Your search keyword '"modular multilevel matrix converter (m3c)"' showing total 14 results

1. Fully Decoupled Branch Energy Balancing Control Method for Modular Multilevel Matrix Converter Based on Sequence Circulating Components

Author

Zexin Zhao, Weijiang Chen, Zhichang Yang, Guoliang Zhao, Bin Han, Yunfei Xu, Nianwen Xiang, and Shulai Wang

Subjects

Branch energy balancing control, decoupled control, low-frequency AC transmission, modular multilevel matrix converter (M3C), sequence circulating components, Technology, Physics, QC1-999

Abstract

The modular multilevel matrix converter (M3C) is a potential frequency converter for low-frequency AC transmission. However, capacitor voltage control of high-voltage and large-capacity M3C is more difficult, especially for voltage balancing between branches. To solve this problem, this paper defines sequence circulating components and theoretically analyzes the influence mechanism of different sequence circulating components on branch capacitor voltage. A fully decoupled branch energy balancing control method based on four groups of sequence circulating components is proposed. This method can control capacitor voltages of nine branches in horizontal, vertical and diagonal directions. Considering influences of both circulating current and voltage, a cross decoupled control is designed to improve control precision. Simulation results are taken from a low-frequency transmission system based on PSCAD/EMTDC, and effectiveness and precision of the proposed branch energy balancing control method are verified in the case of nonuniform parameters and an unbalanced power system.

Published

2024

2. Seven levels highly efficient modular multilevel matrix converter (M3C) for low frequency three-phase AC-AC conversion.

Author

Karpagam, V. and Narmadhai, N.

Subjects

MATRIX converters, FREQUENCY changers, JOB performance

Abstract

An Innovative Modular multilevel matrix converter (M3C) is proposed with reduced number of switching device owing to the improved efficiency, reduced cost and minimizes the size. Offshore Low-Frequency AC (LFAC) transmissions are economical with greater reliability for short and intermediate distance transmissions. Similar to HVDC, it increases the transmission capacity and also distance can be increased in LFAC.M3C is proposed as frequency converters for LFAC transmissions which link AC systems operating at 16.7 and 50 Hz. The double αβ0 transform control technique has been the most often used approach for decoupling control of input, output and circulating currents in such applications. The performances of this work's proposed modular multilevel matrix converters are analysed using simulation in MATLAB/SIMULINK software. [ABSTRACT FROM AUTHOR]

Published

2023

3. Seven levels highly efficient modular multilevel matrix converter (M3C) for low frequency three-phase AC-AC conversion

Author

V. Karpagam and N. Narmadhai

Subjects

Modular multilevel matrix converter (M3C), PMSG wind turbine, MOSFET, power grid, offshore low frequency AC (LFAC) transmission, branch energy balance circuit, Control engineering systems. Automatic machinery (General), TJ212-225, Automation, T59.5

Abstract

An Innovative Modular multilevel matrix converter (M3C) is proposed with reduced number of switching device owing to the improved efficiency, reduced cost and minimizes the size. Offshore Low-Frequency AC (LFAC) transmissions are economical with greater reliability for short and intermediate distance transmissions. Similar to HVDC, it increases the transmission capacity and also distance can be increased in LFAC.M3C is proposed as frequency converters for LFAC transmissions which link AC systems operating at 16.7 and 50 Hz. The double αβ0 transform control technique has been the most often used approach for decoupling control of input, output and circulating currents in such applications. The performances of this work’s proposed modular multilevel matrix converters are analysed using simulation in MATLAB/SIMULINK software.

