KR101529586B1 - Method for controlling three-phase inverter output - Google Patents

Abstract

More particularly, the present invention relates to a method of controlling an output of a three-phase inverter, more specifically, by detecting output phase information of an inverter by removing harmonics other than a frequency to be controlled from an output signal of the three- It is possible to accurately detect the control target frequency at the time of detecting the output and to accurately control the inverter output based on the detected output information so as to stabilize the output control performance of the inverter In addition, as the utilization of the inverter is increased due to the stabilization of the control performance, the operation of the power system can be diversified and flexible, and particularly, the development of the renewable energy generation field with high utilization of the inverter can be promoted, 3-phase inverter that has the effect of ensuring stability and reliability of the whole system It relates to a control method.

Description

METHOD FOR CONTROLLING THREE-PHASE INVERTER OUTPUT BACKGROUND OF THE INVENTION [0001]

The present invention relates to a method of controlling an output of a three-phase inverter, more specifically, to a method of controlling an output of a three-phase inverter by removing harmonics other than a frequency to be controlled from an output signal of the three- Phase inverter to control the output size and phase of the inverter based on the phase information of the three-phase inverter.

The phase information of the photovoltaic system is important information for operating the entire controller. When disturbances such as harmonics are introduced into the system voltage, harmonics are added to the phase control to affect the entire system.

Since the actual commercial power source does not have a fully balanced power supply and also includes harmonic voltages, the phase angle detector should have fast and accurate characteristics even under distorted supply voltage conditions.

1 is a block diagram showing the configuration and operation of an output controller of a conventional three-phase inverter.

As shown in Fig. 1, the output controller of the conventional three-phase inverter senses a, b, and c phases from the output of the three-phase power supply end to convert it into dq axis stop coordinates, dq axis synchronous coordinate. The d-axis of the synchronous coordinate passes through a low pass filter which is a low-pass filter, and the output size of the inverter is detected. The q-axis of the synchronous coordinate passes through the PI controller and the output frequency of the inverter is detected. The detected output frequency of the inverter is negative feedbacked to the synchronous coordinate, and the output error of the inverter is controlled based on the output frequency of the negative feedback inverter.

 The output controller of the conventional three-phase inverter can detect the phase information of the inverter by detecting the output size and frequency of the inverter that is the output control target. However, when there is a harmonic in the output of the system power supply end, The harmonics are introduced into the phase information and affect the output controller of the inverter and the entire system. For example, the output controller may recognize the harmonics as an input signal and cause malfunction, The control unit may recognize that the output of the inverter is contained in the harmonic wave, so that the control operation may not be performed.

Since the low pass filter included in the output controller of the conventional three-phase inverter for detecting the output size of the inverter and the PI controller for detecting the output frequency of the inverter are used for the purpose of stabilizing the output, which is not easy to remove harmonics, The harmonics can not be removed at the time of detecting the phase information of the inverter and the phase information of the inverter is detected as it is.

Therefore, in order to solve the problems of the conventional techniques, the output control method of the three-phase inverter described in the present specification adds a resonance controller that removes harmonics other than the frequency to be controlled to the existing control method, Phase inverter control method capable of improving the output control of the inverter and the stability of the system operation by making it possible to accurately control the inverter output based on the detected output information.

A method of controlling an output of a three-phase inverter according to an embodiment of the present invention includes the steps of removing harmonics from an output signal of a three-phase inverter, detecting output phase information of the inverter in the output signal from which the harmonics are removed, And controlling the output phase and magnitude of the inverter based on the phase information.

In an embodiment, removing the harmonics may include converting the output signal of the inverter to d-q axis stationary coordinates and removing harmonic components from the stationary coordinates.

In an embodiment, the step of detecting the output phase information of the inverter may comprise the steps of converting the stationary coordinates into d-q axis synchronous coordinates and detecting the phase information in the synchronous coordinates.

In one embodiment, removing the harmonic component from the stationary coordinate includes removing a harmonic component through a resonant controller, wherein the resonant controller removes harmonic components except for the output control frequency of the inverter at the stationary coordinate, Lt; / RTI >

In the embodiment, the synchronous coordinate may be obtained by transforming the stationary coordinates from which the harmonic components are removed, where the output magnitude of the inverter on the d-axis and the output frequency of the inverter on the q-axis may appear.

