KR101359761B1 - Controller and control method for supplying three phase power - Google Patents

Abstract

The present invention relates to a three-phase power supply control device and a control method thereof. A control method of a three-phase power supply control device having a power adjustment unit according to the present invention, and applying a voltage control signal to the power adjustment unit to control the power adjustment unit to supply power to a predetermined load, has a reverse phase to the voltage control signal. Forcibly including a minute voltage control component; In the initialization state, a reverse phase voltage and a reverse phase current are extracted from voltages and currents detected at specific points on a circuit connected to the power controller, and the reference reverse phase impedance is calculated and stored using the extracted reverse phase voltage and reverse phase current. Making a step; The reverse phase voltage during operation and the reverse phase current during operation are extracted from the voltage and current sensed at the specific point during operation, and the reverse phase impedance during operation is calculated using the extracted reverse phase voltage during operation and reverse phase current during operation. Making a step; And when the calculated value of the reverse phase impedance during operation is out of a predetermined range based on the value of the reference reverse phase impedance, determining the single operation state with respect to the load.

Description

3-phase power supply control device and its control method {CONTROLLER AND CONTROL METHOD FOR SUPPLYING THREE PHASE POWER}

The present invention relates to a three-phase power supply control device and a control method thereof, and more particularly, to a three-phase power supply control device that cuts off the power supply to the load when an abnormality occurs, such as the power is cut off from the system and control thereof It is about a method.

The load operated by the power supply (for example, an electric mechanism, a heat transfer mechanism, etc.) may be supplied with power from various power sources, rather than being supplied by any one power source, that is, a single power source.

In particular, power generated from environmentally friendly facilities, such as solar power supply (or power generation) facilities as well as conventional power supply (or power generation) facilities, can be supplied to the load at the same time.

For example, if a home is equipped with a photovoltaic facility, some of the power consumed in the home may be supplied from the photovoltaic power supply and the rest may be supplied from external power that is charged.

If each home is equipped with eco-friendly power supply facilities such as solar power supply facilities, each home can reduce the cost of power consumption and can help to manage power supply efficiently at the national level. Can be.

This is not limited to each household, but the same effect can be obtained when the solar power supply unit is used together with the general power supply unit on a local basis.

However, when power is simultaneously supplied from a plurality of power supply facilities (first power supply facility and second power supply facility) to any load or region, there may be a risk associated with troubleshooting.

For example, if a disconnection occurs on a line that is connected to the first power supply and the load, the first power supply repair engineer must supply power to the load from the first power supply before performing the disconnection repair for safety. Will block.

However, even in this state, power may be supplied to the load from the second power supply facility. This state may be referred to as a standalone operation from the second power supply facility.

In this single operation state, an electric shock accident may occur due to the electric power supplied from the second power supply facility during disconnection repair if the first power supply facility repairman does not know the existence of the second power supply facility.

Therefore, there is a demand that each power supply facility includes a configuration capable of detecting a single operation state and taking measures to prevent various safety accidents such as an electric shock accident.

Patent Publication No. 10-2009-0100704

The present invention has been made to meet the above-described conventional request, and an object thereof is to provide a method for more accurately detecting a single driving state and an apparatus implementing the method.

In order to achieve the above object, a three-phase power supply control apparatus according to the present invention, the power regulator for adjusting the power supplied from a predetermined voltage source; A control signal applying unit configured to apply a voltage control signal to the power adjusting unit so as to control the power adjusting unit to supply power to a predetermined load, and forcibly including a reverse phase voltage control component in the voltage control signal; A detector for sensing a voltage and a current at a specific point on a circuit connected to the power regulator; A reverse phase signal extracting unit extracting a reverse phase voltage and a reverse phase current from each of the voltage and current sensed by the detector; A reference range setting unit configured to calculate a reference reverse phase impedance by using the reverse phase voltage and the reverse phase current extracted by the reverse phase signal extractor and to set a reference range around the calculated reference reverse phase impedance; An operating impedance calculator configured to calculate the reverse phase impedance during operation by using the reverse phase voltage during operation and the reverse phase current during operation extracted by the reverse phase signal extractor during operation; And a state determination unit that determines that the value of the reverse phase impedance during operation calculated by the operation impedance calculator is outside the reference range set by the reference range setting unit, and determines the single operation state for the load.

