Global ETD Search

101	Non reciprocal passive components on LTCC ferrite substrate / Composants passifs non réciproques hyperfréquences sur substrat ferrite LTCC Yang, Shicheng 02 October 2015 (has links) Cette thèse concerne de l’étude de composants passifs non-réciproque (circulateurs) fabriqué sur substrat LTCC ferrite. Les aimants externes utilisés dans les circulateurs classiques doivent créer un champ magnétique intense pour compenser le champs de démagnétisant dans le ferrite. Le nouveau circulateur présenté ici utilise une bobine intégrée dans le LTCC ferrite pour magnétiser le matériau de l'intérieur, pour réduire considérablement les effets des champs démagnétisants. Il est possible de contrôler le champ de polarisation rendant le dispositif multifonctionnel: lorsque la bobine est excitée par un courant, le dispositif fonctionne comme un circulateur dynamique dans lequel la direction de circulation peut être basculée en changeant la direction du courant. Si un aimant externe est placé sur le circulateur, sa fréquence de fonctionnement peut être accordée en ajustant le courant de polarisation. Contrairement à d'autres circulateurs LTCC avec aimants externes, le dispositif proposé peut même fonctionner comme un diviseur de puissance sans courant de polarisation. Un prototype de circulateur a été réalisé et caractérisé dans trois états: 1. démagnétisé, 2. Magnétisé par la bobine, 3. magnétisé par la bobine et des aimants externes. En l'absence de courant appliqué, la transmission de chaque port est d'environ -5 dB avec un coefficient de réflexion inférieur à -20 dB à 14,8 GHz. Quand un courant de 300 mA est injecté dans la bobine, les pertes d'insertion et l'isolation mesurées sont d'environ 3 dB et 8 dB, respectivement. Le coefficient de réflexion est inférieur à -20 dB à 14,2 GHz. Lorsque les aimants externes sont ajoutés avec un courant de 200 mA, les pertes d'insertion et l'isolation a été améliorée à 1,6 dB et 23 dB, respectivement à 14,2 GHz. La variation de la fréquence de travail du circulateur est de 0,6 GHz. Elle est due par la variation de l'aimantation M interne lorsque le courant est inférieur à 120 mA, puis par l’augmentation de la température créée par le courant dans la bobine. La taille (L * W * H) totale du circulateur réalisé est de 8mm * 8mm 1.1mm. Ce travail monte qu’il est possible d’intégrer (MMIC) sur un substrat LTCC ferrite des circuits passifs non-réciproques / This thesis investigates passive non-reciprocal components (mainly circulators) based on ferrite Low Temperature Co-fired Ceramic (LTCC) substrate. The external magnets used in conventional circulators must be strong to overcome the ferrite's demagnetization field. The novel circulator presented herein uses an embedded winding within the ferrite substrate to magnetize the material from the inside, thereby significantly reducing the demagnetization effects. Because of the controllability of the bias field, the resulting device is also multifunctional: when the windings are energized by a current, the device operates as a dynamic circulator in which the circulation direction can be changed by switching the direction of the current. Unlike other LTCC circulators with external magnets, the proposed device can even operate as a power splitter by removing the bias current. A circulator prototype has been characterized in three states: unbiased, biased by winding and biased by winding and external magnets. When no current is applied, the transmission of each port is about -5 dB with return loss better than 20 dB at 14.8 GHz. When a current of 300 mA is injected into the winding, the measured insertion loss and isolation of the circulator is approximately 3 dB and 8 dB, respectively, whereas the return loss is better than 20 dB at 14.2 GHz. When external magnets are added in addition to the current of 200 mA, the insertion loss and isolation is improved to 1.6 dB and 23 dB, respectively at 14.2 GHz. The variation of the circulator's working frequency is 0.6 GHz. This is achieved firstly by the change of internal magnetization M when current is less than 120 mA, then the heat in the substrate due to the winding introduces more frequency shifting. The total size (LWH) is 8mm8mm*1.1mm Circulateur Ferrite LTCC Non-réciproque Bobine Saturation partielle Accordable Déplacement des champs Circulator Ferrite LTCC Non reciprocal Winding Partial saturation Moving fields
