Microprocessor control of 6-pulse 3-phase/3-phase cycloconverter employing flywheeling techniques

Cade, M.

January 1987

No description available.

621.3192

Cycloconverter control

Power Quality Analysis of a Three-Phase Cycloconverter Under Variable Operating Conditions

Palani, Kevin

01 June 2010

The objective of this study is to observe the correlations between variable operating conditions and power quality parameters for a three-phase to single-phase cycloconverter. The cycloconverter is examined in its most straightforward form without additional output filters or elaborate control methods. Variable operating conditions include input frequency, output frequency, and resistive load size. The power quality parameters of interest are power factor, input current total harmonic distortion (THD), output voltage THD, and efficiency. The scope of the project includes analytical calculations, PSpice simulations, as well as a hardware implementation. The results show that output frequency has minimal effect on power quality. High input frequencies tend to yield less efficiency and larger loads yield higher efficiency. Total harmonic distortion undesirably peaks at a combination of low input frequency and high output frequency. Extrapolations can be made for the cycloconverter operating at different frequencies and loads based on the trends observed within the test matrix.

three phase cycloconverter

power quality

Bidirectional Invertor With High Frequency Ac Link

Karuppuswamy, C

03 1900

It is customary to obtain ac power from batteries through a power converter, where mains ac power is not readily available. Such a power converter is also needed in several mobile/ airborne/ space applications. Till recently this application is served by a H bridge inverter followed by a low frequency transformer and a passive low pass filter. The H bridge inverter employs high frequency pulse width modulation. The transformer is made of standard silicon steel. The filter is made of L and C elements. In such a converter the magnetics account for about 30% of cost and 50% of weight. Moreover the dc input current in such converters is discontinuous, leading to poor efficiency. There is need for an input filter as well. This thesis presents the development of an inverter with high frequency (hf) link. The power converter employs a boost front end resulting in continuous input current. The H bridge inverter employs phase modulation technique with soft switching features. The boost converter and the H bridge share power devices. The isolation transformer handles high frequency ac power and is compact. It is shown that the transformer size can be reduced by more than one order of magnitude. There is a rear end cycloconverter to reconvert the high frequency ac power into 50 Hz output power. Innovative pulse sequencing in the cycloconverter ensures loss-less switching. The pulse width modulation shifts the dominant harmonic frequency to double the switching frequency. The output LC filter is light. The converter can handle bidirectional power. The controller is digital. The overall concept was demonstrated through the 500 W prototype design. The proposed topology offers small size, low losses and continous input current. The controller is digital and offers totally software based compensation and settings. It is expected that on account of the small size and cost, this topology is likely to become more popular in the near future. The applications of such power converters will bring down the size and cost of UPS, solar inverters, wind mill inverters etc.

Electric Inverters

Electric Converter

High Frequency Ac Link

Power Converters

Digital Controllers

Cycloconverter

H Bridge Inverter

HF-Transformer

Electrical Engineering

Modeling, Real-time Simulation And Design Of Matrix Converters

Gopinath, Dinesh

09 1900

Power converters have evolved from the classical low switching frequency thyristorised converters to the modern high-frequency switched mode converters employing fast power devices such as Insulated Gate Bipolar Transistors (IGBTs). This evolution has changed the way power is processed in all the four functional areas of power conversion namely, AC-DC, DC-DC, DC-AC and AC-AC. High frequency switching has made it possible to reduce the size of the converters by using smaller energy storage elements. Switched mode conversion applied to AC-AC power conversion results in the use of two approaches: An indirect (two stage) conversion with a rectifier and an inverter with a dc link storage and a direct conversion scheme with a matrix converter. Matrix converter is a potential candidate in certain applications where a compact power converter design is required. Two approaches in topology, namely direct and indirect matrix converters are well reported in the literature. This thesis looks at the analysis, modeling and control of matrix converters from the perspective of converter switching functions. The switching functions as proposed for the line frequency switching rectifiers and cycloconverters is extended to the high frequency switching pulse-width modulated inverters and rectifiers. The matrix converter modulation schemes are analysed and a fresh interpretation in terms of these switching functions is presented in this thesis. The application of the switching function based analysis also yields a better insight into popular space phasor moulation techniques employed in matrix converters such as indirect-space-phasor modulation. The topology of the matrix converter is simple. There are no energy storage elements. However, the control, modulation and protection processes are more complex than other converters. The complexities involved in the control, modulation, commutation and protection of the matrix converter necessitates a much more complex controller capable of carrying out these tasks fast and effectively. In this work, a versatile FPGA based digital controller is designed which is not only capable of carrying out all the modulation, control, commutation and protection requirements of the matrix converter but also, can simulate the converter and the load in real-time. The real-time simulation capabilities of the control and real-time simulation platform are demonstrated with a suitable example of dynamic system. The real-time models of the matrix converter feeding passive load are developed and demonstrated in comparison with offline simulation models. Matrix converters are buck-derived converters and hence the input currents are discontinuous. Hence design of an appropriate filter becomes necessary. Some guidelines are suggested to design an appropriate input filter considering the non-idealities of the source. Finally, hardware designs of suitably rated direct and indirect matrix converters are presented and some representative results are given.

