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Warianty tytułu
DPV model i analiza pracy pięciofazowego synchronicznego silnika reluktancyjnego do bezpośredniego startu on-line
Języki publikacji
Abstrakty
The direct-phase variable (DPV) model of a five-phase synchronous reluctance motor (SRM) for direct-on-line starting is presented. The model eliminates the dependence of inductances on rotor position. Machine performance characteristics namely vector potential, speed, flux linkage and current were monitored under different conditions. The DPV model was simulated in MATLAB/Simulink while a finite element model (FEM) was simulated using ANSYS Maxwell FEA software for comparison and validation. Very close similarities in obtained results justify the DPV model.
Przedstawiono moddel pięciofazowego reluktancyjnego silnika synchronicznego wykorzystywanego do startu on-line. Zbadano potencjał wektorowy, szybkość, strumień rozproszony i prąd w różnych warunkach pracy.
Wydawca
Czasopismo
Rocznik
Tom
Strony
24--29
Opis fizyczny
Bibliogr. 25 poz., rys., tab.
Twórcy
autor
- Department of Electrical Engineering, Maritime Academy of Nigeria, Oron, Akwa-Ibom State, Nigeria
autor
- Department of Electrical Engineering, University of Nigeria, Nsukka, Enugu State, Nigeria
autor
- Department of Electrical Engineering, University of Nigeria, Nsukka, Enugu State, Nigeria
autor
- Department of Electrical and Electronic Engineering, Akwa Ibom State Polytechnic, Ikot Osurua, Nigeria
autor
- Department of Electrical Engineering, University of Nigeria, Nsukka, Enugu State, Nigeria
Bibliografia
- [1] Aree P., Precise Analytical Formula for Starting Time Calculation of Medium- and High-Voltage Induction Motors under Conventional Starter Methods, Electrical Engineering, 100 (2018),1195–1203
- [2] Kocman S., Orsag P., Pecinka P., Simulation of Start-Up Behaviour of Induction Motor with Direct Online Connection, Advances in Electrical and Electronic Engineering, 15 (2017), No.5, 754-762
- [3] Ogbuka C., Nwosu C., Umoh G., A New Cross-Saturated Torque Model of Highly Utilized Synchronous Reluctance Machine, Archives of Electrical Engineering, 67 (2018), No. 1 109–121
- [4] Obe E., Binder A., Direct-Phase-Variable Model of a Synchronous Reluctance Motor Including All Slot and Winding Harmonics, Energy Conversion and Management, 52 (2011), No. 1, 284-291
- [5] Stipetic S., Zarko D., Cavar N., Adjustment of Rated Current and Power Factor in a Synchronous Reluctance Motor Optimally Designed for Maximum Saliency Ratio, IEEE Transactions on Industry Applications, 56(2020), No. 3, 2481-2490
- [6] Jurca F., Inte R., Martis C., Optimal Rotor Design of Novel Outer Rotor Reluctance Synchronous Machine, Electrical Engineering, 102 (2020), 107–116
- [7] Chai W., Zhao W., Kwon B., Optimal Design of Wound Field Synchronous Reluctance Machines to Improve Torque by Increasing the Saliency Ratio, IEEE Transactions on Magnetics, 53 (2017), No. 11
- [8] V. Hrabovcová V, Makyš P, Rafajdus P, Šebest M., Improved Barriers Rotor of the Reluctance Synchronous Motor, Electrical Engineering, 99 (2017), 1325–1335
- [9] Alves de Souza S., Suemitsu W., Five-Phase Permanent- Magnet Synchronous Motor, IEEE Latin America Transactions, 15 (2017), No. 4, 639-645
- [10] Umoh G., Ogbuka C., Obe E., Modelling and Analysis of Five-Phase Permanent Magnet Synchronous Motor in Machine Variables, Przegląd Elektrotechniczny, 96 (2020), No.1, 87-92
- [11] Umoh G., Obe E., Five-Phase Synchronous Reluctance Motor: a Better Alternative to The Three-Phase Synchronous Reluctance Motor, ICEPENG 2015 International Conference Nsukka, (2015), 56-61
- [12] Umoh G., Obe E., Analysis of Five-Phase Synchronous Reluctance Motor under Loaded and Faulted Conditions, ICEPENG 2015 International Conference Nsukka, (2005), 37-43
- [13] Mahmoudi A., Kahourzade S., Rahim N., Ping H., Improvement to Performance of Solid-Rotor Ringed Line-Start Axial-Flux Permanent-Magnet Motor, Progress in Electromagnetics Research, 124 (2012), 383-404
- [14] Torkaman H., Afjei E., Gorgani A., Faraji N., Karim H., Arbab N., External Rotor SRM with High Torque per Volume: Design, Analysis, and Experiments, Electrical Engineering, 95 (2013), 393–401
- [15] Duan Y., Ionel I., A Review of Recent Developments in Electrical Machine Design Optimization Methods with a Permanent-Magnet Synchronous Motor Benchmark Study, IEEE Transactions on Industry Applications, 49 (2013), No. 3,1268–1275
- [16] Tahi S., Ibtiouen R., Bounekhla M., Design Optimization of Two Synchronous Reluctance Machine Structure with Maximized Torque and Power Factor, Progress in Electromagnetics Research, 35 (2011), 369-387
- [17] Krüttgen C., Steentjes S., Glehn G., Hameyer K., Parametric Homogenized Model for Inclusion of Eddy Currents and Hysteresis in 2-D Finite-Element Simulation of Electrical Machines, IEEE Transactions on Magnetics. 53 (2017), No. 6
- [18] Zhao W., Xing F., Wang X., Lipo T., Kwon B., Design and Analysis of a Novel PM-Assisted Synchronous Reluctance Machine with Axially Integrated Magnets by the Finite-Element Method, IEEE Transactions on Magnetics, 53 (2017), No. 6
- [19] Tiegna H., Bellara A., Amara Y., Barakat G., Analytical modeling of the open-circuit magnetic field in axial flux permanent-magnet machines with semi-closed slots, IEEE Transactions on Magnetics, 48 (2012), No. 3, 1212-1226
- [20] Azizi H., Vahedi A., Sensitivity Analysis and Optimum Design for the Stator of Synchronous Reluctance Machine using the Coupled Finite and Taguchi Method, Turkish Journal of Electrical and Computer Sciences, 23 (2015), 17–27
- [21] Nekoubin A, Soltani J, Dowlatshahi M (2020) Comparative Analysis of Three-Phase and Five-Phase Permanent-Magnet Motor Based on Finite Element Method, Journal of Electrical Engineering & Technology, 15 (2020), 1705–1712
- [22] Perreira L., Scharlau C., Pereira L., Haffner S., Influence of Saturation on the Airgap Induction Waveform of Five-Phase Induction Machines, IEEE Transactions on Energy Conversion, 27 (2012), No. 1, 29-41
- [23] Parsa L., Toliyat H., Goodarzi A., Five-phase Interior Permanent-Magnet Motors with Low Torque Pulsation, IEEE Transactions on Industry Applications, 43 (2007), No. 1 40–46
- [24] Baek J., Bonthu S., Choi S., Design of Five-Phase Permanent Magnet Assisted Synchronous Reluctance Motor for Low Output Torque Ripple Applications, IET Electric Power Applications, 10 (2016), No. 5, 339–346
- [25] Lin C., Hwang C., High Performances Design of a Six-Phase Synchronous Reluctance Motor Using Multi-Objective Optimization with Altered Bee Colony Optimization and Taguchi Method, Energies, 11 (2018), 1-14
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-98c156df-e850-494f-b1a2-9771f8497c0a