In addition, in order to achieve the above object is provided with a power adjusting unit according to the present invention, by applying a voltage control signal to the power adjusting unit control of the three-phase power supply control device to control the power adjusting unit to supply power to a predetermined load The method includes forcibly including a reverse phase voltage control component in the voltage control signal; In the initialization state, a reverse phase voltage and a reverse phase current are extracted from voltages and currents detected at specific points on a circuit connected to the power controller, and the reference reverse phase impedance is calculated and stored using the extracted reverse phase voltage and reverse phase current. Making a step; The reverse phase voltage during operation and the reverse phase current during operation are extracted from the voltage and current sensed at the specific point during operation, and the reverse phase impedance during operation is calculated using the extracted reverse phase voltage during operation and reverse phase current during operation. Making a step; And when the calculated value of the reverse phase impedance during operation is out of a predetermined range based on the value of the reference reverse phase impedance, determining the single operation state for the load.

As described above, according to the present invention, it is possible to easily detect a single operation state by detecting an impedance change. In particular, the reverse phase voltage and the reverse phase current are forcibly included in the power supplied using the reverse phase voltage control signal, thereby easily calculating the reverse phase impedance even in a circuit in which the reverse phase does not occur naturally (e.g., a balanced circuit). It is possible to check the state of change of the reverse phase impedance and to detect the single operation state.

1 is an overall power system configuration including a three-phase power supply control apparatus according to an embodiment of the present invention,
2 is a functional block diagram of the three-phase power supply control device of FIG.
3 is a detailed functional block diagram of a control signal applying unit of FIG. 2;
4 is a control flowchart of a three-phase power supply control apparatus according to an embodiment of the present invention,
Figure 5 shows the experimental results of determining the reverse phase impedance when the three-phase power supply control device according to an embodiment of the present invention when the system power off.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

An example of the entire system including the three-phase power supply control apparatus according to an embodiment of the present invention is shown in FIG.

Here, the three-phase power supply control device may be connected to a predetermined power supply, for example, a solar module, to perform a function of supplying power to a load. In FIG. 1, the illustration of such a power supply is omitted for convenience.

For example, the three-phase power supply control device performs a function of supplying power generated from a solar power module to a load by adjusting a voltage or a current according to a predetermined control.

In Figure 1, the load is connected to the power supply control device as well as the grid, where the grid refers to a power system that includes another load or another power source, in this embodiment another power source- For example, suppose it is connected to a commercial power source by a power generation facility. Such a system may include power transmission facilities such as transformers.

In FIG. 1, passive elements (coils, resistors, and capacitors) forming a load with a transmission path are just examples for convenience of description and the present invention is not limited thereto.

The present invention also relates to a three-phase power supply control device, but FIG. 1 shows only one of three phases, i.e., a single-phase circuit, for convenience.

The three-phase power supply control apparatus according to the present embodiment calculates the reverse phase impedance of the initialization state (normal state), and then changes the reverse phase impedance that occurs when a disconnection occurs between a specific position, for example, PP '. Detect and determine the single operation state.

Specific features of the three-phase power supply control device will be described with reference to the functional block of FIG.

As shown in the figure, the three-phase power supply control apparatus according to an embodiment of the present invention, the power adjusting unit 110, the control signal applying unit 120, the sensing unit 130, the reverse phase signal extraction unit 140 , A reference range setting unit 150, an operating impedance calculating unit 160, and a state determining unit 170 are configured.

The power adjusting unit 110 adjusts the power supplied from the predetermined voltage supply source according to the control signal applied by the control signal applying unit 120 to be described later.

For example, the power adjusting unit 110 is connected to the solar module to change the power generated by the solar cell using at least one of voltage control, current control, and power control scheme. Here, the photovoltaic module includes at least one photovoltaic cell (solar cell or photovoltaic) to generate sunlight to generate actual electromotive force and to flow current in a predetermined direction.

The power adjusting unit 110 may be configured as an inverter circuit including at least one switching element. The inverter circuit controls the control signal applying unit 120 together with a function of converting a direct current generated from a solar module into an alternating current. By changing the on / off duty ratio of the switching element according to the signal to change the terminal voltage generated in the solar module. As such, if the terminal voltage of the solar module is changed, the current also changes according to the characteristics of the solar module, which in turn changes or adjusts the power (voltage and current) supplied by the solar module.

