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Title of the article

POSSIBILITIES FOR OPTIMAL DESIGN OF A CAR TIRE BASED ON A CRITERION OF SPATIAL STRENGTH BALANCE
Authors

KHOTKO Alexander V., Head of the Division of Calculation Studies of Tire Mechanics of the Department of Tire Design and Construction of the R&D Center, BELSHINA JSC, Bobruisk, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.

SHIL’KO Sergey V., Ph. D. in Eng., Assoc. Prof., Head of the Laboratory “Mechanics of Composites and Biopolymers”, V.A. Belyi Metal-Polymer Research Institute of the NAS of Belarus, Gomel, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.

BUHAROV Sergey N., Ph. D. in Eng., Head of the Sector “Vibroacustics of Materials and Tribojoints of Machines”, V.A. Belyi Metal-Polymer Research Institute of the NAS of Belarus, Gomel, Republic of Belarus, This email address is being protected from spambots. You need JavaScript enabled to view it.">This email address is being protected from spambots. You need JavaScript enabled to view it.
In the section MECHANICS OF MOBILE MACHINES
Year 2020 Issue 4 Pages 11–18
Type of article RAR Index UDK 539.3; 621.891; 691.175 Index BBK  
DOI https://doi.org/10.46864/1995-0470-2020-4-53-11-18
Abstract A procedure is proposed for calculating the internal profile and optimal distribution of materials for a pneumatic car tire in a mold configuration. To adequately describe the elastic-dissipative properties of tire rubbers and rubber-cord composites, nonlinear elastic deformation Mooney–Rivlin model and viscoelastic Prony model as well as experimental data of static and dynamic tests are considered. An algorithm for finite element analysis of the stress-strain state of a passenger car tire is described in the MSC.Marc software package, and results of numerical solution of applied problems are presented on the tire landing on the rim and its loading with working pressure, as well as on the contact interaction of a passenger car tire with the road surface at maximum operating load at rest and during stationary rolling at a speed of 90 km/h. It was found that the contact loading of the tire when interacting with the road surface does not lead to a significant difference in the deformed state in the zone opposite diametrically to the contact zone from that for a tire mounted on a rim and loaded with excess operating pressure. In this case, the nature of the distribution of strains in the radial section near the contact zone of the tire with the road surface is the same under conditions of compression and stationary rolling. Areas of concentration of equivalent stresses and strains in the bead zone of the tire and in the zone of the edges of the breaker are revealed. For a quick comparison of competing tire designs, it is recommended to calculate the average values of the total strain energy density per wheel revolution. The developed calculation methods make it possible to predict the performance characteristics of automobile tires at the design stage and are tested in the manufacturing of these products.
Keywords

car tire, rubber-cord composites, stress-strain state, equilibrium configuration, viscoelasticity, design and check calculation, finite element method
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Bibliography
  1. Biderman V.L., Guslitser R.L., Zakharov S.P., Seleznev I.I. Avtomobilnye shiny (konstruktsiya, raschet, ispytanie, ekspluatatsiya) [Automobile tires (design, calculation, testing, operation)]. Moscow, Gosudarstvennoe nauchnotekhnicheskoe izdatelstvo khimicheskoy literatury Publ., 1963. 353 p. (in Russ.).
  2. Mechanics of Pneumatic Tires. Washington National Bureau of Standards, 1971. 853 p.
  3. Bukhin B.L. Vvedenie v mekhaniku pnevmaticheskikh shin [Introduction to mechanics of pneumatic tires]. Moscow, Khimiya Publ.,1988. 222 p. (in Russ.).
  4. Nakajima Y. Advanced Tire Mechanics. Springer Nature Singapore Pte Ltd., 2019. 1264 p.
  5. Mozharovskii V.V., Shil’ko, S.V., Anfinogenov S.B., Khot’ko A.V. Opredelenie soprotivleniya kacheniyu avtomobilnykh shin v zavisimosti ot usloviy ekspluatatsii. Chast 1. Metodika mnogofaktornogo eksperimenta [Determination of resistance to rolling of tires in dependence on operating conditions. Part 1. Method of multifactorial experiment]. Trenie i iznos, 2007, vol. 28, no. 2, pp. 151–157 (in Russ.).
  6. Khotko A.V., Shil’ko S.V. Primenenie teorii setchatykh obolochek pri proektirovanii avtomobilnykh shin [Application of the theory of gridshells in the design of diagonal automobile tires]. Mechanics of machines, mechanisms and materials, 2020, no. 1(50), pp. 5–11 (in Russ.).
  7. User Documentation. Vol. A: Theory and User Information. Copyright ©2017 MSC Software Corporation.
  8. Koutny F. Geometry and mechanics of pneumatic tires. Zlin, CZE, 2007. 139 p.
  9. User Documentation. MAR10 Experimental Elastomer Analysis. Copyright ©2017 MSC Software Corporation.
  10. Rivlin R.S., Saunders D.W. Large elastic deformations of isotropic materials, VII, Experiments on the deformation of rubber. Philosophical Transactions of the Royal Society of London, 1951, vol. 243(Pt. A), pp. 251–288.
  11. Cristensen R.M. Theory of viscoelasticity. Academic Press, New York, 1982. 378 p.
  12. Ivanov L.A., Demenev A.V., Muminova S.R. The inventions in nanotechnologies as practical solutions. Part II. Nanotechnologies in construction, 2019, vol. 11, no. 2, pp. 175–185.