Design and control of matrix converters : regulated 3-phase power supply and voltage sag mitigation for linear loads / Anindya Dasgupta, Parthasarathi Sensarma.
Dasgupta, Anindya, author.; Sensarma, Parthasarathi, author.
2017
TK7872.C8
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Title Design and control of matrix converters : regulated 3-phase power supply and voltage sag mitigation for linear loads / Anindya Dasgupta, Parthasarathi Sensarma.
Author Dasgupta, Anindya, author.
ISBN 9789811038310 (electronic book)
9811038317 (electronic book)
9789811038297
DOI https://doi.org/10.1007/978-981-10-3831-0
Published Singapore : Springer, 2017.
Language English
Description 1 online resource (xvi, 124 pages) : illustrations.
Other Standard Identifiers 10.1007/978-981-10-3831-0 doi
Call Number TK7872.C8
Dewey Decimal Classification 621.3815/322
Summary This book describes two target applications for synchronous systems: regulated 3-phase voltage supply and voltage sag mitigation. It presents a detailed design procedure for converter switches and filters considering all steady-state, commutation and dynamic requirements. This work has evolved from previously published research by the authors, which in turn is part of a larger effort to expand the application domain of matrix converters to power systems. The objectives of the work have been categorized into the following: developing a dynamic model that provides adequate design insights; designing filters; and devising a control scheme. The low frequency dynamic model is first analyzed for regulated voltage supplies assuming balanced system. The system is modeled relative to a synchronous rotating (dq) frame linearized around an operating point. The input–output variables are related by non-diagonal transfer function matrices. Individual transfer function sub-matrices are sequentially investigated and it is shown that, depending on the input power, input voltage and filter parameters, the appearance of a set of right half zeros is possible. The book then considers filter design, as well as general issues like ripple attenuation, regulation, reactive current loading, and filter losses. The book also addresses additional constraints that may be imposed by dynamic requirements and commutation. In the third stage, voltage controller design is detailed for a 3-phase regulated voltage supply. In dq domain, output voltage control represents a multivariable control problem. This is reduced to a single variable control problem while retaining all possible right half zeros, thereby preserving the internal stability of the system. Consequently, the standard single variable control design technique has been used to design a controller. The analytically predicted dynamic response has been verified by experimental results. It was possible to operate the system beyond the critical power boundary where the right half zeros emerge. Lastly, the developed control approach has been extended to voltage sag mitigation with adequate modifications. A 3-wire linear load and both symmetrical and asymmetrical voltage sags have been considered. Experimentally obtained response time for sag mitigation was found to be less than the power supply holdup time of most of the sensitive equipment. This book will be useful to both researchers and graduate students.
Bibliography, etc. Note Includes bibliographical references.
Access Note Access limited to authorized users.
Digital File Characteristics text file PDF
Source of Description Online resource; title from PDF title page (SpringerLink, viewed April 7, 2017).
Added Author Sensarma, Parthasarathi, author.
Series Energy systems in electrical engineering.
Available in Other Form Print version: 9789811038297
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Preface; Contents; About the Authors; List of Figures; List of Tables; 1 Introduction; 1.1 Overview of 3-Phase Matrix Converter; 1.1.1 Hardware Design; 1.1.2 Commutation; 1.1.3 Topology; 1.1.4 Modulation; 1.1.5 Dynamic Model for Controller Design; 1.2 Motivation and Objectives; 1.3 Assumptions and Scope; 1.4 Layout of the Book; 2 Low Frequency Dynamic Model; 2.1 Low Frequency Gain of 3-Phase MC; 2.1.1 Indirect Space Vector Modulation (ISVM) Approach; 2.2 Linearized Model; 2.3 Composition of Gc(s); 2.3.1 Poles and Zeros of CdTM; 2.3.2 Poles and Zeros of Gc(s); 2.4 Concluding Remarks

3 Filter Design3.1 Input Filter Design; 3.1.1 Attenuation to Switching Frequency Ripple and Gain to Lower Order Harmonics; 3.1.2 Voltage Regulation and Reactive Current Loading; 3.1.3 Selecting Damping Resistor Rd; 3.1.4 Lower Limit of Cf; 3.1.5 Effect of Ls; 3.1.6 Design Modifications for a Non-minimum Phase Plant; 3.2 Output Filter; 3.2.1 Lower Limit of Lo; 3.3 Selection of Parameter Values; 3.4 Results and Discussion; 3.4.1 Open Loop Experimental Results; 3.5 Concluding Remarks; 4 Controller Design for Regulated Voltage Supply; 4.1 Specifications and Assumptions; 4.2 SISO Based Control

4.2.1 Nff(s) and Hv(s)4.3 Experimental Results and Discussion; 4.4 Concluding Remarks; 5 Voltage Sag Mitigation; 5.1 Topology and Voltage Injection Method; 5.2 Plant Model; 5.3 Control Scheme for DVR; 5.3.1 FB Controller; 5.3.2 FF Controller; 5.4 Experimental Results and Discussion; 5.5 Concluding Remarks; 6 Conclusion; 6.1 Conclusions and Contributions; 6.2 Scope of Future Work; 6.3 Relevance of This Work at Present; Appendix A Derivations Associated with Low Frequency Dynamic Model; Appendix B 3 Phase Direct Matrix Converter Prototype; Appendix C Phase Locked Loop; References

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