KR101039431B1 - Voltage management system and method - Google Patents

Abstract

PURPOSE: A system and a method for managing voltages are provided to supply controlling signals to a user in order to control a power system when the user manually drives the system. CONSTITUTION: A voltage managing system is composed of a fast adaptive voltage controller(100), a reactive power distributor(200), an output device(330), a voltage input(360), and an automatic voltage controller(390). The fast adaptive voltage controller generates information related to the output ratio of reactive power based on information related to the output of system reactive power and information related to maximum and minimum output ratio when a user manually drives the automatic voltage controller. The reactive power distributor receives the information related to the output ratio of the reactive power or information related to the difference of output ratio from the fast adaptive voltage controller. The voltage input receives the voltage control information of the reactive power distributor when the user automatically drives the automatic voltage controller.

Description

[0001] VOLTAGE MANAGEMENT SYSTEM AND METHOD [0002]

The present invention relates to a voltage management system, and more particularly, to a voltage management system and a voltage management method.

The Voltage Management System (VMS) is a control system that improves the voltage stability of the power system by dividing the reactive power generation amount according to the ratio of each power generation capacity of the power system generators. The voltage management system calculates the electrical distance of the power system bus and selects representative buses to determine the change of all voltage fluctuations. As a result, the voltage management system controls the generation amount of the reactive power of the generators to maintain the voltage level of the representative bus line at a constant level.

The voltage management system includes a continuous voltage controller (CVC), a discrete voltage controller (DVC), and a reactive power dis- patcher (RPD) to control the generation amount of reactive power.

The reactive voltage controller and the stationary voltage controller each generate a control signal for controlling the reactive power of the generator and the reactive power of the ancillary equipment. The accelerated voltage controller provides a reference value of the amount of reactive power that each generator should output using the voltage difference of the representative bus. The reference value of the reactive power amount is converted through the reactive power distributor attached to the generator and supplied to an automatic voltage regulator (AVR). The automatic voltage regulator uses the signal received from the reactive power distributor to control the generation amount of the reactive power of the generators. That is, the voltage management system is connected to the power system on-line to distribute the reactive power of the power system and improve the voltage stability.

However, in the absence of a voltage management system, the generator outputs reactive power by its automatic voltage regulator, thus outputting a reactive power amount that is in no way contrary to the control signal from the voltage management system. Accordingly, in the conventional case, if the initial value of the reactive power amount is not set when the voltage management system is first applied to the system or when the voltage management system is replaced, a transient phenomenon occurs in the power system.

In addition, when the voltage management system is operated manually, it is not possible to provide an optimal control signal to the power system.

SUMMARY OF THE INVENTION The present invention provides a voltage management system and method capable of turning on or off a voltage management system without transient phenomena.

It is another object of the present invention to provide a voltage management system and method capable of providing a control signal for controlling a power system to a user when manually operating.

According to an aspect of the present invention, there is provided a voltage management system for managing a voltage of a power system.

According to an embodiment of the present invention, there is provided a voltage management system for managing a voltage of a power system, the system comprising: a reactive voltage controller for generating reactive power output ratio information using maximum and minimum power ratio information and grid reactive power output information; And a reactive power distributor for generating reactive power reference information using the reactive power output ratio information and the maximum and minimum output ratio information and generating voltage control information using the reactive power reference information and the system reactive power output information, A voltage management system is provided.

The reactive voltage controller may generate the reactive power correction information by calculating the maximum and minimum power ratio information and the system reactive power output information and generate the reactive power output ratio information by correcting the reactive power correction information have.

Wherein the reactive power divider generates the reactive power reference information by calculating the reactive power output ratio information and the maximum and minimum output ratio information and calculates the reactive power reference information and the grid reactive power output information, And may generate the voltage control information by correcting the voltage correction information.

Wherein the accelerated voltage controller generates the calculated output ratio information by calculating the maximum and minimum output ratio information and the reference output ratio information, compares the calculated output ratio information with the grid reactive power output information, Generates reactive power correction information, and generates the reactive power output ratio information by correcting the reactive power correction information.

The quick reactive voltage controller may generate the output ratio difference information by comparing the reactive power output ratio information and the reference output ratio information, and may transmit the generated output ratio difference information to the reactive power distributor.

Wherein the reactive power divider generates the reactive power reference information by calculating the maximum and minimum power ratio information and the output ratio difference information, and calculates the reactive power reference information, the system reactive power output information, and the reactive power average information Generates voltage correction information, and generates the voltage control information by correcting the voltage correction information.

The voltage management system includes a voltage input unit for receiving the voltage control information when the power system is automatically operated from the reactive power distributor and generating voltage input information using the voltage control information, the terminal voltage information, and the system reference voltage information; And an automatic voltage regulator for controlling the power system using the voltage input information.

The voltage management system may further include an output device for outputting the voltage control information.

According to another aspect of the present invention, there is provided a quick-response voltage controller for managing a voltage of a power system.

According to an embodiment of the present invention, there is provided a quick response voltage controller for managing a voltage of a power system, comprising: a signal processing unit for generating reactive power correction information using maximum and minimum power ratio information and system reactive power output information; And an integral control unit for correcting the reactive power correction information to generate reactive power output ratio information.

According to another aspect of the present invention, there is provided a reactive power distributor for managing a voltage of a power system.

According to an embodiment of the present invention, there is provided a reactive power distributor for managing a voltage of a power system, the reactive power distributor comprising: a reactive power generator for generating reactive power reference information by using reactive power output ratio information or output ratio difference information, 1 power calculator; A second power calculator for generating voltage correction information using the reactive power reference information and the system reactive power output information; And an integral control unit for correcting the voltage correction information to generate voltage control information.

