Thematische Bibliographien / Multi-phase DC/DC converter

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  1. Zeitschriftenartikel
  2. Dissertationen
  3. Bücher
  4. Buchteile
  5. Konferenzberichte
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Auswahl der wissenschaftlichen Literatur zum Thema „Multi-phase DC/DC converter“

Autor: Grafiati
Veröffentlicht am 23. November 2024

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Zeitschriftenartikel zum Thema "Multi-phase DC/DC converter"

1

Hinov, Nikolay, und Tsvetana Grigorova. „Design Considerations of Multi-Phase Buck DC-DC Converter“. Applied Sciences 13, Nr. 19 (08.10.2023): 11064. http://dx.doi.org/10.3390/app131911064.

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The main objective of this article is to propose a rational methodology for designing multi-phase step-down DC-DC converters, which can find applications both in engineering practice and in power electronics education. This study discusses the main types of losses in the multi-phase synchronous buck converter circuit (transistors’ conduction losses, high-side MOSFET’s switching losses, reverse recovery losses in the body diode, dead time losses, output capacitance losses in the MOSFETs, gate charge losses in MOSFETs, conduction losses in the inductor, and losses in the input and output capacitors) and provides analytical dependencies for their calculation. Based on the control examples for applications characterized by low voltage and high output current, the multi-phase buck converter’s output and input current ripples are analyzed and compared analytically and graphically (3D plots). Furthermore, graphical results of the converter efficiency at different numbers of phases (N = 2, 4, 6, 8, and 12) are presented. An analysis of the impact of various parameters on power losses is conducted. Thus, a discussion on assessing the factors influencing the selection of the number of phases in the multi-phase synchronous buck converter is presented. The proposed systematized approach, which offers a fast and accurate method for calculating power losses and overall converter efficiency, reduces the need for extensive preliminary computational procedures and achieves optimized solutions. Simulation results for investigating power losses in 8-phase multi-phase synchronous buck converters are also presented. The relative error between analytical and simulation results does not exceed 4%.
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Krishna, P. Mohan. „DESIGN OF MULTI-PORT DC-DC CONVERTER“. INTERANTIONAL JOURNAL OF SCIENTIFIC RESEARCH IN ENGINEERING AND MANAGEMENT 08, Nr. 06 (09.06.2024): 1–5. http://dx.doi.org/10.55041/ijsrem35616.

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Integrating Energy sources to have a sustainable energy supply is an important aspect to handle the significant loads. Multiport power converters are used to connect various types of energy sources and loads. The key advantages of multi-input converters lie in their capability to interface with multiple input sources such as solar panels, wind turbines, batteries, and grid power, thereby optimizing energy utilization and enhancing system reliability. In the paper, a new configuration of single switch Dual– Input Single-Output (DISO) DC-DC converter is proposed. This paper presents an overview of multi-input converters, focusing on their design, operation, and applications in renewable energy integration Multiport converter reduces the system size and cost by reducing the number of components. The proposed converter is verified in MATLAB/ Simulink and validated with simulation results. Key Words: Dul-input single-output converter (DISO), switch, and Multiport converter.
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Harimon, M. A., A. Ponniran, A. N. Kasiran und H. H. Hamzah. „A Study on 3-phase Interleaved DC-DC Boost Converter Structure and Operation for Input Current Stress Reduction“. International Journal of Power Electronics and Drive Systems (IJPEDS) 8, Nr. 4 (01.12.2017): 1948. http://dx.doi.org/10.11591/ijpeds.v8.i4.pp1948-1953.

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This paper analyses a 3-phase interleaved DC-DC boost converter for the conversion of low input voltage with high input current to higher DC output voltage. The operation of the 3-phase interleaved DC-DC boost converter with multi-parallel of boost converters is controlled by interleaved of switching signals with 120 degrees phase-shifted. Therefore, with this circuit configuraion, high input current is evenly shared among the parallel units and consequently the current stress is reduced on the circuit and semiconductor devices and contributes reduction of overall losses. The simulation and hardware results show that the current stress and the semiconductor conduction losses were reduced approximately 33% and 32%, respectively in the 3-phase interleaved DC-DC boost converter compared to the conventional DC-DC boost converters. Furthermore, the use of interleaving technique with continuous conduction mode on DC-DC boost converters is reducing input current and output voltage ripples to increase reliability and efficiency of boost converters.
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Kumar, Mukesh, Manoj Kumar Dewangan und Maheedhar Dubey. „Implementation on Modeling and Analysis of Multi Stage with Multi Phase DC-DC Boost Converter“. International Journal of Advance Research and Innovation 9, Nr. 1 (2021): 35–43. http://dx.doi.org/10.51976/ijari.912106.