102	Construction Of Equivalent Circuit Of A Single Isolated Transformer Winding From Frequency Response Mukherjee, Pritam 07 1900 (has links) (PDF) Frequency response analysis (FRA) of transformers is universally accepted as a highly sensitive tool to detect deformations in its windings. This is evident from the fact that customized commercial equipment (popularly called FRA or SFRA instruments) are used and recently the IEEE has issued a draft trial-use guide. Nevertheless, use of FRA is still limited to only detection and there is little progress towards its use for localization of winding deformation. Toward this end, a possible approach would be to compare the healthy and deformed systems in a suitable domain, e.g., their respective models could be compared. In this context, the mutually-coupled ladder network is ideally suited because not only does it map the length of the winding to sections of the ladder network, but, also inherently captures all subtle intricacies of winding behaviour under lightning impulse excitations insofar as the terminal response, internal oscillations and voltage distributions are concerned. The task of constructing a ladder network from frequency response is not trivial, and so exploration of newer methods is imperative. A system can comprehensively be characterized by its frequency response. With this as the starting point, many approaches exist to construct the corresponding rational function (in s-domain). But, the subsequent step of converting this rational function into a physically-realizable mutually-coupled ladder network has, as yet, remained elusive. A critical analysis of the circuit synthesis literature reveals that there exists no analytical procedure to achieve this task, a fact unequivocally stated by Guillemin in his seminal book "Synthesis of Passive Networks". In recent years, use of iterative methods to synthesize such ladder networks has also been attempted with some degree of success. However, there exists a lot of scope for improvement. Based on this summary, the objectives of this thesis are as follows- _ Development of an analytical procedure, if possible, to synthesize a mutually-coupled ladder network starting from the s-domain representation of the frequency response _ Construction of a nearly-unique, mutually-coupled ladder network employing constrained optimization technique and using frequency response as input, with time-efficiency, physical realizability and repeatability as its features In Chapter 2, analytical solution is presented to convert a given driving-point impedance function (in s-domain) into a physically-realizable ladder network with inductive couplings (between any two sections) and losses considered. The number of sections in the ladder network can vary, but, its topology is assumed fixed. A study of the coefficients of the numerator and denominator polynomials of the driving-point impedance function of the ladder network, for increasing number of sections, led to the identification of certain coefficients, which exhibit very special properties. Generalized expressions for these specific coefficients have also been derived. Exploiting their properties, it is demonstrated that the synthesis method essentially turns out to be an exercise of solving a set of linear, simultaneous, algebraic equations, whose solution directly yields the ladder network elements. The proposed solution is novel, simple, and guarantees a unique network. Presently, the formulation can synthesize a unique ladder network up to 6-sections. Although it is an analytical solution, there are issues which prevent its implementation with actual FRA data. Keeping the above aspect in mind, the second part of the thesis presents results of employing an artificial bee colony search algorithm for synthesizing a mutuallycoupled lumped-parameter ladder network representation of a transformer winding, starting from its measured magnitude frequency response. The bee colony algorithm is modified by defining constraints and bounds to restrict the search-space and thus ensure synthesis of a nearly-unique ladder network, corresponding to each frequency response. Ensuring near-uniqueness while constructing the reference circuit (i.e., a uniform healthy winding) is the objective. The proposed method is easy to implement, time-efficient, ensures physical realizability and problem associated with supply of initial guess in existing methods is circumvented. Experiments were performed on two types of actual, single, isolated transformer windings (continuous-disc and interleaveddisc) and the results are encouraging. Further details are presented in the thesis. Electric Transformers Frequency Response Analysis (FRA) Electric Transformers - Windings Ladder Networks Equivalent Circuit Transformer Winding Electrical Engineering
103	Věcný koncept a účetní řešení likvidace korporace v ČR a komparace s koncepty a účetním řešení v zahraničí / Comparison of legal, accounting and tax aspects of dissolution of the business company in the Czech republic and in the Poland republic Lelková, Petra January 2013 (has links) The goal of the diploma thesis is describing the process of winding up of business company, as a process leading to closure of business and dissolution of a company. The work is focused on legal, accounting and tax purposes in the Czech Republic and as well as in the Poland republic, including analysis of the diversity.