According to another aspect of the present invention, there is provided a voltage management method in which a voltage management system including a deassertive voltage controller and a reactive power divider manages a voltage of a power system.

According to an embodiment of the present invention, there is provided a voltage management method for managing a voltage of a power system by a voltage management system including a deactivation voltage controller and a reactive power divider, the method comprising the steps of: (a) Generating reactive power output ratio information or output ratio difference information using information and system reactive power output information; (b) transmitting the reactive power output ratio information or the output ratio difference information to the reactive power distributor; (c) generating the reactive power reference information by using the reactive power output ratio information or the output ratio difference information, the maximum and minimum output ratio information; And (d) generating the voltage control information using the reactive power reference information and the system reactive power output information by the reactive power divider.

The voltage management system and method according to the embodiment of the present invention may not cause a transient phenomenon when the voltage management system is turned on or off.

In addition, the voltage management system and method according to the embodiment of the present invention can provide a control signal to the user to control the power system when operating manually.

Further, the voltage management system and method according to the embodiment of the present invention can be changed to a passive mode or an automatic mode without instability of the power system, thereby improving usability and stability.

1 is a block diagram illustrating a voltage management system according to an embodiment of the present invention.
2 is a block diagram illustrating a quick response voltage controller of a voltage management system in accordance with an embodiment of the present invention.
3 is a block diagram illustrating a quick-response voltage controller of a voltage management system in accordance with another embodiment of the present invention.
4 is a block diagram illustrating a reactive power divider of a voltage management system according to an embodiment of the present invention.
5 is a flowchart illustrating a voltage management method according to an embodiment of the present invention.
6 is a diagram illustrating an example of a voltage management system according to an embodiment of the present invention.
7 is a flowchart illustrating a voltage management method according to another embodiment of the present invention.
8 is a diagram illustrating an example of a voltage management system according to another embodiment of the present invention.
9 is a graph showing bus voltage information according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. It is to be understood, however, that the invention is not to be limited to the specific embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The terms first, second, etc. may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

The terminology used in this application is used only to describe a specific embodiment and is not intended to limit the invention. The singular expressions include plural expressions unless the context clearly dictates otherwise. In the present application, the terms "comprises" or "having" and the like are used to specify that there is a feature, a number, a step, an operation, an element, a component or a combination thereof described in the specification, But do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or combinations thereof.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, embodiments of a voltage management system and method according to the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals refer to like or corresponding components throughout. A duplicate description will be omitted.

1 is a block diagram illustrating a voltage management system according to an embodiment of the present invention.

1, a voltage management system (VMS) 50 includes a CVC (Continuous Voltage Controller) 100, a Reactive Power Dispatcher (RPD) 200, an output device 330 A voltage input unit 360, and an automatic voltage regulator (AVR) 390. Here, the power system will be described as an example with the generator 450.

The reactive voltage controller 100 generates the reactive power output ratio information using the maximum and minimum power ratio information and the grid reactive power output information when the automatic voltage regulator 390 is manually operated. The reactive voltage controller 100 is connected to the reactive power distributor 200. The reactive voltage controller 100 transmits the reactive power output ratio information to the reactive power distributor 200.

In addition, the quick reactive voltage controller 100 generates the output ratio difference information using the reactive power output ratio information. The quick response voltage controller 100 transmits the output rate difference information.

On the other hand, when the automatic voltage regulator 390 is automatically operated, the quick response voltage controller 100 generates voltage comparison information using bus voltage information and voltage reference information. The reactive voltage controller 100 generates reactive power output ratio information using the voltage comparison information. The reactive voltage controller 100 transmits the generated output ratio information to the reactive power distributor 200. The accelerated voltage controller 100 will be described in detail with reference to FIGS. 2 and 3. FIG.

The reactive power divider (200) is connected to the quick reactive voltage controller (100). The reactive power distributor (200) receives the reactive power output ratio information or the output ratio difference information from the quick reactive voltage controller (100). The reactive power distributor 200 generates the reactive power reference information using the reactive power output ratio information, the output ratio difference information, and the maximum and minimum output ratio information. Then, the reactive power distributor 200 generates the voltage control information using the reactive power reference information and the system reactive power output information.

The reactive power distributor (200) connects to the output device (330) or the voltage input device (360). That is, the reactive power distributor 200 connects to the output device 330 when the automatic voltage regulator 390 is manually operated, and transmits the voltage control information to the output device 330. The reactive power distributor 200 is connected to the voltage input unit 360 when the automatic voltage regulator 390 is automatically operated and is connected to the voltage input unit 360 to transmit the voltage control information to the automatic voltage regulator 390 send. The reactive power divider 200 will be described in detail with reference to FIG.

The output device 330 is connected to the reactive power distributor 200. The output device 330 receives the voltage control information from the reactive power distributor 200 when the automatic voltage regulator 390 is manually operated. The output device 330 outputs voltage control information. At this time, the output device 330 may be at least one of a tester, a display, a speaker, and a print. For example, if the tester is a tester, the tester can display the voltage control information in numbers or by using instructions. The display device can display voltage control information using a user interface (UI). At this time, the display device includes a cathode ray tube, a liquid crystal display (LCD), an organic light emitting display (OLED), an electrophoretic display (EPD), and a plasma display panel : PDP), or the like, and may be a computer including an apparatus for displaying.

Further, the speaker can output the voltage control information by voice. The print can output the voltage control information through an output such as paper.

Accordingly, the user can determine the voltage control information through the output device 330. [ The user can determine the voltage input information of the generator 450 using the voltage control information, the terminal voltage information, and the system reference voltage information.

Here, the output device 330 has been described as an example of a tester, a display device, a speaker, and a printer. However, the present invention is not limited to this.

