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A High Power Density Three-level Parallel Resonant Converter for Capacitor ChargingSheng, Honggang 28 May 2009 (has links)
This dissertation proposes a high-power, high-frequency and high-density three-level parallel resonant converter for capacitor charging. DC-DC pulsed power converters are widely used in military and medical systems, where the power density requirement is often stringent. The primary means for reducing the power converter size has been to reduce loss for reduced cooling systems and to increase the frequency for reduced passive components. Three-level resonant converters, which combine the merits of the three-level structure and resonant converters, are an attractive topology for these applications. The three-level configuration allows for the use of lower-voltage-rating and faster devices, while the resonant converter reduces switching loss and enhances switching capability.
This dissertation begins with an analysis of the influence of variations in the structure of the resonant tank on the transformer volume, with the aim of achieving a high power density three-level DC-DC converter. As one of the most bulky and expensive components in the power converter, the different positions of the transformer within the resonant tank cause significant differences in the transformer's volume and the voltage and current stress on the resonant elements. While it does not change the resonant converter design or performance, the improper selection of the resonant tank structure in regard to the transformer will offset the benefits gained by increasing the switching frequency, sometimes even making the power density even worse than the power density when using a low switching frequency. A methodology based on different structural variations is proposed for a high-density design, as well as an optimized charging profile for transformer volume reduction.
The optimal charging profile cannot be perfectly achieved by a traditional output-voltage based variable switching frequency control, which either needs excess margin to guarantee ZVS, or delivers maximum power with the danger of losing ZVS. Moreover, it cannot work for widely varied input voltages. The PLL is introduced to overcome these issues. With PLL charging control, the power can be improved by 10% with a narrow frequency range.
The three-level structure in particular suffers unbalanced voltage stress in some abnormal conditions, and a fault could easily destroy the system due to minimized margin. Based on thoroughly analysis on the three-level behaviors for unbalanced voltage stress phenomena and fault conditions, a novel protection scheme based on monitoring the flying capacitor voltage is proposed for the three-level structure, as well as solutions to some abnormal conditions for unbalanced voltage stresses. A protection circuit is designed to achieve the protection scheme.
A final prototype, built with a custom-packed MOSFET module, a SiC Schottky diode, a nanocrystalline core transformer with an integrated resonant inductor, and a custom-designed oil-cooled mica capacitor, achieves a breakthrough power density of 140W/in3 far beyond the highest-end power density reported (<100 W/in3) in power converter applications. / Ph. D.
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A modular compact kW-class IPOS DC-DC converter for pulsed power applicationsThames, Walker Joseph 10 May 2024 (has links) (PDF)
Pulsed power systems are concerned with the delivery of significant amounts of power in a greatly condensed time frame. To achieve this, energy is often stored in a capacitor, where it can be rapidly discharged. Certain applications require repeated charging and discharging of the load capacitor in a specifically modulated manner; special power electronics systems must be developed for these situations. Existing systems on the market sacrifice a small form factor for greater pulsed power output. The proposed design outlines the development of a compact pulsed power capacitor charger capable of charging a load capacitor to high voltages at a pulse repetition frequency of 30 kHz. Due to the compact form factor, the charger features a unique design of four full-bridge converters modularly connected in Input-Parallel Output-Series configuration. Experimental verification shows that the system exceeds expectations and can be utilized and adapted to fit many pulsed power applications.
