Showing total 4 results

1. A Modular Multilevel HVDC Buck?Boost Converter Derived From Its Switched-Mode Counterpart.

Author

Kung, Sunny H. and Kish, Gregory J.

Subjects

*HIGH-voltage direct current converters, *ELECTRIC power conversion, *SWITCHING power supplies, *ELECTRIC power conversion harmonics, *ELECTRIC network topology

Abstract

This paper begins by presenting a generalized methodology for conceptualizing modular multilevel converter (MMC)-based dc–dc topologies, which is predicated on the concept of harmonic power balance. A compelling implication is that MMC-based variants of conventional switched-mode converter structures can be realized. As an example case study, this paper introduces a new dc–dc MMC for HVdc applications, which is derived from the classical buck–boost dc–dc converter. This new topology, which is revealed to be an alternative option to the well-known dual active bridge (DAB) converter with an intermediate transformer, offers buck–boost functionality and bidirectional dc fault blocking, using only two quadrant switching cells. Comparative analysis shows the proposed topology has lower operating losses and a lower total magnetics rating in comparison to an MMC-based DAB solution for dc stepping ratios around unity. A dynamic controller is developed that regulates the converter dc power throughput while maintaining balanced capacitor voltages. The converter operating principle, dynamic controller performance, and dc fault blocking are verified by simulation. [ABSTRACT FROM PUBLISHER]

Published

2018

2. A New Parallel-Connected Diode-Clamped Modular Multilevel Converter With Voltage Self-Balancing.

Author

Gao, Congzhe and Lv, Jingliang

Subjects

*CAPACITORS, *VOLTAGE control, *DIODES, *CASCADE converters, *ELECTRIC network topology, *EQUIPMENT & supplies

Abstract

The modular multilevel converter (MMC or M2C) is an emerging attractive multilevel topology for medium-voltage high-power applications. The capacitor voltage balancing control and the improvement of output current rating are two challenging issues of MMC. This paper proposed a new parallel-connected diode-clamped M2C (DCM2C), in which each arm consists of two parallel-connected clusters. In this topology, the capacitor voltages can be balanced automatically without any balancing control algorithms. Theoretically, no voltage sensors are needed to measure the capacitor voltages theoretically. Thus, the control of the converter can be simplified greatly. With a simple current-sharing control, an equal current distribution can be achieved between the two clusters. Furthermore, an extended parallel-DCM2C is proposed for larger current applications, and the corresponding current-sharing control method is developed. Experimental results validated the voltage self-balancing capability of parallel-DCM2C and the effectiveness of the proposed current-sharing control. [ABSTRACT FROM PUBLISHER]

Published

2017

3. The Research of SM Topology With DC Fault Tolerance in MMC-HVDC.

Author

Zhang, Jianpo and Zhao, Chengyong

Subjects

*FAULT tolerance (Engineering), *DIRECT currents, *ROTARY converters, *HIGH-voltage direct current transmission, *ELECTRIC network topology

Abstract

The high voltage direct current transmission system based on modular multilevel converter (MMC-HVDC) technology is now studied and used widely. But traditional half bridge topology of sub module (HBSM) of MMC can't block dc link fault current because of the freewheeling effect of diodes. In order to solve this problem, firstly, this paper improves HBSM topology, a series connected double sub module (SDSM) is designed and dc link fault current blocking capability is realized without tripping ac circuit breaker, so MMC-HVDC with this improved topology can immediately rebuild dc link voltage and resume power transmission. Secondly, the self starting and fault disposing procedure are also designed. At last, simulations in the software PSCAD/EMTDC are carried out to verify its effectiveness and feasibility. [ABSTRACT FROM AUTHOR]

Published

2015

4. Impact of HVDC Transmission System Topology on Multiterminal DC Network Faults.

Author

Kontos, E., Pinto, R. Teixeira, Rodrigues, S., and Bauer, P.

Subjects

*HIGH-voltage direct current transmission, *ELECTRIC network topology, *ELECTRIC faults, *ELECTRIC circuit breakers, *IDEAL sources (Electric circuits), *ELECTRICAL engineering

Abstract

This paper compares how a dc fault affects a multiterminal dc (MTdc) network depending on the HVDC transmission system topology. To this end, a six-step methodology is proposed for the selection of the necessary dc fault protection measures. The network consists of four voltage-source converters converters radially connected. The converters natural fault response to a dc fault for the different topologies is studied using dynamic simulation models. For clearing of the dc faults, four different dc breaker technologies are compared based on their fault interruption time, together with a current direction fault detection method. If necessary, the converters are reinforced with limiting reactors to decrease the peak value and rate of rise of the fault currents providing sufficient time for the breakers to isolate the fault without interrupting the MTdc network operation. The study shows that the symmetric monopolar topology is least affected by dc contingencies. Considering bipolar topologies, the bipolar with metallic return exhibits better fault response compared to the one with ground return. Topologies with ground or metallic return require full semiconductor or hybrid breakers with reactors to successfully isolate a dc fault. [ABSTRACT FROM AUTHOR]

Published

2015