Model of Spring Liquid-Gas Tension Compensator of Overhead Catenary Wires and Messenger Cables

There is discussed the design version of spring liquid-gas type tension compensator of overhead catenary wires and messenger cables. Also presented is computer model of oscillations under conditions of linear and non-linear resistance. The task of improving current collection at high train speeds requires efficient suppression of the first large-amplitude oscillation and of all the subsequent small-amplitude oscillations as well. It has been indicated that non-linear quadratic resistance is necessary for efficient suppression of the first oscillation and linear resistance is needed for efficient suppression of the subsequent oscillations. Quadratic characteristic of the compensator resistance has been obtained employing liquid friction provisions and gas friction provisions have been used for obtaining its linear characteristic. Based on the solution results of the piston motion differential equations, piston position curves have been plotted for the cases of large and small deviations. It has been demonstrated that the proposed compensator design version and combined use of liquid friction and liquid-gas friction ensure efficient suppression of the overhead catenary major and slight oscillations. Application of the spring liquid-gas tension compensator of wires and messenger cables of overhead catenary system PZhG-1 makes possible forgoing of awkward wireline-roller systems.

overhead catenary system, tension, compensator, liquid friction, gas friction

1. Derbaremdiker A. D. Gidravlicheskie amortizatory avtomobiley [Hydraulic shock absorbers of cars]. Moscow, Mashinostroenie Publ., 1969. 236 p.

2. Mikheev V. P., Sebelev V. I. Kontaktnye podveski i ikh kharakteristiki [Contact suspenders and their characteristics]. Omsk, Omsk Institute of Railway Engineers Publ., 1990. 79 p.

3. Vologin V. A. Vzaimodeystvie tokopriemnikov i kontaktnoy seti [Pantograph/catenary interaction]. Moscow, Intext Publ., 2006. 256 p.

4. Eroshenko S. V., Demchenko A. T., Turkin V. V. Metod pryamogo matematicheskogo modelirovaniya dinamiki kontaktnykh podvesok [Direct method of mathematical modeling of the dynamics of overhead lines]. Transport Rossiyskoy Federatsii, spec. issue “Nauka i transport”, 2007, pp. 32 – 33.

5. Vologin V. A., Gerasimov A. S. Dinamicheskie parametry sistemy kontaktnaya set’ — tokopriemnik [Dynamic parameters of catenary-current collector system]. Vestnik VNIIZhT [Vestnik of the Railway Research Institute], 2008, no. 2, pp. 19 – 23.

6. Kolesnikov G. N., Kuvshinov D. A. Chislennoe modelirovanie dinamicheskogo vzaimodeystviya tokopriemnikov i kontaktnoy seti [Numerical modeling of dynamic interaction of pantograph and catenary]. Vestnik VNIIZhT [Vestnik of the Railway Research Institute], 2012, no. 1, pp. 9 – 12.

7. Issledovanie kontaktnoy podveski po silam vzaimodeystviya tokopriemnika i kontaktnogo provoda [The study of the overhead catenary by the interaction forces of pantograph and contact wire]. Zheleznye dorogi mira, 2007, no. 11, pp. 45 – 52.

8. Khalikov K. R. Vyravnivanie zhestkosti kontaktnoy podveski v proletakh ankernogo uchastka [Equalization of rigidity of catenary in spans of anchor section]. Izvestiya Transsiba, 2012, no. 4 (12), pp. 58 – 69.

9. Kudryashov E. V., Zarenkov S. V., Khodunova O. A. Metod rascheta elastichnosti na osnove prostoy konechno-elementnoy modeli. Izmereniya elastichnosti [The method of calculating of the catenary wire elasticity based on simple finite element model. Elasticity measurements]. Izvestiya Transsiba, 2011, no. 4 (8), pp. 16 – 26.

10. Pisano A., Usai E. Contact force estimation and regulation in active pantograph: An algebraic observability approach. Asian Journal of Control, 2010, vol. 12, no. 5, pp. 575 – 666.

11. Capacchione R., Sieg M., Spieß K. Nachspanneinrichtungen für Oberleitungen mit Federkraft [Tensioning device for overhead contact lines using strings]. Elektrische Bahnen, 2011, no. 7, pp. 331 – 337.