Published

2023

4. Control strategy of the modular multilevel matrix converter under unbalanced grid condition

Author

LU Yu, WU Xiaodan, LEI Jiaxing, SUN Xiangxiang, GU Yuehua, and WEI Chaofan

Subjects

modular multilevel matrix converter (m3c), low-frequency transmission system, unbalanced grid condition, capacitance voltage balance, negative sequence control, circulating currents control, Applications of electric power, TK4001-4102

Abstract

Modular multilevel matrix converter (M3C) is a new topology of AC-AC power converter, which has very broad application in low frequency transmission system, high-power asynchronous motor speed regulation and low offshore wind power transmission. Due to the power coupling effect of the two frequencies, the capacitive voltage of M3C bridge arms is prone to instability when the grid voltage is asymmetric. Firstly, the arm power of M3C under unbalanced input conditions is calculated, and the power distribution law among the arms of two different power balance method is summarized. On this basis, the influence of low-frequency circulating currents on the arm power is analyzed. Under the premise of ensuring the balance of input and output power of the system, a capacitor voltage balance control strategy based on the construction of circulating currents is proposed, which avoids the introduction of negative sequence current on the grid side. Under unbalanced conditions, the capacitor voltage can be quickly balanced by the capacitor voltage closed-loop control and direct power compensation strategy. The constructed low-frequency circulating currents only flow inside the converter, and will not affect the decoupling operation of M3C input and output sides. The effectiveness of the proposed control strategy is verified by a 220 kV, 400 MW M3C system implemented in MATLAB.

Published

2023

5. 电网不平衡工况下模块化多电平矩阵变换器控制策略.

Author

卢宇, 吴小丹, 雷家兴, 孙祥祥, 顾跃华, and 韦超凡

Abstract

Copyright of Electric Power Engineering Technology is the property of Editorial Department of Electric Power Engineering Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2023

6. Computationally Efficient MPC for Modular Multilevel Matrix Converters Operating With Fixed Switching Frequency

Author

Rodrigo H. Cuzmar, Andres Mora, Javier Pereda, Ricardo P. Aguilera, Pablo Poblete, and Sebastian Neira

Subjects

Direct ac-to-ac conversion, model predictive control (MPC), modular multilevel matrix converter (M3C), phase shifted pulsewidth modulation (PS-PWM), sequential analysis, triple-star bridge cells (TSBC), Electronics, TK7800-8360, Industrial engineering. Management engineering, T55.4-60.8

Abstract

Modular multilevel matrix converters stand out for their performance in ac–ac high-power conversion. However, they require multiple control loops to govern the currents from both ac ports, the internal circulating currents, and the capacitor voltages. This article proposes a computationally efficient model predictive control (MPC) strategy based on a new converter modeling to exploit the phase-shifted pulsewidth modulation working principle fully, achieving four improvements: 1) control unification of both ac-ports currents, circulating currents, and capacitor voltages; 2) constrained optimization to safeguard the converter limits; 3) computational burden reduction and high scalability compared to standard MPC strategies; and 4) wide frequency operation with fast closed-loop transient responses, low harmonic distortion, and fixed switching frequency.

Published

2023

7. Operation, Design, and Losses of the Modular Multilevel Matrix Converter in a Flywheel Energy Storage System

Author

Jonas Kienast, Steffen Bernet, and Gino Sturm

Subjects

Doubly fed induction generator (DFIG), flywheel energy storage system (FESS), loss calculation, modular multilevel matrix converter (M3C), Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

This article presents an analysis of selected characteristics of the modular multilevel matrix converter (M3C) operating a doubly fed induction generator (DFIG) in a flywheel energy storage system. A detailed analysis of the necessary electrical input and output quantities, as well as the identification of required internal currents and voltages, leads to a newly introduced iterative design process for the converter. This process ultimately provides information on the required number of submodules and demonstrates the overload capability of the converter in reactive power operation. Also, the short-circuit current contribution of the system for this unique configuration of M3C and DFIG is investigated for the first time. Taking into account the unique operating characteristics of the M3C, a loss analysis of the converter and the machine is performed, and a loss-optimized distribution of reactive power between the machine and the converter is proposed. The article is conducted analytically and is validated by experimental results on a small-scale demonstrator.

