UDC: 629.1.07
https://doi.org/10.25198/2077-7175-2023-6-92
EDN: MIGLEO

THEORETICAL JUSTIFICATION OF THE CHOICE OF THE SPEED MODE DURING THE DRIVING TEST EXPRESS DIAGNOSTICS OF TRANSMISSION UNITS

K. Y. Leliovsky
Nizhny Novgorod State Technical University named after R. E. Alekseev, Nizhny Novgorod, Russia
e-mail: kleliovskiy@mail.ru

Abstract. The relevance of the study is determined by the need to solve the problem of operational management of the current technical condition of the rolling stock. Based on this, technical diagnostics activities become important because they allow you to quickly identify the current technical condition of the vehicle in question. At the same time, it is important, even at the stage of planning diagnostic measures, to choose such operational modes of movement along the test section that would ensure the best information content of the test runs. The theoretical substantiation of the choice of speed modes of arrivals of the studied vehicles along the test section of the road during express diagnostics was the purpose of this work. Research methods: analytical mechanics, differential methods, matrix calculus methods, mathematical numerical methods. The main results are in the proposal of a dynamic model of the vehicle transmission, which takes into account the disturbing effects from the engine and from the support base of the test section, where diagnostic runs are carried out. The amplitude-frequency characteristics of vibration accelerations of the vehicle body are calculated when it moves at given speeds along the simulated test diagnostic section. The practical significance of the study is confirmed by the results of the analysis of the obtained graphs, during which a conclusion was made about the most vibration-dangerous frequency ranges. This is important, since vibrations that occur at certain frequencies, which are directly dependent on the speed of movement, as a rule, cause the most intense responses in specific components and parts of transmission units. Further research is related to the theoretical substantiation of the choice of rational ranges of speed modes of the studied vehicles on the test diagnostic section of the support base, taking into account the characteristics and features of its surfaces. The results of the work are aimed at improving the system of maintenance and repair of the rolling stock of motor vehicles, namely, its diagnosis to determine the presence and degree of development of operational defects and damage, as well as the current technical condition of the transmission units.

Key words: test diagnostics, dynamic loading, transmissions, Lagrange equation of the second kind, speed mode, automobile.

Cite as: Leliovsky, K. Y. (2023) [Theoretical justification of the choice of the speed mode during the driving test express diagnostics of transmission units]. Intellekt. Innovacii. Investicii [Intellect. Innovations. Investments]. Vol. 6, pp. 92–106. – https://doi.org/10.25198/2077-7175-2023-6-92.


