KR100863672B1 - Training simulator of distribution automation system and drivig method there of - Google Patents

Abstract

The present invention provides a distribution automation training system and a method of driving the same, which testers and test subjects of the Korea Electric Power Plant can train using a real-time distribution system simulator similar to the actual distribution system before operating the actual distribution automation system. .

The driving method of the distribution automation training system according to the present invention includes the steps of: a tester generating a virtual failure signal generated in an actual distribution system through a real-time distribution system simulator; Converting the virtual failure signal into an input signal of a distribution automation system; Generating a control signal for controlling a failure state of the distribution automation system by the virtual failure signal to a normal state; And converting the control signal into an input signal of the real-time power distribution system simulator.

Description

TRAINING SIMULATOR OF DISTRIBUTION AUTOMATION SYSTEM AND DRIVIG METHOD THERE OF

1 is a block diagram showing a conventional distribution automation education and training system.

2 is a block diagram illustrating a distribution automation education and training system according to the present invention.

3 is a block diagram illustrating in detail a method of driving a power distribution automation education and training system according to an exemplary embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: distribution automation education system 110: real-time distribution system simulator 120: distribution automation system 130: signal conditioning device

146: distribution automation central control system 148: recloser

152: first terminal device 154: first automation switch

162: second terminal device 164: second automation switch

172,174: Amplifier

The present invention relates to a distribution automation education system and a method of driving the same, and in particular, testers and test subjects of the Korea Electric Power Corporation are trained using a real-time distribution system simulator similar to the actual distribution system before operating the actual distribution automation system. The invention relates to a distribution automation education system that can be operated and a method of driving the same.

Currently, the Korea Electric Power Corporation's TDAS has been distributed since 1999, and has been installed in 67 establishments as of 2006, and 1,295 units of automation switchgear have been supplied to establishments nationwide. It is expected to be distributed to all distribution centers in the country in the future, and automatic switchgear plans to automate about 50% of all switchgear.

However, KEPCO installed a laboratory-scale distribution automation system at the central education center for the education and training of distribution facilities, and is intended for remote monitoring and control during training or simply using the automation system. There is no training for operators' response to system accidents.

1 is a view briefly showing a system for teaching a tester and a test subject of the Korea Electric Power Corporation. The distribution automation education system simply installs a few first and second switchgear (54, 64) and recloser (48) installed in the distribution automation system server line, and the test subject gives the device control command and receives the control result. It was only a training of system operation. Accordingly, it is a training system that can not perform any training according to the change of the actual distribution system situation.

Accordingly, the technical problem to be achieved by the present invention is a distribution automation education system that can be trained by the tester and test subjects of the Korea Electric Power Plant using a real-time distribution system simulator similar to the actual distribution system before operating the actual distribution automation system and It is to provide a driving method thereof.

In order to achieve the above technical problem, a method of driving a distribution automation training system according to the present invention includes the steps of a tester generating a virtual failure signal generated in the actual distribution system through a real-time distribution system simulator; Converting the virtual failure signal into an input signal of a distribution automation system; Generating a control signal for controlling a failure state of the distribution automation system by the virtual failure signal to a normal state; And converting the control signal into an input signal of the real-time power distribution system simulator.

Here, the virtual failure signal is characterized in that it can be generated by a signal such as a one-line ground fault and three-line short fault.

In addition, the input signal of the power distribution automation system is characterized in that the analog current / voltage signal.

Meanwhile, the test subject generates the control signal through a man-machine interface.

The input signal of the real-time power distribution system simulator is a digital signal.

In order to achieve the above technical problem, the distribution automation system according to the present invention includes a real-time distribution system simulator for generating a virtual failure signal of a failure state occurring in the actual distribution system; A distribution automation system for generating a control signal for adjusting the virtual failure signal to a normal state and supplying a control signal to the real-time distribution system simulator; It characterized in that it comprises a signal conditioning device for converting the signals of the real-time distribution system simulator and the distribution automation system according to each input signal.

Here, the signal conditioning apparatus is characterized in that the input signal of the real-time power distribution system simulator to adjust the level of the signal as a digital signal, the input signal of the power distribution automation system as an analog voltage / current signal.

The distribution automation system may include a recloser that protects the distribution system; First and second automatic switchgears for switching according to the fault condition and the normal state; First and second terminal devices for providing the input signals of the fault state and the normal state according to the input signals of the first and second automation switches; And a distribution automation central control system for generating the control signal for adjusting to the steady state.

Meanwhile, the test subject generates the control signal through a man-machine interface.

Technical objects and features of the present invention in addition to the above technical problem will become apparent through the description of the embodiments with reference to the accompanying drawings. Hereinafter, exemplary embodiments will be described with reference to the accompanying drawings.

2 is a block diagram showing a distribution automation training system according to the present invention.

The distribution automation training system 100 shown in FIG. 2 generates a real-time distribution system simulator 110 for generating a virtual failure signal generated in an actual distribution system, and generates a control signal for adjusting to a normal state according to the virtual failure signal. It includes a distribution automation system 120 for supplying control signals to the real-time power distribution system simulator 110, and a signal conditioning device 130 for converting the signals of the real-time power distribution system simulator 110 and the power distribution automation system 120. .

