896 research outputs found
Fault-Tolerant Control of a Flux-switching Permanent Magnet Synchronous Machine
Je jasnĂ©, ĆŸe nejĂșspÄĆĄnÄjĆĄĂ konstrukce zahrnuje postup vĂcefĂĄzovĂ©ho ĆĂzenĂ, ve kterĂ©m kaĆŸdĂĄ fĂĄze mĆŻĆŸe bĂœt povaĆŸovĂĄna za samostatnĂœ modul. Provoz kterĂ©koliv z jednotek musĂ mĂt minimĂĄlnĂ vliv na ostatnĂ, a to tak, ĆŸe v pĆĂpadÄ selhĂĄnĂ jednĂ© jednotky ostatnĂ mohou bĂœt v provozu neovlivnÄny. ModulĂĄrnĂ ĆeĆĄenĂ vyĆŸaduje minimĂĄlnĂ elektrickĂ©, magnetickĂ© a tepelnĂ© ovlivnÄnĂ mezi fĂĄzemi ĆĂzenĂ (mÄniÄe). SynchronnĂ stroje s pulznĂm tokem a permanentnĂmi magnety se jevĂ jako atraktivnĂ typ stroje, jejĂĆŸ pĆednostmi jsou vysokĂœ kroutĂcĂ moment, jednoduchĂĄ a robustnĂ konstrukce rotoru a skuteÄnost, ĆŸe permanentnĂ magnety i cĂvky jsou umĂstÄny spoleÄnÄ na statoru. FS-PMSM jsou pomÄrnÄ novĂ© typy stĆĂdavĂ©ho stroje stator-permanentnĂ magnet, kterĂ© pĆedstavujĂ vĂœznamnĂ© pĆednosti na rozdĂl od konvenÄnĂch rotorĆŻ - velkĂœ kroutĂcĂ moment, vysokĂœ toÄivĂœ moment, v podstatÄ sinusovĂ© zpÄtnĂ© EMF kĆivky, zĂĄroveĆ kompaktnĂ a robustnĂ konstrukce dĂky umĂstÄnĂ magnetĆŻ a vinutĂ kotvy na statoru. SrovnĂĄnĂ vĂœsledkĆŻ mezi FS-PMSM a klasickĂœmi motory na povrchu upevnÄnĂœmi PM (SPM) se stejnĂœmi parametry ukazuje, ĆŸe FS-PMSM vykazuje vÄtĆĄĂ vzduchovĂ© mezery hustoty toku, vyĆĄĆĄĂ toÄivĂœ moment na ztrĂĄty v mÄdi, ale takĂ© vyĆĄĆĄĂ pulzaci dĂky reluktanÄnĂmu momentu. Pro stroje buzenĂ© permanentnĂmi magnety se jednĂĄ o tradiÄnĂ rozpor mezi poĆŸadavkem na vysokĂœ kroutĂcĂ moment pod zĂĄkladnĂ rychlostĂ (oblast konstantnĂho momentu) a provozem nad zĂĄkladnĂ rychlostĂ (oblast konstantnĂho vĂœkonu), zejmĂ©na pro aplikace v hybridnĂch vozidlech. Je pĆedloĆŸena novĂĄ topologie synchronnĂho stroje s permanentnĂmi magnety a spĂnanĂœm tokem odolnĂ©ho proti poruchĂĄm, kterĂĄ je schopnĂĄ provozu bÄhem vinutĂ naprĂĄzdno a zkratovanĂ©ho vinutĂ i poruchĂĄch mÄniÄe. SchĂ©ma je zaloĆŸeno na dvojitÄ vinutĂ©m motoru napĂĄjenĂ©m ze dvou oddÄlenĂœch vektorovÄ ĆĂzenĂœch napÄĆ„ovĂœch zdrojĆŻ. VinutĂ jsou uspoĆĂĄdĂĄna takovĂœm zpĆŻsobem, aby tvoĆila dvÄ nezĂĄvislĂ© a oddÄlenĂ© sady. Simulace a experimentĂĄlnĂ vĂœzkum zpĆesnĂ vĂœkon bÄhem obou scĂ©nĂĄĆĆŻ jak za normĂĄlnĂho provozu, tak za poruch vÄetnÄ zkratovĂœch zĂĄvad a ukĂĄĆŸĂ robustnost pohonu za tÄchto podmĂnek. Tato prĂĄce byla publikovĂĄna v deseti konferenÄnĂch pĆĂspÄvcĂch, dvou Äasopisech a kniĆŸnĂ kapitole, kde byly pĆedstaveny jak topologie pohonu a aplikovanĂĄ ĆĂdĂcĂ schĂ©mata, tak analĂœzy jeho schopnosti odolĂĄvat poruchĂĄm.It has become clear that the most successful design approach involves a multiple phase drive in which each phase may be regarded as a single-module. The operation of any one module must have minimal impact upon the others, so that in the event of that module failing the others can continue to operate unaffected. The modular approach requires that there should be minimal electrical, magnetic and thermal interaction between phases of the drive. Flux-Switching permanent magnet synchronous machines (FS-PMSM) have recently emerged as an attractive machine type virtue of their high torque densities, simple and robust rotor structure and the fact that permanent magnets and coils are both located on the stator. Flux-switching permanent magnet (FS-PMSM) synchronous machines are a relatively new topology of stator PM brushless machine. They exhibit attractive merits including the large torque capability and high torque (power) density, essentially sinusoidal back-EMF waveforms, as well as having a compact and robust structure due to both the location of magnets and armature windings in the stator instead of the rotor as those in the