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Fast-response rotating brushless exciters for improved stability of synchronous generatorsNøland, Jonas Kristiansen January 2016 (has links)
The Norwegian Network Code FIKS from the Norwegian Transmission System Operator (TSO) Statnett, states that synchronous generators ≥ 25 MVA must have a static excitation system. It also includes requirements on the step time response and the available field winding ceiling voltage of the excitation system. An improved brushless excitation system is in operation in some pilot power plants. A rotating thyristor bridge is controlled via Bluetooth. The step time response is as fast as conventional static excitation systems. However, a ceiling voltage factor of 2 requires the thyristor bridge to operate at firing angles about 60 degrees. High torque pulsations, low power factor and low utilization of the exciter is the end result. New power electronic interfaces on the shaft results in a betterutilization of the designed exciter and improves the mechanical performance as well as the controllability of the generator field winding. Permanent magnet rotating exciters increase the field forcing strength of the synchronous generator, yielding improved transient stability (Fault Ride-Through req.). Brushless exciters also reduces regular maintenance of the generator. The thesis includes experiments on a state of the art synchronous generator test setup including constructed PM exciter and different power electronic solutions. Some investigations has been done on industrial power plants as well.
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Μελέτη σύγχρονης μηχανής μόνιμου μαγνήτη για λειτουργία ως ανεμογεννήτρια με τη χρήση μεθόδου πεπερασμένων στοιχείωνΜπαρμπατζά, Αλεξάνδρα 20 February 2014 (has links)
Η παρούσα διπλωματική εργασία πραγματεύεται τη μελέτη και προσομοίωση ενός τμήματος μιας ανεμογεννήτριας η οποία μελλοντικά θα συνδεθεί στο τριφασικό δίκτυο. Η εργασία αυτή εκπονήθηκε στο Εργαστήριο Ηλεκτρομηχανικής Μετατροπής Ενέργειας του Τμήματος Ηλεκτρολόγων Μηχανικών και Τεχνολογίας Υπολογιστών της Πολυτεχνικής Σχολής του Πανεπιστημίου Πατρών.
Συγκεκριμένα μελετήθηκε και προσομοιώθηκε μια σύγχρονη μηχανή μόνιμου μαγνήτη, η οποία θα αποτελέσει τη γεννήτρια της διάταξης, η οποία συνδέεται στην έξοδο με έναν τριφασικό μετατροπέα. Σκοπός του μετατροπέα είναι η μετατροπή της εναλλασσόμενης τάσης που δέχεται στην είσοδο του, και προέρχεται από την τάση εξ επαγωγής στο στάτη της μηχανής, σε μια συνεχή τάση στην έξοδο του μετατροπέα, δηλαδή πρόκειται για έναν ανορθωτή. Επιπλέον ο μετατροπέας αυτός είναι ένας μετατροπέας ανύψωσης της τάσης, δηλαδή ένας μετατροπέας τύπου boost. Η ανύψωση αυτή γίνεται έχοντας ως δεδομένο ότι ο απώτερος σκοπός μας είναι η σύνδεση της ανεμογεννήτριας στο δίκτυο των 220 V. Συγκεκριμένα η συνεχής τάση που θα μας δώσει ο ανορθωτής προορίζεται να μετατραπεί εκ νέου σε εναλλασσόμενη, από μια διάταξη αντιστροφέα, ώστε τελικά να προκύψει μια κατάλληλη τάση για σύνδεση της ανεμογεννήτριας στο δίκτυο. Ύστερα από μελέτη διαφόρων ανορθωτικών διατάξεων επιλέχθηκε να χρησιμοποιηθεί στην προσομοίωσή ο τριφασικός ανορθωτής ανύψωσης ενός διακοπτικού στοιχείου. Ο διακόπτης του ανορθωτή παλμοδοτήθηκε με την τεχνική της Διαμόρφωσης Εύρους των Παλμών (Pulse Width Modulation-P.W.M) ενώ ένας PI ελεγκτής χρησιμοποιήθηκε προκειμένου να προσαρμοστεί η συνεχής τάση εξόδου του μετατροπέα στις απαιτήσεις του δικτύου.