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Magnetohydrodynamic Simulations of Fast Instability Development in Pulsed-Power--Driven Explosions and Implosions of Electrical ConductorsCarrier, Matthew James 21 June 2024 (has links)
Recent concepts for controlled magneto-inertial fusion (MIF), such as magnetized liner inertial fusion (MagLIF), have suffered from magnetohydrodynamic (MHD) instabilities that lead to degradations in fusion yield. High levels of azimuthally-correlated MHD instability structures have been observed on cylindrical liner experiments without a pre-imposed axial magnetic field (Bz=0) elsewhere in the literature and are believed to be seeded from surface machining roughness. This dissertation uses highly resolved (0.5 μm and less resolution) 1D and 2D resistive magnetohydrodynamics (MHD) arbitrary-Lagrangian-Eulerian (ALE) simulations of electrical wire explosions (EWEs) and liner implosions to show that micrometer-scale surface roughness seeds the electrothermal instability (ETI), which induces early melting in pockets across the conductor and leads to millimeter-scale instability growth. The relationship between the ETI and the MRTI in liner implosions is also described in this dissertation, which shows that the traditional growth rates associated with these modes are coupled together and are not linearly independent. This dissertation also describes the preliminary implementation of a Koopman neural network architecture for learning the nonlinear dynamics of a high energy density (HED) exploding or imploding electrical conductor. / Doctor of Philosophy / Researchers have been working on controlling nuclear fusion and harnessing it as a power source since the discovery that nuclear fusion powers stars. In many of these controlled nuclear fusion concepts the aim is to heat the fuel until it forms a high-temperature plasma state of matter and then compress it to the point that the atoms are close enough and at high enough speeds that they collide fuse together. In the magnetized liner inertial fusion (MagLIF) concept these temperatures, densities, and pressures are achieved by surrounding the fusion fuel with a cylindrical piece of metal called a liner and using magnetic fields to implode the liner inward. Experiments have shown, however, that these liner implosions do not occur smoothly and that the system becomes unstable and can mix liner material into the fuel, which disrupts the fusion process. This dissertation investigates the stability of liner implosions and electrical wire explosions. In particular, this dissertation shows that surface roughness imparted on the surface of a solid fusion target by a machining process can grow into a millimeter-scale perturbation. It also describes the relationship between two common types of instabilities found in current-driven nuclear fusion: the magneto-Rayleigh-Taylor instability and the electrothermal instability. Finally, it looks at using neural networks to better understand the dynamics of electrical wire explosions.
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Investigation of a Pulsed Plasma Thruster Plume Using a Quadruple Langmuir Probe TechniqueZwahlen, Jurg C 08 January 2003 (has links)
The rectangular pulsed plasma thruster (PPT) is an electromagnetic thruster that ablates Teflon propellant to produce thrust in a discharge that lasts 5-20 microseconds. In order to integrate PPTs onto spacecraft, it is necessary to investigate possible thruster plume-spacecraft interactions. The PPT plume consists of neutral and charged particles from the ablation of the Teflon fuel bar as well as electrode materials. In this thesis a novel application of quadruple Langmuir probes is implemented in the PPT plume to obtain electron temperature, electron density, and ion speed ratio measurements (ion speed divided by most probable thermal speed). The pulsed plasma thruster used is a NASA Glenn laboratory model based on the LES 8/9 series of PPTs, and is similar in design to the Earth Observing-1 satellite PPT. At the 20 J discharge energy level, the thruster ablates 26.6 mg of Teflon, creating an impulse bit of 256 mN-s with a specific impulse of 986 s. The quadruple probes were operated in the so-called current mode, eliminating the need to make voltage measurements. The current collection to the parallel to the flow electrodes is based on Laframboise's theory for probe to Debye length ratios between 5 and 100, and on the thin-sheath theory for ratios above 100. The ion current to the perpendicular probe is based on a model by Kanal and is a function of the ion speed ratio, the applied non-dimensional potential and the collection area. A formal error analysis is performed using the complete set of nonlinear current collection equations. The quadruple Langmuir probes were mounted on a computer controlled motion system that allowed movement in the radial direction, and the thruster was mounted on a motion system that allowed angular variation. Measurements were taken at 10, 15 and 20 cm form the Teflon fuel bar face, at angles up to 40 degrees off of the centerline axis at discharge energy levels of 5, 20, and 40 J. All data points are based on an average of four PPT pulses. Data analysis shows the temporal and spatial variation in the plume. Electron temperatures show two peaks during the length of the pulse, a trend most evident during the 20 J and 40 J discharge energies at 10 cm from the surface of the Teflon fuel bar. The electron temperatures after the initial high temperature peak are below 2 eV. Electron densities are highest near the thruster exit plane. At 10 cm from the Teflon surface, maximum electron densities are 1.04e20 ± 2.8e19 m-3, 9.8e20 ± 2.3e20 m-3, and 1.38e21 ± 4.05e20 m-3 for the 5 J, 20 J and 40 J discharge energy, respectively. The electrons densities decrease to 2.8x1019 ± 8.9e18 m-3, 1.2e20 ± 4.2e19 m-3, and 4.5e20 ± 1.2e20 m-3 at 20 cm for the 5 J, 20 J, and 40 J cases, respectively. Electron temperature and density decrease with increasing angle away from the centerline, and with increasing downstream distance. The plume is more symmetric in the parallel plane than in the perpendicular plane. Ion speed ratios are lowest near the thruster exit, increase with increasing downstream distance, but do not show any consistent angular variation. Peak speed ratios at a radial distance of 10 cm are 5.9±3.6, 5.3±0.39, and 4.8±0.41 for the 5 J, 20 J and 40 J discharge energies, respectively. The ratios increase to 6.05±5.9, 7.5±1.6, and 6.09±0.72 at a radial distance of 20 cm. Estimates of ion velocities show peak values between 36 km/s to 40 km/s, 26 km/s to 30 km/s, and 26 km/s to 36 km/s for the % J, 20 J, and 40 J discharge energies, respectively.