104	Nízkovýkonový přístrojový transformátor proudu / Low power current transformers Zolich, Ladislav January 2018 (has links) Master‘s thesis is focused on current instrument transformers, current sensors and low power current transformers. Discussion is made on advantages and disadvantages of each measuring principle. Low power current transformers is then designed and manufactured. Manufactured LPCT is then measured for accuracy class. Results are then compared.
105	Vliv vinutí na vlastnosti asynchronního motoru / Impact of winding on induction machine characteristics Mikmek, Vladislav January 2020 (has links) This thesis deals with the analysis of a three-phase winding of an induction engine. After the theoretical introduction concerning different types of windings, two types of their analysis and the importance of the winding factor, two methods of analysis and design tools are explained: Görges diagram and Tingley scheme. This scheme is then used for the design of all possible variants of winding for a certain number of stator slots and the theoretical shape of magnetic field is analysed. The next step is a deeper software analysis of the engines with variants of windings with different coil pitches and number of conductors per slot. Especially the finite element method is used in this part. The obtained values and their characteristics of the simulated engines are compared numerically and graphically. Then the changes of important values for different windings are described. The optimal winding according to chosen requirements is chosen.
106	Návrh olejového distribučního transformátoru / Design of oil distribution transformer Mrajca, Miroslav January 2021 (has links) This master thesis deals with the manufacturing process of oil distribution transformers. Firstly, the thesis devotes to the design arrangement of the magnetic circuit and its manufacturing technology. The procedure of cutting laminations for core and their building into the core. Subsequently, the thesis describes technologies used for manufacturing primary and secondary windings including procedures on winding machines. Then it deals with the production of the tank and the final assembly of the transformer into one unit. The next part of the thesis discusses the design procedure of the assigned distribution oil transformer with a numerical calculation while respecting the requirements of the standards. Finally, the costs of the material of the designed transformer are determined.
107	Accelerated Aging Study of Machine Winding Insulation under AC and High Frequency Pulse Voltage Application Chalise, Sajal Raj 01 May 2010 (has links) It is common practice to perform accelerated aging with 60 Hz ac to determine the lifetime characteristics of insulation used in the machine. Comparable breakdown measurements are performed at different voltage levels and temperatures for the polyimide insulated machine winding under normal operating conditions of 60 Hz ac. The result shows that the time to failure can be represented by the inverse power law and the Arrhenius equation with respect to test voltage and temperature respectively. However, the use of power electronic devices causes harmonics, and spikes that electrically degrade the machine winding insulation. Applied high frequency pulse voltages can be used to study the impact of electrical degradation of the machine winding insulation that exists in electrical machines. Evaluation of change in dielectric strength, partial discharge and breakdown voltage is monitored versus aging caused by high frequency pulse voltage at 90% of operating temperature. Accelerated aging Machine winding insulation High frequency pulse voltage 60 Hz ac voltage Partial discharge Breakdown voltage
108	Experimental study on compressive behavior and failure analysis of composite concrete confined by glass/epoxy ±55° filament wound pipes Gemi, L., Koroglu, M.A., Ashour, Ashraf 21 December 2017 (has links) Yes / This paper investigates the strength and ductility of concrete confined by Glass/Epoxy ±55° Filament Wound Pipes (GFRP) under axial compression. A total of 24 cylinderical specimens were prepared with expansive and Portland cements, properly compacted and un-compacted for different composite fresh concrete matrix. Test results showed that compressive strength and axial deformation at failure of concrete confined with GFRP tubes increased by an average of 2.85 and 5.57 times these of unconfined concrete, respectively. Macro and micro analyses of GFRP pipes after failure were also investigated. Debonding, whitening, matrix/transfer cracking, delamination and splitting mechanisms were detected at failure, respectively. The experimental results were also employed to assess the reliability of design models available in the literature for confined concrete compressive strength.