The configuration of the photovoltaic module and the power control unit 110 may be variously changed, and the configuration and the functions of the photovoltaic module and the power control unit 110 are only known technologies, and thus a detailed description thereof will be omitted.

The control signal applying unit 120 applies a voltage control signal to the power adjusting unit 110 to control the power adjusting unit 110 to supply power to a predetermined load. In this case, the control signal applying unit 120 reverses the voltage control signal. Force the inclusion of a minute voltage control component.

Here, the meaning of "inverse phase" means a component that corresponds to "normal phase" and in which the order of the original voltage and the phase is reversed in the three-phase circuit. For example, if the phase of the voltage supplied to the three-phase circuit has 0 degrees, 120 degrees, and 240 degrees in the clockwise direction, the reverse phase voltage signal component is a voltage component having a phase of 0 degrees, 120 degrees and 240 degrees in the counterclockwise order. Means.

That is, the control signal applying unit 120 may apply the feedback voltage control signal to the power adjusting unit 110, which includes forcibly including the reverse phase voltage signal in the voltage control signal.

The detailed functional block of the control signal applying unit 120 is as shown in FIG. 3.

That is, as shown in the drawing, the control signal applying unit 120 may include a feedback linkage control unit 122, an inverse phase voltage signal generation unit 123, and a signal synthesis unit 121.

Here, the feedback linkage control unit 122 generates a feedback linkage control signal for voltage control or current control or power control based on the feedback signal, for example, a voltage and / or current signal detected at a predetermined node. For example, a feedback linkage control signal for generating a maximum power or a constant power to the load is generated and provided to the signal synthesizer 121.

The feedback linkage control unit 122 may generate a feedback linkage control signal according to a specific algorithm based on the input feedback signal. In this case, the algorithm used in the feedback linkage control unit 122 may be various known methods (eg, Algorithm for keeping the power supplied to the load is kept constant or algorithm for allowing the maximum power to be supplied to the load) may be applied, so a detailed description thereof will be omitted.

The reverse phase voltage signal generator 123 generates a reverse phase voltage control signal, for example, a reverse phase voltage control component having a predetermined fixed shape, and provides the reverse phase voltage control component to the signal synthesizer 121. Here, having a fixed form means having a fixed form, for example, a fixed value or a fixed waveform, regardless of the magnitude or shape of the feedback current or voltage.

That is, the reverse phase voltage signal generation unit 123 does not need to consider the feedback current or voltage, and only needs to generate the reverse phase voltage control component having a certain shape, and thus the configuration thereof may be simplified and simplified.

The signal synthesizing unit 121 generates a voltage control signal obtained by simply synthesizing the feedback linkage control signal received from the feedback linkage control unit 122 and the reverse phase voltage control signal received from the reverse phase voltage signal generator 123. Performs a function provided to the power adjuster 110.

Accordingly, the reverse phase voltage control component is included in the voltage control signal applied from the control signal applying unit 120 to the power adjusting unit 110, which is inversely reversed to the three phase voltage supplied to the load by the power adjusting unit 110. It means that the ingredients are included.

In this case, the power supplied from the power adjusting unit 110 by the reverse phase voltage control component may be controlled to include a reverse phase voltage / current having the same frequency as the corresponding power (for example, 60 Hz).

Meanwhile, the sensing unit 130 detects a voltage and a current at a specific point on a circuit connected to the power adjusting unit 110.

Here, the specific point may correspond to the feedback point of the feedback voltage control. For example, the sensing unit 130 is connected to the power control unit 110 and the feedback point starts a feedback route among arbitrary positions before being supplied to the load. The voltage and current at the point A of FIG. 1 can be sensed. In this case, since the current and voltage sensing by the conventional feedback circuit can be used as it is, there is no need to additionally provide a separate sensing unit 130 for sensing the reverse phase voltage and the reverse phase current.

Sensing current and voltage on a particular node itself is well known in the art and thus a detailed description thereof will be omitted.

The reverse phase signal extractor 140 extracts the reverse phase voltage and the reverse phase current from the voltage and the current sensed by the detector 130, respectively. That is, as described above, according to the reverse phase voltage signal included in the voltage control signal applied by the control signal applying unit 120, the power adjusting unit 110 has a voltage including the reverse phase voltage component and the reverse phase current component accordingly. The reverse phase signal extracting unit 140 performs the function of extracting the reverse phase voltage and the reverse phase current from the voltage and the current at a specific point.