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Etude de nouvelles architectures modulaires d'alimentations électriques pour les applications de hautes puissances pulsées. / Study and realization of modulators based on the use of resonant and / or pulsed transformers associated with a system of strong current triggered spark gapsAllard, Florian 18 July 2018 (has links)
De nos jours, pour accroître le potentiel applicatif des machines de hautes puissances pulsées, il est nécessaire de développer des modulateurs compacts capables de délivrer des impulsions de l’ordre de plusieurs Mégawatts de durée pouvant atteindre plusieurs centaines de microsecondes. Cette amélioration requiert le développement de structures innovantes dont le but est de produire aussi bien des puissances moyennes que des puissances crêtes importantes. Les modulateurs étudiés dans ce mémoire sont basés sur l’utilisation de divers transformateurs pour la génération d’impulsions de très forte puissance. Le projet AGIR (acronyme de « Architecture pour la Génération d’Impulsions Rectangulaires de forte de puissance ») est réalisé dans le cadre d’un RAPID (Régime d’Appui Pour l’Innovation Duale) financé par la Direction Générale de l’Armement (DGA). Le projet est une collaboration avec EFFITECH, une entreprise spécialisée dans les puissances pulsées. L’objectif est de développer deux générateurs pour deux gammes de puissance crête (jusqu’à 10MW pour l’un et 1GW pour l’autre). Le premier modulateur « AGIR1 » repose sur l’association d’un convertisseur AC-DC et de 12 convertisseurs résonants DC-DC qui permettent la génération de plusieurs types d’impulsions (fort courant ou forte tension) en fonction de la configuration choisie. Le second modulateur repose sur le développement d’un transformateur impulsionnel à quatre primaires synchronisés. Chaque primaire est relié à un système de mise en forme de type Blumlein dont le déclenchement est assuré par un éclateur pressurisé à trois électrodes. La synchronisation des quatre éclateurs est assurée par un générateur impulsionnel innovant à faible gigue. La principale difficulté du travail effectué au laboratoire réside dans l’étude des différents transformateurs haute-tension utilisés (résonant ou impulsionnel) et du système de synchronisation des éclateurs. Chaque élément constituant le système est étudié et simulé de manière électrostatique, électromagnétique ou électrique avant d’être réalisé et assemblé. Des essais ponctue l’étude afin de valider le fonctionnement en récurrent avec un système de dissipation thermique adapté. / Nowadays, to increase the application potential of high power pulsed machines, it is necessary to develop compact modulators able to deliver pulses in the range of several megawatts with duration of up to several hundred microseconds. This improvement requires the development of innovative structures whose purpose is to produce both average power and large peak power. Modulators studied in this thesis are based on the use of various transformers for the generation of very high power pulses. The AGIR project (French acronym for "Architecture for Rectangular High Pulse power generation") is achieved within the framework of a RAPID (Dual Innovation Support Regime) funded by the French Defense (DGA). The project is carried on by a collaboration with EFFITECH, a company specialized in pulsed powers. The goal is to develop two generators for two peak power ranges (up to 10MW for one and 1GW for the other). The first modulator "AGIR1" is based on the association of an AC-DC converter and 12 DC-DC resonant converters allowing the generation of several types of pulses (high current or high voltage) depending on the chosen configuration. The second modulator is based on the development of a four synchronized primary pulse transformer. Each primary is connected to a Blumlein pulse forming line triggered by a three-electrode pressurized spark gap. The synchronization of the four spark gaps is ensured by an innovative pulse generator with low jitter. The main difficulty of the work which was completed in the laboratory relies in the study of the different high-voltage transformers used (resonant or pulse) and the spark gap synchronization system. Each element constituting the system is studied and simulated electrostatically, electromagnetically or electrically before being realized and assembled. Trials punctuate the study to validate the recurrent operation with a suitable heat dissipation system.
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Energy storage system requirements for shipboard power systems supplying pulsed power loadsDuvoor, Prashanth, January 2007 (has links)
Thesis (M.S.)--Mississippi State University. Department of Electrical and Computer Engineering. / Title from title screen. Includes bibliographical references.
