740 internal combustion engine on the cycles of its delivery within the boundaries of technical support», \textit{Izvestiya Tula state University. Technical scienc}e, No.8, pp. 79–93.

20. }Breki A.D., Tyurikova I.A., Shatulsky A.A., Gvozdev A.E., Kutepov S.N. 2018, «Influence of magnetic Fe3O4 nanoparticles on friction and wear of 10H17N13M2T steel in the spinning mode in the medium of lubricating oil», \textit{Bulletin of the Rybinsk state aviation technological Academy. P.A. Solovyov}, No.4(47), pp. 103–111.

21. }Breki A.D., Kol'tsova T.S., Skvortsova A.N., Tolochko O.V., Aleksandrov S.E., Kolmakov A.G., Lisenkov A.A., Fadin Y.A., Gvozdev A.E., Provotorov D.A. 2018, «Tribotechnical properties of composite material «aluminum–carbon nanofibers» under friction on steels 12KH1 and SHKH15», \textit{Inorganic Materials: applied research}, Vol.9, No.4, pp. 639–643.

22. }Breki A.D., Aleksandrov S.E., Tyurikov K.S., Kolmakov A.G., Gvozdev A.E., Kalinin~A.A. 2018, «Antifriction properties of plasma-chemical coatings based on $SiO_2$ with $MoS_2$ nano\-particles under conditions of spinning friction on SHKH15 steel», \textit{Inorganic Materials: Applied Research}, Vol.9, No.4, pp. 714–718.

23. }Stankevich P., Mironovs V., Vasilyeva E., Breki A., Tolochko O. 2017, «The possibility of modifying the elements of the bearing assembly with nanoparticles in order to reduce the friction coefficient», \textit{IOP Conference Series: Materials Science and Engineering}, pp. 012084.

24. }Alexandrov S.E., Tyurikov K.S., Breki A.D. 2017, «Low-temperature plasma-chemical depo\-sition of nanocomposite antifriction molybdenum disulfide (filler)–silicon oxide (matrix) coa\-tings», \textit{Russian Journal of Applied Chemistry}, Vol.90, No.11, pp. 1753–1759.

25. }Breki A.D., Koltsova T.S., Skvortsova A.N., Tolochko O.V., Alexandrov S.E., Kolmakov A.G., Lisenkov A.A., Gvozdev A.E., Fadin Yu.A., Provotorov D.A. 2017, «Tribotechnical properties of the composite material «aluminum-carbon nanofibers» at friction on steels 12X1 and SHX15», \textit{Material Science}, No.11. pp. 37–42.

26. }Breki A.D., Medvedeva V.V., Krylov N.A., Kolmakov A.G., Fadin Yu.A., Gvozdev A.E., Sergeev N.N., Alexandrov S.E., Provotorov D.A. 2017, «Anti-Wear properties of plastic lubricating composite materials «LITHOL24-particles of magnesium hydrosilicates»», \textit{Material Science}, No.3, pp. 38–42.

27. }Breki A.D., Alexandrov S.E., Tyurikov K.S., Gvozdev A.E., Kalinin A.A. 2017, «Antifriction properties of a $SiO_2$-based coating containing $MoS_2$ nanoparticles with an average size of 61 nm when friction occurs on steel SHX15», \textit{Proceedings of the Tula state University. Technical science}, No.7, pp. 334–343.

28. }Breki A.D., Alexandrov S.E., Tyurikov K.S., Gvozdev A.E., Kalinin A.A. 2017, «Investigation of the friction of SHX15 steel on a coating based on $SiO_2$ containing nanoparticles of molybdenum disulfide with an average size of 53 nm», \textit{Proceedings of the Tula state University. Technical science}, No.7, pp. 363–373.

29. }Breki A.D., Alexandrov S.E., Tyurikov K.S., Gvozdev A.E., Ageev E.V., Provotorov D.A., Kuts V.V. 2017, «Laboratory studies of the friction of SHX15 steel on a SIO2-based coating containing $MoS_2$ nanoparticles with an average size of 64 nm», \textit{Izvestiya Yugo-ZAPADNOGO gosudarstvennogo universiteta}, No.4(73), pp. 52–67.

30. }Breki A.D., Gvozdev A.E., Kolmakov A.G., Starikov N.E., Provotorov D.A., Sergeyev N.N., Khonelidze D.M. 2017, «On friction of metallic materials with consideration for superplasticity phenomenon», \textit{Inorganic Materials: Applied Research}, Vol.8, No.1, pp. 126–129.

31. }Breki A.D., Didenko A.L., Kudryavtsev V.V., Vasilyeva E.S., Tolochko O.V., Kolmakov A.G., Gvozdev A.E., Provotorov D.A., Starikov N.E., Fadin Yu.A. 2017, «Synthesis and dry sliding behavior of composite coating with (R-OOO)FT polyimide matrix and tungsten disulfide nanoparticle filler», \textit{Organic Materials: Applied Research}, Vol.8, No.1, pp. 32–36.