The voltage input unit 360 is connected to the reactive power distributor 200. The voltage input unit 360 receives the voltage control information from the reactive power distributor 200 when the automatic voltage regulator 390 is automatically operated. The voltage input unit 360 adds the voltage control information and the terminal voltage information, subtracts the system reference voltage information, and generates voltage input information. At this time, the voltage control information indicates the voltage generated by the reactive power distributor 200 to control the amount of reactive power output of the generator 450. The terminal voltage information represents a voltage at a terminal of the current generator 450 and the system reference voltage information represents a voltage that is a reference to a terminal voltage of the generator 450. [

The automatic voltage regulator 390 receives voltage input information from the voltage input unit 360 when automatically operating. On the other hand, the automatic voltage regulator 390 receives voltage input information from the user. The automatic voltage regulator 390 controls the generator 450 using the voltage input information received from the voltage input unit 360 or received from the user. That is, the automatic voltage regulator 390 controls the terminal voltage of the generator 450 by using the voltage input information, and controls the system reactive power output information output from the generator 450.

2 is a block diagram illustrating a quick response voltage controller of a voltage management system in accordance with an embodiment of the present invention.

2, the quick response type voltage controller 100 includes a signal processing unit 110, a first switch unit 140, a voltage operation unit 150, a second switch unit 160, and a first integration control unit 170 . At this time, the deassertion voltage controller 100 may be a digital controller.

The signal processing unit 110 generates reactive power correction information using the maximum and minimum power ratio information and the grid reactive power output information. In other words, the signal processing unit 110 divides the maximum and minimum power ratio information in the system reactive power output information to generate reactive power correction information. At this time, the system reactive power output information is information indicating the reactive power output of the generator 450, and the maximum and minimum power ratio information indicates the ratio of the reactive power output information according to the maximum reactive power and the minimum reactive power. For example, when the grid reactive power output information is a positive number, the maximum and minimum power ratio information represents the ratio of the reactive power maximum amount to the grid reactive power output information, and when the grid reactive power output information is negative, Can represent the ratio of the minimum reactive power and the system reactive power output information.

The first switch unit 140 is formed between the signal processing unit 110 and the first integration control unit 170. The first switch unit 140 is turned on when the automatic voltage regulator 390 is manually operated. At this time, the signal processing unit 110 can turn on the first switch unit 140 to transmit the reactive power correction information to the first integration control unit 170. [

The first switch unit 140 is turned off when the automatic voltage regulator 390 is automatically operated or when the automatic voltage regulator 390 is updated. At this time, the signal processing unit 110 can not transmit the reactive power correction information to the first integration control unit 170 because the first switch unit 140 is turned off.

The voltage calculator 150 generates voltage comparison information using bus voltage information and voltage reference information. That is, the voltage calculator 150 receives the bus voltage information from the bus voltage measuring device. At this time, the bus voltage measuring apparatus connects to the representative bus, measures the voltage flowing to the representative bus, generates initial voltage information, and converts the initial voltage information to generate bus voltage information. Here, the initial voltage information may be an instantaneous value, and the bus voltage information may be an effective value. In addition, the voltage reference information may be voltage information that is a reference in the representative bus line.

Here, the bus voltage measuring apparatus is described as an example, but the bus voltage measuring apparatus is not limited thereto, and it may be any apparatus that connects to the representative bus and generates bus voltage information using the bus voltage. For example, the device for generating the bus voltage information may be a Field Data Measurement Unit (FDMU).

The voltage calculator 150 compares the voltage reference information with the bus voltage information to generate voltage comparison information. The voltage calculator 150 transmits voltage comparison information to the first integration controller 170 when the automatic voltage regulator 390 is automatically operated or updated.

The second switch unit 160 is formed between the voltage operation unit 150 and the first integration control unit 170. The second switch unit 160 is turned on when the automatic voltage regulator 390 is automatically operated or updated. At this time, the voltage calculator 150 may transmit the voltage comparison information generated by turning on the second switch unit 160 to the first integration controller 170. FIG. Also, the first integration controller 170 is turned off when the automatic voltage regulator 390 is manually operated. Therefore, the voltage operation unit 150 can not transmit the generated voltage comparison information to the first integration control unit 170 because the second switch unit 160 is off.

The first integration controller 170 receives the reactive power correction information from the signal processor 110 when the automatic voltage regulator 390 is manually operated. The first integration control unit 170 generates the reactive power output ratio information by correcting the error of the reactive power correction information and restricting the corrected reactive power correction information to the operation range information of the generator 450. [ At this time, the operation range information indicates the reactive power that the generator 450 can output, and may include the maximum value and the minimum value.

Then, the first integration controller 170 transmits the generated reactive power output ratio information to the reactive power distributor 200.

On the other hand, when the automatic voltage regulator 390 is automatically operated or updated, the first integration controller 170 receives the voltage comparison information from the voltage calculator 150. The first integral control unit 170 corrects the error of the voltage comparison information, and generates the reactive power output ratio information by limiting the corrected voltage comparison information to the operation range information. The first integration controller 170 transmits the generated reactive power output ratio information to the reactive power distributor 200.

3 is a block diagram illustrating a quick-response voltage controller of a voltage management system in accordance with another embodiment of the present invention.

3, the quick response type voltage controller 100 includes a signal processing unit 110, a first switch unit 140, a voltage operation unit 150, a second switch unit 160, a signal input unit 165, An integration control unit 170 and a sample holder 180. [ At this time, the deassertion voltage controller 100 may be an analog controller.

