RU2554856C1 - Multilevel power converter supplying synchronous and asynchronous motors from high dc voltage source - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: multilevel power converter supplying synchronous and asynchronous motors from a high DC voltage source includes output inverter-recovery modules, each of them containing the first high-frequency bridge and the second bridge and a capacitor. DC current circuits of the first and second bridges are connected in parallel to the capacitor, AC current circuit of the second bridge is connected in series to AC current circuits of the second bridges of another output inverter-recovery modules so that wye-connected groups and the first and second high-frequency transformers and input inverter-recovery modules as well are formed, each of the latter containing a high-frequency bridge and a capacitor. The DC current circuits of the bridge are connected in parallel to the capacitor. The AC current circuits of the bridges in input inverter-recovery modules and the first bridges in output inverter-recovery modules are interconnected in parallel through the high-frequency transformers; the DC current circuits of the bridges in the input inverter-recovery modules are connected in series while outputs of the received circuit are connected to the high DC voltage source.

EFFECT: invention allows the technical result that lies in the reduced weight and dimensions and increased efficiency factor of the converter at operation from the line of high direct voltage.

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Description

The invention relates to a conversion technique and can be used to power synchronous and asynchronous motors from a high DC voltage source.

Known devices for power distribution in transformerless multi-level frequency converters [1], in which the voltage in the DC link is divided into the required number of levels due to the serial connection of buffer capacitors, and the output circuit of the converter at each time through serial connected power switches are connected to the desired node in connection of buffer capacitors.

Significant disadvantages of such devices are the relatively low reliability due to the possibility of an unacceptably high voltage on the buffer capacitors and power switches, as well as the loss of operability of the entire device in the event of the failure of any element.

A power distribution device [2] is also known, comprising a power low-frequency (50-60 Hz) transformer, an output filter, inverter-recovery modules, each of which contains two single-phase bridges consisting of power transistors with reverse diodes, and a battery of buffer capacitors, and the DC circuits of both bridges are connected in parallel to the buffer capacitor bank, the AC circuit of the first bridge is connected to one of the secondary windings of the power transformer, and the AC circuit of the second mos a, which is the output module, connected in series with the output of other modules, so that three groups are formed, connected in a star, whose output is connected the output filter.

The advantage of this converter is the presence of an energy recovery function, as well as the ability to build a converter with high reliability when setting up bypass circuits for inverter-recovery modules, which ensure the operability of the frequency converter as a whole when any inverter-recovery module fails.

However, this device also has drawbacks, for example, the high mass and size characteristics of the low-frequency (50-60 Hz) transformer and the large total capacity of the buffer capacitors required to reduce low-frequency voltage dips in the DC links of the inverter-recovery modules.

The closest in technical essence to the proposed and taken as a prototype is a device made by the method of power distribution in a multi-level frequency converter for supplying synchronous and asynchronous motors [3], including output inverter-recovery modules, each of which contains the first high-frequency and second bridges and a capacitor, while the DC circuits of the first and second bridges are connected in parallel to the capacitor, the AC circuit of the second bridge is connected in series with by means of alternating current of the second bridges of other output inverter-recovery modules so that groups connected in a star are formed, as well as the first and second groups of high-frequency transformers and input inverter-recovery modules, each of the latter contains a high-frequency bridge and a capacitor, while the DC circuit the bridge current is connected in parallel to the capacitor, and the alternating current circuit of the bridges of the input inverter-recovery modules and the first bridges of the output inverter-recovery muzzle are connected together in parallel by alternating current through high-frequency transformers.

The disadvantage of the closest technical solution is the inefficient use of input inverter-recovery modules in the case of connecting the input of the converter to the high-voltage DC power line due to the presence of second single-phase bridges in the input inverter-recovery modules. Consequently, there are unreasonable losses of power and efficiency of the converter, unnecessarily large weight and size indicators.

The problem to which the present invention is directed is to increase the efficiency of the converter and reduce its overall dimensions when operating from a high-voltage direct current supply line.

The technical result of the claimed invention is to increase the efficiency of the converter and reduce its overall dimensions when operating from a high DC voltage power line.