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In this paper, a new version of the new Hybrid Boost DC-DC ready to draw power from two different DC sources for standard DC-bus feeds is presented. An important feature of the proposed converter is that both sources provide simultaneous power to a lower load than the reduced current rate. This feature is very attractive for DC grid applications. With the analysis of the time zone, steadystate performance is established and the transformational power correction parameters are obtained. In this paper, a powerful converter is introduced, with its operating principles based on charging pumps and converters of reinforcement series. In addition, although three switches are used, no separate gate driver is required instead of one bridge gate driver and one gate driver on the lower side. As such, the proposed converter is easy to analyze and easy to operate. In addition, additional test results are provided to confirm the effectiveness of the proposed converter.
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Yan, Junchi. „Comparison and Optimization of Non-isolated DC-DC Converters for Electric Vehicle Applications“. Highlights in Science, Engineering and Technology 76 (31.12.2023): 609–17. http://dx.doi.org/10.54097/zdpznq48.

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This paper discusses the importance of electric vehicles in solving the problem of environmental pollution. In electric vehicles, DC/DC converter is a vital part to connect many electrical units with high voltage bus, so it plays a vital and indispensable role in electric vehicles. The paper analyzes the disadvantages of isolated DC/DC converter, and concludes that non-isolated DC/DC converter is a more suitable technical solution for electric vehicles. The research paper introduces a number of fundamental non-isolated DC/DC converter topologies before analyzing the technical optimization strategies of a number of DC/DC converters in general. which are Half-bridge converters, Cascaded Half-bridge converter (CHB), multi-phase interleaved parallel converter, tri-level converter, soft-switching converter, and switched-capacitor converter (SC converter). The benefits and drawbacks of these DC/DC converter optimization measures are compared, the findings can serve as a technical framework for guiding the application of DC/DC converter technology in the context of electric vehicles. Finally, this paper analyzes and looks forward to the development prospect of flying switched-capacitor DC/DC converters (FCDCs) technology, puts forward the existing technical problems, and gives suggestions for the solution of these problems, which is conducive to the wider application of this technical solution in electric vehicles.
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Verma, Vipin, und Aruna Patel. „(MIMO Buck Converter) Multi-Input Multi-Output DC-DC Buck Converter“. International Journal for Research in Applied Science and Engineering Technology 12, Nr. 3 (31.03.2024): 691–96. http://dx.doi.org/10.22214/ijraset.2024.58908.

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Abstract: Designs of the power electronics circuitry are nowadays reducing the size, space, and weight of converter and inverter circuits. This is possible because of the availability of new high-switching frequency devices. This paper presents a generalized model of buck converters that is multi-input multi-output(MIMO) fixed and variable. The converter used for stepping down the voltage is called a buck converter. The buck converter is designed, analyzed simulated & developed. The proposed model of this Buck converter consists of two parts: (a) Main converter circuits with the components like switch, inductor, diode, capacitor, and load, (b) A control circuit for controlling the operation of the switch using 10 10-turn potentiometer. This model can accurately give the power output voltage.
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Liu, Zhengxin, Jiuyu Du und Boyang Yu. „Design Method of Double-Boost DC/DC Converter with High Voltage Gain for Electric Vehicles“. World Electric Vehicle Journal 11, Nr. 4 (07.10.2020): 64. http://dx.doi.org/10.3390/wevj11040064.

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Direct current to direct current (DC/DC) converters are required to have higher voltage gains in some applications for electric vehicles, high-voltage level charging systems and fuel cell electric vehicles. Therefore, it is greatly important to carry out research on high voltage gain DC/DC converters. To improve the efficiency of high voltage gain DC/DC converters and solve the problems of output voltage ripple and robustness, this paper proposes a double-boost DC/DC converter. Based on the small-signal model of the proposed converter, a double closed-loop controller with voltage–current feedback and input voltage feedforward is designed. The experimental results show that the maximum efficiency of the proposed converter exceeds 95%, and the output voltage ripple factor is 0.01. Compared with the traditional boost converter and multi-phase interleaved DC/DC converter, the proposed topology has certain advantages in terms of voltage gain, device stress, number of devices, and application of control algorithms.
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Faraj, Karrar Saad, und Jasim F. Hussein. „Analysis and Comparison of DC-DC Boost Converter and Interleaved DC-DC Boost Converter“. Engineering and Technology Journal 38, Nr. 5A (25.05.2020): 622–35. http://dx.doi.org/10.30684/etj.v38i5a.291.