The signal processing unit 110 generates reactive power correction information using the maximum and minimum power ratio information and the grid reactive power output information. To this end, the signal processing unit 110 includes a ratio operation unit 120, a comparison unit 125, and a signal generation unit 130.

The ratio calculating unit 120 generates the calculation output ratio information using the maximum and minimum output ratio information and the reference output ratio information. That is, when the automatic voltage regulator 390 is manually operated, the ratio calculating unit 120 multiplies the maximum and minimum output ratio information by the reference output ratio information to generate the calculated output ratio information. At this time, the reference output ratio information is information on the basis of the reactive power output ratio of the generator 450, and the reference output ratio information can be set by inputting from the user when the operation of the voltage management system 50 is started. Thereafter, the reference output ratio information is used to manually operate the automatic voltage regulator 390, and when the quick reactive voltage controller 100 is in operation, The power output ratio information can be set as the reference output ratio information.

The ratio calculator 120 is connected to the comparator 125. The ratio calculation unit 120 transmits the generated calculation output ratio information to the comparison unit 125.

The comparator 125 generates the reactive power correction information using the calculation output ratio information and the system reactive power output information. In other words, the comparator 125 compares the calculation output ratio information received from the ratio calculator 120 with the grid reactive power output information, and generates the reactive power correction information according to the comparison result.

The signal generating unit 130 is connected to the comparing unit 125 and receives the reactive power correction information from the comparing unit 125. [ The signal generator 130 generates a signal corresponding to the reactive power correction information to the voltage calculator 150.

The first switch unit 140 is formed between the signal processing unit 110 and the first integration control unit 170. The first switch unit 140 is turned on when the automatic voltage regulator 390 is manually operated. At this time, the first integration control unit 170 can turn on the first switch unit 140 to transmit the reactive power output ratio information to the ratio operation unit 120 of the signal processing unit 110.

On the other hand, the first switch unit 140 is turned off when the automatic voltage regulator 390 is automatically operated or when the automatic voltage regulator 390 is updated. At this time, the signal processing unit 110 can not transmit the reactive power output ratio information to the ratio calculating unit 120 of the signal processing unit 110 because the first switch unit 140 is turned off.

The voltage calculator 150 compares the voltage reference information with the bus voltage information to generate voltage comparison information. That is, the voltage calculator 150 subtracts the bus voltage information from the voltage reference information to generate voltage comparison information. The voltage calculator 150 transmits voltage comparison information to the first integration controller 170 when the automatic voltage regulator 390 is automatically operated or updated.

The second switch unit 160 is formed between the voltage operation unit 150 and the first integration control unit 170. The second switch unit 160 is turned on when the automatic voltage regulator 390 is automatically operated or updated. At this time, the voltage operation unit 150 may transmit the voltage comparison information to the first integration control unit 170 through the second switch unit 160 that is turned on. Also, the first integration controller 170 is turned off when the automatic voltage regulator 390 is manually operated. Therefore, the voltage operation unit 150 can not transmit the voltage comparison information to the first integration control unit 170 because the second switch unit 160 is off.

The signal input unit 165 adds the reactive power correction information and the voltage comparison information to the first integral control unit 170, In other words, when the automatic voltage controller is manually operated, the signal input unit 165 receives the reactive power correction information from the signal generation unit 130, but does not receive the voltage comparison information from the voltage operation unit 150. Since the signal input unit 165 has not received the voltage comparison information, only the reactive power correction information is transmitted to the first integration control unit 170. [

On the other hand, the signal input unit 165 receives the voltage comparison information from the voltage operation unit 150, but does not receive the reactive power correction information from the signal generation unit 130 when the automatic voltage controller is automatically operated or updated. Since the signal input unit 165 has not received the reactive power correction information, only the power correction information is transmitted to the first integration control unit 170. [

The first integration controller 170 receives the reactive power correction information from the signal input unit 165 when the automatic voltage regulator 390 is manually operated. The first integral control unit 170 corrects the error of the reactive power correction information and generates the reactive power output ratio information by limiting the corrected reactive power correction information to the operation range information of the power system. Then, the first integration controller 170 transmits the generated reactive power output ratio information to the sample holder 180. The first integration controller 170 transmits the reactive power output ratio information to the ratio calculator 120.

On the other hand, when the automatic voltage regulator 390 is automatically operated or updated, the first integration controller 170 receives the voltage comparison information from the signal input unit 165. The first integral control unit 170 corrects the error of the voltage comparison information, and generates the reactive power output ratio information by limiting the corrected voltage comparison information to the operation range information. The first integration controller 170 transmits the generated reactive power output ratio information to the sample holder 180. [

The sample holder 180 generates the output ratio difference information using the reactive power output ratio information and the reference output ratio information. In other words, the sample holder 180 receives the reactive power output ratio information from the first integration control section 170. The sample holder 180 compares the reactive power output ratio information with the reference output ratio information to generate output ratio difference information. The sample holder 180 transmits the generated output ratio difference information to the reactive power distributor 200.

4 is a block diagram illustrating a reactive power divider of a voltage management system according to an embodiment of the present invention.

4, the reactive power divider 200 includes a first power calculation unit 210, a second power calculation unit 220, a third switch unit 230, a second integration control unit 240, and a fourth switch unit 250).

The first power calculator 210 generates the reactive power reference information using the reactive power output ratio information, the output ratio difference information, and the maximum and minimum output ratio information. Specifically, the first power calculation unit 210 receives the reactive power output ratio information from the first integration control unit 170 of the quick response type voltage controller 100. At this time, the quick response voltage divider may be a digital controller. The first power calculator 210 multiplies the reactive power output ratio information by the maximum and minimum ratio information to generate reactive power reference information. The first power calculator 210 transmits the reactive power reference information to the second power calculator 220.