In the embodiment, the step of detecting the phase information of the inverter in the synchronous coordinate may include detecting the output magnitude of the inverter in the d-axis of the synchronous coordinate and detecting the output frequency of the inverter in the q-axis of the synchronous coordinate .

In an embodiment, the output size of the inverter can be detected through a Low Pass Filter.

In an embodiment, the output frequency of the inverter can be detected via a PI controller.

In the embodiment, the detected phase information of the inverter may be controlled to be fed back to the synchronous coordinate.

In the output control method of the three-phase inverter described in this specification, when the inverter output for controlling the output of the inverter is detected, harmonics are removed and only the frequency to be controlled is detected, so that accurate output detection is performed and accurate control operation of the inverter output controller is possible The output control performance can be stabilized and the phase control method for the output control of the conventional three-phase inverter can be improved.

In addition, as the utilization of the inverter is increased due to the stabilization of the control performance, the operation of the power system can be diversified and flexible, and particularly, it is possible to promote the development of the renewable energy field with high utilization of the inverter. Stability and reliability can be secured.

1 is a block diagram showing the configuration and operation of an output controller of a conventional three-phase inverter;
2 is a flow diagram according to an embodiment of a method of controlling the output of a three-phase inverter disclosed herein;
3 is a block diagram according to an embodiment of an output control method of a three-phase inverter disclosed herein.
4 is a flowchart according to a specific embodiment of a method of controlling an output of a three-phase inverter disclosed herein.
5 is a configuration diagram of a resonance controller according to a specific embodiment of the output control method of the three-phase inverter disclosed in this specification.

The technique disclosed in this specification can be applied to a three-phase grid interconnected inverter. However, the technology disclosed in this specification is not limited to this, and can be applied to all grid interconnected inverter systems, emergency power generation systems, and other new renewable energy generation systems to which the technical idea of the above technology can be applied. In particular, renewable energy generation is an eco-friendly development using renewable energy. For example, solar power generation, solar power generation, biomass generation, small hydro power generation, marine energy generation, waste energy generation, geothermal generation, Power generation, etc., and the technique described in this specification is most useful because it is a field where utilization of an inverter is a mainstay for power conversion.

It is noted that the technical terms used herein are used only to describe specific embodiments and are not intended to limit the scope of the technology disclosed herein. Also, the technical terms used herein should be interpreted as being generally understood by those skilled in the art to which the presently disclosed subject matter belongs, unless the context clearly dictates otherwise in this specification, Should not be construed in a broader sense, or interpreted in an oversimplified sense. In addition, when a technical term used in this specification is an erroneous technical term that does not accurately express the concept of the technology disclosed in this specification, it should be understood that technical terms which can be understood by a person skilled in the art are replaced. Also, the general terms used in the present specification should be interpreted in accordance with the predefined or prior context, and should not be construed as being excessively reduced in meaning.

Also, the singular forms "as used herein include plural referents unless the context clearly dictates otherwise. In this specification, the terms "comprising ", or" comprising "and the like should not be construed as necessarily including the various elements or steps described in the specification, Or may be further comprised of additional components or steps.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals denote like or similar elements, and redundant description thereof will be omitted.

Further, in the description of the technology disclosed in this specification, a detailed description of related arts will be omitted if it is determined that the gist of the technology disclosed in this specification may be obscured. It is to be noted that the attached drawings are only for the purpose of easily understanding the concept of the technology disclosed in the present specification, and should not be construed as limiting the spirit of the technology by the attached drawings.

First, the configuration according to the embodiment of the output control method of the three-phase inverter disclosed in this specification will be described with reference to Fig.

2 is a flow chart according to an embodiment of the output control method of the three-phase inverter disclosed herein.

As shown in FIG. 2, an embodiment of the output control method of the three-phase inverter includes a step (S10) of removing a harmonic from an output signal of the three-phase inverter, Detecting information (S20), and controlling an output phase and a size of the inverter based on the detected phase information (S30).