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The step-up converters are widespread use in many applications, including powered vehicles, photovoltaic systems, continuous power supplies, and fuel cell systems. The reliability, quality, maintainability, and reduction in size are the important requirements in the energy conversion process. Interleaving method is one of advisable solution for heavy-performance applications, its harmonious in circuit design by paralleling two or more identical converters. This paper investigates the comparison performance of a two-phase interleaved boost converter with the traditional boost converter. The investigation of validation performance was introduced through steady-state analysis and operation. The operation modes and mathematical analysis are presented. The interleaved boost converter improves low-voltage stress across the switches, low-input current ripple also improving the efficiency compared with a traditional boost converter. To validate the performance in terms of input and output ripple and values, the two converters were tested using MATLAB/SIMULINK. The results supported the mathematical analysis. The cancelation of ripple in input and output voltage is significantly detected. The ripple amplitude is reducing in IBC comparing with a traditional boost converter, and the ripple frequency is doubled. This tends to reduce output filter losses, and size.
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Zhou, Shijia, Fei Rong, Zhangtao Yin, Shoudao Huang und Yuebin Zhou. „HVDC Transmission Technology of Wind Power System with Multi-Phase PMSG“. Energies 11, Nr. 12 (26.11.2018): 3294. http://dx.doi.org/10.3390/en11123294.

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The high voltage DC (HVDC) transmission technology of wind power system, with multi-phase permanent magnetic synchronous generator (PMSG) is proposed in this paper. Each set of three-phase winding of the multi-phase PMSG was connected to a diode rectifier. The output of the diode rectifier was connected by several parallel isolated DC–DC converters. Each DC–DC converter was connected to a sub-module (SM). All SMs and two inductors were connected in a series. The proposed wind power system has several advantages including, transformerless operation, low cost, low voltage stress, and high fault tolerance. The maximum power point tracking (MPPT) and energy balance of the DC–DC converters were achieved by controlling the duty cycles of the DC–DC converters. The HVDC transmission was achieved by the nearest level control (NLC) with voltage sorting. The simulation model with 18-phase PMSG was established. Experimental results were also studied based on RT-Lab.
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Ankur Kumar, Gupta, Mitra Uliya und Verma Hemant Kumar. „A study of converter configurations for vehicular applications“. Trends in Computer Science and Information Technology 9, Nr. 1 (20.02.2024): 010–22. http://dx.doi.org/10.17352/tcsit.000075.

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Renewable energy sources like hydro, wind, geothermal and solar along with fuel cells are nowadays solutions to the global energy crisis, environmental issues, and fossil fuel exploitation. The nature of the output of these renewable sources is D.C. The role of DC-DC converters in the integration of energy sources with microgrids is vital. These converters find their major applications in power generation, energy systems, vehicular applications, portable electronic devices, aerospace, etc. These converters help to boost the voltage and improve the reliability, stability, efficiency, and performance of the system. This study gives a brief overview of three DC-DC converters of non-isolated topology. They are: Clamped H-type boost DC-DC converter, Multi-Port Dual-Active-Bridge DC-DC Converter, and Four-Phase Interleaved Four-Switch Buck-Boost Converter. This study will make researchers learn and make their concept clear about the operation, performance, and usage of these converters.
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Dissertationen zum Thema "Multi-phase DC/DC converter"

1

Qin, Ruiyang. „Study on Three-level DC/DC Converter with Coupled Inductors“. Thesis, Virginia Tech, 2016. http://hdl.handle.net/10919/73169.

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High power multi-level converters are deemed as the mainstay power conversion technology for renewable energy systems including the battery storage system, PV farm and electrical vehicle charge station. This thesis is focused on the study of three-level DC/DC converter with multi-phase interleaved structure, with coupled and integrated magnetics to achieve high power density. The proposed interleaved phased legs offer the benefit of output current ripple reduction, while inversed coupled inductors can suppress the circulating current between phase legs. Compared with conventional non-interleaving three-level DC/DC converter with non-coupling inductors, both inductor current ripple and output current ripple are largely reduced by interleaving with inverse-coupled inductors. Because of the non-linearity of the inductor coupling, the equivalent circuit model is developed for the proposed interleaving structure. The model identifies the existence of multiple equivalent inductances during one switching cycle. A combination of them determines the inductor current ripple and dynamics of the system. By virtue of inverse coupling and means of controlling the coupling coefficients, one can minimize the current ripple and the unwanted circulating current. To further reduce the magnetic volume, the four inductors in two-phase three-level DC/DC converter are integrated into one common structure, incorporating the negative coupling effects. The integrated magnetic structure can effectively suppress the circulating current and reduce the inductor current ripple and it is easy to manufacture. This thesis provides an equivalent circuit model to facilitate the design optimization of the integrated system. A prototype of integrated coupled inductors is assembled with nano-crystalline C-C core and powder block core. It is tested with both impedance analyzer and single pulse tester, to guarantee proper mutual inductance for inductor current ripple and output current ripple target. With a two-phase three-level DC/DC converter hardware, the concept of integrated coupled inductors is verified, showing its good performance in high-voltage, high-power conversion applications.
Master of Science
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Jacobs, Joseph [Verfasser]. „Multi-Phase Series Resonant DC-to-DC Converters / Joseph Jacobs“. Aachen : Shaker, 2006. http://d-nb.info/1166513211/34.