References

  1. Banach, L. Ya. (1976) [Simplification of calculation schemes of dynamic systems]. Kolebaniya i dinamicheskaya prochnost’ mashin [Vibrations and dynamic strength of machines] Moscow: Science, pp. 77–81. (In Russ.).
  2. Becker, M. G. (1973) Vvedenie v teoriyusistemmestnost’ – mashina Ch. 1. Mestnost’. Ch. 2. Mashina [Introduction to the theory of terrain – machine systems Part 1. Terrain. Ch. 2. The machine]. Moscow: Mechanical engineering, 520 p.
  3. Belabenko, D. S, Algin, V. B. (2019) [Simulation of the transient process of a hydromechanical transmission with a block of interacting frictions]. Bulletin of the Belarusian-Russian University [Vestnik Belorussko-Rossiyskogo universiteta]. Vol. 3(64), pp. 5−14. https://doi.org/10.53078/20778481_2019_3_5 (In Russ.).
  4. Vejc, V. L., Kochura, A. E. (1976) Dinamikamashinnyhagregatov s dvigatelyamivnutrennegosgoraniya [Dynamics of machine units with internal combustion engines]. Leningrad: Mechanical engineering, 384 p.
  5. Vejc, V. L., Kochura, A. E. (1975) [On the mathematical description of holonomic mechanical systems]. Prikladnaya mekhanika [Applied Mechanics]. Vol. 9. No. 11, pp. 23–28. (In Russ.).
  6. Galevsky, E. A., Spitsyn, A. V. (2005) [An integrated approach to the selection of elements of a dynamic transmission model]. Proyektirovaniye kolesnykh mashin: materialy mezhdunar. simpoz., posvyashch. 175-letiyu MGTU im. N.E. Baumana [Design of wheeled vehicles: materials of inter. symposium dedicated to 175th Anniversary of Bauman Moscow State Technical University]. Moscow: Publishing House of the BMSTU, pp. 150–161. (In Russ.).
  7. Leliovsky, K. Ya. (2021) [Calculation of the dynamic transmission model of a transport and technological means moving progressively over uneven rough terrain in the circumpolar Arctic regions]. Arktika: innovatsionnyetekhnologii, kadry, turizm [Arctic: innovative technologies, personnel, tourism].Voronezh: Publishing House of the G. F. Morozov VGLTU. pp. 222–230. (In Russ.).
  8. Leliovsky K. Ya. (2008) Razrabotka metodiki vibroakusticheskoj ocenki nagruzhennosti i defektov korobok peredach kolyosnyh mashin. Kand.Diss. [Development of methods for vibroacoustic assessment of loading and defects of gearboxes of wheeled vehicles.Cand.Diss.]. Nizhny Novgorod, 253 p. (In Russ.).
  9. Malashkov, I. I., Zel’cer, E. A. (1977) [Investigation of the dependence of the dynamic loads of the car transmission on the schemes of bringing its masses and compliance]. Konstrukcii avtomobilej. Ekspress–informaciya [Constructions of cars. Express information.]. Vol. 8, pp. 29–37. (In Russ.).
  10. Buharin, N. A. et al. (1974) [Determination of damping coefficients in the transmission of a car]. Avtomobil’naya promyshlennost’ [Automotive industry]. Vol. 11, pp. 30–31. (In Russ.).
  11. Alekseeva, S. V. et al. (1982) Silovye peredachi transportnyh mashin: dinamika i raschyot [Power transmission of transport vehicles: dynamics and calculation]. Leningrad: Machine buildings, 256 p.
  12. Taratorkin A. I. (2021) Prognozirovanie I snizhenie dinamicheskoj i vibroakusticheskoj nagruzhennosti energosilovyh blokov kolesnyh I gusenichnyh mashin na osnove sovershenstvovaniy amodal’nyh svojstv [Forecasting and reduction of dynamic and vibroacoustic loading of power units of wheeled and tracked vehicles based on the improvement of modal properties]. Kurgan: Kurgan State University, 200 p.
  13. Shuplyakov, V. S. (1974) Kolebaniya i nagruzhennost’ transmissii avtomobilya [Fluctuations and loading of the transmission of the car]. Moscow: Transport. 328 p.
  14. Board, D. B. (1977) Incipient failure detection for helicopter drive trans.AIAA Pap., No. 898, pp. 1–11. (In Eng.).
  15. Harting, D. R. (1978) Demodulated resonance analysis – аpowerful incipient failure detection technique, ISA Transactions. Vol. 17. No. 1, pp. 35–40. (In Eng.).
  16. Hodges, T. (2003) Development of refined friction materials. Proceedings of the 5-th International symposium of friction products and materials. Yarofri. Yaroslavl, pp. 203–208. (In Eng.).
  17. Leliovsky, K. Ya., (2019) Vibration load of transmission units at vehicle’s motion over different roads. IOP Conference Series: Journal of Physics. No. 012053. https://doi.org/10.1088/1742-6596/1177/1/012053 (In Eng.).
  18. Monk, R. (1979) Machinery health monitoring: Some common defects. J.Noise control vibration, Vol. 10, No. 1, pp. 24–26. (In Eng.).
  19. Olshevskiy, A. et al. (2018) An improved dynamic model of friction draft gear with a transitional characteristic accounting for housing deformation / Hyun-Ik Yang, Chang-Wan Kim. Vehicle System Dynamics: International Journal of Mechanics & Mobility. Vol. 56, iss. 10, pp. 1471–1491. http://dx.doi.org/10.1080/00423114.2017.1415453 (In Eng.).
  20. Schell, J. et al. (2006) Three dimensional vibration testing in automotive application utilizing a new non-contact scanning method. SAE 2006 World Congress & Exhibition. https://doi.org/10.4271/2006-01-1095 (In Eng.).
  21. Taratorkin, A. (2020) Improving the Quality of Transmission Shifting Transients Due to Controlling Torque Redistribution. Journal of Vibration Engineering & Technologies. Vol. 8, iss. 3, pp. 431–441. https://doi.org/10.1007/s42417-019-00183-4. (In Eng.).
  22. Tseng, J.-G., Wickert, J. A. (1994) On the vibration of bolted plate and flange assemblies. Journal of Vibration and Acoustics. Vol. 116(4), pp. 468–473. https://doi.org/10.1115/1.2930450 (In Eng.).