Extracting the reverse phase voltage or reverse phase current from the current or voltage flowing on the three-phase power system per se is a well-known technique, and thus a detailed description thereof will be omitted.

The reference range setting unit 150 calculates a reference reverse phase impedance by using the reverse phase voltage and the reverse phase current extracted by the reverse phase signal extractor 140 in the initialization state. Since impedance is expressed as a ratio of voltage and current, reverse phase impedance can be calculated using reverse phase voltage and reverse phase current.

Here, the initialization state means a normal state in which no abnormality is found in the system, and a time point corresponding to the initialization state may mean, for example, a time point at which the three-phase power supply control device according to the present embodiment starts operation. Although not shown in the drawing, when the user input unit is further provided, it may mean a time point for detecting the initialization setting input through the user input unit.

In addition, the reference range setting unit 150 also performs a function of setting a reference range centered on the reference anti-phase impedance calculated above. The reference range may be determined in consideration of the high frequency filter component (impedance) existing between the power adjuster 110 and the point A as shown in the example of FIG.

For example, when the calculated reference reverse phase impedance is 15 + j30, the reference range setting unit 150 may set 5 + j25 to 20 + j35 as the reference range so that the real part and the imaginary part have an error of 10, respectively. .

The operating impedance calculator 160 uses the reverse phase voltage during operation and the reverse phase current during operation extracted by the reverse phase signal extractor 140 after the reference range is set by the reference range setting unit 150. To calculate the reverse phase impedance during operation.

The function of calculating the reverse phase impedance of the operating impedance calculator 160 is not different from the function of calculating the reference reverse phase impedance except that the reference range is set after the reference range is set by the reference range setting unit 150. .

The state determining unit 170 determines the stand-alone driving state for the load when the value of the reverse phase impedance during operation calculated by the operating impedance calculating unit 160 is out of the reference range set by the reference range setting unit 150. Do this.

For example, when a disconnection occurs in the PP ′ section of FIG. 1, the state determining unit 170 may not load power from another power supply of the system through reverse phase impedance comparison, and may load only through the power adjusting unit 110. It is determined as a stand-alone operation state in which power is being supplied.

In general, the load impedance is much larger than the grid impedance, so the total impedance seen at point A when the grid is connected (i.e., normal state) is close to the grid impedance. Blocked state) The total impedance seen at point A is close to the load impedance.

Therefore, since the impedance difference between the grid connection and the grid disconnection is greatly widened, the three-phase power supply control device according to the present embodiment can determine whether to operate alone.

As a result of the determination, the control signal applying unit 120 described above may apply the voltage control signal to the power adjusting unit 110 to stop the power supply to the load.

Hereinafter, the overall control process of the three-phase power supply control apparatus according to an embodiment of the present invention will be described with reference to FIG.

First, the three-phase power supply control device applies a reverse phase voltage signal so that the reverse phase voltage is included in the voltage or current supplied to the load (step S1).

The three-phase power supply control device then detects the voltage and current at a specific point (e.g. feedback point for voltage control or current control, etc.) (step S3) and extracts the reverse phase voltage and current (step S5). .

The three-phase power supply control device calculates the reverse phase impedance using the extracted reverse phase voltage and reverse phase current (step S7), and checks whether a reference range is already set (step S9).

If the reference range is not set (step S9), the three-phase power supply control device determines that it is an initialization setting step and sets the reference range (step S11).

For example, the three-phase power supply control device determines that the calculated reverse phase impedance is the reverse phase impedance in the initialization state, that is, the reference reverse phase impedance, and sets the reference range including the range of the preset reverse phase impedance as much as the preset value. / Can be saved.

After setting the reference range, the process continues again from step S1.

In the present embodiment, the process of performing the voltage control or the current control based on the feedback voltage and current values, the process of adjusting the control signal based on the feedback voltage and current values, corresponds to a known technique. Omit.

As a result of the determination, if the reference range is already set (step S9), the three-phase power supply control device determines that the calculated reverse phase impedance is the reverse phase impedance during operation, and whether the reverse phase impedance during operation is outside the preset reference range. (Step S13).

If the three-phase power supply control device determines that the reverse phase impedance during operation does not deviate from the preset reference range (step S13), the three-phase power supply control device starts again from step S1. In step S13, it is determined that a single driving state has occurred (step S15), and the power supply is stopped (step S17). Of course, at this time, by sending a warning sound can be confirmed by the administrator.