The inverter means an apparatus for converting the power sent to the DC in the energy conversion apparatus into the commercial AC form of the power system so as to supply the power converted from the energy conversion apparatus to the usable form, Is referred to as a grid-connected inverter.

The system is a system in which power supply and supply of electric energy is performed, and refers to a system of infinite buses in which a plurality of power plants, substations, and transmission / distribution lines are integrated to generate electric power and transmission / distribution.

Since the power output from the inverter is converted from DC to AC and the phase and waveform are unstable compared to the voltage of the system, the output of the inverter must be monitored and controlled for stable operation of the system.

In order to monitor and control the output of the inverter, the output information of the inverter must be detected from the output signal of the inverter. When the output information of the inverter is detected, the output control of the inverter becomes possible.

The output information of the inverter may be information on the output voltage of the inverter or the output current of the inverter.

The output information of the inverter may include frequency distortion due to harmonics. If the output information includes harmonics and distortion components, the control operation of the inverter may not be performed properly.

For example, when a control section or controller for controlling the output of the inverter includes a harmonic in the output information to be an input signal, the control section or the controller recognizes a harmonic included in the output information as an input signal The control target frequency phase can not be controlled during the control operation, and the harmonics to be removed can be controlled.

Alternatively, if the output information including harmonics is recognized as an input signal, the output can be controlled in a form in which the harmonics remain in the control operation.

In the step (S10) of removing the harmonics from the output signal of the inverter, harmonics may be removed from the output signal of the inverter including the harmonics, thereby changing the output signal of the inverter to a stable form.

In step (S10) of removing the harmonics from the output signal of the inverter, the harmonics can be controlled through either the harmonic filter capable of controlling the harmonics or the harmonic controller.

The harmonic controller may be a proportional integral controller.

In the step S20 of detecting the output phase information of the inverter, the phase information of the inverter can be detected from the output signal of the inverter from which the harmonics other than the frequency to be controlled are removed.

In the step (S10) of removing the harmonics from the output signal of the three-phase inverter, the output signal of the inverter is changed into a stable form in which the harmonics other than the frequency to be controlled are removed, Can be accurately and stably detected.

In step S30 of controlling the output phase and size of the inverter based on the detected phase information, phase information of the frequency to be controlled is detected in step S20 of detecting output phase information of the inverter The output phase and the magnitude of the inverter can be controlled.

Hereinafter, a specific embodiment of the output control method of the three-phase inverter disclosed in this specification will be described with reference to FIG. 3 and FIG.

3 is a block diagram according to a specific embodiment of the output control method of the three-phase inverter disclosed herein.

4 is a flow chart according to a specific embodiment of the output control method of the three-phase inverter disclosed in this specification.

3, the three-phase output signal 10 is converted into the dq axis stop coordinates 20, and the dq axis stop coordinates 20 ) Are removed from the harmonic components except for the frequency to be controlled through the resonance controller 30 and the dq axis stop coordinates 20 from which the harmonic components are removed are converted into the dq axis synchronization coordinates 40, The phase information 50 may be detected in the phase detector 40. [

The three-phase output signal 10 may be a signal for the output of the three-phase inverter.

The three-phase output signal 10 may be a signal representing the output of the three-phase inverter in a-b-c.

The three-phase output signal 10 may include a harmonic component.

The d-q axis stop coordinates 20 may be obtained by modeling the signal of the output of the three-phase inverter with d-q axis coordinates.

The resonance controller 30 can remove the harmonic components included in the d-q axis stop coordinates 20.

The d-q axis synchronization coordinates 40 may be obtained by converting the d-q axis stop coordinates 20 from which harmonics have been removed through the resonance controller 30 into d-q axis coordinates.

The phase information 50 may be output magnitude and frequency information of the three-phase inverter from which the harmonics other than the control target frequency are removed from the three-phase output signal 10.

Hereinafter, specific steps of the output control method of the three-phase inverter according to the above-described embodiment will be described with reference to FIG.

As shown in FIG. 4, in a specific implementation step of the output control method of the three-phase inverter, step (S10) of removing harmonics from the output signal of the three-phase inverter is performed by setting the output signal of the inverter as dq axis stop coordinates (Step S11), and removing harmonic components from the stop coordinates, wherein detecting (S20) the output phase information of the inverter comprises converting the stop coordinates into dq axis synchronous coordinates And detecting the phase information in the synchronous coordinate (S22).