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Experiments with and modelling of explosively driven mangetic flux compression generatorsAppelgren, Patrik January 2008 (has links)
This thesis presents work performed on explosively driven magnetic flux compression generators. This kind of devices converts the chemically stored energy in a high explosive into electromagnetic energy in the form of a powerful current pulse. The high energy density of the high explosives makes flux compression generators attractive as compact power sources. In order to study these devices a generator was designed at FOI in the mid-90ies. Two generators remained unused and became available for this licentiate work. The thesis reports experiments with, and simulations of, the operation of the two remaining generators. The aim was to fully understand the performance of the generator design and be able to accurately simulate its behaviour. The generators were improved and fitted with various types of diagnostics to monitor the generator operation. Two experiments were performed of which the first generator was operated well below its current capability limits while the second was stressed far above its limits. Since the generator generates a rapidly increasing current, a current measurement is the most important diagnostic revealing the current amplification of the generator and its overall performance. Further it is important to measure the timing of various events in the generator. With a common time reference it is possible to combine data from different probes and extract interesting information which cannot be directly obtained with a single measurement. Two types of numerical simulations have been performed: Hydrodynamic simulations of the high explosive interaction with the armature were used to verify the measured armature dynamics. A zero-dimensional code was used to perform circuit simulations of the generator. The model takes into account the inductance reduction due to the compression of the generator as well as the change in conductivity due to heating of the conductors in the generators. / QC 20101103
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Langmuir Probe Measurements in the Plume of a Pulsed Plasma ThrusterByrne, Lawrence Thomas 19 December 2002 (has links)
"The ablative Teflon pulsed plasma thruster (PPT) is an onboard electromagnetic propulsion enabling technology for small spacecraft missions. The integration of PPTs onboard spacecraft requires the understanding and evaluation of possible thruster/spacecraft interactions. To aid in this effort the work presented in this thesis is directed towards the development and application of Langmuir probe techniques for use in the plume of PPTs. Double and triple Langmuir probes were developed and used to measure electron temperature and density of the PPT plume. The PPT used in this thesis was a laboratory model parallel plate ablative Teflon® PPT similar in size to the Earth Observing (EO-1) PPT operating in discharge energies between 5 and 40 Joules. The triple Langmuir probe was operated in the current-mode technique that requires biasing all three electrodes and measuring the resulting probe currents. This new implementation differs from the traditional voltage-mode technique that keeps one probe floating and requires a voltage measurement that is often susceptible to noise in the fluctuating PPT plume environment. The triple Langmuir probe theory developed in this work incorporates Laframboise’s current collection model for Debye length to probe radius ratios less than 100 in order to account for sheath expansion effects on ion collection, and incorporates the thin-sheath current collection model for Debye length to probe radius ratios greater than 100. Error analysis of the non-linear system of current collection equations that describe the operation of the current-mode triple Langmuir probe is performed as well. Measurements were taken at three radial locations, 5, 10, and 15 cm from the Teflon® surface of the PPT and at angles of 20 and 40 degrees to either side of the thruster centerline as well as at the centerline. These measurements were taken on two orthogonal planes, parallel and perpendicular to the PPT electrodes. A data-processing software was developed and implements the current-mode triple Langmuir probe theory and associated error analysis. Results show the time evolution of the electron temperature and density. Characteristic to all the data is the presence of hot electrons of approximately 5 to 10 eV at the beginning of the pulse, occurring near the peak of the discharge current. The electron temperature quickly drops off from its peak values to 1-2 eV for the remainder of the pulse. Peak electron densities occur after the peak temperatures. The maximum electron density values on the centerline of the plume of a laboratory PPT 10 cm from the Teflon® surface are 6.6x10^19 +/- 1.3x10^19 m^-3 for the 5 J PPT, 7.2x10^20 +/- 1.4x10^20 m^-3 for the 20 J PPT, and 1.2x10^21 +/- 2.7x10^20 m^-3 for the 40 J PPT. Results from the double Langmuir probe taken at r=10 cm, theta perpendicular=70 degrees and 90 degrees of a laboratory PPT showed good agreement with the triple probe method."