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3

Liu, Changrong. „A Novel High-Power High-Efficiency Three-Phase Phase-Shift DC/DC Converter for Fuel Cell Applications“. Diss., Virginia Tech, 2005. http://hdl.handle.net/10919/26048.

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Fuel cells are a clean, high-efficiency source for power generation. This innovative technology is going to penetrate all aspects in our life, from utility distributed power, transportation applications, down to power sources for portable devices such as laptop computer and cell phones. To enable the usage of fuel cell, developing power converters dedicated for fuel cells becomes imminent. Currently, the full-bridge converter is the dominating topology in high power dc/dc applications. Although multiphase converters have been proposed, most of them are dealing with high input-voltage systems, and their device characteristic is not suitable for a low voltage source such as a fuel cell. For a high power fuel cell system, high voltage conversion ratios and high input currents are the major obstacles to achieving high-efficiency power conversions. This dissertation proposes a novel 3-phase 6-leg dc/dc power converter with transformer isolation to overcome these obstacles. Major features of the proposed converter include: (1) Increase converter power rating by paralleling phases, not by paralleling multiple devices; (2) Double the output voltage by transformer delta-wye connection, thus lowering the turns-ratio; (3) Reduce the size of output filter and input dc bus capacitor with interleaved control; (4) Achieve Zero-Voltage Zero-Current Switching (ZVZCS) over a wide load range without auxiliary circuitry. High conversion efficiency above 96% is verified with different measurement approaches in experiments. This dissertation also presents the power stage and control design for the proposed converter. Control design guideline is provided and the design result is confirmed with both simulation and hardware experiments. When using the fuel cell for stationary utility power applications, a low-frequency ripple interaction was identified among fuel cell, dc/dc converter and dc/ac inverter. This low frequency ripple tends to not only damage the fuel cell, but also reduce the source capability. This dissertation also investigates the mechanism of ripple current propagation and exploits the solutions. A linearized ac model is derived and used to explain the ripple propagation. An active ripple reduction technique by the use of the current loop control is proposed. This active current loop control does not add extra converters or expensive energy storage components. Rather, it allows a reduction in capacitance because the ripple current flowing into the capacitor is substantially reduced, and less capacitance can be used while maintaining a clean dc bus voltage. The design process and guideline for the proposed control is suggested, and the effectiveness of this active control is validated by both simulation and experimental results.
Ph. D.
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Wallberg, Alexander. „Design and construction of a bidirectional DC/DC converter“. Thesis, Uppsala universitet, Elektricitetslära, 2019. http://urn.kb.se/resolve?urn=urn:nbn:se:uu:diva-385240.

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A four quadrant general single-phase bi-directional DC/DC converter was designed and constructed for high effect systems. The target application for the DC/DC converter was to be used to transfer energy between different energy storages, a miniature DC power grid and the high voltage AC power city grid. The converter is capable of step-up and step-down operations in both directions i.e. it is bi-directional at varying voltage levels. Different DC/DC topologies were investigated, and thereafter simulations were performed in LTspice and Simulink to ensure its capabilities and functionalities. The result of the simulations was a two layered PI-regulator, controlling both the external DC-grid voltage and inductor current through the converter. Once a suitable topology and control strategy was found, a suitable power transistor investigated and a PCB driver card were developed with KiCad. The final converter is capable to seamlessly change between its four modes and controlling voltages up to 1200 V and currents up to 200 A.
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Fan, Shixiong. „Current source DC/DC converter based multi-terminal DC wind energy conversion system“. Thesis, University of Strathclyde, 2012. http://oleg.lib.strath.ac.uk:80/R/?func=dbin-jump-full&object_id=17007.

