KR101113510B1 - Diagnosis control system for transformer - Google Patents

Abstract

According to the present invention, in the diagnostic control system for a transformer, at least one sensor means for measuring the state of the transformer is installed inside or outside the transformer, and is installed and input to at least one control device of the transformer At least one driving means for controlling driving of each control device according to a control signal, at least one input / output for collecting and outputting data measured by the sensor means, and transferring a control signal input to each driving means; Intelligent report that analyzes the state of the transformer on the basis of an I / O module and data input through each input / output module, and outputs a control signal for controlling the driving means of the transformer according to the analyzed state Diagnostic control systems for transformers with relays (field IEDs) can be provided. All.

Transformer, diagnostic control, transformer analysis, manual control, automatic control

Description

Diagnostic control system for transformers {DIAGNOSIS CONTROL SYSTEM FOR TRANSFORMER}

The proposed embodiments of the present invention relate to a diagnostic control system for a transformer that analyzes, monitors and controls the condition of the transformer.

When the insulation breakdown with an arc occurs inside the transformer, the internal pressure of the transformer increases rapidly because gas generated by insulation carbonization and insulation oil decomposition is generated. This pressure rise can lead to transformer failure. Accordingly, a diagnostic device such as an impact pressure relay is installed inside the transformer to detect such an abnormal pressure rise and to disconnect the transformer from the track. In order to efficiently process the information on these mechanical protection devices, it is very important to digitize the power equipment.

 In the case of transformers, the spillover effect of accidents is very large, and the number of transformers that are difficult to operate due to high age transformers or overload are increasing. Therefore, the transformer diagnosis and control system is necessary to monitor the transformer in operation at all times by using the transformer monitoring, diagnostic sensor technology and IT to determine the necessity of precise diagnosis, to predict the life of the transformer, and to determine the transformer operation ability in case of overload. It can be called an enemy.

Conventional diagnostic equipment for transformer failure is installed in the transformer, to monitor the status of the transformer or diagnostics for malfunction. In addition, the diagnostic apparatus diagnoses a failure of a plurality of transformers by interworking with an external system or a terminal.

However, the conventional diagnostic apparatus may be difficult to grasp or diagnose all the states of the transformer only by a monitoring function or an interworking function with an external system.

In particular, when the conventional diagnostic apparatus does not include a local control function in the apparatus, it may not be precise to control the transformer in an external system or terminal.

Embodiments of the present invention provide a diagnostic control system for a transformer to install a plurality of sensor means and driving means in the transformer, to diagnose the state of the transformer and to control the state of the transformer through the control of the drive means.

In addition, embodiments of the present invention is provided with a diagnostic control system for a transformer for analyzing the state of the transformer by a plurality of analysis items.

In addition, embodiments of the present invention is provided with a diagnostic control system for a transformer to enable the control of the transformer in accordance with the control mode set by the user.

According to an aspect of the present invention, in the diagnostic control system for a transformer, at least one sensor means for measuring the state of the transformer is installed inside or outside the transformer and at least one control unit of the transformer At least one driving means for controlling the driving of each control unit according to an input control signal, at least one of collecting and outputting data measured by the sensor means, and transmitting the control signal input to each of the driving means; Intelligent to analyze at least one analysis item of the transformer based on the input and output module and the data input from the input and output module, and outputs a control signal for controlling the at least one drive means in accordance with the analysis result of the analysis item For transformers, including reporting relays (field IEDs) Provide a diagnostic control system.

In this case, the analysis item may be characterized in that it comprises at least one or more of the temperature analysis, analysis of the OLTC device, cooling device analysis, gas analysis, abnormal analysis.

The intelligent protection relay may further include a data storage configured to store at least one analysis item, at least one control mode for control of each analysis item, and data based on data measured by the respective sensor means. And an algorithm module for analyzing the state of the transformer and controlling the driving means of the transformer in a control mode according to the analysis item according to the analyzed state.

The control mode may include at least one of an auto mode indicating automatic performance of each analysis item, a manual mode indicating automatic performance according to the situation of each analysis item, and a user mode indicating manual control of a user of each analysis item. It may be characterized by including.

According to the present invention, by real-time monitoring, diagnosis, and control of the ultra-high voltage power transformer, it is possible to predict an abnormality detection and facility management of the transformer, and it may be possible to expect economic savings through preliminary measures for the abnormal facility. It also has its own HMI, which can replace the existing local panel, and can check and control various states of transformers in the field as well as remotely.

In addition, it is possible to cope with existing hard wiring to a single communication line, minimizing cost and manpower time.

In addition, based on the data obtained from the various monitoring sensors and protective relays of the transformer, the transformer in operation is always monitored to determine the need for rough inspection or precise diagnosis, and the transformer is operated in an optimal state through the control function. By enabling this, it is possible to secure high reliability and reduce maintenance costs of the transformer. In addition, the monitoring and diagnostic control system of the transformer can check and control all the status information of the transformer in the field, and it is located at the maintenance base using the existing wide area network, and the transformer operation status and the monitoring diagnostic information of the remote site are needed as needed. I can access it.

 BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. In describing the present invention, when it is determined that detailed descriptions of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terminology used herein is a term used to properly express a preferred embodiment of the present invention, which may vary according to a user, an operator's intention, or a custom in the field to which the present invention belongs. Therefore, the definitions of the terms should be made based on the contents throughout the specification.

1 and 2 are views showing the configuration of a monitoring diagnostic control system according to an embodiment of the present invention.

Referring to Figure 1, the monitoring diagnostic control system 200 is connected to the transformer 100, the sensor means 210, the drive means 220, the I / O Module 230 and the field IED (Intelligent Electronic Device) 240) and field human machine interaction (HMI) 250.

The sensor means 210 is installed inside or outside the transformer 100 to measure the state of the transformer 100.

To this end, the sensor means 210 is a plurality of measuring and protective instruments for voltage, current, temperature, pressure (for example, pressure relief valve, shock pressure relay, Buchholz relay, gas detection relay, oil level meter, step changer protection relay, etc. ) Can be implemented. Then, the data measured by the sensor means 210 is transmitted to the field IED 240 through the I / O Module 230.

The driving means 220 controls the driving of each control unit according to a control signal installed and input to at least one or more control units (eg, power supply units) of the transformer 100.

The I / O module 230 corresponds to a predetermined input / output module, collects and outputs data measured by the sensor means 210, and transmits a control signal input to the driving means 220.

In other words, the I / O module 230 collects AI (Analog Input) and DI (Digital Intput) data output from the sensor means 210 and delivers the data to the field IED 240 and from the field IED 240. The control signal is transmitted to the driving means 220 to interlock. The I / O module 230, together with the sensor means 210 and the driving means 220, can be expanded according to the number and type of data.

The field IED 240 is an intelligent reporting relay, which analyzes at least one analysis item of the transformer and outputs a control signal for controlling the at least one driving means according to the analysis result of the analysis item.

For this purpose, the field IED 240 may include multiple configurations 241 to 244 as shown in FIG. 2.

The field IED 240 includes a data processor 241, a data storage unit 242, an algorithm module 243, and a communication processor 244.

The data processor 241 collects data input from each I / O module 230 and stores the data input in the data storage unit 242 as necessary for recording.

The data storage unit 242 may be configured as a read only memory (ROM), a flash memory, a random access memory (RAM), and the like, and data and control necessary for driving the field IED 240. Save the procedure. In particular, the data storage unit 242 stores at least one analysis item and at least one control mode for automatic control of each analysis item.

In this case, the analysis item may include at least one or more of the temperature analysis, LTC analysis, cooling device analysis, gas analysis, abnormal analysis.

In addition, the control mode is the auto mode indicating the automatic performance mode for each analysis item of the transformer 100, the manual mode indicating the automatic performance mode according to the situation for each analysis item, the user indicating the manual control of the user for each analysis item At least one of the modes may be included.

The algorithm module 243 analyzes the state of the transformer according to the analysis item based on the data measured by each sensor means 210, and operates the driving means 220 in a preset control mode according to the analyzed state. To control.

In this case, the preset control mode may be set in real time through the screen window provided by the algorithm module 243 (the screen windows 10, 20, 30, and 40 shown in FIGS. 3 to 6).

To this end, the algorithm module 243 uses the temperature analysis control module 243a, the LTC analysis control module 243b, the cooling device analysis control module 243c, the gas analysis control module 243d, and the abnormality analysis control module 243e. Include.

The temperature analysis control module 243a is based on data input from a sensor for temperature measurement among the plurality of sensor means 210, and the state of the transformer (for example, the oil temperature, the winding temperature, the ambient temperature, the highest temperature of the upper or lower portion), and the highest. Hot-Spot Temperature, Overload Capacity, Load Rate, Life Expectancy, and Degradation Rate) are analyzed and output.

Referring to FIG. 3, the screen window 10 is an example of the screen window provided by the temperature analysis control module 243a, and includes portions 11, 12, and 13 for displaying a menu, and a state for displaying the phase A temperature state. It may include a display portion 14, and a portion 15 for indicating whether or not the item is displayed. In addition, the temperature analysis control module 243a analyzes the A phase temperature among the plurality of analysis items of the transformer 100, and displays a plurality of state information according to the analyzed A phase temperature on the state display portion 14. In addition, the user may switch to another screen window by using an input through the displayed menu parts 11, 12, 13.

Referring to FIG. 4, the display window 20 is an example of the display window provided by the temperature analysis control module 243a, and displays portions 21 and 22 for displaying a menu and a temperature state through historical trend. The part 23 may include a part 24 and a part 24 indicating whether an item is displayed. At this time, the temperature analysis control module 243a displays the state information of the A phase temperature to be analyzed on the display portion 23 through a graph according to the historical trend.

The LTC analysis control module 243b is based on the data input from the sensor means for measuring the state of the OLTC device in the transformer 100 of the plurality of sensor means 210, the state information of the OLTC device (for example, OLTC Moisture in water, temperature difference with transformer, motor drive current, internal temperature, top position, tank level gauge, protective relay, live oil pressure, degree of failure, power condition, amount of wear and residual operation Etc.) and output it.

