Signature Analysis of the Hydraulic Accumulators when Using in Energy Recovery Systems in Automobiles

  • Authors

    • Bogdan Korobko
    • Oleksiy Vasyliev
    • Ivan Rohozin
    • Ievgen Vasyliev
    2018-10-13
    https://doi.org/10.14419/ijet.v7i4.8.27446
  • energy recovery, hydraulic accumulator, hydrostatic transmission.

  • The design of a car, which includes the hydrostatic transmission with a kinetic energy recovery system oriented at large-load freights under the conditions of frequent acceleration and repeated brakings has been proposed in this article. Rationale for choosing hydro accumulators for a dream-car (prototype vehicle) has been fulfilled, as well as energy storage battery capacity and the influence of these batteries on the car performance in different operating modes has been carefully analyzed.

     

     

  • References

    1. [1] Moro D, Cavina N, Trivić I, Ravaglioli V, â€Guidelines for Integration of Kinetic Energy Recovery System (KERS) based on Mechanical Flywheel in an Automotive Vehicleâ€, SAE Technical Paper, (2010), 2010-01-1448. doi: 10.4271/2010-01-1448

      [2] Boretti A, â€Modeling of Engine and Vehicle for a Compact Car with a Flywheel Based Kinetic Energy Recovery Systems and a High Efficiency Small Diesel Engineâ€, SAE Technical Paper, (2010), 2010-01-2184. doi: 10.4271/2010-01-2184

      [3] Ho TH, Ahn KK, â€Modeling and simulation of hydrostatic transmission system with energy regeneration using hydraulic accumulatorâ€, Journal of Mechanical Science and Technology, Vol. 24 (5), (2010), pp. 1163–1175. doi: 10.1007/s12206-010-0313-8

      [4] Mastromarco C, Runkel M, â€Rule changes and competitive balance in Formula One motor racingâ€, Applied Economics, Vol. 41:23, (2009), pp. 3003–3014. doi: 10.1080/ 00036840701349182

      [5] Petrov VA, Gidroobyomnyie transmissii samohodnyih mashin, M.: Mashinostroenie, (1988), p. 248.

      [6] Shemelev AM, Shibeko AS, â€Energosberegayuschaya sistema tormozheniya frontalnogo pogruzchikaâ€, Stroitelnyie i dorozhnyie mashinyi, Vol. 6, (2004), pp. 10–14.

      [7] Bauman VA, Stroitelnyie mashinyi: Spravochnik, T. 1, M.: Mashinostroenie, (1976), p. 502.

      [8] Litvinov AS, Farobin YaE, Avtomobil: Teoriya ekspluatatsionnyih svoystv, M.: Mashinostroenie, (1989), p. 240.

      [9] Vasilchenko VA, Gidravlicheskoe oborudovanie mobilnyih mashin: katalog-spravochnik, M.: Mashinostroenie, (1983), p. 301.

      [10] Puddu P, Paderi M, â€Hydro-pneumatic accumulators for vehicles kinetic energy storage: Influence of gas compressibility and thermal losses on storage capabilityâ€, Energy, Vol. 57, (2013), pp. 326–335. doi: 10.1016/j.energy.2013.04.072

      [11] Christians J, â€Approach for Teaching Polytropic Processes Based on the Energy Transfer Ratioâ€, International Journal of Mechanical Engineering Education, Vol. 40/1, (2013), pp. 53–65. doi: 10.7227/IJMEE.40.1.9

      [12] Gulia NV, Nakopiteli energii, M.: Nauka, (1980), p. 152.

      [13] Lin T, Wang Q, Hu B, Gong W, â€Development of hybrid powered hydraulic construction machineryâ€, Automation in Construction, Vol. 19/1, (2010), pp. 11–19. doi: 10.1016/j.autcon.2009.09.005

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  • How to Cite

    Korobko, B., Vasyliev, O., Rohozin, I., & Vasyliev, I. (2018). Signature Analysis of the Hydraulic Accumulators when Using in Energy Recovery Systems in Automobiles. International Journal of Engineering & Technology, 7(4.8), 713-719. https://doi.org/10.14419/ijet.v7i4.8.27446