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Wind power energy conversion is growing rapidly in the world. There are two main wind farm types, namely ac grid-based and dc grid-based wind farms. The dc grid-based approach reduces the size and weight of the magnetic components and cables. In the dc system, the step-up dc/dc converter is the key component when interfacing the wind turbine to the ac grid, via its low/medium voltage generator. This thesis focuses on the control and design of a wind energy conversion system based on dc/dc current source converters. An optimized One-Power-Point method for maximum power tracking is proposed. It incorporates One-Power-Point control and Maximum Power Differential Voltage control to allow the wind turbine to extract more energy during rapid wind speed changes. A current output hard-switched full bridge converter and serial-parallel resonant converter with an intermediate high frequency transformer are investigated for interfacing wind turbines to a local dc grid. These converters are assessed and compared in terms of semiconductor stresses and losses. A new modified One-Power-Point control method is proposed for the dc/dc converter, which tracks the maximum power during wind speed changes. A design procedure for the serial-parallel resonant converter is presented, based on its characteristics specific to a wind energy conversion system (WECS). A current source dc/dc converter based multi-terminal dc WECS is presented, investigated, and simulated. A practical multi-terminal dc WECS verifies its feasibility and stability, using two dc current output wind turbine units. Furthermore, a coordinated de-loading control scheme for the current sourcing based WECS is proposed, to cater for ac grid demand changes. It combines pitch control, dc dumping chopper control, and dc/dc converter control, to safely and quickly establish de-loading control. Both simulation and experimental results verify the de-loading scheme.
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Rezaee, Ali. „WIDE RANGE BI-DIRECTIONAL DC-DC CONVERTER“. Thesis, Mittuniversitetet, Institutionen för elektronikkonstruktion, 2021. http://urn.kb.se/resolve?urn=urn:nbn:se:miun:diva-41189.

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Bi-directional DC-DC converters are used for applications that require a flow of energy in two directions, while a wide range converter offer efficient operation over a wide range of input and output voltages. However, an efficient technology that is both bi-directional and Wide Input Wide Output (WIWO), currently, does not currently exist.   To find a suitable topology, the work began by surveying the existing literature and when a potentially suitable solution was identified, it was evaluated via simulation.   Using a wide range, unidirectional topology as the starting point, a converter topology was designed, capable of reconfiguring its transformer ratios by controlling the synchronization of its switches.   By aiming to use soft switching in simulation, this topology was improved to reach 92\% efficiency in the forward mode and 95\% in the reverse mode of operation. Furthermore, a prototype of this converter was developed that reached 82\% efficiency. While this prototype requires a better controller, hardware optimization and testing for optimal performance, the proposed technology was verified via simulation to work as a WIWO converter that is also bi-directional.
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Ward, Gillian Anne. „Design of a multi-kilowatt, high frequency, DC-DC converter“. Thesis, University of Birmingham, 2003. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.274596.

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Gunawan, Tadeus. „Two-Phase Boost Converter“. DigitalCommons@CalPoly, 2009. https://digitalcommons.calpoly.edu/theses/200.

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A boost converter is one of the most efficient techniques to step up DC input voltage to a higher needed DC output voltage. The boost converter has many possible applications, such as in a photovoltaic system, hybrid car and battery charger. The proposed prototype in this report is a proof of concept that a Two-Phase Boost Converter is a possible improvement topology to offer higher efficiency without compromising any advantages readily offered by a basic boost. The prototype is designed to be able to handle up to 200 watts of output power with an input of 36 volts and an output of 48 volts. This paper goes through step-by-step the calculation, design, build and test of a Two-Phase Boost Converter. Calculations found in this paper were done on Mathcad and the simulations were done on LTSpice and Pspice. These include converter’s efficiency and other measures of converter’s performance. Advantages, disadvantages as well as possible improvements of the proposed topology will be presented. Data collected and analyzed from the prototype were done on a bench test, not through an actual application.
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Mazza, Luan Carlos dos Santos. „Single phase bidirectional DAB DC-DC converter based on three state switching cell“. Universidade Federal do CearÃ, 2014. http://www.teses.ufc.br/tde_busca/arquivo.php?codArquivo=14412.

