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Power flows in a hydrostatic-mechanical transmission of a mining locomotive during the braking process

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Języki publikacji
EN
Abstrakty
EN
This paper considers the braking process of a mine diesel locomotive with hydrostatic mechanical transmission (HSMT) operating according to the “input differential” scheme. Braking process modeling involves four implementation methods. Identification and systematization of basic regularities in the distribution of power flows within a closed transmission contour in the process of braking have been performed with the help of software support developed by means of MatLab/Simulink. The simulation results of braking due to the hydrostatic transmission and the braking system during the movement of a diesel locomotive in the transport and traction ranges are presented in the form of graphical correlations. The process of theoretical studies of the braking process of a diesel locomotive with HSMT operating according to the “input differential” scheme has helped determine that, in terms of deceleration at the expense of a hydrostatic drive (HSD) and braking system while preserving kinematic engine-wheels connection, it is not permitted to implement this method of braking process as it is followed by excess of the allowable value of working pressure differential within HSD up to 2.8 times.
Czasopismo
Rocznik
Strony
17--28
Opis fizyczny
Bibliogr. 35 poz.
Twórcy
  • National Technical University "Kharkiv Polytechnic Institute" Kyrpychova st., 2, Kharkiv, 61002, Ukraine
  • National Technical University "Kharkiv Polytechnic Institute" Kyrpychova st., 2, Kharkiv, 61002, Ukraine
autor
  • Dnipro University of Technology D. Yavornytsky av., 19, Dnipro, 49005, Ukraine
  • Dnipro University of Technology D. Yavornytsky av., 19, Dnipro, 49005, Ukraine
Bibliografia
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  • 2. Zabolotny, K. & Panchenko, E. Definition of rating loading in spires of multilayer winding of rubberrope cable. New Techniques and Technologies in Mining. 2010. P. 223-229.
  • 3. Ilin, S.R. & Samusya, V.I. & Kolosov, D.L. & Ilina, I.S. & Ilina, S.S. Risk-forming dynamic processes in units of mine hoists of vertical shafts. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu. 2018. Vol. 5. P. 64-71.
  • 4. Belmas, I. & Kolosov, D. The stress-strain state of the stepped rubber-rope cable in bobbin of winding. Technical and Geoinformational Systems in Mining: School of Underground Mining 2011. P. 211-214.
  • 5. Сладковски, А. К вопросу моделирования привода локомотива при помощи МКЭ. Вестник Ростовского государственного университета путей сообщения. 2011. Vol. 4(44). P. 121-128. [In Russian: Sladkowski, А. To the problem of modeling of the locomotive transmission by means of the FEM. Bulletin of the Rostov State University of Railway Transport].
  • 6. Larsson, L.V. & Larsson, K.V. Simulation and Testing of Energy Efficient Hydromechanical Drivelines for Construction Machinery. Master’s Thesis, Linkoping University. Linkoping, Sweden. 2014. 136 p.
  • 7. Taran, I. & Klymenko, I. Innovative mathematical tools for benchmarking transmissions of transport vehicles. Naukovyi visnyk Natsionalnoho hirnychoho universytetu. 2014. Vol. 3. P. 76-81.
  • 8. Haniszewski, T. Modeling the dynamics of cargo lifting process by overhead crane for dynamic overload factor estimation. Journal of Vibroengineering. 2017. Vol. 19(1). P.75-86.
  • 9. Anderl, T. & Winkelhake, J. & Scherer, M. Power-split transmissions for construction machinery. In: Proceedings of the 8th International Fluid Power Conference (IFK 2012), Dresden, Germany. 22–24 March 2012. P. 189–201.
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  • 15. Taran, I.A. Laws of power transmission on branches of double-split hydrostatic mechanical transmissions. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu. 2012. Vol. 2. P. 69-75.
  • 16. Zabolotnyi, K.S. & Panchenko, O.V. & Zhupiiev, O.L. & Polushyna, M.V. Influence of parameters of a rubber-rope cable on the torsional stiffness of the body of the winding. Naukovyi Visnyk Natsіonalnoho Hіrnychoho Unіversitetu. 2018. Vol. 5. P. 54-63.
  • 17. Singh, R.B. & Kumar, R.& Das, J. Hydrostatic transmission systems in heavy machinery: overview. International Journal of Mechanical and Production Engineering. 2013. Vol. 1. No. 4. P. 47-51.
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  • 31. Zhang, H. & Liu, F. & Zhu, S. & Xiao, M. & Wang, G. & Wang, G. & Zhang, W. The optimization design of a new type of hydraulic power-split continuously variable transmission for high-power tractor. J. Nanjing Agric. Univ. 2016. Vol. 39. P. 156-165.
  • 32. Taran, I. & Klymenko, I. Transfer ratio of double-split transmissions in case of planetary gear input. Naukovyi visnyk Natsionalnoho hirnychoho universytetu. 2013. Vol. 6. P. 60-66.
  • 33. Bublikov, A.V. & Gruhler, G. & Gorlach, I.A. & Cawood, G. Control strategy for a mobile platform with an omni-directional drive. Naukovyi Visnyk Natsionalnoho Hirnychoho Universytetu. 2015. Vol. 2. P. 84-90.
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  • 35. Pettersson, K. Design Automation of Complex Hydromechanical Transmissions. In: Linkoping Studies in Science and Technology. Licentiate Thesis Linkoping University. Linkoping, Sweden, 2013. P. 1620.
Uwagi
PL
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-061b850a-5be7-468d-a506-1708a479d698
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