JPH0386022A - Higher harmonic compensator - Google Patents

Abstract

PURPOSE:To improve followability of current by performing firing/extinguishing control of the upper and lower arms at an additional arm section based on detection of maximum or minimum difference between a set value and an actual value of compensating current in each phase. CONSTITUTION:Difference between a set value and an actual value of compensating current in each phase is provided from each adder 6a-6c to each detecting circuit 7a, 7b for detecting positive and negative maximum and minimum values. When the detected value exceeds over a reference level, comparators 7c, 7d output 'H' level signals and producing a firing pulse for the upper and lower arms AU, AD at an additional arm section 1c. Furthermore, an adder 7e compares the maximum absolute difference at positive side with the minimum absolute difference at negative side and determines which of the upper and lower arms AU, AD should be fired in relation to the output signal from a comparator 7f. By such arrangement, the degradation of current followability due to the influence of other phase current can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Application Field) The present invention relates to a so-called power converter, which is comprised of a power converter for compensating and suppressing harmonic current, reactive power, etc. generated by a power conversion device such as a rectifier. The present invention relates to harmonic compensation devices such as power active filters.

(Prior art) Conventional harmonic compensators of this type use a three-phase voltage source inverter consisting of a total of six arms with three groups of upper and lower arms, and three sets of single-phase inverters consisting of two groups of upper and lower arms. something is known. All of these harmonic compensators are configured to individually control output currents (compensation currents) of each phase of the inverter to compensate for harmonic currents and the like in the power system.

(Problems to be Solved by the Invention) Among the conventional harmonic compensators described above, in the harmonic compensator using a three-phase voltage source inverter consisting of three groups of upper and lower arms, it is difficult to control the output current of each phase of the inverter. The output current control of other phases is not unrelated due to the configuration of the main circuit, and the output current of each phase is determined by the voltage phase of the power supply side and the conduction state of each arm. Therefore, it is compensated during one cycle of the power supply. The deviation between the current setting value and the actual value may become large, and the compensation effect may be significantly reduced.

In addition, the above-mentioned problem is eliminated with a harmonic compensator using three sets of single-phase inverters, but due to the configuration of the main circuit, the number of upper and lower arms is 12 in total, which is twice the number of arms of a three-phase voltage source inverter. This poses a problem of increasing the size of the device.

The present invention was proposed in order to solve the above-mentioned problems, and its purpose is to provide a harmonic compensation device consisting of a three-phase voltage source inverter. To provide a harmonic compensator which prevents deterioration of followability, improves compensation performance, and can be configured by only slightly increasing the number of arms and adding a simple control circuit, thereby preventing the device from increasing in size. There is a particular thing.

(Means for Solving the Problems) In order to achieve the above object, the present invention provides a three-phase voltage source inverter with one set of upper and lower arms separate from the main arm section that generates each phase output current of the three-phase voltage source inverter. An additional arm section consisting of upper and lower arms is added between the positive and negative poles of the DC circuit of the inverter, and the connection point of the upper and lower arms constituting the additional arm section is connected to the output of the inverter via an AC reactor having an appropriate actance component. It is connected to the neutral point of the human winding of the side transformer.

In addition, in this harmonic compensator, the main arm part is subjected to normal compensation control to turn on and off based on the deviation between the compensation current setting value of each phase and the actual value and the comparison result with a predetermined reference level. Regarding the additional arm section, when the deviation becomes maximum or minimum, the turning-off control is performed based on a comparison result between this deviation and a predetermined reference level.

(Function) According to the present invention, by point-extinguishing control of the additional arm added to the main circuit of a three-phase voltage source inverter, each upper and lower arm current can be controlled independently of the conventional point-extinguishing control of the main arm. It becomes possible to perform correction control, obtain a desired inverter output current, and compensate for harmonics.

(Example) An embodiment of the present invention will be described below with reference to the drawings.

First, FIG. 1 shows the main circuit configuration of a harmonic compensator according to this embodiment, and in the figure, 1 is a three-phase voltage source inverter. This inverter 1 is a normal 3
Main arm part 1a consisting of 6 arms consisting of upper and lower arms of the group
and terminals P and N of capacitor 1b as a DC constant voltage source.
It has an additional arm part 1c consisting of an upper and lower arm connected between them.

Here, each of the main arm section 1a and the additional arm section 1c is composed of a transistor and a freewheeling diode connected in antiparallel.

Below, for convenience, each arm of the main arm portion 1a will be referred to as U, V.
, W, X, Y, Z, each arm of the additional arm part 1c is AU
, AD.

In addition, the AC side terminal of the main arm portion 1a is connected to the AC reactor 2.
The AC side terminal of the additional arm portion 1c is connected to the neutral point of the human winding 3a via the AC reactor 4. Further, each connection point of the Δ winding 3b of the transformer 3 is connected to each phase of the power system, and a current detector 5a detects the actual values icR, ics, and icy of the compensation current of each phase.

A current detection section 5 consisting of 5b and 5c is provided.

Next, FIG. 2 shows a control circuit for the three-phase voltage source inverter 1. As shown in FIG. This control circuit is composed of a normal harmonic current compensation control circuit 6 and an additional arm control circuit 7 for controlling the operation of the additional arm 1c.

Here, the harmonic current compensation control circuit 6 calculates the actual values icR, ics, icy of the compensation current and the set value ic++''.

adders 6a to 6c in which "i as" and "i aT" are hexagonally arranged in polarity as shown; comparators 6d to 6f such as hysteresis comparators that compare the outputs of these adders 6a to 6c with a predetermined reference level; It is composed of pulse shaping distribution circuits 6g to 61 which output signals to the firing drive circuits of each set of upper and lower arms U-W and X-Z of the main arm portion 1a according to the outputs of these comparators 6d to 6f. .