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This work presented is DC-DC isolated ZVS Bidirectional Dual Active Bridge (DAB) single phase converter, based three-state switching cell is presented. The proposal is to apply it in photovoltaic systems with battery bank into smart networks. Basically the drive control is the duty cycle (D) of the switches and the Phase Shift (φ) of the fundamental tensions between the bridges. The gyrator modeling of the converter is presented, highlighting its natural operating characteristic as gyrator. Shows the qualitative and quantitative analysis of the converter, realizing the full study of the stages of operation of the topology and checking all sixteen regions of operation. To obtain the regions of soft-switching, the fundamental model is applied. The design procedure of the converter is presented, and the results of simulations. A 2kW prototype was developed, aimed at obtaining experimental results validate the theoretical analysis
Neste trabalho à apresentado o conversor CC-CC ZVS isolado bidirecional Dual Active Bridge (DAB) monofÃsico, baseado na cÃlula de comutaÃÃo de trÃs estados. A proposta à aplicÃ-lo em sistemas fotovoltaicos com banco de baterias em redes inteligentes. Basicamente o controle do conversor consiste na razÃo cÃclica (D) dos interruptores e o Phase Shift (φ) entre as componentes fundamentais das tensÃes entre as pontes. A modelagem por gyrator do conversor à apresentada, destacando-se sua caracterÃstica natural de funcionamento como gyrator. Mostra-se a anÃlise qualitativa e quantitativa do conversor, realizando o estudo completo das etapas de operaÃÃo da topologia e verificando todas as dezesseis regiÃes de operaÃÃo. Para obtenÃÃo das regiÃes de comutaÃÃo suave, à aplicado o modelo fundamental. O procedimento de projeto do conversor à apresentado, alÃm dos resultados de simulaÃÃes. Um protÃtipo de 2 kW foi desenvolvido, visando a obtenÃÃo dos resultados experimentais e validando a anÃlise teÃrica.
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Francisco, Venustiano Canales Abarca. „Novel DC/DC Converters For High-Power Distributed Power Systems“. Diss., Virginia Tech, 2003. http://hdl.handle.net/10919/28612.

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One of the requirements for the next generation of power supplies for distributed power systems (DPSs) is to achieve high power density with high efficiency. In the traditional front-end converter based on the two-stage approach for high-power three-phase DPSs, the DC-link voltage coming from the power factor correction (PFC) stage penalizes the second-stage DC/DC converter. This DC/DC converter not only has to meet the characteristics demanded by the load, but also must process energy with high efficiency, high reliability, high power density and low cost. To meet these requirements, approaches such as the series connection of converters and converters that reduce the voltage stress across the main devices have been proposed. In order to improve the characteristics of these solutions, this dissertation proposes high-efficiency, high-density DC/DC converters for high-power high-voltage applications. In the first part of the dissertation, a DC/DC converter based on a three-level structure and operated with pulse width modulation (PWM) phase-shift control is proposed. This new way to operate the three-level DC/DC converter allows soft-switching operation for the main devices. Zero-voltage switching (ZVS) and zero-voltage and zero-current switching (ZVZCS) soft-switching techniques are studied, analyzed and compared in order to improve the characteristics of the proposed converter. This results in a series of ZVS and ZVZCS three-level DC/DC converters for high-power high-voltage applications. In all cases, results from 6kW prototypes operating at 100 kHz are presented. In addition, with the ultimate goal of improving the power density of the DC/DC converter, a study of several resonant DC/DC converters that can operate at higher switching frequencies is presented. From this study, a three-element ZVS three-level resonant converter for applications with wide input voltage and load variations is proposed. Experimental results at 745 kHz obtained without penalizing the efficiency of the PWM approaches are presented. The second part of the dissertation proposes a quasi-integrated AC/DC three-phase converter that aims to reduce the complexity and cost of the traditional two-stage front-end converter. This converter improves the complexity/low-efficiency tradeoff characteristics evident in the two-stage approach and previous integrated converters. The principle of operation for the converter is analyzed and verified on a 3kW experimental prototype.
Ph. D.
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Bücher zum Thema "Multi-phase DC/DC converter"

1

Xu, Dianguo, Yueshi Guan, Yijie Wang und Xiangjun Zhang. Multi-MHz High Frequency Resonant DC-DC Power Converter. Singapore: Springer Singapore, 2021. http://dx.doi.org/10.1007/978-981-15-7424-5.

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2

Anne, WardhGillian. Design of a multi-kilowatt, high frequency, DC-DC converter. Birmingham: University of Birmingham, 2003.

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3

Durie, A. F. Fixed link DC voltage converter with GTO devices for single phase traction drives. Birmingham: University of Birmingham, 1987.

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4

Stergiopoulos, Fotis. Analysis and control design of the three-phase voltage-sourced AC/DC PWM converter. Birmingham: University of Birmingham, 1999.

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5

Zhang, Xiangjun, Dianguo Xu, Yijie Wang und Yueshi Guan. Multi-MHz High Frequency Resonant DC-DC Power Converter. Springer Singapore Pte. Limited, 2020.

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Zhang, Xiangjun, Dianguo Xu, Yijie Wang und Yueshi Guan. Multi-MHz High Frequency Resonant DC-DC Power Converter. Springer Singapore Pte. Limited, 2021.

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Strouth, Larue. 3 Phase AC DC Converter Design : How to DIY Phase Converter: Static Phase Converter Design. Independently Published, 2021.

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Vaquez, Everett. 3 Phase AC DC Converter Design : How to DIY Phase Converter: Static Phase Converter Design. Independently Published, 2021.