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Etude et réalisation d’une source de rayonnement large bande de forte puissance basée sur un concept innovant de transformateur résonant impulsionnel / Study and realization of a high-power and wideband electromagnetic source based on an innovative resonant pulse transformerPecquois, Romain 21 December 2012 (has links)
De nos jours, un large éventail d’applications de défense nécessite des générateurs de puissances pulsées pour produire des rayonnements électromagnétiques de fortes puissances. Dans les systèmes conventionnels, le générateur est composé d’une source d’énergie primaire et d’une antenne, séparé par un système d’amplification de la puissance, généralement un générateur de Marx ou un transformateur Tesla, qui transmet l’énergie vers l’antenne. Le système présenté dans ce mémoire, utilise un concept innovant basée sur un transformateur résonant impulsionnel compact pour alimenter l’antenne. La source développée, appelée MOUNA (acronyme de « Module Oscillant Utilisant une Nouvelle Architecture ») est composé d’une batterie, d’un convertisseur DC/DC permettant de charger quatre condensateurs, de quatre éclateurs à gaz synchronisés, d’un transformateur résonant impulsionnel qui génère des impulsions de 600kV en 265ns, d’un éclateur de mise en forme à huile, et d’une antenne dipôle. / Nowadays, a broad range of modern defense applications requires compact pulsed power generators to produce high-power electromagnetic waves. In a conventional design, such generators consist of a primary energy source and an antenna, separated by a power-amplification system, such as a Marx generator or a Tesla transformer, which forwards the energy from the source to the antenna. The present system, however, uses a novel and very compact high-voltage resonant pulsed transformer to drive a dipole antenna. The complete pulsed power source, termed MOUNA (French acronym for “Module Oscillant Utilisant une Nouvelle Architecture”), is composed of a set of batteries, a dc/dc converter for charging four capacitors, four synchronized spark gap switches, a resonant pulsed transformer that can generate 600 kV in 265 ns pulses, an oil peaking switch and, a dipole antenna.
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Etude d’un système d’amplification de puissance de type multiplicateur de courant dynamique sur l’installation SPHINX du CEA Gramat / Study of a Dynamic Load Current Multiplier system on the SPHINX facility of the CEA GramatMaysonnave, Thomas 20 December 2013 (has links)
Depuis plusieurs décennies, les générateurs forts courants sont utilisés dans différents domaines comme l’étude des matériaux, la radiographie ou la fusion par confinement inertiel. Ces générateurs sont capables de délivrer des impulsions de courant de plusieurs millions d’ampères avec des fronts de montée inférieurs à la microseconde. Plusieurs projets à travers le monde ont, aujourd’hui, pour but d’améliorer encore et encore le gradient de courant des impulsions transmises à la charge. De nombreux schémas d’amplificateurs de puissance, dont le rôle est de jouer à la fois sur l’amplitude du courant de charge et sur son temps de montée, ont ainsi été testés. Le multiplicateur de courant dynamique (DLCM pour Dynamic Load Current Multiplier) fait partie de ces concepts novateurs permettant de contourner les limitations des générateurs de puissances pulsées actuels. Il est composé d’un réseau d’électrodes (servant d’autotransformateur), d’un extrudeur de flux dynamique (basé sur l’implosion d’un réseau de fils cylindrique) et d’un commutateur à fermeture sous vide. Dans la thèse, le principe de fonctionnement du DLCM est analysé d’un point de vue théorique par le biais de simulations de type circuits électriques et magnétohydrodynamiques. Une étude spécifique portant sur l’organe principal du DLCM est réalisée. Il s‘agit du commutateur à fermeture sous vide. Ainsi, après une phase de dimensionnement à l’aide d’outils de simulations électrostatiques, deux versions de commutateurs sont validées expérimentalement dans des conditions proches de celles d’un tir très fort courant. Enfin, des tirs sur le générateur SPHINX du CEA Gramat, capable de délivrer une impulsion de courant de 6MA en 800ns (sur charge Z-pinch), sont exposés pour retracer l’évolution du dispositif. Les résultats probants obtenus permettent, au final, de valider le concept DLCM connecté à une charge de type compression isentropique. / For several decades, high power generators are used in various fields such as materials research, radiography or inertial confinement fusion. These generators are capable of delivering current pulses of several millions of amperes with rise times below 1 microsecond. Several projects around the world are, today, trying to improve again and again the current gradient of pulses delivered to the load. Many concepts of power amplifiers, whose role is to optimize both the amplitude of the load current and its rise time, were tested. The Dynamic Load Current Multiplier (DLCM) is one of those innovating concepts used to overcome the existing pulsed power generators limitations. It is made up of concentric electrodes (for autotransformer), a dynamic flux extruder (based on the implosion of cylindrical wire array) and a vacuum closing switch. In this these, the operating principle of the DLCM is theoretically analyzed through electrical and magneto hydrodynamic simulations. A specific study of the DLCM key component is performed. This is the vacuum closing switch. Thus, after a design phase using electrostatic simulation tools, two versions of switches are experimentally validated in conditions similar to those of a very high current shot. Finally, shots on the SPHINX facility located at the CEA Gramat, capable of delivering a current pulse of 6MA in 800ns (on Z-pinch load), are exposed to trace the evolution of this device. The convincing results are used, ultimately, to validate the DLCM concept connected to an isentropic compression experiment load.
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