On the other hand, the additional arm control circuit 1c performs additions s6a to 6c.
A maximum value detector 7a and a minimum value detector 7b each consisting of three diodes to which the output of
Comparator 7c compares the outputs of a and 7b with respective predetermined reference levels.

7d, an adder 7e to which the outputs of the detectors 7a and 7b are added with the polarities shown, a comparator 7f that compares the output of the adder 7e with a predetermined reference level, and the outputs of the comparators 7c and 7f are added. AND circuit 7g,
An AND circuit 71 to which the output of the comparator 7f and the output of the comparator 7d are added via the negative circuit 7h, and an additional arm section 1 to which the outputs of the AND circuits 7g and 7i are added.
The pulse shaping distribution circuit 7j outputs a signal to the upper and lower arms AU c and the ignition drive circuit AD. Here, the pulse shaping/distributing circuit 7j performs pulse shaping in consideration of the short-circuit prevention period between the upper and lower arms.

Note that the comparator 7c in the additional arm control circuit 7,
The reference level 7d is set to a value larger than the reference levels of the comparators 6d to 6f in the harmonic current compensation control circuit 6.

The operation of this embodiment will be explained below.
The main arm portion 1a is controlled by a normal harmonic current compensation control circuit 6.
In addition to controlling the operation of the
As shown in the figure, by controlling the additional arm part 1c by the additional arm part control circuit 7 which uses the deviation between the compensation current setting value of each phase and the actual value outputted from the adders 6a to 6c as an input signal, harmonics can be generated. Compensate the current.

The above-mentioned deviation is input to each of the detection circuits 7a and 7b, and the maximum value or minimum value is detected for each positive and negative value, and when these exceed a certain reference level, the comparators 7c and 7d output an "H" level signal. ignition pulses are generated for the upper and lower arms AU and AD of the additional arm section 1c. Furthermore, the adder 7e compares the absolute values of the maximum value of the positive side deviation and the minimum value of the negative side deviation, and in combination with the comparator 7f, either the upper arm AU or the lower arm AD of the additional arm section 1c is activated. I am deciding whether to do so. Then, the output signal of the comparator 7f is sent to an AND circuit 7g and a NOT circuit 7h.
The signal is applied to one input terminal of the AND circuit 71 via the input terminal 71, and functions as an interlock signal for generating upper and lower arm firing pulses.

As a result, even if the comparators 7c and 7d cause the firing pulses of the upper and lower arms AU and AD to be fired at the same time, the firing pulse will be given to only one arm by the output signal of the comparator 7f. ,
It is possible to prevent the upper and lower arms from firing at the same time and causing a DC short circuit.

As described above, in this embodiment, the harmonic current compensation control circuit 6
In addition to normal compensation control for the main arm section 1a, the additional arm section control circuit 7 detects the maximum or minimum value of the deviation between the compensation current setting value of each phase of the inverter 1 and the actual value, and controls the additional arm section 1c. It controls the turning on and off of the upper and lower arms AU and AD. Therefore, for the main circuit condition determined by the point-off state of the main arm portion 1a consisting of three phases and six arms, the main circuit is determined by the point-off state of the additional arm portion 1C, regardless of each phase of the main arm portion 1a. Compared to compensation control using a three-phase voltage source inverter consisting of only the main arm portion 1a, this additional condition makes it possible to control the compensation current independently for each set of weights, and the current followability is improved due to the influence of other phase currents. You can prevent it from getting worse.

(Effects of the Invention) As described above, according to the present invention, an additional arm section is added to the main circuit of a three-phase voltage source inverter, and the turning-on/off control of the upper and lower arms is performed based on the compensation current setting value of each phase and the actual value. Since the configuration is configured to detect the maximum or minimum value of the deviation of By controlling the compensation current independently for each set of weights of the inverter, it is possible to improve the followability of the current waveform and improve the harmonic compensation performance.

Further, in terms of the circuit configuration, since it is only necessary to add the additional arm section and its control circuit, there are advantages such as the ability to downsize the device compared to the case where three sets of single-phase inverters are used.

[Brief explanation of drawings]

1 is a main circuit configuration diagram of a three-phase voltage source inverter showing an embodiment of the present invention, and FIG. 2 is a circuit diagram showing its control circuit. 1... Three-phase voltage type inverter la... Main arm part 1b... Capacitor 1c.
...Additional arm part 2, 4...AC reactor 3...
- Inverter output transformer 3a... human winding 3b... Δ winding 5... current detection section 5a, 5b, 5c... current detector 6...
Harmonic current compensation control circuit 7...Additional arm control circuits 6a to 6c, 7e...Adders 6d to 6f, 7c, 7d, 7f - Comparators 6g to 6
i, 7j...Pulse shaping distribution circuit 7a...Maximum value detection circuit 7b...Minimum value detection circuit

Claims (2)

[Claims] (1) In a harmonic compensator constituted by a three-phase voltage source inverter whose main circuit includes a main arm section consisting of three groups of upper and lower arms, an additional arm section consisting of the upper and lower arms is provided between the DC terminals of the main circuit. and the mutual connection point of the upper and lower arms constituting the additional arm portion is connected to the neutral point of the human winding of a transformer connected to the power system via an AC reactor. Device. (2) Based on the comparison result between the deviation between each phase compensation current set value and the actual value and a predetermined reference level, the switching element in the main arm is controlled to turn on and off, and the deviation is maximized or minimized. 2. The harmonic compensator according to claim 1, wherein the switching element of the additional arm is controlled to turn on and off based on a comparison result between this deviation and a predetermined reference level.