On-line partial discharges detection in conversion systems used in aeronautics / Détection on-line des décharges partielles dans des systèmes de conversion utilisés en aéronautique

Cella, Benjamin

02 December 2015

Le concept de l'avion plus électrique a conduit les industriels à focaliser une partie de leurs efforts sur les risques liés à l'utilisation de la haute tension dans un environnement sévère (Basse pression, large plage de température et d'humidité …). Les risques associés sont l'existence et le développement de décharges partielles conduisant à terme à la défaillance du système dans lequel, elles se produisent. Considérant cette problématique, le groupe Liebherr Elektronik GmbH, en collaboration avec le laboratoire Laplace, a lancé l'étude d'une méthode permettant de détecter les décharges partielles dans des convertisseurs destinés à des applications aéronautiques. Ce sont les résultats de ce travail qui font l'objet de cette thèse. La première partie fait état des connaissances actuelles sur les décharges partielles, de leur nature physique aux méthodes de détection utilisées. Dans la seconde partie, trois phases de mesures validant l'efficacité de la méthode étudiée sont présentées et leurs résultats sont discutés. Enfin, dans une troisième partie, les conclusions de nos travaux et leurs perspectives sont présentées. / The more electrical airplane concept led industrial companies to focus a part of their efforts on risks linked to the use of high voltage in a severe environment (Low pressure, wide range of temperature and humidity …). Associated risks are the existence and the growing of partial discharges ultimately leading to the breakdown of the system in which they occur. Considering this problematic, the Liebherr Elektronik GmbH group, in collaboration with the Laplace laboratory, launched the study of a method allowing partial discharges detection in converters intended to be used in aeronautical applications. The results of this work are the subject of this thesis. The first part brings the status of the current knowledge about partial discharges from their physical nature to the detection methods which are used. In the second part, three measurement phases assessing the efficiency of the studied method are introduced and their results discussed. Finally, in the third part, the conclusionsof our works and their perspectives are presented.

Décharges partielles

On-line

Aéronautique

Tension MLI

Capteur non-intrusif

Partial discharges

Aeronautics

On-line

PWM voltage

Non-intrusive sensor

Alimentação de cargas hospitalares críticas utilizando conversores estáticos

Oliveira, Yuri Calil Loures de

12 January 2016

Submitted by Renata Lopes (renatasil82@gmail.com) on 2016-05-05T18:23:07Z No. of bitstreams: 1 yuricalillouresdeoliveira.pdf: 2613361 bytes, checksum: b14d216c9e91ffe085e35724d58bc704 (MD5) / Approved for entry into archive by Adriana Oliveira (adriana.oliveira@ufjf.edu.br) on 2016-06-07T15:42:11Z (GMT) No. of bitstreams: 1 yuricalillouresdeoliveira.pdf: 2613361 bytes, checksum: b14d216c9e91ffe085e35724d58bc704 (MD5) / Made available in DSpace on 2016-06-07T15:42:11Z (GMT). No. of bitstreams: 1 yuricalillouresdeoliveira.pdf: 2613361 bytes, checksum: b14d216c9e91ffe085e35724d58bc704 (MD5) Previous issue date: 2016-01-12 / CNPq - Conselho Nacional de Desenvolvimento Científico e Tecnológico / Esta dissertação apresenta um estudo de estratégias de alimentação de cargas hospitalares críticas utilizando conversores estáticos de energia. As cargas hospitalares escolhidas foram os equipamentos de raio x, tomografia computadorizada e ressonância magnética, sendo comparadas as seguintes formas de integração à rede: (i) estrutura com um retificador trifásico conectado à rede e três inversores monofásicos conectados às cargas ou (ii) estrutura com três retificadores monofásicos conectados à rede e três inversores monofásicos conectados às cargas. Por questões de patente, houve dificuldade em se encontrar os circuitos de front-end das fontes de alimentação das cargas hospitalares. Logo, as mesmas foram construídas dentro do ambiente de simulação do software PSIM utilizando dados de medição obtidos na literatura. O controle dos retificadores trifásico e monofásico foi realizados utilizando duas malhas de controle em cascata, com a malha interna controlando a corrente consumida da rede e a malha externa regulando a tensão no barramento CC. Para os três inversores monofásicos de saída foram implementados os controles PI RES e PI SRF visando uma comparação quanto ao desempenho. Como forma de validar o modelo matemático do sistema e o algoritmo de controle, foram feitas simulações utilizando o software PSIM. A análise feita comprovou que os resultados de simulação se mostraram coerentes com a modelagem matemática do sistema. / This master thesis presents a study about feeding strategies of critical hospital loads through power static converters. The chosen hospital loads were the x ray equipment, the computed tomography and the magnetic resonance. The following forms of grid integration were compared: (i) structure with a three-phase rectifier connected to the network and three single-phase inverters connected to the loads or (ii) structure with three single-phase rectifiers connected to the network and three single-phase inverters connected to the loads. Due to patent issues, it was difficult to find the front-end circuits for power supplies of hospital loads. Therefore, the loads were implemented in PSIM software environment using measurement data obtained from literature. The control of three-phase and single-phase rectifiers was implemented using two cascaded control loops, with the inner loop controlling the current drawn from the network and the outer loop regulating the DC bus voltage. For the single-phase inverter, PI RES and PI SRF controls were implemented, targeting a comparison in terms of performance. In order to validate the mathematical model of the system and the control algorithm, simulations were performed using the PSIM software. The analysis showed that the simulation results were consistent with the mathematical modeling of the system.

CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA

Alimentação de Cargas Críticas

Equipamentos Hospitalares

Retificadores PWM Fonte de Tensão

Inversores PWM Fonte de Tensão

Controlador PI ressonante

Controlador PI-SRF

Critical Loads

Hospital Equipments

PWM Voltage Rectifier

PWM Voltage Inverter

PI Resonant Controller

PI-SRF Controller

Detection and Pattern Recognition of Partial Discharge in Electric Machine Coils with Pulsed Voltage Excitation

Xiong, Han

11 July 2019

No description available.

Electrical Engineering

Analysis of Electrical and Thermal Stresses in the Stress Relief System of Inverter Fed Medium Voltage Induction Motors

Sharifi-Ghazvini, Emad

10 January 2011

Pulse width modulation (PWM) voltage source converters (VSC) are one type of motor drives that have become popular because they enable precise control of speed and torque in medium voltage motors. However, these drives are known to have adverse effects on the insulation system particularly on conductive armour tape (CAT) and semi-conductive stress grading tape (SGT). These tapes, which are crucial components of the insulation system, control the surface electrical stresses in the stator slot and in the end portion of the form-wound coils outside the grounded stator. The material properties of CAT and SGT and the methods by which they are applied on form-wound motor coils are traditionally designed for power frequency, or a 60 Hz sinusoidal voltage. However, because of the high frequencies associated with the repetition rate and the fast rise time of the PWM pulses, elevated electrical and thermal stresses develop in these tapes, which can lead to premature insulation failure. Little research has been conducted with respect to understanding the mechanism of dielectric heating as a function of frequency and repetitive pulse characteristics. The material characterization of CAT and SGT is a vital part of an investigation of the performance of the stress relief system at high frequencies. In this study, the anisotropic dielectric properties of CAT and SGT have been measured in dc and ac and in low and high electric fields. The laboratory experiments for determining the material characteristics are discussed and the results analyzed. According to the ac space charge limited field (SCLF) theory, the maximum ac tangential component of the electric field in a nonlinear resistive SGT on medium voltage form-wound motor coils can be predicted from the field dependent electrical conductivity and the frequency. However, the SCLF theory cannot predict the total electric field (vector sum of the tangential and normal components) in the air adjacent to the surface of the tapes. Simulations of the electric field using a finite element method (FEM), is one of the best ways of finding the resultant electric field distribution in the air space adjacent to the SGT. However, prior to this study, researchers simplified the modelling of the stress relief system to avoid the convergence problems that develop due to the nonlinearity of the SGT conductivity as a function of the electric field, and also because of the geometry and dimensions of the tapes when their depths are orders of magnitude smaller than the other dimensions associated with form-wound coils. For modelling the stress grading (SG) system at power frequency and at the rated voltage, the dc isotropic conductivity of the SGT and CAT has also been extensively investigated. However, relatively little work has been done with respect to the ac electrical behaviour of these materials and dc modelling cannot reflect the effects of high-frequency stresses on the machine insulation. In this study, comprehensive transient FEM modelling has been developed in order to simulate the insulation system with nonlinear field dependent materials. The actual dimensions of the components are applied in the model, and the appropriate material parameters for the FEM simulations are extracted from the experimental test results. One crucial point that has not been considered in previous studies is the effect of the component of the electric field that is normal to the surface of the coil. In most studies, only the tangential component of the electric field is considered; however, in this study, both components and the resultant electric field are computed. The surface tangential field is calculated with reference to the gradient of the surface potential as measured with an electrostatic voltmeter. It is shown that this technique can provide a reasonable estimate for the tangential field along the SG system, but not without limitations, which are discussed in detail. Based on laboratory work and analytical analysis, this research has successfully determined the relationship between the thermal effect of the PWM voltage and the other repetitive fast pulses, such as square wave and impulse voltages. The influence of the pulse characteristics on the development of stresses has also thoroughly investigated, and the results are presented. A coupled electric and thermal model that incorporates the finite element method (FEM) is used as a means of studying thermal stresses and determining appropriate remedies. However, using transient analysis as an approach for finding the temperature profile associated with high repetitive impulses (1-10 kHz) and fast rise times (~200 ns) is both difficult and impractical. According to these considerations, an alternative method has been developed from stationary analyses based on two sinusoidal voltages of different frequencies. The frequency and amplitude of these sinusoids are measured relative to the switching frequency, signal power, and nonlinearity of the system, and the results of the simulation are then verified experimentally, thus showing the efficacy of this method. This research also concluded that a capacitive SG system with conductive foil embedded in the groundwall insulation can be a practical alternative to a conventional SGT of form-wound coils in inverter fed motors. The performance of the capacitive SG scheme is independent of frequency and can therefore provide the required mitigation of the stress caused by repetitive fast pulses. The results of the evaluation of this system with respect to qualification tests demonstrate the effectiveness of the system.