The second power calculator 220 generates the voltage correction information using the reactive power reference information and the system reactive power output information. In other words, the second power calculator 220 subtracts the system reactive power output information from the reactive power reference information received from the first power calculator 210 to generate voltage correction information.

Meanwhile, the first power calculator 210 receives the output ratio difference information from the sample holder 180 of the quick response voltage controller 100. At this time, the quick response voltage divider may be an analog controller. The first power calculator 210 multiplies the output ratio difference information by the maximum and minimum ratio information to generate reactive power reference information. The first power calculation unit 210 transmits the generated reactive power reference information to the second calculation unit.

The second power calculator 220 generates voltage correction information using the reactive power reference information, the reactive power average information, and the system reactive power output information. The second power calculator 220 adds up the reactive power reference information received from the first power calculator 210 and the reactive power average information to generate reactive power operation information. The second power calculator 220 subtracts the system reactive power output information from the reactive power calculation information to generate voltage correction information.

At this time, the reactive power average information represents the average of the reactive power output from at least one generator 450 managed by the voltage management system 50. That is, the reactive power average information can be generated using the system reactive power output information and the reactive power output ratio information.

The third switch unit 230 is formed between the second power calculator 220 and the second integration controller 240. The third switch unit 230 is turned on when the automatic voltage regulator 390 is manually operated. At this time, the second power calculator 220 may transmit the voltage correction information to the second integration controller 240 through the third switch 230 that is turned on. The third switch unit 230 is turned off when the automatic voltage regulator 390 is updated. At this time, the second power calculation unit 220 can not transmit the voltage correction information to the second integration control unit 240 because the third switch unit 230 is off.

The second integration controller 240 generates voltage control information using the voltage correction information. That is, when the automatic voltage regulator 390 is manually operated, the second integration controller 240 receives the voltage correction information from the second power calculator 220. The second integration controller 240 corrects the voltage correction information and limits the voltage correction information to the voltage range information of the generator 450 to generate voltage control information. At this time, the voltage range information indicates the voltage of the terminal that can operate in the generator 450, and may include the maximum value and the minimum value.

The fourth switch unit 250 is connected to the output device 330 when the automatic voltage regulator 390 is manually operated. At this time, the second integration controller 240 transmits the voltage control information to the output device 330 through the fourth switch 250 connected to the output device 330. The fourth switch unit 250 connects to the voltage input unit 360 when the automatic voltage regulator 390 is automatically operated. At this time, the second integration control unit 240 transmits the voltage control information to the voltage input unit 360 through the fourth switch unit 250 connected to the voltage input unit 360.

A voltage management method according to an embodiment of the present invention will be described with reference to FIGS. 5 and 6. FIG.

5 is a flowchart illustrating a voltage management method according to an embodiment of the present invention.

5, in the manual operation of the automatic voltage regulator 390, the quick reactive voltage controller 100 of the voltage management system 50 uses the maximum and minimum power ratio information and the grid reactive power output information to calculate the reactive power output And generates ratio information (S520). In other words, the signal processing unit 110 of the de-coupled voltage controller 100 divides the maximum and minimum power ratio information QgkM / m from the system reactive power output information Qgk as shown in FIG. 6, And generates correction information.

At this time, when the number of generators 450 managed by the voltage management system 50 is at least two, the system reactive power output information Qgk is generated by all the generators managed by the voltage management system 50 And the system reactive power output information (Qgk) of the system reactive power output information (450). The maximum and minimum power ratio information QgkM / m is calculated by multiplying the maximum and minimum power ratio information QgkM / m corresponding to all the generators 450 managed by the voltage management system 50 May be the value to be added. Here, the number of the generators 450 managed by the voltage management system 50 is one and will be described as an example.

The signal processing unit 110 transmits the reactive power correction information to the first integration control unit 170 through the first switch unit 140 that is turned on.

The first integration controller 170 generates the reactive power output ratio information using the reactive power correction information. That is, as shown in FIG. 6, the first integration controller 170 corrects the error of the reactive power correction information using the proportional coefficient Kpsc and the integral coefficient Kisc. The first integration controller 170 generates the reactive power output ratio information by limiting the corrected reactive power correction information to the operation range information of maximum 1 and minimum -1 of the generator 450.

Then, the first integration controller 170 transmits the reactive power output ratio information to the first power calculator 210 of the reactive power distributor 200.

The reactive power divider 200 of the voltage management system 50 generates the reactive power reference information using the reactive power output ratio information and the maximum and minimum output ratio information (S540). 6, the first power control unit of the reactive power distributor 200 multiplies the reactive power output ratio information q by the maximum and minimum output ratio information QgkM / m to calculate the reactive power reference information Qgref).

The reactive power distributor 200 of the voltage management system 50 generates the voltage control information using the reactive power reference information and the system reactive power output information (S560). Specifically, the second power calculator 220 of the reactive power divider 200 subtracts the system reactive power output information Qg from the reactive power reference information Qgref to generate a voltage correction signal do.

The second power calculation unit 220 transmits the voltage correction signal to the second integration control unit 240 through the third switch unit 230 which is turned on. 6, the second integration control unit 240 generates a first and a second integration control signals for the generator 450 and the line impedance Xt, the bus line equivalent impedance Xeq and the time constant Tvsc of the integral control unit, Is used to correct the voltage correction signal. The second integration controller 240 generates a voltage control signal by limiting the corrected voltage correction signal to voltage range information of a maximum of 0.15 and a minimum of -0.2.