conventional rotor-PM machines. The comparative results between a FS-PMSM and a traditional surface-mounted PM (SPM) motor having the same specifications reveal that FS-PMSM exhibits larger air-gap flux density, higher torque per copper loss, but also a higher torque ripple due to cogging -torque. However, for solely permanent magnets excited machines, it is a traditional contradiction between the requests of high torque capability under the base-speed (constant torque region) and wide speed operation above the base speed (constant power region) especially for hybrid vehicle applications. A novel fault-tolerant FS-PMSM drive topology is presented, which is able to operate during open- and short-circuit winding and converter faults. The scheme is based on a dual winding motor supplied from two separate vector-controlled voltage-sourced inverter drives. The windings are arranged in a way so as to form two independent and isolated sets. Simulation and experimental work will detail the driverâs performance during both healthy- and faulty- scenarios including short-circuit faults and will show the drive robustness to operate in these conditions. The work has been published in ten conference papers, two journal papers and a book chapter, presenting both the topology of the drive and the applied control schemes, as well as analysing the fault-tolerant capabilities of the drive.
Control Strategies for Open-End Winding Drives Operating in the Flux-Weakening Region
This paper presents and compares control strategies for three-phase open-end winding drives operating in the flux-weakening region. A six-leg inverter with a single dc-link is associated with the machine in order to use a single energy source. With this topology, the zero-sequence circuit has to be considered since the zero-sequence current can circulate in the windings. Therefore, conventional over-modulation strategies are not appropriate when the machine enters in the flux-weakening region. A few solutions dealing with the zero-sequence circuit have been proposed in literature. They use a modified space vector modulation or a conventional modulation with additional voltage limitations. The paper describes the aforementioned strategies and then a new strategy is proposed. This new strategy takes into account the magnitudes and phase angles of the voltage harmonic components. This yields better voltage utilization in the dq frame. Furthermore, inverter saturation is avoided in the zero-sequence frame and therefore zero-sequence current control is maintained. Three methods are implemented on a test bed composed of a three-phase permanent-magnet synchronous machine, a six-leg inverter and a hybrid DSP/FPGA controller. Experimental results are presented and compared for all strategies. A performance analysis is conducted as regards the region of operation and the machine parameters.Projet SOFRACI/FU
A Novel PMSM Hybrid Sensorless Control Strategy for EV Applications Based on PLL and HFI
In this paper, a novel hybrid sensorless control strategy for Permanent Magnet Synchronous Machine (PMSM) drives applied to Electric Vehicles (EV) is presented. This sensorless strategy covers the EV full speed range and also has speed reversal capability. It combines a High Frequency Injection (HFI) technique for low and zero speeds, and a Phase-Locked Loop (PLL) for the medium and high speed regions. A solution to achieve smooth transitions between the PLL and the HFI strategies is also proposed, allowing to correctly detect the rotor position polarity when HFI takes part. Wide speed and torque four-quadrant simulation results are provided, which validate the proposed sensorless strategy for being further implemented in EV.Peer ReviewedPostprint (author's final draft