The step (S10) of removing harmonics from the output signal of the three-phase inverter includes a step (S11) of converting the output signal of the inverter to a dq axis stop coordinate and a step (S12) of removing harmonic components from the stop coordinate And the like.

In the step S11 of converting the output signal of the inverter into the d-q axis stop coordinates, the three-phase output signal of the inverter can be converted into d-q axis stop coordinates as modeling for output control of the inverter.

In the step (S12) of removing the harmonic component from the stationary coordinate, the harmonic component excluding the output control target frequency of the inverter can be removed through the resonance controller in the dq axis stationary coordinate converted from the output signal of the inverter .

The resonance controller may be a PI controller that removes harmonic components except the output control target frequency of the inverter at the stationary coordinates.

5 is a configuration diagram of a resonance controller according to a specific embodiment of the output control method of the three-phase inverter disclosed in this specification.

5, the resonance controller receives a reference value e _dq * and a transfer function K _rc s / s ² + ω ₀ ² , And the output is negatively fed back to the input.

The output of the resonance controller is negatively fed back to the input so that the output of the resonance controller can be controlled to coincide with the input reference value.

The transfer function of the resonant controller is a transfer function of a controller composed of two parallel integrators, 1 / s and ² / s.

Through the integrator, the harmonic components of the d-q axis stop coordinates that are input to the resonance controller can be removed.

4, step (S20) of detecting the output phase information of the inverter includes a step (S21) of converting the stop coordinate into a dq axis synchronous coordinate and a step (S21) of detecting the phase information in the synchronous coordinate (Step S22).

In the step S21 of converting the stop coordinates into the d-q axis synchronous coordinates, the stop coordinates from which harmonic components other than the control subject frequency are removed may be converted into the d-q axis synchronous coordinates through the resonance controller.

The synchronous coordinates are obtained by transforming the stationary coordinates from which the harmonic components are removed, and the output magnitude of the inverter on the d-axis and the output frequency of the inverter on the q-axis may appear.

For example, when the output signal of the three-phase inverter is converted into the dq axis stop coordinates, the harmonic components of the stationary coordinate are removed through the resonance controller, and the stationary coordinate from which the harmonic components are removed is the dq axis synchronous coordinate The output magnitude of the inverter appears on the d axis of the synchronous coordinate and the output frequency of the inverter appears on the q axis of the synchronous coordinate.

In the step (S22) of detecting the phase information in the synchronous coordinate, the output size of the inverter may be detected in the d-axis of the synchronous coordinate, and the output frequency of the inverter may be detected in the q-axis of the synchronous coordinate.

The phase information for the output control of the inverter can be detected by detecting the output size of the inverter and the output frequency of the inverter in the step S22 of detecting the phase information in the synchronous coordinate.

The output size of the inverter can be detected by passing the d-axis of the synchronous coordinate through the Low Pass Filter.

The low pass filter is a low pass filter, which means a high frequency cut filter that passes a frequency band lower than a given cutoff frequency and attenuates a higher frequency band. The output size of the inverter can be detected.

The output frequency of the inverter can be detected by passing the q-axis of the synchronous coordinates through the PI controller.

The PI controller is a proportional integral controller, which is a control technique in which an integral control for integrating an error signal to produce a control signal is connected in parallel. The controller uses the PI controller to control the inverter in the q- The output frequency can be detected.

The output frequency of the inverter is detected in the q-axis of the synchronous coordinate, and can be controlled to be fed back to the synchronous coordinate.

The negative feedback control means a control method in which the output signal is returned to the input signal to compare the value of the control amount with the target value and perform the correcting operation so as to match the value of the control amount and the target value.

The output frequency of the inverter is fed back to the synchronous coordinate, so that the error of the output frequency of the inverter can be controlled.

For example, the detected output frequency of the inverter is negative feedbacked to the synchronous coordinate, and the output error of the inverter can be controlled based on the output frequency of the negative feedback inverter.