Η μηχανή που μελετήθηκε είναι μια σύγχρονη γεννήτρια μόνιμου μαγνήτη οχτώ πόλων, ονομαστικής ισχύος 660 W, ονομαστικής τάσης 48 V και ονομαστικής ταχύτητας 3000 rpm. Για την εξομοίωσή της χρησιμοποιήθηκε το λογισμικό Οpera σε δύο διαστάσεις (2d). Στο περιβάλλον σχεδίασης κυκλωμάτων του ίδιου προγράμματος σχεδιάστηκε σε πρώτη φάση ο τριφασικός ανορθωτής και έτσι έγινε εξαγωγή των αποτελεσμάτων για το σύστημα ανοιχτού βρόχου. Στη συνέχεια έγινε διασύνδεση του λογισμικού Opera με το Simulink του Matlab ώστε να επιτευχθεί έλεγχος κλειστού βρόχου αλλά και εκ νέου εξαγωγή των αποτελεσμάτων ανοιχτού βρόχου, ενώ παράλληλα πραγματοποιήθηκε εξομοίωση του συστήματος μηχανής μετατροπέα εξ ολοκλήρου στο Simulink του Matlab με σκοπό την επιλογή των βέλτιστων παραμέτρων του PI ελεγκτή. / This thesis deals with the design and simulation of a section of a wind turbine which will in future be connected to the three-phase network. The thesis was accomplished in Electromechanical Energy Conversion Laboratory , Department of Electrical and Computer Engineering of the University of Patras.
Specifically, it was studied and simulated a permanent magnet synchronous machine , which is connected to the output with a three-phase converter. The purpose of the converter is to convert the alternating voltage it receives at its entrance, and it comes from the induced voltage in the stator of the machine , into a constant output voltage. Furthermore, the converter’s purpose is to elevate the voltage as it is a boost converter. The voltage should be elevated because the ultimate goal is to connect the wind turbine to the grid of 220 V. Specifically, the dc output voltage of the rectifier, is intended to be converted back into the appropriate ac voltage in order to connect the wind turbine to the grid. Having studying various rectifier’s topologies, it had been chosen the three-phase single switch boost rectifier. The Pulse Width Modulation (PWM) was chosen for the rectifier’s switch and a PI controller was used to adjust the DC output voltage of the converter to the grid .
The studied machine is a permanent magnet synchronous generator with eight poles , rated power 660 W, 48 V nominal voltage and rated speed of 3000 rpm. For the simulation, it was used Opera F.E.M. software in two dimensions (2d). In the same program’s design environment was designed the three-phase rectifier and the results for the open loop system were taken. Then, in order to achieve closed – loop control, the rectifier model was created in the “Matlab/Simulink” environment and the machine F.E.M. model was created in “Opera-2D” environment and they were combined into a composite model. By using this interface we managed to re export also results for the open loop system in order to compare the new results with the ones when only the Opera (machine-rectifier) model was used. Finally, the system machine – rectifier was simulated entirely in Simulink of Matlab in order to select the optimum parameters of the PI controller.
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Control systems for switched reluctance and permanent magnet machines in advanced vehicular electric networksFernando, Weeramundage Udaya Nuwantha January 2012 (has links)
This thesis presents the design and analysis of specialised control systems for switched reluctance (SR) and permanent magnet (PM) machines in vehicular electric applications. Control systems for operation in motoring and power generation are considered for both the types of machines. The SR machine operation considered in this thesis is mainly focused towards the application of aero-engine starter/generators. The control designs for PM machines are formulated considering general fault-tolerant and isolated multiphase PM machines which can be applied in the majority of safety-critical vehicular power and propulsion applications. The SR motoring mode presented in this thesis considers the control design for operation from zero speed to a high speed range, while SR generation mode is confined to the high speed range, such as for the requirements of aero-engine starter/generator operation. This thesis investigates applied control methods for both single-pulse and chopping modes of operation. Classical excitation control versus peak current control and the introduction of a zero-voltage interval are compared for SR motor operation. Optimized excitation control versus two classical forms of excitation control are developed and compared for SR generator operation. Studies include simulation of a 12/8 250kW machine and experimental work on a 6/4 300W machine. The PM motoring and power generation considered in this thesis focuses on a special class of PM machines and drives which are specifically designed for fault-tolerant operation. Optimized control strategies for the operation of PM machines with the parallel H-bridge per-phase converter architecture are investigated. Mathematical modelling of the machine and drive with a consideration of harmonics is presented. The developed control methods are then evaluated by means of finite-element model based simulations of a 125kW five phase surface PM rotor machine and an interior PM rotor machine.
