High efficiency and quick response of torque control for a multi-phase machineUsing discrete/continuous approach: application to five-phase permanent magnet synchronous machine

• Autorzy: Difi Djamel , Halbaoui Khaled , Boukhetala Djamel

Identyfikatory

DOI

10.15199/48.2021.04.23

Warianty tytułu

PL

Sterowanie wielofazowym silnikiem z wykorzystaniem strategii hybrydowej – dyskretno/ciągłej

• Języki publikacji: EN

Abstrakty

EN

This article presents a hybrid control strategy (Discrete/Continuous) for controlling the five-phase permanent magnet synchronous machine powered by a voltage inverter. The hybrid aspect of this approach comes from the fact of taking into account the voltage inverter and the machine in a unified manner during the modelling process, i.e. modelling includes at the same time continuous and discrete variables. Simulation results performed under Matlab/Simulink are presented and discussed for the purpose of the performances verification of the proposed control strategy. The obtained results will show in particular the principal advantages of the adopted control strategy like the enhancement of the dynamic torque response of this machine, and the oscillations’ minimization of controlled parameters such as torque and current.

PL

W artykule zaprezentowano hybrydową strategię sterowania pięciofazowym silnikiem synchronicznym z magnesami trwałymi. Silnik zasilany jest z wykorzystaniem przekształtnika. Przedstawiono wyniki symulacji systemu. Otrzymano poprawę dynamiki momentu I zmniejszenie oscylacji.

Słowa kluczowe

EN

discrete/continuous approach; hybrid control; multi-phase machine

PL

silnik pieciofazowy; silnik synchroniczny; sterowanie hybrydowe

• Wydawca: Wydawnictwo SIGMA-NOT
• Czasopismo: Przegląd Elektrotechniczny
• Rocznik: 2021
• Tom: R. 97, nr 4
• Strony: 128--133
• Opis fizyczny: Bibliogr. 46 poz., rys.