In addition, the LTC analysis control module 243b provides a preset control mode (eg, a manual mode indicating an automatic execution mode according to a situation) to perform the control of the driving means 220.

Referring to FIG. 5, the screen window 30 includes portions 31 and 32 for displaying a menu, a display portion 33 for OLTC monitoring, a setting portion 33a for setting a user, and an item display. It may include a portion 34 to indicate whether or not.

Accordingly, the LTC analysis control module 243b displays the analyzed state information of the OLTC device on the display portion 33. The LTC analysis control module 243b switches and sets the control mode according to the input of the setting portion 33a. For example, the LTC analysis control module 243b may switch the control mode of the current analysis item (analysis of the OLTC device) to an auto mode or a manual mode according to a user input. In addition, when the current control mode is the user mode, the LTC analysis control module 243b may control (Raise or low) the operation of the OLTC device according to the user's input.

The cooling device analysis control module 243c analyzes the state information of the cooling device based on data input from the sensor means 210 for analyzing the cooling device among the plurality of sensor means 210, and analyzes the state of the cooling device. Outputs a control signal for controlling the state.

At this time, the state information of the cooling device to be analyzed may be at least one of the driving state of the fan provided in the transformer, motor residual information, operating time.

Referring to FIG. 6, the screen window 40 includes a portion 41, 42, 43 for displaying a menu, a display portion 44 for displaying an analysis of a cooling apparatus, and a portion for indicating whether an item is displayed ( 45).

In particular, the display portion 44 may further include input portions 44a and 44b for setting of the user as well as data display for analysis of the cooling device.

Accordingly, the cooling device analysis control module 243c displays the state information of the cooling device to be analyzed on the display portion 44, and according to the input of the input portion 44a, the control mode according to the cooling device analysis (eg, a manual). Mode) can be switched. In addition, the cooling apparatus analysis control module 243c may control the driving of the cooling apparatus according to the input through the input portion 44b.

The gas analysis control module 243d analyzes the gas state of the transformer based on the data input from the sensor means 210 for gas analysis among the plurality of sensor means 210, and analyzes the gas state of the transformer according to the analyzed gas state. The driving means 220 of the control.

The abnormality analysis control module 243e is based on data input from the sensor means 210 for failure analysis among the plurality of sensor means 210,

On the other hand, the communication processing unit 244 selects and transmits the data necessary for the remote monitoring panel 300 of the data analyzed by the algorithm module 243. In addition, it can be accessed from anywhere by using the existing network network, and it can be possible to process the hard wiring as a communication line to the existing remote monitoring board.

The on-site HMI 250 may provide a display function for a user and may receive a user's request through a predetermined input method (for example, a touch pad method).

The method according to the present invention can be implemented in the form of program instructions that can be executed by various computer means and recorded on a computer readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on the media may be those specially designed and constructed for the purposes of the present invention, or they may be of the kind well-known and available to those having skill in the computer software arts.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

1 and 2 are views showing the configuration of a monitoring diagnostic control system according to an embodiment of the present invention.

3 to 6 show screen examples of the intelligent reporting relay shown in FIG.

<Name of main parts of drawing>

20 to 40: screen window 100: transformer

200: diagnostic control system 210: sensor means

220: drive means 230: I / O Module

240: field IED 241: data processing unit

242: data storage unit 243: algorithm module

243a: temperature analysis control module 243b: LTC analysis control module

243c: Cooling system analysis control module 243d: Gas analysis control module

243e: abnormal analysis control module 244: communication processing unit

250: field HMI 300: remote monitoring panel

400: communication network

Claims (4)

In the diagnostic control system for a transformer, At least one sensor means installed inside or outside the transformer to measure a state of the transformer; At least one driving means installed in at least one control unit of the transformer and controlling driving of each control unit according to an input control signal; At least one input / output module that collects and outputs data measured by the sensor means and transmits a control signal input to each of the driving means; And Intelligent reporting relay (IED for field) that analyzes at least one analysis item of the transformer based on the data input from the input and output module, and outputs a control signal for controlling the at least one drive means according to the analysis result of the analysis item ), The intelligent protection relay A data storage unit for storing at least one analysis item and at least one control mode for controlling each analysis item; And Analyzing the state of the transformer according to the analysis item on the basis of the data measured by the respective sensor means, the control module corresponding to the analysis item according to the analyzed state from one or more control modules of the at least one control mode An algorithm module for executing according to one of the above to control driving means of the transformer, The analysis item is Transformer voltage / current, alarm / trip of each protection instrument, temperature analysis (including winding thermostat calculation, overload capacity calculation, insulation deterioration rate calculation), OLTC device analysis, chiller analysis, gas analysis, fault analysis, trend At least one or more of the analyzes, The one or more control modes At least one or more of an auto mode indicating automatic performance of each analysis item, a manual mode indicating automatic performance according to the situation of each analysis item, and a user mode indicating manual control of a user of each analysis item, The one or more control modules At least one of a temperature analysis control module, LTC analysis control module, cooling device analysis control module, gas analysis control module, abnormal analysis control module, each one of the one or more control modes is set according to the user's selection input Diagnostic control system for transformers. delete delete delete

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