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Integrated Rotor Air Cooling System Design in Axial Flux Permanent Magnet Machines for Aerospace ApplicationsZaher, Islam January 2022 (has links)
A Thesis Submitted to the School of Graduate Studies in Partial Fulfillment of the Requirements for the Degree of Master of Applied Science in Mechanical Engineering / In the wake of the rising global demand for more electric transportation, aerospace electrification is becoming a highly active research area as commercial fully electric aircrafts are becoming a reality. The transportation electrification industry is challenged to develop powerful, safe, and compact-sized machines that can replace fossil fuel powered engines in aircrafts. Axial Flux Permanent Magnets (AFPM) machines are currently being intensively developed as a great candidate for this purpose due to their inherently higher power density compared to other machine electric machines topologies. The efforts of further increasing AFPM machines power density add more thermal challenges as intensive cooling is required at a relatively small machine package to avoid machine failure. One of the most concerning failure modes in these machines is power output reduction due to overheating of the rotor-mounted permanent magnets or even complete failure due to irreversible demagnetization. This research discusses the design process of an integrated rotor air cooling system for a 100 kW AFPM machine designed for an electric aircraft propulsion system. The embedded cooling system allows the rotor to be self-cooled at a sufficient cooling rate while minimizing the impact on machine efficiency due to windage power losses. The presented design process includes several stages of cooling enhancement including the addition and fine-tuning of rotor fan blades and rotor vents design. These enhancements are done by studying the air flow over the rotor surfaces in conjunction with heat transfer through Conjugate Heat Transfer (CHT) Computational Fluid Dynamics (CFD) analyses. In an initial study, different rotors with different combinations of rotor cooling features are studied and their thermal performance is compared. The results show that using rotor embedded fan blades in throughflow ventilated rotor geometry offers the best performance balance, achieving sufficient rotor cooling rate within a reasonable increase of windage power loss. A parametric study is performed to improve the rotor blade geometry for a higher ratio of heat transfer to windage losses. Another study is performed where the rotor and the enclosure geometries are fine-tuned simultaneously to reduce the negative effect on rotor heat transfer imposed by the enclosure. The final geometry of the rotor enclosure assembly is generated based on the research results and the design is integrated into the final machine prototype to be tested. / Thesis / Master of Applied Science (MASc) / Axial-flux permanent magnets (AFPM) machines are gaining the transportation electrification industy attention as a greener alternative to combustion engines in aircraft propulsion systems due to their high power and torque density. The intense endeavors of the current research to further improve AFPM machines power densities brings thermal design challenges to ensure the safe operation of the machine. Rotor permanent magnets failure due to demagnetization as a result of overheating can impose a great risk to the machine operation and safety. Accordingly, special attention should be paid to rotor thermal management. This research discusses the design process of an integrated rotor air cooling system for an AFPM machine designed for an electric aircraft. The machine mechanical and thermal design parameters are used to set an initial rotor design with different rotor cooling features based on literature findings. Rotor fan blades and air vents are selected as the main rotor cooling features for the design. Several design iterations are then made to fine-tune the rotor geometry targeting low operating temperature of the permanent magnets at a low cost of windage losses. The thermal performance of the different designs is assessed and compared to each other using conjugate heat transfer (CHT) computational fluid dynamics (CFD) analyses. Safe operating temperature of the magnets is achieved at an acceptable windage losses value with the final design, and it is selected for prototyping.