Twórcy

autor

Difi Djamel

• Process Control Laboratory, National Polytechnic School, Algiers, Algeria

autor

Halbaoui Khaled

• Process Control Laboratory, National Polytechnic School, Algiers, Algeria

autor

Boukhetala Djamel

• Process Control Laboratory, National Polytechnic School, Algiers, Algeria

Bibliografia

• [1] Arahal. M.R, Barrero. F, Toral. S, Duran. M, Gregor. R. Multiphase current control using finite-state model-predictive control. Control Engineering Practice 2009; 17: 579–587.
• [2] Echeikh. H, Trabelsi. R, Iqbal. A, Mimouni.M.F. Adaptive direct torque control using Luenberger-sliding mode observer for online stator resistance estimation for five-phase induction motor drives.Electrical Engineering.September 2018, Volume 100, Issue 3, pp 1639–1649.
• [3] Abjadi. N.R. Sliding-mode control of a six-phase series/parallel connected two induction motors drive.ISA Transactions 2014; 53: 1847-1856.
• [4] Hosseyni. A, Trabelsi. R, Mimouni. M.F, Iqbal. A, Alammari. R. Sensorless sliding mode observer for a five-phase permanent magnet synchronous motor drive. ISA Transactions 2015; 58: 462-473.
• [5] IQBAL. A, SINGH. GK, PANT. V.Stability analysis of an asymmetrical six-phase synchronous motor. Turk J Elec Eng & Comp Sci 2016; 24: 1674-1692.
• [6] Saleh. K, Sumner. M.Sensorless speed control of five-phase PMSM drives with low current distortion. Electrical Engineering. June 2018, Volume 100, Issue 2, pp 357–374.
• [7] Wang. X, Wang. Z, Xu. Z. A Hybrid Direct Torque Control Scheme for Dual Three-phase PMSM Drives with Improved Operation Performance. IEEE Transactions on Power Electronics.2018; 63: 321–333.
• [8] Echeikh. H, Trabelsi. R, Iqbal. A, Bianchi. N, Mimouni. M.F. Non-linear control of five-phase IM drive at low speed conditions–experimental implementation. ISA Transactions2016; 65: 244-253.
• [9] Bermudez. M, Gomozov. O, Kestelyn. X, Barrero. F, Nguyen. N.K., Semail. E. Model predictive optimal control considering current and voltage limitations: Real-time validation using OPAL-RT technologies and five-phase permanent magnet synchronous machines. Mathematics and Computers in Simulation. 2019; 158: 148–161.
• [10] Hosseyni. A, Trabelsi. R, Iqbal. A, Mimouni. M.F.. Comparative study of adaptive sliding mode and resonant controllers in fault tolerant five-phase permanent magnet synchronous motor drive,The International Journal of Advanced Manufacturing Technology 2018 ; 96: 2195–2213.
• [11] Záskalický. P. Mathematical model of a five-phase voltage source PWM-controlled inverter. Electrical Engineering. December 2017, Volume 99, Issue 4, pp 1179–1184.
• [12] Schreier. L, Bendl. J, Chomat. M.Operation of five-phase induction motor after loss of one phase of feeding source.Electrical Engineering. March 2017, Volume 99, Issue 1, pp 9–18.
• [13] Iqbal. A, Singh. G.K, Pant. V. Some observations on no-load losses of an asymmetrical six-phase synchronous machine. Turk J Elec Eng & Comp Sci 2016; 24: 4497-4507.
• [14] Barik. S.K, Jaladi. K.K. Five-Phase Induction Motor DTC-SVM scheme with PI Controller and ANN controller. Procedia Technology 2016; 25: 816–823
• [15] Arahal MR, Barrero F, Durán MJ, Ortega MG, Martín C.Trade offs analysis in predictive current control of multi-phase induction machines, Control Engineering Practice 2018; 81:105-113.
• [16] Arahal MR, Duran MJ. PI tuning of five-phase drives with third harmonic injection. Control Engineering Practice 2009; 17: 787–797.
• [17] Boudjema Z, Taleb R, Djeriri Y, Yahdou A. A novel direct torque control using second order continuous sliding mode of a doubly fed induction generator for a wind energy conversion system. Turk J Elec Eng & Comp Sci 2017; 25: 965-975.
• [18] Ouassaid M, Elyaalaoui K, Cherkaoui M. SlidingMode Control of Induction Generator Wind Turbine Connected to the Grid. Advances and Applications in Nonlinear Control Systems.2016. 635:531-553.
• [19] Monmasson. E, Louis. J.P. Presentation of a control law for IM drive based on the dynamic reconfiguration of a DTC algorithm and a SVM-DTC algorithm. Mathematics and Computers in Simulation. 2003; 63: 321–333.
• [20] Sandre-Hernandez . O, Rangel-Magdaleno. J, Morales Caporal. R, Bonilla-Huerta. E. HIL simulation of the DTC for a three-level inverter fed a PMSM with neutral-point balancing control based on FPGA. Electrical Engineering.September 2018, Volume 100, Issue 3, pp 1441–1454.
• [21] Khedher. A, Mimouni. M.F. Sensorless-adaptive DTC of double star induction motor. Energy Conversion and Management2010; 51: 2878–2892.
• [22] Ammar. A, Benakcha. A, Bourek. A. Closed loop torque SVM DTC based on robust super twisting speed controller for induction motor drive with efficiency optimization. international journal of hydrogen energy 2017; xxx: 1-3