The problem is solved, and the required technical result is achieved by the fact that in a multilevel power converter for supplying synchronous and asynchronous motors from a high DC voltage source, including output inverter-recovery modules, each of which contains a first high-frequency and second bridges and a capacitor, while the circuit the direct current of the first and second bridges are connected in parallel to the capacitor, the alternating current circuit of the second bridge is connected in series with the the current of the second bridges of the other output inverter-recovery modules in such a way that groups connected in a star are formed, as well as the first and second high-frequency transformers and input inverter-recovery modules, each of the latter contains a high-frequency bridge and a capacitor, while the bridge DC circuits connected in parallel to the capacitor, moreover, the alternating current circuits of the bridges of the input inverter-recovery modules and the first bridges of the output inverter-recovery modules are connected to forward in parallel AC current through the high-frequency transformers, circuit DC input inverter-bridge-heat recovery units are connected in series, and outputs the chain is connected to a source of high DC voltage.

A distinctive feature of the invention is that in the above device, the DC circuit of the bridges of the input inverter-recovery modules are connected in series, and the conclusions of the resulting chain are connected to a high DC voltage source.

The invention is illustrated in the drawing.

Figure 1 presents the structural diagram of the claimed device (controls, protection and other elements that do not change the essence of the invention are not shown).

The inventive device contains input inverter-recovery modules 1, each of which consists of a high-frequency bridge 2 and a capacitor 3, first and second high-frequency transformers 4 and 6, a two-wire high-frequency bus 5, output inverter-recovery modules 7, each of which consists of a first high-frequency bridge 8, the second bridge 9 and the capacitor 10.

In each input module 1, the DC circuit of the bridge 2 is connected in parallel with the capacitor 3. The DC circuits of the bridges 2 are connected in series with each other, and the conclusions of the resulting circuit are connected to a high DC voltage source. AC circuits of bridges 2 are connected to transformers 4. Transformers 4 are connected to bus 5.

In each module 7, the DC circuit of the bridge 8 is connected in parallel with the capacitor 10 and the DC circuit of the bridge 9. The AC circuits of the bridges 8 are connected to the transformers 6. The transformers 6 are connected to the bus 5.

The AC circuits of the bridges 9 are connected in series with each other so that groups are formed connected in a star with the terminals U, V, W for connecting the motor.

The operation of the device in the mode of transmitting power to the engine is as follows.

The input power from the high DC voltage line is supplied to the input of the modules 1. From the AC circuits of the bridges 2, the high-frequency power is supplied through transformers 4 to the bus 5, which sums up all the power coming from the high DC voltage supply line. Further, from bus 5 through transformers 6, bridges 8 and 9, power is supplied to the engine, connected to the terminals U, V, W.

The bridges 9 are controlled so that the voltage required for transmitting power to the engine appears at the terminals U, V, W. All bridges 3 and 9 are controlled using a single frequency setting signal.

As a result of connecting all transformers 4 and 6 to one bus 5, which forms a single high-frequency power unit, the voltage is automatically equalized in the DC circuits of all modules 2 and 8 like communicating vessels with liquid by mutual power flow through bus 5.

Work in the recovery mode occurs in the reverse order.

The multilevelness of the described system provides a low distortion coefficient of the sinusoidality of the output voltage.

The property of the inventive converter is the ability to set any key management algorithm for the output bridges 9, therefore, other consumers or sources of electricity can be connected to the output of the converter, instead of the motor.

The claimed invention allows to reduce overall dimensions and increase the efficiency of the Converter when operating from a line of high DC voltage.

Information sources

1. Donskoy N.V. and others. Multilevel autonomous inverters. - Power Electronics (www.power-e.ru), 2008, No. 1, pp. 43-46.

2. Patent RU No. 2303851 of 07.27.2007.

3. Patent RU No. 2489791 of 08/10/2013.

Claims (1)

A multi-level power converter for supplying synchronous and asynchronous motors from a high DC voltage source, including output inverter-recovery modules, each of which contains the first high-frequency and second bridges and a capacitor, while the DC circuits of the first and second bridges are connected in parallel to the capacitor, an alternating circuit current of the second bridge is connected in series with the alternating current circuits of the second bridges of the other output inverter-recovery modules in such a way in order to form star-connected groups, as well as the first and second high-frequency transformers and input inverter-recovery modules, each of the latter contains a high-frequency bridge and a capacitor, while the bridge DC circuits are connected in parallel to the capacitor, and the AC circuits of the input bridges inverter-recovery modules and the first bridges of the output inverter-recovery modules are connected together in parallel by alternating current through high-frequency transformers, excellent The fact is that the direct current circuits of the bridges of the input inverter-recovery modules are connected in series, and the conclusions of the resulting chain are connected to a high DC voltage source.