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Koubaâ, Karama. Analysis and Control of the Chaotic Behavior in a Multi-Cell DC/DC Buck Converter. Nova Science Publishers, Incorporated, 2018.

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Borisavljevic, Ana. Digitally controlled three-phase high power switch-mode AC-DC converter. 2002.

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Buchteile zum Thema "Multi-phase DC/DC converter"

1

Van Breussegem, Tom, und Michiel Steyaert. „Noise Reduction by Multi-Phase Interleaving and Fragmentation“. In CMOS Integrated Capacitive DC-DC Converters, 91–110. New York, NY: Springer New York, 2012. http://dx.doi.org/10.1007/978-1-4614-4280-6_4.

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Xu, Dianguo, Yueshi Guan, Yijie Wang und Xiangjun Zhang. „Typical Multi-MHz DC–DC Converter“. In CPSS Power Electronics Series, 55–72. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-7424-5_5.

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Guan, Yueshi, Yueshi Guan, Yijie Wang und Xiangjun Zhang. „Flexible Multi-MHz DC-DC Converter“. In CPSS Power Electronics Series, 121–29. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-7424-5_9.

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Xu, Dianguo, Yueshi Guan, Yijie Wang und Xiangjun Zhang. „Resonant Inverter in Multi-MHz DC–DC Converter“. In CPSS Power Electronics Series, 5–18. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-7424-5_2.

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Xu, Dianguo, Yueshi Guan, Yijie Wang und Xiangjun Zhang. „Resonant Rectifier in Multi-MHz DC–DC Converter“. In CPSS Power Electronics Series, 19–36. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-7424-5_3.

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Xu, Dianguo, Yueshi Guan, Yijie Wang und Xiangjun Zhang. „Matching Network in Multi-MHz DC–DC Converter“. In CPSS Power Electronics Series, 37–54. Singapore: Springer Singapore, 2020. http://dx.doi.org/10.1007/978-981-15-7424-5_4.

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Dias, Nuno, Marcelino Santos, Floriberto Lima, Beatriz Borges und Júlio Paisana. „Monolithic Multi-mode DC-DC Converter with Gate Voltage Optimization“. In Lecture Notes in Computer Science, 258–67. Berlin, Heidelberg: Springer Berlin Heidelberg, 2009. http://dx.doi.org/10.1007/978-3-540-95948-9_26.

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Zhang, Yifei, Chunmei Xu, Haoying Pei und Lingbo Li. „Dual-Mode DC/DC Converter for Multi-energy Drive System“. In Proceedings of the 5th International Conference on Electrical Engineering and Information Technologies for Rail Transportation (EITRT) 2021, 127–34. Singapore: Springer Singapore, 2022. http://dx.doi.org/10.1007/978-981-16-9905-4_15.

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Ruan, Xinbo, Li Zhang, Xinze Huang, Fei Liu, Guoping Zhu und Shiqi Kan. „Second Harmonic Current Reduction for DC-DC Converter in Two-Stage PFC Converters“. In Second Harmonic Current Reduction Techniques for Single-Phase Power Electronics Converter Systems, 147–72. Singapore: Springer Nature Singapore, 2022. http://dx.doi.org/10.1007/978-981-19-1547-5_7.

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Wei, Li, und Wen Yan. „A Wide-Range Input Multi-phase Interleaved DC/DC Converter Suitable for Fuel Cells“. In Lecture Notes in Electrical Engineering, 121–34. Singapore: Springer Nature Singapore, 2022. http://dx.doi.org/10.1007/978-981-19-1922-0_10.

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Konferenzberichte zum Thema "Multi-phase DC/DC converter"

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Akar, Furkan. „A bidirectional multi-phase multi-input DC-DC converter“. In 2017 International Conference on Engineering and Technology (ICET). IEEE, 2017. http://dx.doi.org/10.1109/icengtechnol.2017.8308191.

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Zanwar, Mahesh, und Subhajit Sen. „CMOS multi-phase switched capacitor step-up DC-DC converter“. In 2016 IEEE International Conference on the Science of Electrical Engineering (ICSEE). IEEE, 2016. http://dx.doi.org/10.1109/icsee.2016.7806140.

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Ebrahimzadeh, Faezeh, Ebrahim Babaei, Carlo Cecati und Concettina Buccella. „Four-phase isolated DC-DC converter“. In 2017 14th International Conference on Electrical Engineering/Electronics, Computer, Telecommunications and Information Technology (ECTI-CON). IEEE, 2017. http://dx.doi.org/10.1109/ecticon.2017.8096348.