• [23] Pimkumwong. N, Wang. M.S.Full-order observer for direct torque control of induction motor based on constant V/F control technique. ISA Transactions 2018; 73: 189-200.
• [24] Mesloub. H, Boumaaraf. R, Benchouia. M.T, Goléa. A, Goléa. N, Srairi. K.Comparative study of conventional DTC and DTC SVM based control of PMSM motor - simulation and experimental results. Mathematics and Computers in Simulation. 2018; 63: 321–333.
• [25] Morel. F, Retif. J.M, Lin-Shi. X, Valentin. C. Permanent Magnet Synchronous Machine Hybrid Torque Control. IEEE transactions on Industrial Electronics 2008; 55: 501-511.
• [26] X Lin-Shi, F Morel, A Llor, B Allard, J M Rétif. Implementation of Hybrid Control for Motor Drives. IEEE Transactions on Industrial Electronis 2007; 54: 1946-1952.
• [27] Lin-Shi X. Commande des systèmes de conversion d'énergie. Habilitation à diriger des recherches. Institut National des Sciences Appliquées de Lyon juillet 2007.
• [28] Morel F, Lin-Shi X, Rétif JM, Allard B.A predictive current control applied to a permanent magnet synchronous machine, comparison with a classical direct torque control. Electric Power Systems 2008; 78: 1437-1447.
• [29] Retif JM, Lin-Shi X, Llor AM, Morand F.New Hybrid Direct Torque Control for a Winding Rotor Synchronous Machine. IEEE Power Elecrronics Speciulisrs Conference 2004.
• [30] Morel F, Rtif JM, Lin-Shi X, LIor AM.Fixed Switching Frequency Hybrid Control for a Permanent Magnet Synchronous Machine. IEEE International Conference on Industrial Technology 2004.
• [31] Arichi F, Gorp JV, Djemai M, Defoort M, Cherki B..Hybrid state estimation for a class of switched system using Petri Nets. European Control Conference 2014.
• [32] Elmetennani S, Laleg-Kirati TM, Djemai M, Tadjine M.New MPPT algorithm for PV applications based on hybrid dynamicalapproach. Journal of Process Control 2016; 48: 14-24.
• [33] Gorp JV, Giua A, Defoort M, Djemaï M. Active Diagnosis for Switched Systems Using Mealy Machine Modeling. Diagnosability, Security and Safety of Hybrid Dynamic and Cyber-Physical Systems 2018.147-173.
• [34] Djondiné P, Barbot JP, Ghanes M.On the Petri Nets Control of the Multicellular Converter. International Journal of Emerging Technology and Advanced Engineering 2017; 7: 332-336.
• [35] Liu X, Stechlinski P.Switching and impulsive control algorithms for nonlinear hybrid dynamical systems. Nonlinear Analysis: Hybrid Systems 2018; 27: 307–322.
• [36] Halbaoui K, Belazreg MF, Boukhetala D, Belhouchat MH.Modeling and Predictive Control of Nonlinear Hybrid Systems Using Mixed Logical Dynamical Formalism. Advances and Applications in Nonlinear Control Systems.2016. 635:421-450
• [37] Djondiné P, Barbot JP, Ghanes M.Comparison of Sliding Mode and Petri Nets Control for Multicellular Chopper. International Journal of Nonlinear Science 2018; 25: 67-75.
• [38] Defoort M, Gorp JV, Djemai M..Multicellular Converter: A Benchmark for Control and Observation for Hybrid Dynamical Systems. Hybrid Dynamical Systems 2015 293-313.
• [39] Benmiloud M, Benalia A.Hybrid Control Scheme for Multicellular Converter.IEEE 2013 International Conference on Control, Decision and Information Technologies (CoDIT); 476-482.
• [40] Benmansour K, Benalia A, Djemai M, Leon J.Hybrid control of a multicellular converter. Nonlinear Analysis: Hybrid Systems2007; 1: 16–29.
• [41] Semail E. Entrainements Electriques Polyphasés: vers une approche système. Rapport de L’Habilitation à Diriger des Recherches, Université des Sciences et Technologies de Lille2009.
• [42] Jones M, Satiawan INW. A simple multi-level space vector modulation algorithm for five-phase open-end winding drives. Mathematics and Computers in Simulation 2013: 90: 74–85.
• [43] Toliyat, HA.. Analysis and simulation of multi-phase variable speed induction motor drives under asymmetrical connections. In Applied Power Electronics Conference and Exposition 1996; 2:586-592.
• [44] Vizireanu D, Brisset S, Kestelyn X, Brochet P, Miletet Y, Laloy D. Investigation on multi-star structures for large power direct drive wind generator. Electric Power Components and Systems2007; 35:135-152.
• [45] Kesraoui.H, Benelghali .S, Trabelsi.R, Mimouni. M.F, Outbib.R. Control Of Tow Five-Phase Synchronous Machine Series Connected Supplied Through A Five Arms Inverter With Alternate Mode.IEEE 2014 International Conference on Electrical Sciences and Technologies in Maghreb (CISTEM)
• [46] Guzman. H, Duran. M.J, Barrero.F,Toral. S. Fault- tolerant current predictive control of five-phase induction motor drives with an open phase. 37th Annual Conference of the IEEE Industrial Electronics Society 2011.

Uwagi

Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2021).