3,177 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.
Emerging Multiport Electrical Machines and Systems: Past Developments, Current Challenges, and Future Prospects
Distinct from the conventional machines with only one electrical and one mechanical port, electrical machines featuring multiple electrical/mechanical ports (the so-called multiport electrical machines) provide a compact, flexible, and highly efficient manner to convert and/or transfer energies among different ports. This paper attempts to make a comprehensive overview of the existing multiport topologies, from fundamental characteristics to advanced modeling, analysis, and control, with particular emphasis on the extensively investigated brushless doubly fed machines for highly reliable wind turbines and power split devices for hybrid electric vehicles. A qualitative review approach is mainly adopted, but strong efforts are also made to quantitatively highlight the electromagnetic and control performance. Research challenges are identified, and future trends are discussed
Multiphase induction motor drives - a technology status review
The area of multiphase variable-speed motor drives in general and multiphase induction motor drives in particular has experienced a substantial growth since the beginning of this century. Research has been conducted worldwide and numerous interesting developments have been reported in the literature. An attempt is made to provide a detailed overview of the current state-of-the-art in this area. The elaborated aspects include advantages of multiphase induction machines, modelling of multiphase induction machines, basic vector control and direct torque control schemes and PWM control of multiphase voltage source inverters. The authors also provide a detailed survey of the control strategies for five-phase and asymmetrical six-phase induction motor drives, as well as an overview of the approaches to the design of fault tolerant strategies for post-fault drive operation, and a discussion of multiphase multi-motor drives with single inverter supply. Experimental results, collected from various multiphase induction motor drive laboratory rigs, are also included to facilitate the understanding of the drive operatio
Low-cost, high-resolution, fault-robust position and speed estimation for PMSM drives operating in safety-critical systems
In this paper it is shown how to obtain a low-cost, high-resolution and fault-robust position sensing system for permanent magnet synchronous motor drives operating in safety-critical systems, by combining high-frequency signal injection with binary Hall-effect sensors. It is shown that the position error signal obtained via high-frequency signal injection can be merged easily into the quantization-harmonic-decoupling vector tracking observer used to process the Hall-effect sensor signals. The resulting algorithm provides accurate, high-resolution estimates of speed and position throughout the entire speed range; compared to state-of-the-art drives using Hall-effect sensors alone, the low speed performance is greatly improved in healthy conditions and also following position sensor faults. It is envisaged that such a sensing system can be successfully used in applications requiring IEC 61508 SIL 3 or ISO 26262 ASIL D compliance, due to its extremely high mean time to failure and to the very fast recovery of the drive following Hall-effect sensor faults at low speeds. Extensive simulation and experimental results are provided on a 3.7 kW permanent magnet drive
Field Oriented Sliding Mode Control of Surface-Mounted Permanent Magnet AC Motors: Theory and Applications to Electrified Vehicles
Permanent magnet ac motors have been extensively utilized for adjustable-speed traction motor drives, due to their inherent advantages including higher power density, superior efficiency and reliability, more precise and rapid torque control, larger power factor, longer bearing, and insulation life-time. Without any proportional-and-integral (PI) controllers, this paper introduces novel first- and higher-order field-oriented sliding mode control schemes. Compared with the traditional PI-based vector control techniques, it is shown that the proposed field oriented sliding mode control methods improve the dynamic torque and speed response, and enhance the robustness to parameter variations, modeling uncertainties, and external load perturbations. While both first- and higher-order controllers display excellent performance, computer simulations show that the higher-order field-oriented sliding mode scheme offers better performance by reducing the chattering phenomenon, which is presented in the first-order scheme. The higher-order field-oriented sliding mode controller, based on the hierarchical use of supertwisting algorithm, is then implemented with a Texas Instruments TMS320F28335 DSP hardware platform to prototype the surface-mounted permanent magnet ac motor drive. Last, computer simulation studies demonstrate that the proposed field-oriented sliding mode control approach is able to effectively meet the speed and torque requirements of a heavy-duty electrified vehicle during the EPA urban driving schedule
Direct torque control of electric vehicle drives using hybrid techniques