The real-time power distribution system simulator 110 generates a virtual failure signal that may occur due to dynamic characteristics and transients in an actual power distribution system and supplies it to the power distribution automation system 120. In detail, the real-time power distribution system simulator 110 may include a virtual failure signal of the first and second terminal devices 152 and 162, the first and second automation switches 154 and 164 included in the power distribution automation system 120, and the recloser. 148, to each of the distribution automation central control unit 146 to simulate any failure condition. Here, the virtual failure signal includes signals such as voltage, current, failure, and the like. In addition, the real-time power distribution system simulator can make fault conditions such as one-wire ground fault and three-wire short fault at any position or duration of failure. Meanwhile, the real-time power distribution system simulator 110 receives a control signal through the power distribution automation system 120.

The distribution automation system 120 generates a control signal capable of detecting a failure and adjusting it to a normal state when a virtual failure occurs in the real-time distribution system simulator 110. Here, the distribution automation system 120 includes a recloser 148, first and second terminal devices 152 and 162, first and second automation switches 154 and 164, and a distribution automation central control device 146.

The recloser 148 is a protection device that protects the power distribution line. Specifically, by detecting the current flowing in the distribution line, if the current flows over a certain current, it is determined that an abnormality has occurred in the line, and thus disconnects the line, and immediately connects the line.

The first and second terminal devices 152 and 162 match the virtual failure signal to the input signals of the first and second automation switches 154 and 164 when any failure occurs in the real-time distribution system simulator 110. (152, 162). In other words, the first and second terminal devices 152 and 162 serve as providers to supply the first and second automation switches 154 and 164 according to a signal of a state. The first and second automation switches 154 and 164 serve to switch the opening and closing of the line according to the signals provided to the first and second terminal devices 152 and 162.

In addition, the first and second terminal devices 152 and 162 transmit control signals corresponding to failure states of the first and second automation switches 154 and 164 in the distribution automation central control system 146. To (154,164). On the other hand, when the device becomes not only the first and second terminal devices 152 and 162 and the recloser 148, but also a multi-circuit breaker or a newly improved fault indicator which is currently being developed and planned to be installed on site, the device is connected to a simulation system of such a device. An interlocking test similar to

The distribution automation central control system 146 is a common control device that performs logical operations for sequentially reading and controlling according to the signals supplied from each device. In detail, the distribution automation control system 146 adjusts an arbitrary virtual failure signal according to each of the first and second automation switches 154 and 164 and the recloser 148 to control the first and second control signals. The second automation switches 154 and 164 are supplied to the recloser 148. Here, the distribution automation central control system 146 is a front end processing device 144 that performs tasks such as receiving and transmitting signals, error detection and correction, and a distribution automation server 142 supplying control signals of the received signals. It includes.

On the other hand, the distribution automation server 142 is a man-machine interface for the test subject to identify any failure state of each of the first and second automation switches 154 and 164 and the recloser 148 and supply control signals accordingly. (MMI).

The signal conditioning apparatus 130 adjusts signal levels of analog voltage / current and digital input / output between the real-time distribution system simulator 110 and the distribution automation system devices. In detail, the signal conditioning apparatus 130 adjusts and supplies a signal level supplied from the real-time distribution system simulator 110 to devices of the distribution automation system 120 according to an input signal. In addition, the signal conditioning apparatus 130 adjusts the signal level according to the input signal of the real-time distribution system simulator 110 based on the signal supplied from the device of the power distribution automation system 120.

3 is a block diagram illustrating in detail a driving method of a distribution automation training system according to an exemplary embodiment of the present invention.

The driving method of the distribution automation training system 100 according to an embodiment of the present invention includes the steps of a tester generating a virtual failure signal generated in an actual distribution system through a real-time distribution system simulator 110 and distributing the virtual failure signal. Converting the devices of the automation system 120 according to a signal, generating a control signal by adjusting a virtual failure signal to a normal state through the power distribution automation system 120, and converting the control signal into a real-time power distribution system simulator ( Converting according to the signal of 110), and continuously converting any position or failure with respect to the failure situation.

Specifically, the tester simulates any failures that may occur due to dynamic characteristics and transients in the actual distribution system through the real-time distribution system simulator 110 and outputs a virtual failure signal accordingly. In this case, the virtual failure signal is supplied to the signal conditioning device 130 to be supplied to the first and second terminal devices 152 and 162 and the recloser 148 included in the distribution automation system 120 in real time. Here, the virtual failure signal outputs the voltage and current signals of the distribution system in real time.