Published

2023

8. Research on a risk evaluation and suppression method for high-frequency resonance of flexible low-frequency transmission

Author

HUA Wen, LIN Jintian, QIU Peng, LU Yi, PAN Wulue, ZHANG Jing, and LIN Yizhe

Subjects

modular multilevel matrix converter （m3c）, flexible low-frequency alternating current transmission （lfac）, high-frequency resonance, control delay, resonance suppression, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Due to the long delay of their control chains， voltage source converters （VSCs） in the high frequency band tend to show negative damping， which may give rise to high-frequency resonance when VSCs are connected to power systems. Flexible low-frequency alternating current transmission （LFAC） system adopts the modular multilevel matrix converter （M3C） as the core equipment and its high-frequency resonance risk needs to be evaluated. Based on practical engineering， this paper establishes the high-frequency impedance model of M3C. It evaluates the high-frequency resonance risk of the LFAC system under multiple operating modes through impedance analysis method. The operating conditions with high resonance risk are obtained， and the generation mechanism of the resonance is analyzed. Furthermore， a high-frequency resonance suppression strategy of installing an extra low-pass filter in the voltage feedforward control of M3C is proposed for practical engineering. Finally， the accuracy of the analysis results and the effectiveness of the proposed high-frequency resonance suppression strategy are verified by electromagnetic transient simulation.

Published

2022

9. Undisturbed grid connection control strategy for two-terminal flexible low-frequency transmission system

Author

LU Liwen, WU Xiaodan, ZHOU Qian, DONG Yunlong, QIU Defeng, and PAN Lei

Subjects

low-frequency transmission, modular multilevel matrix converter (m3c), temporary blocking, without the synchronization, without voltage or current impulse, grid connection control, Applications of electric power, TK4001-4102

Abstract

Low-frequency transmission system (LFTS) based on modular multilevel matrix converter (M3C) has great application potential in offshore wind power transmission,urban power grid and long-distance power transmission. In order to study the startup process and the control strategies of LFTS and connect the converter station to the low-frequency transmission line without voltage or current impulse of M3C,a startup method of undisturbed grid connection is proposed. Firstly,the structure and operating principle of the LFTS are analyzed. Then,the selection principle of sub modules and the charging process of M3C are analyzed with two-terminal LFTS as the target. Taking the advantage that the blocked M3C does not exchange power with the low-frequency power grid when the capacitor is at rated voltage,the problems of over-voltage and over-current that tend to occur during LFTS startup can be solved by flexible control of M3C and reasonable design of startup strategy,without additional control devices and detecting the synchronization of the breaker. Finally,a real time digital simulation system (RTDS) is built to verify the proposed startup method. The simulation results show that converter stations connect to the low-frequency transmission line without voltage or current impulse. Also,the proposed strategy is correct and has a great prospect of the engineering application.

Published

2022

10. Analysis and Control of Modular Multilevel Matrix Converters Under Branch Fault Conditions.

Author

Wang, Chao, Zheng, Zedong, Wang, Kui, Yang, Bo, Zhou, Peiyi, and Li, Yongdong

Subjects

*MATRIX converters, *NODAL analysis, *INTEGRATED circuit fault tolerance

Abstract

The modular multilevel matrix converter (M3C) is a promising topology for high-voltage and high-power direct ac-to-ac power conversion applications. Fault tolerance ability is one of the advantages of the M3C. To further enhance the reliability of the M3C, this article proposes a novel branch current configuration method for branch fault conditions, which is available either one or two branches are failed. By deriving basic branch current configurations and analyzing branch dc power equations under branch fault conditions, feasible branch current configurations can be directly derived. In terms of minimizing the maximum peak branch current, the derived configuration is also the optimal one for the single branch fault condition. Compared with the existing method, the proposed method does not need to solve configuration coefficients of branch currents offline, which is automatically adaptive to different load conditions. An M3C prototype with three submodules each branch is built, and experimental results are presented to validate the proposed branch fault tolerance method. [ABSTRACT FROM AUTHOR]

Published

2022

11. An Optimal Full Frequency Control Strategy for the Modular Multilevel Matrix Converter Based on Predictive Control.

Author

Fan, Boran, Wang, Kui, Wheeler, Pat, Gu, Chunyang, and Li, Yongdong

Subjects

*CASCADE converters, *PREDICTIVE control systems, *HIGH voltages, *MOTOR drives (Electric motors), *CAPACITORS, *STRAINS & stresses (Mechanics)