Magnetic noise reduction of in-wheel permanent magnet synchronous motors for light-duty electric vehicles
This paper presents study of a multi-slice subdomain model (MS-SDM) for persistent low-frequency sound, in a wheel hub-mounted permanent magnet synchronous motor (WHM-PMSM) with a fractional-slot non-overlapping concentrated winding for a light-duty, fully electric vehicle applications. While this type of winding provides numerous potential benefits, it has also the largest magnetomotive force (MMF) distortion factor, which leads to the electro-vibro-acoustics production, unless additional machine design considerations are carried out. To minimize the magnetic noise level radiated by the PMSM, a skewing technique is targeted with consideration of the natural frequencies under a variable-speed-range analysis. To ensure the impact of the minimization technique used, magnetic force harmonics, along with acoustic sonograms, is computed by MS-SDM and verified by 3D finite element analysis. On the basis of the studied models, we derived and experimentally verified the optimized model with 5 dBA reduction in A-weighted sound power level by due to the choice of skew angle. In addition, we investigated whether or not the skewing slice number can be of importance on the vibro-acoustic objectives in the studied WHM-PMSM.Postprint (published version
Advanced deep flux weakening operation control strategies for IPMSM
This paper proposes an advanced flux-weakening control method to enlarge the speed range of interior permanent magnet synchronous motor (IPMSM). In the deep flux weakening (FW) region, the flux linkage decreases as the motor speed increases, increasing instability. Classic control methods will be unstable when operating in this area when changing load torque or reference speed is required. The paper proposes a hybrid control method to eliminate instability caused by voltage limit violation and improve the reference velocity-tracking efficiency when combining two classic control methods. Besides, the effective zone of IPMSM in the FW is analyzed and applied to enhance stability and efficiency following reference velocity. Simulation results demonstrate the strength and effectiveness of the proposed method
Constrained field-oriented control of permanent magnet synchronous machine with field-weakening utilizing a reference governor
This paper presents a complete solution for constrained control of a permanent magnet synchronous machine. It utilizes field-oriented control with proportional-integral current controllers tuned to obtain a fast transient response and zero steady-state error. To ensure constraint satisfaction in the steady state, a novel field-weakening algorithm which is robust to flux linkage uncertainty is introduced. Field weakening problem is formulated as an optimization problem which is solved online using projected fast gradient method. To ensure constraint satisfaction
during current transients, an additional device called current reference governor is added to the existing control loops. The constraint satisfaction is achieved by altering the reference signal. The reference governor is formulated as a simple optimization problem whose objective is to minimize the difference between the true reference and a modified one. The proposed method is implemented on Texas instruments F28343 200 MHz microcontroller and experimentally verified on a surface mounted permanent magnet synchronous machine
Field weakening and sensorless control solutions for synchronous machines applied to electric vehicles.