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On Design and Analysis of a Novel Transverse Flux Generator for Direct-driven Wind ApplicationSvechkarenko, Dmitry January 2010 (has links)
This thesis deals with the analysis of a permanent magnet synchronous generator suited for direct-drivenwind turbines inmegawatt class. The higher specific torque and power density of a transverse flux permanent magnet machine in comparison to conventional radial-flux machines make it a promising solution for direct-driven wind turbine generators. The novel transverse flux generator investigated in this work would allow a better utilization of the available nacelle space due to its more compact construction. The major part of the thesis deals with the finite element analysis and analytical calculations of transverse flux generators. The computations are performed for single units of the basic transverse flux topology (BTFM) and the one utilizing iron bridges (IBTFM). As the selection of the pole length in a transverse flux machine affects the pole-to-pole flux leakage and thus its performance, the topologies have been analyzed with respect to the varying dimensions in the direction of movement. The topologies utilizing IBTFM have been found to be superior to the BTFM with respect to the flux linkage (by 110%) and utilization of the magnets (by 84%). The machines with longest magnets gave the largest flux linkage, while machines with short magnets should be preferred for better magnet utilization. The four sets of dimensions have been selected for a dynamic finite element analysis. The power factor is evaluated for the topologies with the varying dimensions in the peripheral plane in static finite element analysis. The performance of the topologies with the best power factor in the studied range (0.62 in the BTFM and 0.57 in the IBTFM), as well as the topologies that give the highest power factor to magnet volume ratio, is compared with the dynamic simulations.The electromagnetic and cogging forces of the transverse-flux generator are estimated. The IBTFM is superior to the BTFM with respect to the force production, where the three-phase electromagnetic force is twice as large as in the BTFM. The force ripples of the three-phase electromagnetic force are found to be insignificant in both topologies. An analytical procedure based on the results from the finite element simulations is applied for evaluation of the transverse flux generators with different shapes and topologies. The effectiveness of each topology is investigated based on the estimation of the torque production in a certain nacelle volume. A toroidal generator with the iron-bridge topology is the most compact alternativefor a wind turbine as it has the highest torque-per-volume ratio. Furthermore, the analyticalmodel, including evaluation of the synchronous inductance, is developed and compared with the results obtained in the threedimensional finite element analysis. Themodel provides a good agreement for the studied set of dimensions. / QC 20101109
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A finite element based optimisation tool for electrical machinesGerber, Stiaan 03 1900 (has links)
Thesis (MSc (Electrical and Electronic Engineering))--University of Stellenbosch, 2011. / ENGLISH ABSTRACT: Knowledge of the magnetic fields in the domain of electrical machines is required in order
to model machines accurately. It is difficult to solve these fields analytically because of
the complex geometries of electrical machines and the non-linear characteristics of the
materials used to build them. Thus, finite element analysis, which can be used to solve
the magnetic field accurately, plays an important part in the design of electrical machines.
When designing electrical machines, the task of finding an optimal design is not simple
because the performance of the machine has a non-linear dependence on many variables.
In these circumstances, numerical optimisation using finite element analysis is the most
powerful method of finding optimal designs.
In this thesis, the work of improving an existing finite element simulation package, formerly
known as the Cambridge package among its users, and the use of this package in the
optimisation of electrical machine designs, is presented. The work involved restructuring
the original package, expanding its capabilities and coupling it to numerical optimisers.
The developed finite element package has been dubbed SEMFEM: the Stellenbosch Electrical
Machines Finite Element Method.
The Cambridge package employed the air-gap element method, first proposed by Razek
et. al. [2], to solve the magnetic field for different positions of the moving component
in a time-stepped finite element simulation. Because many new machine topologies have
more than one air-gap, the ability to model machines with multiple air-gaps is important.
The Cambridge package was not capable of this, but during the course of this work, the
ability to model machines with multiple air-gaps using the air-gap element method was
implemented.
