Development of an experimental plant and a numerical model of an axial magnetic rotor suspension

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Abstract

This article presents the results of the work on the creation of an experimental plant, its testing, as well as the development of a computational model of a rotor magnetic suspension with the use of axial electromagnets. The main purpose of producing the plant was to test the results of the developed numerical finite element model. An automatic control system was developed for the experimental installation. The electrical circuit was assembled on the basis of a ESP32 microcontroller with a clock frequency of 240 MHz and a PWM with a capacity of 10 bits. A PID-regulator program was developed. The coefficients kP, kD, kI used in the code of the electronic control system program (PID-controller) were selected. An experimental study of the bearing capacity of the axial active magnetic bearing under the influence of an external axial force was conducted. The required power of the axial active magnetic bearing was determined. The maximum load-bearing capacity of the installation for the selected coefficients of the PID-controller was determined. An axisymmetric finite-element model of the axial active magnetic bearing was created in the open-source program FEMM 4.2. The load-bearing capacity of the installation for a given current intensity value was calculated.  The results of the numerical modelling were compared with the experimental data obtained. The basic principles of creation and operation of the experimental plant and its numerical model are outlined.

About the authors

M. A. Benedyuk

Samara National Research University

Author for correspondence.
Email: benedyuk00@bk.ru
ORCID iD: 0000-0003-0356-2618

Student of the Institute of Engine and Power Plant Engineering

Russian Federation

A. O. Lomachev

Samara National Research University

Email: al.lomachev@gmail.com

Student of the Institute of Engine and Power Plant Engineering

Russian Federation

R. R. Badykov

Samara National Research University

Email: renatbadykov@gmail.com
ORCID iD: 0000-0003-1605-0320

Candidate of Science (Engineering), Associate Professor of the Department of Aircraft Engine Construction and Design

Russian Federation

K. V. Bezborodova

Samara National Research University

Email: krityborodova@gmail.com

Student of the Institute of Engine and Power Plant Engineering

Russian Federation

A. A. Yurtaev

Samara National Research University

Email: don.yurtaev2016@yandex.ru

Student of the Institute of Engine and Power Plant Engineering

Russian Federation

References

  1. Kazakov L.A. Elektromagnitnye ustroystva REA: spravochnik [Electromagnetic devices in electronics: Handbook]. Moscow: Radio i Svyaz' Publ., 1991. 352 p.
  2. Solnyshkin N.I. Teoreticheskie osnovy elektrotekhniki. Modelirovanie elektromagnitnykh poley [Theoretical foundations of electrical engineering. Simulation of electromagnetic fields]. Pskov: Pskov State University Publ., 2013. 64 p.
  3. Zhuravlev Yu.N. Aktivnye magnitnye podshipniki: Teoriya, raschet, primenenie [Active magnetic bearings: Theory, calculation, application]. SPB: Politekhnika Publ., 2003. 206 p.
  4. Makridenko L.A., Sarychev A.P., Abduragimov A.S., Vereshchagin V.P., Rogoza A.V. VNIIEM methods for electromagnetic bearing design. Electromechanical Matters. VNIIEM Studies. 2016. V. 152, no. 3. P. 3-14. (In Russ.)
  5. Yu J., Zhu Ch. A sensor-fault tolerant control method of active magnetic bearing in flywheel energy storage system. Proceedings of the IEEE Vehicle Power and Propulsion Conference (VPPC) (October, 17-20, 2016, Hangzhou, China). doi: 10.1109/VPPC.2016.7791595
  6. Spece H., Fittro R., Knospe C. Optimization of axial magnetic bearing actuators for dynamic performance. Actuators. 2018. V. 7, Iss. 4. doi: 10.3390/act7040066
  7. Izosimova T.A., Evdokimov Yu.K. Metodika proektirovaniya aktivnogo magnitnogo podvesa v sostave rotornoy mashiny s avtomaticheskoy sistemoy upravleniya. Materialy XI Vserossiyskoy nauchno-tekhnicheskoy konferentsii «Informatsionnye Tekhnologii v Elektrotekhnike i Elektroenergetike» (June, 08, 2018, Cheboksary). Cheboksary: Chuvash State University, 2018. P. 98-101. (In Russ.)
  8. Whitlow Z.W., Fittro R.L., Knospe C.R. Dynamic performance of segmented active magnetic thrust bearings. IEEE Transactions on Magnetics. 2016. V. 52, Iss. 11. doi: 10.1109/TMAG.2016.2587700
  9. Amoskov V.M., Andreev E.N., Belyakov V.A., Vasiliev V.N., Vasilieva O.S., Dyomina A.A., Kaparkova M.V., Kukhtin V.P., Lamzin E.A., Lantzetov A.A., Lantzetov V.A., Larionov M.S., Nezhentzev A.N., Rodin I.Y., Samoilov S.K., Sytchevsky S.E., Firsov A.A., Shatil N.A. Dynamic measurements of train-to-track air gap for levitated transport. Transportation Systems and Technology. 2016. V. 2, no. 2. P. 39-42. (In Russ.). doi: 10.17816/transsyst20162239-42
  10. Rossi M., Dezza F.C., Mauri M., Carmeli M.S., Braghin F. Rotor position estimation in a large air gap active magnetic bearing. Proceedings of the 11th IEEE International Conference on Compatibility, Power Electronics and Power Engineering (CPE-POWERENG) (April, 4-6, 2017, Spain). P. 258-263. doi: 10.1109/CPE.2017.7915179

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