184 p.La poluciĂłn es uno de los mayores problemas en los paĂses industrializados. Por ello, la electrificaciĂłn del transporte por carretera estĂĄ en pleno auge, favoreciendo la investigaciĂłn y el desarrollo industrial. El desarrollo de sistemas de propulsiĂłn eficientes, fiables, compactos y econĂłmicos juega un papel fundamental para la introducciĂłn del vehĂculo elĂ©ctrico en el mercado.Las mĂĄquinas sĂncronas de imanes permanentes son, a dĂa de hoy la tecnologĂa mĂĄs empleada en vehĂculos elĂ©ctricos e hĂbridos por sus caracterĂsticas. Sin embargo, al depender del uso de tierras raras, se estĂĄn investigando alternativas a este tipo de mĂĄquina, tales como las mĂĄquinas de reluctancia sĂncrona asistidas por imanes. Para este tipo de mĂĄquinas sĂncronas es necesario desarrollar estrategias de control eficientes y robustas. Las desviaciones de parĂĄmetros son comunes en estas mĂĄquinas debido a la saturaciĂłn magnĂ©tica y a otra serie de factores, tales como tolerancias de fabricaciĂłn, dependencias en funciĂłn de la temperatura de operaciĂłn o envejecimiento. Las tĂ©cnicas de control convencionales, especialmente las estrategias de debilitamiento de campo dependen, en general, del conocimiento previo de dichos parĂĄmetros. Si no son lo suficientemente robustos, pueden producir problemas de control en las regiones de debilitamiento de campo y debilitamiento de campo profundo. En este sentido, esta tesis presenta dos nuevas estrategias de control de debilitamiento de campo hĂbridas basadas en LUTs y reguladores VCT.Por otro lado, otro requisito indispensable para la industria de la automociĂłn es la detecciĂłn de faltas y la tolerancia a fallos. En este sentido, se presenta una nueva estrategia de control sensorless basada en una estructura PLL/HFI hĂbrida que permite al vehĂculo continuar operando de forma pseudo-Ăłptima ante roturas en el sensor de posiciĂłn y velocidad de la mĂĄquina elĂ©ctrica. En esta tesis, ambas propuestas se validan experimentalmente en un sistema de propulsiĂłn real para vehĂculo elĂ©ctrico que cuenta con una mĂĄquina de reluctancia sĂncrona asistidas por imanes de 51 kW
PMSM Sensorless Speed Control Drive
Permanent magnet synchronous machines (PMSM) are very popular in many industrial applications such as in mechatronics, automotive, energy storage flywheels, centrifugal compressors, vacuum pumps, and robotics. This paper proposes Sensorless control for a PMSM speed drive which is based on a closed loop control system using a proportional and integral (PI) controller that is designed to operate in flux weakening regions under a constant torque angle. This Sensorless element was adopted for best estimating the PMSM rotor position based on its performance characteristics eliminating the need for speed sensors which are usually required in such control applications. To achieve this goal, a pulse width modulation (PWM) control scheme was developed to work in conjunction with a field oriented motor control drive using Simulink.This innovative control system was simulated assuming realistic circuit components to maximize the accuracy of the proposed model. Finally, simulation results obtained under different operation conditions at below and above the rated speed of the motor were presented and discussed in this paper
Review of flux-weakening algorithms to extend the speed range in electric vehicle applications with permanent magnet synchronous machines
This article reviews Flux-Weakening (FW) algorithms for Permanent Magnet Synchronous Machines (PMSMs), focusing on the automotive sector, especially in electric and hybrid electric vehicles. In the past few years, the spread of Electric Vehicles (EVs) has improved the technology of electric machines and their control to achieve more compact and competitive solutions. PMSMs are the most widespread electric machines used in EVs thanks to their high-power density and potential operation at constant power range during high speed. Such high speed implies a high electromotive force. An FW technique is mandatory to reduce the electromagnetic flux generated by the electric machine due to the voltage limits of the traction inverter and the energy source. This article classifies and analyses the state-of-the-art FW control strategies by comparing their main advantages and drawbacks. The Vector Current Control (VCC) method that regulates the modulus of the applied voltage is the most common one in the literature thanks to i) its robustness to parameter modification and model unsureness, ii) low computational complexity, and iii) high dynamic response and control stability.Peer ReviewedPostprint (published version
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