32. }Breki A.D., Didenko A.L., Kudryavtsev V.V., Vasilyeva E.S., Tolochko O.V., Gvozdev A.E., Sergeyev N.N., Provotorov D.A., Starikov N.E., Fadin Yu.A., Kolmakov A.G. 2017, «Composite coatings based on A-OOO polyimide and WS2 nanoparticles with enhanced dry sliding characteristics», \textit{Organic Materials: Applied Research}, Vol.8, №1, pp. 56–59.

33. }Breki A.D., Gvozdev A.E., Kolmakov A.G. 2017, «Application of generalized pascal triangle for description of oscillations of friction forces», \textit{Inorganic Materials: Applied Research}, Vol.8, No.4, pp. 509–514.

34. }Breki A.D., Alexandrov S.E., Tyurikov K.S., Gvozdev A.E., Kalinin A.A., Ageev E.V., Ivakhnenko A.G. 2017, «Regularities of the friction of twisting steel SHX15 on the surface of a coating based on $Si_2$ containing $MoS_2$ nanoparticles with an average size of 70 nm, deposited on a substrate made of steel 12X18N10T», \textit{Izvestiya Yugo-ZAPADNOGO gosudarstvennogo universiteta. Series: Engineering and technology}, No.3(24), pp. 48–59.

35. }Breki A.D., Vasilyeva E.S., Tolochko O.V., Didenko A.L., Kudryavtsev V.V., Kolmakov A.G., Sergeyev N.N., Gvozdev A.E., Starikov N.E., Provotorov D.A., Fadin Y.A. 2016, «Synthesis and tribotechnical properties of composite coatings with PM–DADPE polyimide matrix and fillers of tungsten dichalcogenide Nanoparticles upon dry Sliding friction», \textit{Inorganic materials: applied Research}, Vol.7, No.4, pp. 542–546.

36. }Ondracek G. 1977, «Zum Zussaummenhang zwischen Eigenschaften und Gefugestruktur mehrphasiger Werkstoffe», \textit{Werkstofftechnik}, No.8, pp. 240–246.

37. }Khokhlov V.M. 1999, \textit{Calculation of contact areas, allowable stresses, wear and wear-resistant machine parts}. Bryansk, Belgorod state technological University, 104 p.

38. }Khokhlov V.M. 1990, «The basis of the calculation and the actual contour of the areas of contact and pressure», \textit{Vestnik mashinostroeniya}, No.7, pp. 21–22.

39. }Khokhlov V.M. 1990, «The calculation of the contour areas of contact and pressure», \textit{Proceedings of the universities. Engineering}, No.4. pp. 20–24.

40. }Khokhlov V.M. 1990, «Foundations underlying the calculation of contour and actual contact areas and pressures», \textit{Russian Engineering Research}, Vol.10, No.7, pp. 15–18.

41. }Khokhlov V.M. 1994, «Calculation of contour and nominal working stresses», \textit{Russian Engineering Research}, Vol.14, No.4, pp. 1–4.

42. }Demkin N.B. 1990, «Investigation of the contact of two rough surfaces», \textit{Friction and wear}, Vol.11, No.6, pp. 1002–1006.

43. }Moore D. 1978, \textit{Principles and applications of trebonice}. – Moscow, Mir, 488 p.

44. }Petrusevich A.I. 1951, \textit{Main conclusions from the contact-hydrodynamic theory of lubrication}, Moscow, USSR Academy of Sciences, OTN, No.2. pp. 209–223.

45. }Ishlinsky A.Yu. 1944, «Axisymmetric problem of plasticity theory and Brinell test», \textit{Applied mathematics and mechanics}, Vol.8, Vol.3, pp. 201–224.

46. }Bowden F.P., Tabor D. 1959, \textit{Reibung und Schmierung fester Korper}. Berlin-Gottingen-Heidelberg, Springer-Verlag, 410 p.

47. }Petrov Yu.V., Gruzdkov A.A., Sitnikova E.V. 2007, «Anomalous behavior of the yield point when the temperature increases in high-speed deformation», \textit{Reports of the Academy of Sciences}, T.417, No.4. pp. 493–496.

48. }Yanushkevich Zh.Ch., Lugovskaya A.S., Belyakov A.N., Dobatkin S.V., Kaibyshev R.O. 2016, «Influence of the test temperature on the yield strength of austenitic corrosion-resistant steels subjected to rolling at different temperatures», \textit{VI all-Russian conference on nanomaterials with elements of a scientific school for young people Collection of materials}, pp. 320–321.

49. }Tabachnikova E.D., Bengus V.Z., Podolsky A.V., Smirnov S.N., Valiev R.Z. 2009, «Yield Strength and plasticity of nanostructured titanium of different purity at temperatures of 300, 77 and 4.2 K», \textit{Сrystallography}, T.54. No.6. pp. 1119–1122.

50. }Alexandrov S.E., Lyamina E.A., Novozhilova O.V. 2013, «Influence of the dependence of the yield point on temperature on the stress state in a thin hollow disk», \textit{Problems of mechanical engineering and machine reliability}, No.3, pp. 43–48.

51. }Sitnikov I.V., Salomatova E.S. 2014, «Numerical simulation of friction welding with mixing», \textit{Master's Journal}, No.2, pp. 84–88.

52. }Buckley D. 1986, \textit{Surface phenomena in adhesion and frictional interaction}. Moscow, Mashi\-no\-stroenie, 360 p.