109	Design of HF Forward Transformer Including Harmonic Eddy Current Losses Ammanambakkam Nagarajan, Dhivya January 2010 (has links) No description available. Electrical Engineering Electromagnetics Engineering Forward transformer Forward converter Harmonic Losses Eddy current Losses winding losses
110	PCB-Based Heterogeneous Integration of PFC/Inverter Wang, Shuo 05 April 2023 (has links) State-of-the-art silicon-based power supplies have reached a point of maturity in performance. Efficiency, power density, and cost are major trade-offs involved in further improvements. Most products are custom designed with significant non-recurrent engineering and manufacturing processes that are labor intensive. In particular, conventional magnetic components, including transformers and inductors, have largely remained the same for the past five decades. Those large and bulky magnetic components are major roadblocks toward an automated manufacturing process. In addition, there is no specific approach to reduce electromagnetic interference (EMI) in conventional practices. In certain cases, EMI filter design even requires a trial-and-error process. With recent advances in wide-bandgap (WBG) power semiconductor devices, namely, SiC and GaN, we have witnessed significant improvements in efficiency and power density, compared to their silicon counterparts. In a power factor correction (PFC) rectifier/inverter, the totem-pole configuration with critical conduction mode (CRM) operation to realize zero-voltage switching (ZVS) is deemed most desirable for a switching frequency 10 times higher than current practice. With a significantly higher operating frequency, the integration of inductors with embedded windings in the printed circuit board (PCB) is feasible. However, a PCB winding-based inductor has a fundamental limitation in terms of its power handling capability. The winding loss is proportional to the magnetomotive force (MMF), which is Ni. That is to say, with the number of layers (turns) and currents increased, winding loss is increased nonlinearly. Furthermore, for a large-size planar inductor, flux distribution is usually non-uniform, resulting in dramatically increased hysteresis loss and eddy loss. Thus, current designs are challenged by the capability to increase their power range. To address those issues, a modular building block approach is proposed in this dissertation. A planar PCB inductor is formed by an array of pillars that are integrated into one magnetic core, where each pillar handles roughly 750 W of power. The winding loss is reduced by limiting the number of turns for each pillar. The core loss is minimized with a proposed planar magnetic structure where rather uniformly distributed fluxes were observed in the plates. The proposed approach has a similar loss to a conventional litz wire-based design but features a higher power density and can be easily assembled in automation. A 3 kW high frequency PFC converter with 99% efficiency is demonstrated as an example. Furthermore, PCB-based designs up to 6 kW are provided. Another challenge in a WBG-based PFC/inverter is the high common-mode (CM) noises associated with the high dv/dt of the WBG devices. Symmetry and cancellation techniques are often employed to suppress CM noises in switching power converters. Meanwhile, shielding technique has been demonstrated to effectively suppress CM noises in an isolated converter with PCB-based transformer design. However, for non-isolated converters, such as PFC circuits, none of the techniques mentioned above are deemed applicable or justifiable. Recently, the balance technique has been demonstrated to effectively suppress CM noises up to a point where the parasitic ringing between the inductor and its winding capacitor is observed. This dissertation presents an improved balance technique in a PCB-based coupled inductor design that compensates for the detrimental effect of the interwinding capacitors. A CM noise model is established to simplify the convoluted couplings into a decoupled representation so as to illustrate the necessary conditions for realizing a balanced network. In the given 1 kW PFC example, CM noise suppression is effective in the frequency range of interest up to 30 MHz. The parasitic oscillation of inductors, known to be detrimental for CM noise reduction, is circumvented with the improved magnetic structure. By applying the balance technique to a PFC converter and the shielding technique to an LLC DC/DC converter, significant noise reductions were realized. This provides the opportunity to use a simple one-stage EMI filter to achieve the required EMI noise attenuation for a server power supply. This dissertation further offers an in-depth study on reducing the unwanted near-field couplings between the CM/DM inductors and DM filter capacitors, as well as unwanted self-parasitics such as the ESL of the DM capacitors. An exhaustive finite element analysis (FEA) and near field measurements are conducted to better understand the effect of frequency on the polarization of the near field due to the displacement current. The knowledge gained in this study enables one to minimize unwanted mutual coupling effects by means of physical placement of these filter components. Thus, for the first time, a single-stage EMI filter is demonstrated to meet the EMI standard in an off-line 1 kW, 12 V server power supply. With