Then, the second integration controller 240 transmits the voltage control information to the output device 330 through the fourth switch 250 connected to the output device 330. At this time, the output device 330 outputs the voltage control device received from the second integration control part 240. [ Accordingly, even when the automatic voltage regulator 390 is manually operated, the user can confirm the voltage control device that can control the terminal voltage of the generator 450 through the output device 330. The user can generate the voltage input information to manually operate the automatic voltage regulator 390 and the generator 450 using the voltage control device output through the output device 330. [ The automatic voltage regulator 390 can control the terminal voltage of the generator 450 using the voltage input information received from the user.

A voltage management method according to another embodiment of the present invention will be described with reference to FIGS. 7 and 8. FIG.

7 is a flowchart illustrating a voltage management method according to another embodiment of the present invention. Here, the voltage management system 50 manages one generator 450 will be described as an example.

Referring to FIG. 7, the voltage management system 50 determines whether all of the reactive power distributors 200 connected to the generator 450 are off (S710).

The voltage management system 50 resets the information stored in the first integration control unit 170 when the reactive power distributor 200 connected to the generator 450 is all off, and the reactive power distributor 200 resets the information stored in the second And resets the information stored in the integral control unit 240 (S720).

Thereafter, the voltage management system 50 generates the reactive power average information using the system reactive power output information and the reactive power output ratio information. That is, the voltage management system 50 multiplies the grid reactive power output information of the at least one generator 450 managed by the voltage management system 50 and the reactive power output ratio information, . Then, the voltage management system 50 divides the value obtained by the addition operation by the number of the generators 450 to generate the reactive power average information.

The quick response voltage controller 100 of the voltage management system 50 generates reactive power correction information using the maximum and minimum power ratio information and the grid reactive power output information (S730). 6, when the automatic voltage regulator 390 is manually operated, the ratio calculator 120 of the signal processor 110 included in the quick response voltage controller 100 controls the first integral controller 170 (Q) from the reactive power output ratio information (q). The ratio calculation unit 120 sets the reactive power output ratio information as the reference output ratio information. The ratio operation unit 120 multiplies the reference output ratio information by the maximum and minimum output ratio information Qg1M / m to generate operation output ratio information.

Then, the comparator 125 compares the calculation output ratio information with the system reactive power output information Qg1 as shown in FIG. 6, and generates reactive power correction information according to the comparison result. For example, when the calculation output ratio information is larger than the system reactive power output information (Qg1), the comparator 125 generates reactive power correction information having a value of 1, and the calculation output ratio information and the system reactive power output information (Qg1) , And generates reactive power correction information whose value is -1 if the calculated output ratio information is smaller than the system reactive power output information (Qg1). Then, the signal generator generates a signal corresponding to the reactive power correction information in the signal input unit 165. [

On the other hand, when updating the automatic voltage regulator 390, the voltage calculator 150 subtracts the bus voltage information from the voltage reference information to generate voltage comparison information during the update time. The voltage operation unit 150 transmits the voltage comparison information to the first integration control unit 170 during the update time through the second switch unit 160 that is turned on. At this time, the quick-response voltage controller subtracts the grid reactive power output information from the value obtained by multiplying the maximum and minimum output ratio information by the reactive power output ratio information, and outputs the calculated operation information to the voltage comparator 170, The signal processing unit 110 of the quick response voltage controller 100 is stopped.

The quick response voltage controller 100 of the voltage management system 50 generates output ratio difference information using the reactive power correction information (S740). In other words, the first integration controller 170 of the quick response voltage controller 100 receives the reactive power correction information from the signal input unit 165. The first integration controller 170 corrects the error of the reactive power correction information using the proportional coefficient Kpsc and the integral coefficient Kisc as shown in FIG. The first integration controller 170 generates the reactive power output ratio information q by limiting the corrected reactive power correction information to the operation range information of maximum 1 and minimum -1 of the generator 450.

The sample holder 180 of the quick reactive voltage controller 100 compares the reactive power output ratio information with the reference output ratio information as shown in FIG. 8 to generate output ratio difference information? Q. The sample holder 180 transmits the output ratio difference information? Q to the first power calculator 210 of the reactive power distributor 200.

The reactive power divider 200 of the voltage management system 50 generates voltage correction information using the output ratio difference information (S750). Specifically, the first power calculator 210 of the reactive power divider 200 multiplies the output ratio difference information (? Q) by the maximum and minimum power ratio information (Qg1M / m) as shown in FIG. 8, And generates power reference information ([Delta] Qgref). The maximum and minimum power ratio information QgkM / m may be the maximum and minimum power ratio information Qg1M / m of the first generator 450, since one generator 450 is exemplified herein. 8, the second power calculator 220 generates reactive power calculation information by adding the reactive power reference information? Qgref and the reactive power average information Qavg to generate reactive power calculation information, And subtracts the power output information (Qg) to generate a voltage correction signal.

The reactive power divider 200 of the voltage management system 50 corrects the voltage correction signal to generate a voltage control signal (S760). In other words, as shown in FIG. 8, the second integration control unit 240 of the reactive power distributor 200 generates the bus line equivalent impedance (Xeq) of the generator 450, the line impedance Xt, ) And the time constant Tvsc of the integral control unit. The second integration controller 240 generates a voltage control signal by limiting the corrected voltage correction signal to voltage range information of a maximum of 0.15 and a minimum of -0.2. At this time, the second integration controller 240 may generate the voltage control signal so that the generator 450 outputs the reactive power in a direction desired by the voltage management system 50. [ That is, the second integration controller 240 can generate the voltage control signal such that the voltage comparison information becomes 0 or the system output difference information, which is the difference between the grid reactive power output information of all the generators 450, becomes zero.