Many linear electrical machines have tubular, axisymmetric topologies. The functionality
to simulate these machines was newly implemented because the original program was not
capable of analysing these machines. Amongst other things, this involved the derivation
of the coefficients of an axisymmetric air-gap element’s stiffness matrix. This derivation,
along with the original air-gap element derived by Razek et. al. [2] and the extension of
the method to the Cartesian coordinate system by Wang et. al. [29, 30], completes the
derivation of all two-dimensional air-gap elements. In order to speed the numerical optimisation process, which is computationally expensive,
parallelisation was introduced in two areas: at the level of the finite element simulation
and at the level of the optimisation program.
The final product is a more powerful, more usable package, geared for the optimisation
of electrical machines. / AFRIKAANSE OPSOMMING: Kennis van die magnetiese velde in die gebied van elektriese masjiene word benodig om
masjiene akkuraat te modelleer. Dit is moeilik om hierdie velde analities op te los as
gevolg die komplekse geometrieë van elektriese masjiene en die nie-lineêre karakteristieke
van die materiale wat gebruik word om hulle te bou. Dus speel eindige element analise ’n
belangrike rol in die ontwerp van elektriese masjiene omdat dit gebruik kan word om die
magnetiese veld akkuraat te bepaal.
Wanneer elektriese masjiene ontwerp word, is dit nie ’n eenvoudige taak om ’n optimale
ontwerp te vind nie omdat die werkverrigting van die masjien nie-lineêr afhanklik is van
baie veranderlikes. Onder hierdie omstandighede is numeriese optimering, tesame met
eindige element analise, die kragtigste metode om optimale ontwerpe te vind.
In hierdie tesis word die verbetering van ’n bestaande eindige element simulasie pakket,
wat onder gebruikers van die pakket as die Cambridge pakket bekend staan, en die gebruik
van hierdie pakket vir die optimering van elektriese masjiene, voorgelê. Die werk het die
herstrukturering van die oorspronklike pakket, die uitbreiding van die pakket se vermoëns
en die koppeling van die pakket aan numeriese optimeerders behels. Die ontwikkelde
eindige element pakket word SEMFEM genoem: die Stellenbosch Elektriese Masjiene
Finite Element Method.
Die Cambridge pakket het van die lugspleet element metode, soos oorspronlik deur Razek
et. al. [2] voorgestel, gebruik gemaak om die magnetiese veld vir verskillende posisies
van die bewegende komponent in ’n tyd-stapsgewyse eindige element simulasie op te los.
Omdat baie nuwe masjien topologieë meer as een lugspleet het, is die vermoë om masjiene
met meer as een lugspleet te kan modelleer belangrik. Die Cambridge pakket was nie hier
toe in staat nie, maar die vermoë om masjiene met meervoudige lugsplete te modelleer is
gedurende hierdie werk geïmplementeer.
Baie lineêre masjiene het tubulêre, assimmetriese topologieë. Die funksionaliteit om hierdie
masjiene te simuleer is nuut geïmplementeer omdat die oorspronlike program nie in
staat was om hierdie masjiene te analiseer nie. Dit het onder andere behels dat die koeffisiënte
van ’n assimmetriese lugspleetelement se styfheidsmatriks afgelei moes word. Hierdie
afleiding, tesame met die oorspronlike lugspleetelement afgelei deur Razek et. al. [2]
en die uitbreiding na die Cartesiese koördinaatstelsel deur Wang et. al. [29, 30], voltooi
die afleiding van alle twee-dimensionele lugspleet elemente.
Om die numeriese optimeringsproses, wat tipies tydsgewys duur is, te versnel, is parallellisering
op twee vlakke ingebring: op die vlak van die eindige element simulasie en op die
vlak van die optimeringsprogram.
Die finale produk is ’n kragtiger, meer bruikbare pakket, goed aangepas vir die optimering
van elektriese masjiene.