Embodiments of the output control method of the three-phase inverter disclosed in this specification can be applied to a controller that controls the output of the three-phase inverter.

Embodiments of the output control method of the three-phase inverter disclosed in this specification can be applied to the PLL technique for detecting the output phase of the three-phase inverter.

Embodiments of the output control method of the three-phase inverter disclosed in this specification can be implemented by applying a software operation method by programming the calculation process.

The embodiments of the output control method of the three-phase inverter disclosed in this specification can be applied to at least any one of the control unit configured in the grid interconnected inverter, the separate control unit for controlling the grid interconnected inverter, It can be applied to one.

Embodiments of the output control method of the three-phase inverter disclosed in this specification may be applied to a system operation system that integrally operates the system.

Embodiments of the output control method of the three-phase inverter disclosed in this specification can be implemented by being applied to a power control apparatus including an inverter.

Embodiments of the method of controlling the output of the three-phase inverter disclosed herein are applied to control units and protective devices of all emergency power plants, including inverters for residential, building, utility, industrial and emergency power applications .

In the output control method of the three-phase inverter disclosed in this specification, when the inverter output for controlling the output of the inverter is detected, accurate output detection is performed by detecting only the frequency to be controlled by eliminating harmonics, and accurate control operation of the inverter output controller is possible In addition, it has an effect of stabilizing the output control performance as well as the output of the inverter. Further, since the efficiency of the inverter is increased due to the stabilization of the control performance, the operation of the power system can be diversified and flexible, The development of the renewable energy field can be promoted, and further, the stability and reliability of the entire power system can be secured.

It will be apparent to those skilled in the art that various modifications and changes can be made in the present invention without departing from the spirit or scope of the present invention as defined by the appended claims. It will be appreciated that such modifications and variations are intended to fall within the scope of the following claims.

10: 3-phase output signal 20: dq axis stop coordinate
30: resonance controller 40: dq axis synchronous coordinate
50: Phase information
S10: removing the harmonics from the output signal of the three-phase inverter
S11: Step of converting the output signal of the inverter into dq axis stop coordinates
S12: removing the harmonic components from the stop coordinates
S20: Detecting the output phase information of the inverter
S21: Step of converting stop coordinates into dq axis synchronous coordinates
S22: detecting the phase information in synchronous coordinates
S30: controlling the output phase and size of the inverter

Claims (8)

Removing harmonics from an output signal of the three-phase inverter;
Detecting output phase information of the inverter from the output signal from which the harmonics have been removed; And
And controlling an output phase and a magnitude of the inverter based on the detected phase information,
The step of removing harmonics
And inputting an error between the input power of the three-phase inverter represented by the stationary coordinate system voltage and the output voltage of the three-phase inverter represented by the stationary coordinate system voltage to the resonance controller,
And the resonance controller removes the harmonics from the input error. The method according to claim 1,
The step of removing harmonics comprises:
Converting the output signal of the inverter into dq axis stop coordinates; And
Removing a harmonic component from the stationary coordinate,
Wherein the step of detecting the output phase information of the inverter comprises:
Converting the stop coordinates into dq axis synchronous coordinates; And
And detecting the phase information at the synchronous coordinate. 3. The method of claim 2,
Wherein removing the harmonic component from the stationary coordinate comprises:
A harmonic component is removed through a resonance controller,
Wherein the resonance controller is a PI controller that removes harmonic components except the output control target frequency of the inverter at the stop coordinates. 3. The method of claim 2,
The transformed synchronous coordinate may be expressed as:
Wherein the stop coordinates from which the harmonic components have been removed are transformed,
wherein an output magnitude of the inverter appears on the d-axis, and an output frequency of the inverter appears on the q-axis. 3. The method of claim 2,
Wherein the step of detecting the phase information of the inverter in the synchronous coordinate comprises:
Wherein an output size of the inverter is detected in a d-axis of the synchronous coordinate, and an output frequency of the inverter is detected in a q-axis of the synchronous coordinate. 6. The method of claim 5,
The output size of the inverter,
Wherein the output signal is detected through a low pass filter. 6. The method of claim 5,
The output frequency of the inverter
PI controller of the three-phase inverter. delete

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