Converters

Matrix Converters - Simulation

Converters - Modeling

Matrix Converters

Power Converters

Power Converter Design

Digital Controller

Cycloconverter

Power Electronics

System Aspects and Modulation Strategies of an HVDC-based Converter System for Wind Farms

Meier, Stephan

January 2009

In this thesis, a new HVDC-based converter system for wind farms is investigated. It is based on a mutually commutated soft-switching converter system and provides a unique integrated solution for the wind turbine generator drive systems, the wind turbine interconnection, and the power conversion for HVDC transmission. In a wind farm, the mutually commutated converter system is a distributed system. A medium-frequency collection grid connects the converter station, equipped with a single-phase voltage source converter and a medium-frequency transmission transformer, with the wind turbines, each containing a cycloconverter and a medium-frequency distribution transformer. In this thesis, various system aspects regarding the application of a distributed mutually commutated converter system in a wind farm are investigated. Special attention is paid to the design of a medium-frequency collection grid that has an acceptable level of transient overvoltages, the design of medium-frequency transformers with suitable magnetic, electric and thermal properties, and the development of a strategy to commutate the voltage source converter during low power generation. In order to adapt the mutually commutated converter system for an application in a wind farm, it had to be further developped. Different carrier-based and space-vector oriented modulation methods have been investigated. It turns out that for any load angle there is a quasi-discontinuous pulse width modulation strategy that can produce the same pulse patterns as space vector modulation. In addition, a modulation strategy has been developed that allows to replace the IGBTs in the cycloconverter with cheap, robust, and reliable fast thyristors, despite their absence of turn-off capability. The feasibility of different modulation strategies for mutually commutated converter systems has been verified on a down-scaled prototype converter system with both IGBT- and thyristor-based cycloconverters. Finally, a feasible wind farm layout is proposed, which considerably reduces the energy generation costs for large winds farms distant to a strong grid connection point. As a consequence, the proposed solution may facilitate the establishment of remotely located wind farms. / QC 20100802

Isolated AC/DC Converter

Mutual Commutation

Soft Switching

Voltage Source Converter

Cycloconverter

Modulation Strategies

Medium-Frequency Transformer

HVDC Transmission

Wind Power

Wind Farms

Electric power engineering

Elkraftteknik

Electrical engineering

Elektroteknik

Modeling methodology of converters for HVDC systems and LFAC systems: integration and transmission of renewable energy

Cho, Yongnam

20 September 2013

The major achievements of this work are based on two categories: (A) introduction of an advanced simulation technique in both time domain and frequency domain, and (B) realistic and reliable models for converters applicable to analysis of alternative transmission systems. The proposed modeling-methodology using a combination of model quadratization and quadratic integration (QMQI) is demonstrated as a more robust, stable, and accurate method than previous modeling methodologies for power system analyses. The quadratic-integration method is free of artificial numerical-oscillations exhibited by trapezoidal integration (which is the most popularly used method in power system analyses). Artificial numerical oscillations can be the direct reason for switching malfunction of switching systems. However, the quadratic-integration method has a natural characteristic to eliminate fictitious oscillations with great simulation accuracy. Also, model quadratization permits nonlinear equations to be solved without simplification or approximation, leading to realistic models of nonlinearities. Therefore, the QMQI method is suitable for simulations of network systems with nonlinear components and switching subsystems. Realistic and reliable converter models by the application of the QMQI method can be used for advanced designs and optimization studies for alternative transmission systems; they can also be used to perform a comprehensive evaluation of the technical performance and economics of alternative transmission systems. For example, the converters can be used for comprehensive methodology for determining the optimal topology, kV-levels, etc. of alternative transmission systems for wind farms, for given distances of wind farms from major power grid substations. In this case, a comprehensive evaluation may help make more-informed decisions for the type of transmission (HVAC, HVDC, and LFAC) for wind farms.

HVDC transmission

LFAC transmission

A QMQI method

Quadratic integration

Model quadratization

Wind-farm systems

Push-pull resonant converter

Three-phase six-pulse converter

Three-phase six-pulse cycloconverter

Three-phase PWM converter

Renewable energy sources

Wind power

Wind power plants

Regulace příkonu přečerpávacích vodních elektráren v čerpadlovém provozu / Regulation of Pumped Storage Power Plants Inputs Under the Pumped Operating Condition.

Lorenz, Tomáš

January 2008

This paper focuses on the Double Fed Induction Machine in the Pumped Storage Power Plants. It includes listing of this plants in the world, where such a technology is used; principle of Double Fed Induction Machine, its usage with variable speed, advantages and disadvantages and also experience of its usage.