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A New Paradigm for Large Brushless Hydrogenerators : Advantages Beyond the Static SystemNøland, Jonas Kristiansen January 2017 (has links)
The grid code, FIKS, from the Norwegian transmission system operator (TSO), Statnett, states that synchronous generators > 25MVA, must have a static excitation system. However, an improved brushless excitation system is in operation on some commercial power plants (36MVA, 93.75rpm & 52MVA, 166.67rpm) with grid-assisting performance beyond the conventional static system. The convenional diode bridge is replaced with a remote-controlled thyristor bridge on the shaft. If wireless communication is not allowed, a control signal through brushes should be employed instead. The thesis explores the expected new era for large brushless hydrogenerators. The proposed brushless system have benefits of reduced regular maintenance due to elimination of brushes and reduced unscheduled maintenance due to redundancy; causing a redused cost-of-energy. A six-phase exciter design with a hybrid-mode thyristor bridge interface leads to improved fault-tolerance, better controllability, minimized torque pulsations and reduced armature currents of the exciter. Excitation boosting (EB) capability is included in the brushless system without additional components or circuitry, contrary to the static excitation system. The brushless excitation system is made insensitive to voltage dips in the interconnected grid, causing improved fault ride-through (FRT) capability and power system stabilizer (PSS) actions.
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On design and analysis of synchronous permanent magnet machines for field-weakening operation in hybrid electric vehiclesMagnussen, Freddy January 2004 (has links)
A regular vehicle of today is equipped with an internal combustion engine that runs on either gasoline or diesel, which are fossil fuels from oil reserves that are millions of years old. In all types of combustion processes carbon dioxide and several other emissions are produced. There are none known technologies of today that can reduce the emissions of carbon dioxide from combustion, but the amount that is produced is mainly dependent on the fuel that is used. Combustion of fossil fuels increases the contamination of carbon dioxide in the atmosphere and diminishes the oil resources. The results are global warming and empty oil reserves within a few decades with the current production tempo, in addition to many other pollution effects that are harmful to the environment. A transition towards a society based on sustainable transportation is therefore urgent. The hydrogen fuel cell powered car with an electric propulsion system has the potential to be the car of the future that possesses the required characteristics of no harmful tailpipe emissions. There are some obstacles in the way for an early commercialisation, including the expensive catalysts used today and the lack of an infrastructure based on hydrogen, though. The hybrid electric vehicle, with both a conventional as well as an electric drivetrain, is a natural candidate for making the transition from the conventional car towards the car of the future. This thesis is focused on the design and analysis of permanent magnet machines for a novel hybrid electric vehicle drive system called the Four Quadrant Transducer. A number of electrical machine aspects are identified, including cores of soft magnetic composites, fractional pitch concentrated windings, core segmentation, novel machine topologies and cost effective production methods. The main objective is to analyse and judge the many unconventional machine aspects of which some may have the potential to improve the performance and reduce the cost of permanent magnet machines. Another objective is to study the effects of the use of fossil fuels and describe them with a new perspective and thereby make one small contribution to the debate about energy issues. Much focus has been spent on the theory of concentrated windings for permanent magnet machines. The potential parasitic effects and methods to improve the torque performance have been described. Other topics that have been given a high priority are material and power loss studies. An important contribution to the understanding of iron losses during field-weakening operation has been presented. A comprehensive use of finite element modeling has been done in the analysis combined with measurements on several laboratory prototypes. The Four Quadrant Transducer drivetrain and its two electrical machines intended for a midsized passenger car has been studied. The gearbox can be of a simple single stage type, which reduces the mechanical complexity and makes the traction performance of the vehicle smooth, without gear changes and drops in power. Simulations on a complete hybrid system show that fuel savings of more than 40% compared to a conventional vehicle can be achieved at citytraffic driving. The savings are modest at highway driving, since the engine is required to operate at high power during such conditions, and the support from the electrical system is negligible. The laboratory prototypes have shown that it is possible to manufacture high performance electrical machines with high material utilization and potential for automated production. The described concepts offer cost effective solutions for future drive systems in automotive and industrial applications. A number of weaknesses with the presented constructions have also been characterized, which should serve as guidelines for creating more optimized machines.