Permanent magnet synchronous motors (PMSM) have the capability of delivering a high torque-to-current ratio, better efficiency and low noise. Because of the above-mentioned factors, PMSMs are commonly employed in variable speed drives, especially in electric vehicle (EV) applications. Without the usage of electromechanical devices, the conventional direct torque control (DTC) can control the speed and torque of PMSM. DTC is highly efficient, fast-tracking and provides smooth torque while limiting its ripple during transient periods. There are many benefits to using a DTC-controlled PMSM drive, including quick and reliable torque reaction, high-performance control speed, and enhanced performance. This research examines the use of the DTC approach to enhance the speed and torque behavior of PMSM. The jellyfish search optimizer (JSO) is used to adjust the DTC's responsiveness and tailor the controller's best gains. In order to train the adaptive neuro-fuzzy inference system (ANFIS) controller, JSO data are utilized. The simulation outcomes demonstrate that the proposed JSO-ANFIS controller achieves a minimal torque ripple of 0.26 Nm and preserves the speed with a harmonic error of 1.21% while contrasted to existing methods
Electric Drives in Alternative Fuel Vehicles â Some New Definitions and Methodologies
This chapter focuses on some new definitions and methodologies of electric drives that are facing new challenges raised by alternative fuel vehicles. It starts with the objectives, fundamentals, and current research issues of alternative fuel vehicles based electric drives, before moving on to new definitions of unified modeling of the entire electric drive system and design of the proposed DC active power filter aimed at energy storage system chaotic current elimination. Next, novel motor control strategies taking into account alternative fuel vehicle operations are presented for improvement of sensorless drive and flux weakening control performance. Finally, conclusions of this chapter are drawn
Lightweight High-Efficiency Power Train Propulsion with Axial- Flux Machines for Electric or Hybrid Vehicles
The aim of this chapter is to present a new type of powertrain with dimensions and low weight, for vehicles with reduced carbon emissions, which have an axial synchronous machine with one stator and two rotor, with static converter that is simple and inexpensive, a broadcast transmission system using an electric differential, with the control of the two rotors so that they can operate as motor/generator, at the same rotational direction or in opposite directions, at the same speed value, at slightly different speeds or at much different speeds by using an original dual vector control with operating on dual frequency. This is a major concern of hybrid and electric vehicle manufacturers. Expected results: a lighter power train with 20% and an increase in 5% of electric drive efficiency, low inertia rotor at high speed, a compact electric drive system with high torque and simple control, intelligent energy management system with a new vision of technological and innovation development, and equal importance of environment protection. The electrical machines for hybrid (HEV) or electric (EV) drives include a variety of different topologies. According to outcomes of literature survey, induction machines alongside synchronous machines take the major place in HEV or EV power trains
Control solutions for multiphase permanent magnet synchronous machine drives applied to electric vehicles
207 p.En esta tesis se estudia la utilizaciĂłn de un accionamiento elĂ©ctrico basado en una mĂĄquina simĂ©trica dual trifĂĄsica aplicada al sistema de propulsiĂłn de un vehĂculo elĂ©ctrico. Dicho accionamiento estĂĄ basado en una mĂĄquina sĂncrona de imanes permanentes interiores. AdemĂĄs, dispone de un bus CC con una configuraciĂłn en cascada. Por otra parte, se incorpora un convertidor CC/CC entre el mĂłdulo de baterĂas y el inversor de seis fases para proveer el vehĂculo con capacidades de carga rĂĄpida, y evitando al mismo tiempo la utilizaciĂłn de semiconductores de potencia con altas tensiones nominales. En este escenario, el algoritmo de control debe hacer frente a las no linealidades de la mĂĄquina, proporcionando un comando de consigna preciso para todo el rango de par y velocidad del convertidor. Por lo tanto, deben tenerse en cuenta los efectos de acoplamiento cruzado entre los devanados, y la tensiĂłn de los condensadores de enlace en cascada debe controlarse y equilibrarse activamente. En vista de ello, los autores proponen un novedoso enfoque de control que proporciona todas estas funcionalidades. La propuesta se ha validado experimentalmente en un prototipo a escala real de accionamiento elĂ©ctrico de 70 kW, probado en un laboratorio y en un vehĂculo elĂ©ctrico en condiciones reales de conducciĂłn.Tecnali
Advances in Rotating Electric Machines
It is difficult to imagine a modern society without rotating electric machines. Their use has been increasing not only in the traditional fields of application but also in more contemporary fields, including renewable energy conversion systems, electric aircraft, aerospace, electric vehicles, unmanned propulsion systems, robotics, etc. This has contributed to advances in the materials, design methodologies, modeling tools, and manufacturing processes of current electric machines, which are characterized by high compactness, low weight, high power density, high torque density, and high reliability. On the other hand, the growing use of electric machines and drives in more critical applications has pushed forward the research in the area of condition monitoring and fault tolerance, leading to the development of more reliable diagnostic techniques and more fault-tolerant machines. This book presents and disseminates the most recent advances related to the theory, design, modeling, application, control, and condition monitoring of all types of rotating electric machines
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