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Akar, Furkan, Murat Kale, Sebahattin Yalcm und Gozde Tas. „A Multi-Input Multi-Phase DC-DC Converter with Soft-Switching Capability“. In 2020 4rd International Conference on Electrical, Telecommunication and Computer Engineering (ELTICOM). IEEE, 2020. http://dx.doi.org/10.1109/elticom50775.2020.9230489.

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Arrozy, Juris, Arwindra Rizqiawan und Pekik Argo Dahono. „Losses Evaluation of Multi-phase Asymmetrical Bridge DC-DC Boost Converter“. In 2018 Conference on Power Engineering and Renewable Energy (ICPERE). IEEE, 2018. http://dx.doi.org/10.1109/icpere.2018.8739666.

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Guiza, Dhaouadi, Djamel Ounnas, Youcef Soufi und Abdelmalek Bouden. „DC-DC Buck Converter Control Improvement“. In 2021 18th International Multi-Conference on Systems, Signals & Devices (SSD). IEEE, 2021. http://dx.doi.org/10.1109/ssd52085.2021.9429371.

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Ozturk, Gokturk, und Guven Onbilgin. „Simulation of Single Phase Matrix Converter as DC-DC and DC-AC Converters“. In The 4th World Congress on Electrical Engineering and Computer Systems and Science. Avestia Publishing, 2018. http://dx.doi.org/10.11159/eee18.119.

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Su, Bing, Yubin Wang, Xuekun Wang, Fan Wang, Jia Ming und Zheng Guo. „Multi-Phase Interleaved Bidirectional DC/DC Converter with Two-Winding Coupled Inductors“. In 2019 IEEE 3rd International Electrical and Energy Conference (CIEEC). IEEE, 2019. http://dx.doi.org/10.1109/cieec47146.2019.cieec-2019189.

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Waffler, S., und J. W. Kolar. „Efficiency optimization of an automotive multi-phase bi-directional DC-DC converter“. In 2009 IEEE 6th International Power Electronics and Motion Control Conference. IEEE, 2009. http://dx.doi.org/10.1109/ipemc.2009.5157451.

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Guo Guoyong und Shi Bingxue. „Design of multi-phase DC-DC converter with averaged current sharing control“. In 2003 5th International Conference on ASIC Proceedings (IEEE Cat No 03TH8690) ICASIC-03. IEEE, 2003. http://dx.doi.org/10.1109/icasic.2003.1277601.

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Berichte der Organisationen zum Thema "Multi-phase DC/DC converter"

1

Amirabadi, Mahshid, Brad Lehman, Masih Khodabandeh, Xinmin Zhang und Junhao Luo. A Universal Converter for DC, Single-phase AC, and Multi-phase AC Systems. Office of Scientific and Technical Information (OSTI), November 2022. http://dx.doi.org/10.2172/1994839.

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Cleary, Summers. Land Cover Summary Statistics for National Capital Region Park Units. National Park Service, 2024. http://dx.doi.org/10.36967/2301309.

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Annotation:
This report documents the acquisition of source data, and calculation of land cover summary statistics datasets for ten National Park Service National Capital Region park units and three custom areas of analysis: Catoctin Mountain Park, Chesapeake & Ohio Canal National Historical Park, George Washington Memorial Parkway, Harpers Ferry National Historical Park, Manassas National Battlefield Park, Monocacy National Battlefield, National Capital Parks - East, Prince William Forest Park, Rock Creek Park, Wolf Trap National Park for the Performing Arts, and the three custom areas of analysis - National Capital Parks - East: Oxon Cove Park, Oxon Hill Farm, Piscataway Park, National Capital Parks - East: Greenbelt Park and Baltimore-Washington Parkway, and National Capital Parks - East: DC and Suitland Parkway. The source data and land cover calculations are available for use within the National Park Service (NPS) Inventory and Monitoring Program. Land cover summary statistics datasets can be calculated for all geographic regions within the extent of the NPS; this report includes statistics calculated for the conterminous United States. The land cover summary statistics datasets are calculated from multiple sources, including Multi-Resolution Land Characteristics Consortium products in the National Land Cover Database (NLCD) and United States Geological Survey?s (USGS) Earth Resources Observation and Science (EROS) Center products in the Land Change Monitoring, Assessment, and Projection (LCMAP) raster dataset. These summary statistics calculate land cover at up to three classification scales: Level 1, modified Anderson Level 2, and Natural versus Converted land cover. The output land cover summary statistics datasets produced here for the ten National Capital Region park units and three custom areas of analysis utilize the most recent versions of the source datasets (NLCD and LCMAP). These land cover summary statistics datasets are used in the NPS Inventory and Monitoring Program, including the NPS Environmental Settings Monitoring Protocol and may be used by networks and parks for additional efforts.
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