The second integration control unit 240 transmits the voltage control information to the output device 330 through the fourth switch unit 250 connected to the output device 330. At this time, the output device 330 outputs the voltage control device received from the second integration control part 240. [ Accordingly, the user can generate the voltage input information to manually operate the automatic voltage regulator 390 and the generator 450 using the voltage control device output through the output device 330. [ The automatic voltage regulator 390 can control the terminal voltage of the generator 450 using the voltage input information received from the user.

Thereafter, even if the automatic voltage controller is changed to the automatic operation, the voltage management system 50 can control the generator 450 without any transient phenomenon.

The voltage management system 50 controls the third switch unit 230 to update the automatic voltage regulator 390 if at least one of the reactive power distributors 200 connected to the generator 450 is on S810). That is, the reactive power distributor 200 turns off the third switch unit 230.

The reactive power divider 200 of the voltage management system 50 accumulates system power difference information (S820). That is, the second integration controller 240 of the reactive power divider 200 receives the systematic difference information indicating the difference of the system reactive power output information of all the generators 450. [ The second integration controller 240 stores the received grid output difference information.

The reactive power divider 200 of the voltage management system 50 generates the voltage control signal by correcting the system output difference information (S830). That is, the second integration controller 240 of the reactive power divider 200 outputs the system output difference information such that the voltage comparison information becomes 0 or the system output difference information indicating the difference of the system reactive power output information of all the generators 450 is 0 The difference information is corrected and limited to the voltage range information to generate the voltage control signal. Thereafter, the automatic voltage controller controls the terminal full-up of the generator 450 using the voltage control signal.

The results of application of the voltage management method according to an embodiment of the present invention will be described with reference to FIG.

9 is a graph showing bus voltage information according to an embodiment of the present invention.

Referring to FIG. 9, (a) is a graph showing the bus voltage information before the generator 450 is controlled using the voltage management system. The bus voltage information is outputted as 1.044 pu as shown in reference numeral 910.

(b) is a graph showing the bus voltage information when the automatic voltage regulator 390 and the generator 450 are controlled using the conventional voltage management system when the automatic voltage regulator 390 is manually operated. The bus voltage information falls from 1.044 pu to 1.029 pu as shown in reference numeral 920. As a result, it can be determined that a very large transient phenomenon occurs.

when the automatic voltage regulator 390 and the generator 450 are controlled using the voltage management system 50 according to an embodiment of the present invention when the automatic voltage regulator 390 is manually operated, Bus line voltage information is shown graphically. it can be determined that the bus voltage information falls from 1.044 pu to 1.043 pu as shown in reference numeral 930 of FIG. it can be determined that the bus voltage information moves between approximately 1.0435 pu and 1.0445 pu as indicated by reference numeral 940 in FIG. In addition, as shown in reference numeral 950 of FIG. 10 (e), the bus voltage information only outputs about 1.0443 pu and outputs 1.044 pu in most cases. the bus voltage information outputs almost 1.044 pu as indicated by reference numeral 960 of FIG.

Accordingly, as shown in (c) to (f), it can be determined that the bus voltage information falls below 0.001 pu, so that a slight transient occurs. In addition, it can be judged that the bus line voltage information is stably outputted at 1.044pu from (c) to (f).

Accordingly, when the automatic voltage controller is manually operated, the voltage management system 50 according to the present invention can output the voltage of the representative bus line by controlling the generator 450 similarly to the case where the automatic voltage controller is automatically operated.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be understood that the invention may be varied and varied without departing from the scope of the invention.

50: Voltage management system
100: Fast-response voltage controller
110: Signal processor
140, 160, 230, and 250:
150:
170, 240: Integral control unit
180: Sample holder
200: reactive power distributor
210 and 220:
330: Output device
390: Automatic voltage regulator
450: generator

Claims (32)