the academic contributions in this dissertation, a PCB winding-based inductor can be successfully applied to a high-frequency PFC/inverter to achieve high efficiency, high power density, automation in manufacturing, lower EMI, and lower cost. Suffice it to say, the proposed approach enables a paradigm shift in the designing and manufacturing of a PFC/inverter for the next generation of power supplies. / Doctor of Philosophy / State-of-the-art silicon device-based switching power supplies have reached a point of maturity in performance. Efficiency, power density, and cost are major trade-offs involved in performance improvements. Most products are custom designed, requiring significant non-recurrent engineering and labor-intensive manufacturing processes. In particular, conventional magnetic components, including transformers and inductors, have largely remained the same for the past five decades. Those large and bulky magnetic components are major roadblocks toward an automated manufacturing process. In addition, there is no specific approach to reduce electromagnetic interference (EMI) in conventional practices. In consequence, a large multi-stage EMI filter is usually adopted between the power converter and the grid to reduce the EMI noise. It generally occupies 1/4-1/3 of the total converter volume. In certain cases, EMI filter design even requires a trial-and-error process. Suffice it to say, EMI is still regarded as both science and art. With recent advances in wide-bandgap (WBG) power semiconductor devices, namely, SiC and GaN, we have witnessed significant improvements in efficiency and power density, compared to their silicon counterparts. With GaN devices, the switching frequency of a PFC converter is able to be increased by 10 times compared to the state-of-the-art design without compromising efficiency. With a significantly higher operating frequency, the integration of inductors with embedded windings in the printed circuit board (PCB) is feasible. However, the state-of-the-art PCB winding-based inductor has a fundamental limitation in power range. Its winding loss and core loss increase dramatically in high powers. To address this issue, a modular building block approach is proposed in this dissertation. A planar PCB inductor is formed by an array of pillars that are integrated into one magnetic core, where each pillar handles roughly 750 W of power. The winding loss is reduced by limiting the number of turns for each pillar. The core loss is minimized with a proposed planar magnetic structure where rather uniformly distributed fluxes have been observed in the magnetic core plates. A 3 kW high-frequency PFC converter with a 99% peak efficiency is demonstrated as an example. Furthermore, PCB-based designs up to 6 kW are provided. Another challenge in a WBG-based PFC/inverter is the high common-mode (CM) noises caused by the high switching speed of the WBG devices. Symmetry and cancellation techniques are often employed to suppress CM noises in switching power converters. Meanwhile, shielding technique has been demonstrated to effectively suppress CM noises in an isolated converter with PCB-based transformer. However, for non-isolated converters, such as PFC circuits, none of the techniques mentioned above are deemed applicable or justifiable. Recently, the balance technique has been demonstrated to effectively suppress CM noises up to several MHz. However, the CM noise reduction is not effective beyond that. This dissertation presents an improved balance technique in a PCB-based coupled inductor to circumvent the limits. In the given 1 kW PFC example, CM noise suppression is effective in the frequency range of interest up to 30 MHz. By applying the balance technique to a PFC converter and the shielding technique to an LLC DC/DC converter, significant noise reductions were realized. This provides the opportunity to use a simple one-stage EMI filter to achieve the required EMI noise attenuation for a server power supply. It features a smaller volume compared to a conventional multi-stage filter. To further enhance the filter's performance at high frequencies, an exhaustive finite element analysis and near field measurements are conducted to better understand the effect of frequency on the polarization of the near field due to the displacement current. The knowledge gained in this study enables one to minimize unwanted mutual coupling effects through physical placement of these filter components. Several approaches for improving the filter performance at high frequency are conducted. With these approaches applied, a single-stage filter is demonstrated in an off-line 1 kW, 12 V server power supply. Thus, for the first time, a single-stage EMI filter can be contemplated to meet the EMI standard in server power supplies. With the academic contributions in this dissertation, a PCB-winding based inductor can be successfully applied to a high-frequency PFC/inverter to achieve high efficiency, high power density, automation in manufacturing, lower EMI, and lower cost. Suffice it to say, the proposed approach in this work enables a paradigm shift in the designing and manufacturing of a PFC/inverter for the next generation of power supplies. Wide-bandgap devices high frequency PCB winding-based inductor EMI balance technique near field effect PFC/inverter

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