Next, the virtual failure signal supplied to the signal conditioning apparatus 130 is converted into a signal that can be supplied to the distribution automation system 120. Specifically, the virtual failure signal simulating any failure in the real-time distribution system simulator 110 is supplied to the amplifiers 172, 174 as analog voltage / current signals 170, 176, and the first and second terminal devices through the amplifiers 172, 174. 152, 162, and the recloser 148. That is, a voltage / current signal is supplied in three phases to each of the first and second terminal devices 152 and 162 and the recloser 148 included in the distribution automation system 120. In addition, a failure state of each of the first and second terminal devices 152 and 162 and the recloser 148 connected to the first and second automation switches 154 and 164 is supplied to the distribution automation central control system 146.

Meanwhile, the first terminal device 152 adjusts the input signal of the first automation switch 154 connected to the first terminal device 152 to supply an analog voltage / current which is a virtual failure signal. The second terminal device 162 adjusts the input signal of the second automation switch 164 connected to the second terminal device 162 to supply an analog voltage / current which is a virtual failure signal.

Next, the distribution automation central control system 146 outputs a control signal for adjusting the failure state of each of the first and second terminal devices 152 and 162 and the recloser 148 to a normal state. Specifically, the failure status of each of the devices input to the distribution automation central control system 146 is displayed through the man-machine interface (MMI) so that the test subject can monitor. The test subject generates a control signal according to a failure state of the first and second terminal devices 152 and 162 and the recloser 148 through the man-machine interface MMI, and then switches the switch according to the control signal.

Next, the control signals of each of the first and second terminal devices 152 and 162 and the recloser 148 are converted into signals that can be supplied to the real-time distribution system simulator 110 by the signal conditioning apparatus 130. Specifically, the signals of the states of the first and second terminal devices 152 and 162 and the recloser 148 according to the control signals are converted into digital signals and supplied to the real-time distribution system simulator 110. Therefore, the investigator can determine whether the test result was shown through the test subject. On the other hand, the tester can implement various failure situations through the above-described repetitive steps.

This training system simulates various systems using the flexible system simulation method of the real-time distribution system simulator, and trains and tests them in connection with the distribution automation system. It can also be used for training, helping the distribution system operator to operate the system, reducing various malfunctions caused by the operation, and testing for the occurrence of failures that cannot be done directly in the real system, the bidirectional recloser under development, and the independent operation of distributed power supply. And systematic impact analysis.

As described above, the distribution automation training system and its driving method according to the present invention can be applied to the real-time distribution system simulator, switchgear, terminal device, and reassembly for failures such as 1-line ground fault and 3-wire short circuit fault occurring in the actual system. Accurate training can be achieved by using closures and signal conditioning devices. You can also learn how to operate these devices. Accordingly, the power distribution system operator's ability to respond to various power distribution system operation conditions can be enhanced to enable efficient and safe operation of the distribution automation system, thereby increasing the reliability of the distribution system.

In addition, the present invention can be used in the development of the distributor and the distribution automation software through the performance verification through simulation system interlock test of the automation distributor. In addition, the present invention can be applied to the operation of the distribution automation system and the performance test of the new distribution machine when the distribution system of various distributed power sources, such as photovoltaic and wind power generation, which are actively installed in the distribution system.

Although the detailed description of the present invention described above has been described with reference to a preferred embodiment of the present invention, those skilled in the art or those skilled in the art, those skilled in the art, described in the claims below It will be understood that various modifications and changes can be made in the present invention without departing from the spirit and scope of the invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification but should be defined by the claims.

Claims (9)

A tester generating a virtual failure signal generated in an actual distribution system through a real-time distribution system simulator; Converting the virtual failure signal into an input signal of a distribution automation system; Generating a control signal for controlling a failure state of the distribution automation system by the virtual failure signal to a normal state; And converting the control signal into an input signal of the real-time distribution system simulator. The method of claim 1, The virtual failure signal may be generated by a signal such as a 1-line ground fault or a 3-wire short circuit fault. The method of claim 1, The input signal of the power distribution automation system is a drive method of the power distribution automation education system, characterized in that the analog current / voltage signal. The method of claim 1, And the test subject generates the control signal through a man-machine interface. The method of claim 1, The input signal of the real-time distribution system simulator is a driving method of a distribution automation education system, characterized in that the digital signal. A real-time distribution system simulator for generating a virtual failure signal of a failure state occurring in an actual distribution system; A distribution automation system for generating a control signal for adjusting the virtual failure signal to a normal state and supplying a control signal to the real-time distribution system simulator; Distribution automation education system comprising a signal conditioning device for converting the signals of the real-time distribution system simulator and the distribution automation system according to each input signal. The method of claim 6, The signal conditioning apparatus is a distribution automation education system, characterized in that the input signal of the real-time power distribution system simulator is a digital signal, the input signal of the distribution automation system to adjust the level of the signal as an analog voltage / current signal. The method of claim 6, The distribution automation system A recloser protecting the distribution system; First and second automatic switchgears for switching according to the fault condition and the normal state; First and second terminal devices for providing the input signals of the fault state and the normal state according to the input signals of the first and second automation switches; And a distribution automation central control system for generating the control signal for adjusting to the normal state. The method of claim 8, A distribution automation education system, wherein a test subject generates the control signal through a man-machine interface.

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