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On design and analysis of synchronous permanent magnet machines for field-weakening operation in hybrid electric vehiclesMagnussen, Freddy January 2004 (has links)
<p>A regular vehicle of today is equipped with an internal combustion engine that runs on either gasoline or diesel, which are fossil fuels from oil reserves that are millions of years old. In all types of combustion processes carbon dioxide and several other emissions are produced. There are none known technologies of today that can reduce the emissions of carbon dioxide from combustion, but the amount that is produced is mainly dependent on the fuel that is used. Combustion of fossil fuels increases the contamination of carbon dioxide in the atmosphere and diminishes the oil resources. The results are global warming and empty oil reserves within a few decades with the current production tempo, in addition to many other pollution effects that are harmful to the environment. A transition towards a society based on sustainable transportation is therefore urgent. The hydrogen fuel cell powered car with an electric propulsion system has the potential to be the car of the future that possesses the required characteristics of no harmful tailpipe emissions. There are some obstacles in the way for an early commercialisation, including the expensive catalysts used today and the lack of an infrastructure based on hydrogen, though. The hybrid electric vehicle, with both a conventional as well as an electric drivetrain, is a natural candidate for making the transition from the conventional car towards the car of the future. </p><p>This thesis is focused on the design and analysis of permanent magnet machines for a novel hybrid electric vehicle drive system called the Four Quadrant Transducer. A number of electrical machine aspects are identified, including cores of soft magnetic composites, fractional pitch concentrated windings, core segmentation, novel machine topologies and cost effective production methods. The main objective is to analyse and judge the many unconventional machine aspects of which some may have the potential to improve the performance and reduce the cost of permanent magnet machines. Another objective is to study the effects of the use of fossil fuels and describe them with a new perspective and thereby make one small contribution to the debate about energy issues. Much focus has been spent on the theory of concentrated windings for permanent magnet machines. The potential parasitic effects and methods to improve the torque performance have been described. Other topics that have been given a high priority are material and power loss studies. An important contribution to the understanding of iron losses during field-weakening operation has been presented. A comprehensive use of finite element modeling has been done in the analysis combined with measurements on several laboratory prototypes. </p><p>The Four Quadrant Transducer drivetrain and its two electrical machines intended for a midsized passenger car has been studied. The gearbox can be of a simple single stage type, which reduces the mechanical complexity and makes the traction performance of the vehicle smooth, without gear changes and drops in power. Simulations on a complete hybrid system show that fuel savings of more than 40% compared to a conventional vehicle can be achieved at citytraffic driving. The savings are modest at highway driving, since the engine is required to operate at high power during such conditions, and the support from the electrical system is negligible. The laboratory prototypes have shown that it is possible to manufacture high performance electrical machines with high material utilization and potential for automated production. The described concepts offer cost effective solutions for future drive systems in automotive and industrial applications. A number of weaknesses with the presented constructions have also been characterized, which should serve as guidelines for creating more optimized machines. </p>
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Modeling And Simulation Of All-electric Aircraft Power Generation And ActuationWoodburn, David 01 January 2013 (has links)
Modern aircraft, military and commercial, rely extensively on hydraulic systems. However, there is great interest in the avionics community to replace hydraulic systems with electric systems. There are physical challenges to replacing hydraulic actuators with electromechanical actuators (EMAs), especially for flight control surface actuation. These include dynamic heat generation and power management. Simulation is seen as a powerful tool in making the transition to all-electric aircraft by predicting the dynamic heat generated and the power flow in the EMA. Chapter 2 of this dissertation describes the nonlinear, lumped-element, integrated modeling of a permanent magnet (PM) motor used in an EMA. This model is capable of representing transient dynamics of an EMA, mechanically, electrically, and thermally. Inductance is a primary parameter that links the electrical and mechanical domains and, therefore, is of critical importance to the modeling of the whole EMA. In the dynamic mode of operation of an EMA, the inductances are quite nonlinear. Chapter 3 details the careful analysis of the inductances from finite element software and the mathematical modeling of these inductances for use in the overall EMA model. Chapter 4 covers the design and verification of a nonlinear, transient simulation model of a two-step synchronous generator with three-phase rectifiers. Simulation results are shown
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