Stress Grading System

Repetitive Fast Pulses

Medium Voltage Motors

Electrical and Thermal Stresses

PWM Voltage

Voltage Source Inverter

Resistive Stress Grading

Capacitive Stress Grading

Stress Relief System

Conductive Armour Tape

Electrical and Computer Engineering

Analysis of Electrical and Thermal Stresses in the Stress Relief System of Inverter Fed Medium Voltage Induction Motors

Sharifi-Ghazvini, Emad

10 January 2011

Pulse width modulation (PWM) voltage source converters (VSC) are one type of motor drives that have become popular because they enable precise control of speed and torque in medium voltage motors. However, these drives are known to have adverse effects on the insulation system particularly on conductive armour tape (CAT) and semi-conductive stress grading tape (SGT). These tapes, which are crucial components of the insulation system, control the surface electrical stresses in the stator slot and in the end portion of the form-wound coils outside the grounded stator. The material properties of CAT and SGT and the methods by which they are applied on form-wound motor coils are traditionally designed for power frequency, or a 60 Hz sinusoidal voltage. However, because of the high frequencies associated with the repetition rate and the fast rise time of the PWM pulses, elevated electrical and thermal stresses develop in these tapes, which can lead to premature insulation failure. Little research has been conducted with respect to understanding the mechanism of dielectric heating as a function of frequency and repetitive pulse characteristics. The material characterization of CAT and SGT is a vital part of an investigation of the performance of the stress relief system at high frequencies. In this study, the anisotropic dielectric properties of CAT and SGT have been measured in dc and ac and in low and high electric fields. The laboratory experiments for determining the material characteristics are discussed and the results analyzed. According to the ac space charge limited field (SCLF) theory, the maximum ac tangential component of the electric field in a nonlinear resistive SGT on medium voltage form-wound motor coils can be predicted from the field dependent electrical conductivity and the frequency. However, the SCLF theory cannot predict the total electric field (vector sum of the tangential and normal components) in the air adjacent to the surface of the tapes. Simulations of the electric field using a finite element method (FEM), is one of the best ways of finding the resultant electric field distribution in the air space adjacent to the SGT. However, prior to this study, researchers simplified the modelling of the stress relief system to avoid the convergence problems that develop due to the nonlinearity of the SGT conductivity as a function of the electric field, and also because of the geometry and dimensions of the tapes when their depths are orders of magnitude smaller than the other dimensions associated with form-wound coils. For modelling the stress grading (SG) system at power frequency and at the rated voltage, the dc isotropic conductivity of the SGT and CAT has also been extensively investigated. However, relatively little work has been done with respect to the ac electrical behaviour of these materials and dc modelling cannot reflect the effects of high-frequency stresses on the machine insulation. In this study, comprehensive transient FEM modelling has been developed in order to simulate the insulation system with nonlinear field dependent materials. The actual dimensions of the components are applied in the model, and the appropriate material parameters for the FEM simulations are extracted from the experimental test results. One crucial point that has not been considered in previous studies is the effect of the component of the electric field that is normal to the surface of the coil. In most studies, only the tangential component of the electric field is considered; however, in this study, both components and the resultant electric field are computed. The surface tangential field is calculated with reference to the gradient of the surface potential as measured with an electrostatic voltmeter. It is shown that this technique can provide a reasonable estimate for the tangential field along the SG system, but not without limitations, which are discussed in detail. Based on laboratory work and analytical analysis, this research has successfully determined the relationship between the thermal effect of the PWM voltage and the other repetitive fast pulses, such as square wave and impulse voltages. The influence of the pulse characteristics on the development of stresses has also thoroughly investigated, and the results are presented. A coupled electric and thermal model that incorporates the finite element method (FEM) is used as a means of studying thermal stresses and determining appropriate remedies. However, using transient analysis as an approach for finding the temperature profile associated with high repetitive impulses (1-10 kHz) and fast rise times (~200 ns) is both difficult and impractical. According to these considerations, an alternative method has been developed from stationary analyses based on two sinusoidal voltages of different frequencies. The frequency and amplitude of these sinusoids are measured relative to the switching frequency, signal power, and nonlinearity of the system, and the results of the simulation are then verified experimentally, thus showing the efficacy of this method. This research also concluded that a capacitive SG system with conductive foil embedded in the groundwall insulation can be a practical alternative to a conventional SGT of form-wound coils in inverter fed motors. The performance of the capacitive SG scheme is independent of frequency and can therefore provide the required mitigation of the stress caused by repetitive fast pulses. The results of the evaluation of this system with respect to qualification tests demonstrate the effectiveness of the system.

Stress Grading System

Repetitive Fast Pulses

Medium Voltage Motors

Electrical and Thermal Stresses

PWM Voltage

Voltage Source Inverter

Resistive Stress Grading

Capacitive Stress Grading

Stress Relief System

Conductive Armour Tape

Electrical and Computer Engineering