WO2012010053A1 - Transformer-less static synchronous compensator (statcom) topological structure based on modular multilevel converter (mmc) - Google Patents

Abstract

Transformerless static synchronous compensator (STATCOM) topological structure based on modular multilevel converter (MMC) comprises three phases that are composed of multiple standard power units of modular multilevel converters connected in series. One ends of serially connected standard power units are connected with each other while other ends are connected with inductors. The inductor is connected with a charging resistor. The charging resistor is connected with a switch in parallel, and is connected to an electrical grid through another switch. The standard power unit is supplied with power by charging the resistor and the capacitor so as to provide direct current voltage. The STATCOM topological structure has no transformer at the synchronization side of a traditional STATCOM, so the STATCOM topological structure is simplified, and the space required for accommodating STATCOM topological structure and costs are reduced.

Description

 Transformerless Static Synchronous Compensator (STATCOM) Topology Based on Modular Multilevel Inverter (丽C) Technical Field

 The invention relates to a transformerless STATCOM topology based on MMC (Modular Multilevel Converter) modular multilevel inverter. Background technique

 In the power system, reactive power is an important factor affecting voltage stability. It is related to the safe and stable operation of the entire power system. Reactive power compensation is one of the effective measures to ensure efficient and reliable operation of the power system.

 The nationwide distribution network transformation is in full swing. The most practical way to solve the current power grid loss, large voltage drop and large voltage drop in the grid, especially the low-voltage city network and the rural power grid, is to use high-performance reactive power compensation device. Compensate the inductive reactive power of the load, reduce the transmission of reactive power on the line, reduce the active power loss and voltage drop on the transmission and distribution equipment, and improve the transmission and distribution capacity of the system. The Static Synchronous Compensator (STATCOM) has a very broad application prospect and huge market potential. The reactive power compensation devices in the prior art are all DC voltages and are converted into three-phase alternating currents and sent to the power grid through the transformers. The transformers are designed in such a way that the equipment investment is large, the land occupation is high, the cost is high, and the production cycle is long. Summary of the invention

 The object of the present invention is to provide a transformerless STATCOM topology based on MMC, which does not require a conventional STATCOM grid-side transformer, thereby achieving cost reduction, space saving, and simple structure.

 To achieve the above object, the present invention is achieved by the following technical solutions:

 A MMC-based transformerless STATCOM topology characterized by three-phase, each phase consisting of a plurality of modular multilevel converte modular multi-level inverters of standard power units connected in series, after being connected in series with standard power units One end is connected together, and the other end is connected to the inductor; the inductor is connected to the charging resistor, and the charging resistor is connected in parallel with one switch, and then connected to the grid through another switch.

 The standard power unit is a half bridge structure, two IGBTs are connected in series, and then a DC capacitor is connected in parallel.

 The standard power unit is powered by a charging resistor and a capacitor to provide a DC side voltage of a standard power unit. Compared with the prior art, the novelty and inventiveness of the present invention are embodied in:

 1, no transformer configuration, reducing equipment costs by 1/2.

 2, no transformer configuration, making the device volume reduced by 1/2.

 3, no transformer configuration, reducing the weight of the device by 1/2.

 4, transformerless configuration, reducing equipment manufacturing cycle by 1/2.

 5, no transformer configuration, eliminating the structure and space of the load transformer.

6, no transformer configuration, eliminating the high voltage cable connecting the transformer. 7, each power unit has only two IGBTs, which greatly reduces the unit volume and cost.

DRAWINGS

 Figure 1 is a topology diagram of a transformerless STATCOM based on MMC;

 Figure 2 is a structural diagram of a standard power unit;

 Figure 3-1 is a current flow diagram of the power unit output state being 0 state;

 Figure 3-2 is a current flow diagram of the power unit output state being 0 state;

 Figure 4-1 is a current flow diagram of the power unit output state being 1 state;

 Figure 4-2 is a current flow diagram in which the power unit output state is 1. detailed description

 See Figure 1. A MMC-based transformerless STATCOM topology consisting of three phases with a star connection. Each phase consists of a series of standard power units of n modular multilevel converte modular multilevel inverters. The standard power units connected in series are connected at one end and the other end is connected to the inductor L. The inductor L is connected to the charging resistor R. After the charging resistor R is connected in parallel with the switch K2, it is connected to the grid through another switch K1. The standard power unit is powered by a charging resistor R and capacitor C (see Figure 2) to provide a standard power unit DC side voltage.

 As shown in Fig. 2, the standard power unit of the inverter consists of two switching device IGBTs and a DC-side capacitor C. The switching devices IGBT1 and IGBT2 are connected in series, and then the DC capacitor C is used, and the switching devices IGBT1 and IGBT2 are connected in parallel. Diodes D1, D2. Switching device The common terminal of IGBT1 and IGBT2, the common terminal of capacitor C and IGBT2 is used as the output end of each unit, and is connected to other units.

 This topology realizes the compensation of reactive power of the grid and improves the quality of the grid by controlling the on and off of the standard power unit switching device. Controlling the gate voltage of the IGBT to turn it on or off allows the cell to have different circuit states. Definition IGBT1 is turned off, IGBT2 is turned on as the 0 state of the cell. At this time, the current can flow in the forward direction of IGBT2 (Fig. 3-1), or it can flow backward through the parallel diode D2 (Fig. 3-2). Definition IGBT1 is turned on, IGBT2 is turned off as the unit's 1 state, current can flow through diode D1 (Fig. 4-1), at this time the capacitor is charged; it can also flow through IGBT1 (Fig. 4-2), at which point the capacitor discharges.

 This topology utilizes MMC power units in series, eliminating the need for transformers to be directly incorporated into the grid, eliminating the need for transformers and associated fans, high voltage cables, auxiliary circuits and load transformers.

Claims

 1. A MMC-based transformerless STATCOM topology, characterized in that it consists of three phases, each phase consisting of a plurality of modular multilevel converte modular multilevel inverters of standard power units connected in series, after being connected in series One end of the power unit is connected together, and the other end is connected to the inductor; the inductor is connected to the charging resistor, and the charging resistor is connected in parallel with one switch, and then connected to the grid through another switch.

 2. The MMC-based transformerless STATCOM topology according to claim 1, wherein the standard power unit is a half bridge structure, two IGBTs are connected in series, and a DC capacitor is connected in parallel.

 3. The MMC-based transformerless STATCOM topology according to claim 1 or 2, wherein the standard power unit is powered by a charging resistor and a capacitor to provide a DC side voltage of a standard power unit.