A voltage management system for managing a voltage of a power system,
A reactive voltage controller for generating reactive power output ratio information using maximum and minimum power ratio information and grid reactive power output information; And
A reactive power divider that generates reactive power reference information using the reactive power output ratio information and the maximum and minimum output ratio information and generates voltage control information using the reactive power reference information and the system reactive power output information, Including a voltage management system.
The method according to claim 1,
Wherein the quick response voltage controller comprises:
And generates reactive power correction information by calculating the maximum and minimum power ratio information and the grid reactive power output information, and generates the reactive power output ratio information by correcting the reactive power correction information.
3. The method of claim 2,
The reactive power distributor comprises:
Generates reactive power reference information by calculating the reactive power output ratio information and the maximum and minimum output ratio information to generate voltage correction information by calculating the reactive power reference information and the grid reactive power output information, And corrects the correction information to generate the voltage control information.
The method according to claim 1,
Wherein the quick response voltage controller comprises:
Generates the calculated power ratio information by comparing the maximum and minimum power ratio information and the reference power ratio information, compares the calculated power ratio information with the grid reactive power output information, and generates reactive power correction information according to the comparison result And generates the reactive power output ratio information by correcting the reactive power correction information.
5. The method of claim 4,
Wherein the quick response voltage controller comprises:
And generates output ratio difference information by comparing the reactive power output ratio information with reference output ratio information, and transmits the output ratio difference information to the reactive power distributor.
6. The method of claim 5,
The reactive power distributor comprises:
Generates the reactive power reference information by calculating the maximum and minimum power ratio information and the output ratio difference information, and calculates the reactive power reference information, the system reactive power output information, and the reactive power average information to generate voltage correction information And generates the voltage control information by correcting the voltage correction information.
The method according to claim 1,
A voltage input unit for receiving the voltage control information when the power system is automatically operated from the reactive power distributor and generating voltage input information using the voltage control information, the terminal voltage information, and the system reference voltage information; And
Further comprising an automatic voltage regulator for controlling the power system using the voltage input information.
The method according to claim 1,
And an output device for outputting the voltage control information.
A quick-response voltage controller for managing a voltage of a power system,
A signal processor for generating reactive power correction information using maximum and minimum power ratio information and system reactive power output information; And
And an integral control unit for correcting the reactive power correction information to generate reactive power output ratio information.
10. The method of claim 9,
The signal processing unit,
And the reactive power correction information is generated by dividing the maximum and minimum power ratio information by the system reactive power output information.
11. The method of claim 10,
Wherein the integral control unit includes:
Wherein the reactive power correction information is corrected and limited to the operation range information of the power system to generate the reactive power output ratio information.
10. The method of claim 9,
The signal processing unit,
A ratio arithmetic unit for multiplying the maximum and minimum output ratio information by reference output ratio information to generate calculation output ratio information;
A comparison unit for comparing the calculation output ratio information with the grid reactive power output information and generating reactive power correction information according to the comparison result; And
And a signal generator for generating a signal according to the reactive power correction information.
13. The method of claim 12,
Wherein the integral control unit includes:
And the voltage comparison information is corrected to limit the operation range information of the power system to generate the reactive power output ratio information.
14. The method of claim 13,
Further comprising a sample holder for comparing the reactive power output ratio information with reference output ratio information to generate output ratio difference information.
10. The method of claim 9,
Further comprising a first switch unit formed between the signal processing unit and the integral control unit and being turned on when the power system is manually operated and turned off when the power system is automatically operated or updated, Controller.
10. The method of claim 9,
Further comprising a voltage calculator for comparing the bus voltage information with the voltage reference information to generate voltage comparison information.
17. The method of claim 16,
Further comprising a second switch unit formed between the voltage operation unit and the integral control unit, the second switch unit being turned on when the power system is automatically operated or updated and turned off when the power system is manually operated.
1. A reactive power distributor for managing a voltage of a power system,
A first power calculator for generating reactive power reference information using the reactive power output ratio information or the output ratio difference information and the maximum and minimum output ratio information;
A second power calculator for generating voltage correction information using the reactive power reference information and the system reactive power output information; And
And an integral control unit for correcting the voltage correction information to generate voltage control information.
19. The method of claim 18,
Wherein the first power calculation unit comprises:
And generates the reactive power reference information by multiplying the reactive power output ratio information by the maximum and minimum output ratio information.
20. The method of claim 19,
Wherein the second power calculator comprises:
And generates the voltage correction information by subtracting the grid reactive power output information from the reactive power reference information.
19. The method of claim 18,
Wherein the first power calculation unit comprises:
And generates the reactive power reference information by multiplying the output ratio difference information by the maximum and minimum power ratio information.
22. The method of claim 21,
Wherein the second power calculator comprises:
And generates the voltage correction information by subtracting the grid reactive power output information from the reactive power operation information to generate the voltage correction information, wherein the voltage correction information is generated by adding the reactive power reference information and the reactive power average information to generate reactive power operation information, Power distributor.
19. The method of claim 18,
Wherein the integral control unit includes:
Wherein the voltage correction information is corrected and limited to voltage range information of the power system to generate the voltage control information.
1. A voltage management method for managing a voltage of a power system by a voltage management system including a reactive voltage controller and a reactive power divider,
(a) generating a reactive power output ratio information or output ratio difference information using the maximum and minimum output ratio information and the grid reactive power output information;
(b) transmitting the reactive power output ratio information or the output ratio difference information to the reactive power distributor;
(c) generating the reactive power reference information by using the reactive power output ratio information or the output ratio difference information, the maximum and minimum output ratio information; And
(d) generating the voltage control information using the reactive power reference information and the system reactive power output information by the reactive power distributor.
25. The method of claim 24,
The step (a)
Generating a reactive power correction information by dividing the maximum and minimum power ratio information in the system reactive power output information by the quick reactive voltage controller; And
And generating the reactive power output ratio information by limiting the reactive power correction information to the operating range information of the power system by the quick reactive voltage controller.
26. The method of claim 25,
The step (b)
And the reactive voltage controller transmits the reactive power output ratio information to the reactive power distributor.
27. The method of claim 26,
The step (c)
Wherein the reactive power divider multiplies the reactive power output ratio information by the maximum and minimum output ratio information to generate the reactive power reference information.
28. The method of claim 27,
The step (d)
The reactive power divider subtracts the reactive power output information from the reactive power reference information to generate voltage correction information; And
And the reactive power divider corrects the voltage correction information and limits the voltage correction information to voltage range information of the power system to generate the voltage control information.
25. The method of claim 24,
The step (a)
Wherein the quick response voltage controller multiplies the maximum and minimum output ratio information by the reference output ratio information to generate calculation output ratio information;
Comparing the calculated output ratio information with the system reactive power output information, and generating reactive power correction information according to a result of the comparison;
Generating the reactive power output ratio information by limiting the operation range information of the power system by correcting the voltage comparison information by the quick reactive voltage controller; And
And the quick response voltage controller compares the reactive power output ratio information with the reference output ratio information to generate output ratio difference information.
30. The method of claim 29,
The step (b)
And the step-up voltage controller transmits the output ratio difference information to the reactive power distributor.
31. The method of claim 30,
The step (c)
Wherein the reactive power divider multiplies the output ratio difference information by the maximum and minimum output ratio information to generate the reactive power reference information.
32. The method of claim 31,
The step (d)
Generating reactive power operation information by adding the reactive power reference information and the reactive power average information to the reactive power divider;
The reactive power divider subtracting the system reactive power output information from the reactive power operation information to generate voltage correction information; And
And the reactive power divider corrects the voltage correction information and limits the voltage correction information to voltage range information of the power system to generate the voltage control information.

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