ПОДТВЕРЖДЕНИЕ АДЕКВАТНОСТИ МАТЕМАТИЧЕСКОЙ МОДЕЛИ ЛИНЕЙНОГО СИНХРОННОГО ДВИГАТЕЛЯ

V. F. Novikov

doi:10.15802/stp2015/46055

Authors

V. F. Novikov Dep. «Electrical Systems», Institute of Transport Systems and Technologies of the National Academy of Sciences of Ukraine, Pysarzhevskyi St., 5, Dnipropetrovsk, Ukraine, 49005, tel. +38 (066) 01 99 673, e-mail nvf2005@ua.fm, ORCID 0000-0002-1695-2714, Ukraine https://orcid.org/0000-0002-1695-2714

DOI:

https://doi.org/10.15802/stp2015/46055

Keywords:

high-speed ground transportation, linear synchronous motor, Popper's criterion, critical experiment, permanent magnet

Abstract

Purpose.To reduce labor costs and the amount of computer time in the design of linear synchronous motors with excitation from a source of a constant magnetic field of high-speed ground transportation it is necessary to use engineering methods. The purpose of this study is to confirm the adequacy of the previously proposed mathematical model of this engine and assumptions. It is also intended to confirm the possibility of applying the method of calculation of traction that occurs in the engine in the interaction of the permanent magnetic field of the excitation system of a vehicle with a coil track structure.Methodology. As for empirical theories the positive result of the experiment is not absolute proof of the truth, for an unambiguous conclusion about the adequacy of the developed model and the effectiveness of the developed methods need to be tested for falsification. In accordance with this criterion, it is necessary to conduct an experiment, the results of which will coincide with the calculation but you also need to avoid errors caused by random coincidences. For this purpose the experiments with varying parameters are conducted. Findings. In a critical experiment configuration changes of the excitation system were held so that the shape dependence of traction from displacement is differed significantly. The comparison of the results of the calculated and experimental values of traction for different configurations showed that the differences are minor and easily explained by measurement error and uneven gaps between the poles and excitation coils of the track structure. Originality. The adequacy of the mathematical model of a linear synchronous motor without a ferromagnetic magnetic circuit and the assumptions and applicability of the calculation method of traction forces involved in it, at the interaction of a permanent magnetic field of the excitation system of a vehicle with a coil track structure were proved. This proof is built on conducting a critical experiment by comparing the calculated and experimentally obtained values of the magnitude of traction for different structures of the linear synchronous motor. Practical value. The adequacy of the mathematical model of a linear synchronous motor of high-speed transport with the excitation of the DC magnetic field and the accepted assumptions is proved in this paper. The author also proved the applicability of the method of calculation of traction that occurs in it, the interaction of static magnetic field of the excitation system of a vehicle with a coil track structure. The use of this technique will reduce the amount of labor and machine time for the design of linear synchronous motors from the DC magnetic field of high-speed ground transportation.

Author Biography

V. F. Novikov, Dep. «Electrical Systems», Institute of Transport Systems and Technologies of the National Academy of Sciences of Ukraine, Pysarzhevskyi St., 5, Dnipropetrovsk, Ukraine, 49005, tel. +38 (066) 01 99 673, e-mail nvf2005@ua.fm, ORCID 0000-0002-1695-2714

В. Ф. Новиков

References

Frolov I.T. Vvedeniye v filosofiyu [Introduction to philosophy].Moscow, Respublika Publ., 2003. 623 p.

Dzenzerskiy V.A., Omelyanenko V.I., Vasilev S.V., Matin V.I., Sergeyev S.A.Vysokoskorostnoy magnitnyy transport s elektrodinamicheskoy levitatsiey [High-speed transport with magnetic electrodynamic levitation]. Kiyev, Naukova dumka Publ., 2001. 479 p.