5 shows the actual single driving test results according to the present embodiment.

That is, FIG. 5 is a three-phase power supply according to the present embodiment when the current input from the system is supplied at a constant amplitude and frequency and is interrupted at a certain time, for example, when a disconnection occurs on a line supplied from the system to a load. The change of the reverse phase impedance judged by the control device is shown.

As shown in the figure, it can be seen that the reverse phase impedance, which is determined by the three-phase power supply control device according to the present embodiment, increases rapidly from the time when single operation occurs, that is, when the current from the system is cut off.

Therefore, the three-phase power supply control device continuously applies the reverse phase voltage control signal, extracts the reverse phase from the supplied voltage and current, checks the reverse phase impedance, and then sets the value of the reverse phase impedance in a predetermined range (preset). By immediately shutting off the power supply to the load in the case of outside the standard range, it is possible to greatly reduce the electric shock accident of the operator who wants to perform the troubleshooting by disconnection in the system.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. It is to be understood that such variations and modifications are intended to be included in the scope of the appended claims.

110: power adjusting unit 120: control signal applying unit
130 detection unit 140 reverse phase signal extraction unit
150: reference range setting unit 160: operating impedance calculation unit
170: state determination unit 121: signal synthesis unit
122: feedback linkage control unit 123: reverse phase voltage signal generation unit

Claims (8)

In the control method of the three-phase power supply control device having a power adjusting unit, by applying a voltage control signal to the power adjusting unit to control the power adjusting unit to supply power to a predetermined load,
(a) forcibly including a reverse phase voltage control component in said voltage control signal;
(b) extracting a reverse phase voltage and a reverse phase current from voltages and currents detected at a specific point on a circuit connected to the power control unit in an initialization state, and using the extracted reverse phase voltage and reverse phase current, a reference reverse phase impedance is obtained. Calculating and storing;
(c) extracting reverse phase voltage during operation and reverse phase current during operation from each of the voltage and current sensed at the specific point during operation and using the extracted reverse phase voltage during operation and reverse phase current during operation Calculating an impedance;
(d) if the calculated value of reverse phase impedance during operation is out of a predetermined range based on the value of the reference reverse phase impedance, and determining the single operation state for the load;
In the step (a), the control method of the three-phase power supply control device, characterized in that the feedback voltage control signal of the feedback type includes a predetermined fixed phase reverse phase voltage control component. The method of claim 1,
Wherein (d) is the control method of the three-phase power supply control device, characterized in that further comprising the step of controlling to cut off the power supplied by the power regulator when it is determined to be a stand-alone operation state for the load. delete The method of claim 1,
The specific point corresponds to the feedback point of the feedback voltage control method of the three-phase power supply control device. In the three-phase power supply control device,
A power adjuster for adjusting power supplied from a predetermined voltage supply source;
A control signal applying unit configured to apply a voltage control signal to the power adjusting unit so as to control the power adjusting unit to supply power to a predetermined load, and forcibly including a reverse phase voltage control component in the voltage control signal;
A detector for sensing a voltage and a current at a specific point on a circuit connected to the power regulator;
A reverse phase signal extracting unit extracting a reverse phase voltage and a reverse phase current from each of the voltage and current sensed by the detector;
A reference range setting unit configured to calculate a reference reverse phase impedance by using the reverse phase voltage and the reverse phase current extracted by the reverse phase signal extractor and to set a reference range around the calculated reference reverse phase impedance;
An operating impedance calculator configured to calculate the reverse phase impedance during operation by using the reverse phase voltage during operation and the reverse phase current during operation extracted by the reverse phase signal extractor during operation;
And a state determination unit for determining an independent operation state of the load when the value of the reverse phase impedance during operation calculated by the operation impedance calculator is outside the reference range set by the reference range setting unit.
And the control signal applying unit includes a fixed reverse phase voltage control component, which is set in a feedback type voltage control signal, and applies it to the power adjusting unit. 6. The method of claim 5,
And the control signal applying unit applies the voltage control signal to the power adjusting unit to stop the power supply to the load when the state determination unit determines that the load is in a single operation state with respect to the load. . delete 6. The method of claim 5,
The specific point is a three-phase power supply control device, characterized in that the feedback point of the feedback voltage control.

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