Abstract

The modular multilevel matrix converter (M3C) is a promising topology for high-voltage high-power applications. Recent researches have proved its significant advantages for adjustable-speed motor drives compared with the back-to-back modular multilevel converter. However, the branch energy balancing in the M3C presents great challenge especially at critical-frequency points where the output frequency is close to zero or grid-side frequency. Generally, this balancing control depends on the appropriate injection of inner circulating currents and the common-mode voltage (CMV), whereas their values are hard to determine and optimize. In this paper, an optimization-based predictive control method is proposed to calculate the required circulating currents and the CMV. The proposed method features a broad frequency range balancing of capacitor voltages and no reactive power in the grid side. For operation at critical-frequency points, there is no increase on branch voltage stresses and limited increase on branch current stresses. A downscaled M3C system with 27 cells is designed and experiment results with the R–L load and induction motor load are presented to verify the proposed control method. [ABSTRACT FROM AUTHOR]

Published

2018

12. Optimized Branch Current Control of Modular Multilevel Matrix Converters Under Branch Fault Conditions.

Author

Fan, Boran, Wang, Kui, Zheng, Zedong, Xu, Lie, and Li, Yongdong

Subjects

*MATRIX converters, *ELECTRIC network topology, *FAULT tolerance (Engineering), *NODAL analysis, *VOLTAGE control

Abstract

The modular multilevel matrix converter (M3C) is a promising topology for high-voltage high-power applications. It features easy scalability, high-quality input and output waveforms, superior availability, etc. This letter aims to further increase the availability of the M3C when one or more of the nine branches are lost. A general nonlinear multivariable optimization model is set up to optimize the branch current configuration after the branch lost. The proposed method reduces system power capability loss after the branch failure. It achieves a smooth transition from a full M3C to a reduced topology without shutdown of the system. A M3C prototype with 27 cells is designed, and experiment results are presented to confirm the validity of this method. [ABSTRACT FROM AUTHOR]

Published

2018

13. A Branch Current Reallocation Based Energy Balancing Strategy for the Modular Multilevel Matrix Converter Operating Around Equal Frequency.

Author

Fan, Boran, Wang, Kui, Wheeler, Pat, Gu, Chunyang, and Li, Yongdong

Subjects

*MATRIX converters, *MODULAR construction, *FAULT tolerance (Engineering), *POWER capacitors, *VOLTAGE control, *FLUCTUATIONS (Physics)

Abstract

The modular multilevel matrix converter (M3C) is a promising topology for medium-voltage, high-power applications. Due to the modular structure, it is scalable and capable to produce high quality output waveforms and can be fault tolerant. However, the M3C suffers from low frequency capacitor voltage fluctuation if the output frequency is close to the input voltage frequency, which limits its application in adjustable speed drive fields. This paper presents a theoretical analysis in the phasor domain to find the branch-energy equilibrium point of the M3C when operating with equal input and output frequency first. Then, a branch energy balancing control method based on branch current reallocation is proposed to equalize the energy stored in the nine converter branches. With the proposed method, the M3C can effectively suppress the capacitor voltage fluctuation without injecting common-mode voltage or applying reactive power to the input side. Experimental results are presented to validate the proposed method. [ABSTRACT FROM AUTHOR]

Published

2018

14. Fully decoupled current control and energy balancing of the Modular Multilevel Matrix Converter.

Author

Kammerer, Felix, Kolb, Johannes, and Braun, Michael

Abstract

The Modular Multilevel Matrix Converter (M3C) is a Modular Multilevel Converter topology which is suitable for high power low speed drive applications. This paper presents a fully decoupled current control which allows an independent input, output and internal balancing current control. To equalize the energy stored in the nine converter arms, an energy and balancing control is presented which includes average, horizontal, vertical and diagonal balancing control loops. Simulation results are used to verify the function of the M3C together with an induction motor drive system. Additionally, the proper function of the recently constructed arm PCB working as single phase multilevel STATCOM is presented. This PCB will be used for each arm in the laboratory prototype of the M3C in the near future. [ABSTRACT FROM PUBLISHER]

Published

2012