Zaytsev A.N., Voskoboynik V.E., Komarov S.V., Voroshilov A.S. Issledovaniye matematicheskoy modeli privoda s lineynym sinkhronnym dvigatelem v perekhodnykh rezhimakh [Research of mathematical model of the actuator with a linear synchronous motor in transient modes]. Visnyk Dnipropetrovskoho natsionalnoho universytetu zaliznychnoho transportu imeni akademika V. Lazariana [Bulletin of Dnipropetrovsk National University of Railway Transport named after Academician V. Lazaryan], 2006, issue 11, pp. 155-159.

Korniyenko V.V., Omelyanenko V.I. Vysokoskorostnoy elektricheskiy transport: Mirovoy opyt [High-speed electric vehicles: World experience].Kharkov,NationalTechnicalUniversity «Kharkiv Polytechnic Institute» Publ., 2007. 159 p.

Lenin V.I. Materializm i empiriokrititsizm [Materialism and empiriocriticism].Moscow, Zveno Publ., 1926, 400 p.

Novikov V.F., Voroshilov A.S., Matin V.I. Usiliya v lineynom sinkhronnom dvigatele ispytatelnogo uchastka [Efforts in the linear synchronous motor of test site]. Transport: Zbirnyk naukovykh prats Dnipropetrovskoho derzhavnoho tekhnichnoho universytetu zaliznychnoho transportu [Transport: Proc. of Dnipropetrovsk State Technical University of Railway Transport], 2001, issue 9, 184 p.

Polyakov V.A., Khachapuridze N.M. Terminalnoye upravleniye dvizheniyem magnitolevitiruyushchego poyezda s ispolzovaniyem lineynogo sinkhronnogo dvigatelya [Terminal control the movement of the magnetic levitating train using linear synchronous motor]. Visnyk Dnipropetrovskoho natsionalnoho universytetu zaliznychnoho transportu imeni akademika V. Lazariana [Bulletin of Dnipropetrovsk National University of Railway Transport named after Academician V. Lazaryan], 2006, issue 12, pp. 138-145.

Novikov V.F., Burylov S.V., Voskoboynik V.E., Dzenzerskiy V.A. Raschetno-eksperimentalnyy metod opredeleniya potokostsepleniya [Calculation-experimental method for the determination of flux linkage]. Transport: Zbirnyk naukovykh prats Dnipropetrovskoho derzhavnoho tekhnichnoho universytetu zaliznychnoho transportu [Transport: Proc. of Dnipropetrovsk State Technical University of Railway Transport], 2004, issue 5, 240 p.

Liu Sh.-K., An B., Liu S.-K., Guo Zh.-J. Characteristic research of electromagnetic force for mixing suspension electromagnet used in low-speed maglev train. IET Electric Power Applications, 2015, vol. 9, issue 3, pp. 223-228. doi: 10.1049/iet-epa.2013.0414.

Hengkun, L., Hu C. Thrust for Permanent Magnet Linear Synchronous Motor. Applied Mathematics&Information Science, 2015, no. 2, pp. 927-933.

Huang W., Cheng M., Ruiwu C. A new modular and complementary double-sided linear flux-switching permanent magnet motor with yokeless secondary. Electrical Machines and Systems (ICEMS) : 17th International Conference (22.10.-25.10. 2014).Hangzhou, 2014, pp. 3648–3652. doi: 10.1109/icems.2014.7014124.

Liu Zh., Long Zh., Li X. Maglev Train Overview. Springer Tracts in Mech. Engineering, 2015, pp. 1-28. doi: 10.1007/978-3-662-45673-6_1.

Khan M. S. A., Rajkumar R.K., Rajkumar R.K., Aravind C.V. Optimization of Multi-Pole Permanent Magnet Synchronous Generator Based 8 Blade Magnetically Levitated Variable Pitch Low Speed Vertical Axis Wind Turbine. Applied Mech. and Materials, 2014, vol. 492, pp. 113-117. doi: 10.4028/www.scientific.net/amm.492.113.