KR20110125579A - A site electricity equipment wrong diagnosis method - Google Patents

Abstract

PURPOSE: An error detection method of field power facilities using a smart terminal is provided to monitor and detect the operation state of the field power facility on real time by receiving an error signal on real time. CONSTITUTION: A local unit(200) receives the state signal of a filed power facility(100) and transmits the state signal. A diagnostic server(400) determines errors by analyzing the state signal through a diagnostic algorithm. A web server(500) detects and monitors the field power facility on the web by connecting the data of the diagnostic server to the web. A smart terminal(600) displays and detect the error of the field power facility by analyzing filed diagnostic data through the diagnostic algorithm of application software.

Description

Fault diagnosis method and fault diagnosis device of on-site power equipment using smart terminal {A site electricity equipment wrong diagnosis method}

The present invention relates to a method and apparatus for diagnosing abnormalities of an on-site power facility using a smart terminal. More specifically, the present invention includes a wireless communication function and a computing function of a smart terminal (also referred to as a 'smartphone and a smart pad'). The present invention relates to a method and apparatus for diagnosing abnormalities of an on-site power facility using a smart terminal that can increase reliability by establishing a system for diagnosing an abnormality of a power facility and taking diagnostic measures regardless of time and place.

Recently, as the industry is highly developed and the dependence on the living environment is increasing, the power consumption is increasing rapidly. Accordingly, the consumer's desire for qualitative development such as supply reliability as well as quantitative development for power supply is increasing.

Accordingly, it is possible to prevent electrical equipment accidents in advance in the on-site power facilities such as power plants or substations, and to recognize alarm signals in advance in case of accidents, to prevent accidents in advance and to respond immediately to accidents. There is a need for conservation techniques.

As an example, in the case of a gas insulated switchgear (GIS), which is a representative high voltage power device using high pressure gas as an insulating medium, GIS has a high insulation strength and a small size, high reliability, and easy maintenance due to sealing. Since it has the advantage, it is widely used in power plants or substations.

However, in the process of manufacturing, installing and using the GIS, conductor projections, spacer cracks, and conductive metal foreign substances may occur. Due to such defects, the electric field concentration phenomenon occurs in the GIS. There is a possibility of reaching, and there is a case of actual breakdown of insulation by metal particles, which causes damage such as unintentional explosion in the field power equipment.

In addition to the GIS, various facilities such as breakers, disconnectors, and taps will be referred to as on-site power facilities.

In most cases, such an accident occurs in a time series pattern other than a sudden accident due to a natural disaster, and if it can be detected by an appropriate method and converted into a signal that can be recognized and interpreted by a manager, Reliability will be improved.

In the case of the conventional diagnostic equipment developed according to this, the administrator carries the diagnostic equipment and directly visits the site, and connects the control device and the portable diagnostic device with a cable to check the data value embedded in the control device on the site. By inputting the measured value of the on-site power equipment into the diagnostic-only program installed in the PC, it determines the abnormality of the power equipment and transmits a text or e-mail in one direction to the administrator's mobile phone to inform the user of the abnormality. It was.

In such a conventional diagnosis method, the administrator must always carry the diagnostic terminal with the visitor directly to the site, and there is a limitation on the type of data that can be checked, and the administrator can set the data value of the site power equipment at any time at any place. There has been a limit to being able to quickly identify and respond promptly to each situation.

The purpose of the present invention is to solve such a problem, and by installing a diagnostic-only app software on the smart terminal, not only the function of notifying via a one-way text or email, but also operating a diagnostic-only program that was previously installed and operated on a PC. The same effect can be expected, and accumulated data and real-time diagnostic data (event, trend data, etc.) and status information (sensor abnormality, communication) through the two-way wireless communication with the local unit and data communication device through the smart terminal Etc.) and 3D shows the abnormality and diagnosis result information through the app software, and also accumulates the partial discharge of the field equipment by analyzing accumulated data and real-time diagnosis data using the diagnosis algorithm included in the app software. Whether, discharge type and abnormal signs anytime, anywhere It is to provide an error diagnosis method and an error diagnosis device of an on-site power facility using a smart terminal that can be known in real time.

This object of the present invention, by receiving a status signal indicating the status of the on-site power equipment and analyzes the received diagnostic data (events, trend data) and status information (sensor abnormality, communication, etc.) error of the on-site power equipment Local unit for determining the presence; According to the state signal and state information analysis, if it is determined in the local unit that an error has occurred in the field power equipment, the diagnosis data and state information are used to determine the size, type, cause of occurrence, and location of the generated error. A data communication device for confirming and transmitting the size, type, cause of occurrence, and location of the identified error to a diagnostic server of a remote monitoring panel and to a smart terminal; The smart terminal according to the present invention includes a smart terminal for performing wireless communication with the data communication device and the local unit, and diagnosing errors in the field power equipment by analyzing diagnostic data and state information using a diagnostic algorithm of Appsoft. It is achieved by the fault diagnosis device of the on-site power equipment.

The object of the present invention is to connect the smart terminal to the local unit and the data communication device, to receive the diagnostic data and status information, and to analyze the data through the diagnostic algorithm and the partial discharge and abnormal signs of the smart terminal liquid crystal display device. Can be achieved through the steps displayed on.

The fault diagnosis method and fault diagnosis device of the on-site power equipment using the smart terminal according to the present invention, through the wireless communication function of the smart terminal, can receive an error signal in real time when an error occurs in the on-site power equipment, By analyzing the site information (diagnosis data, status information) with the installed app software, it is possible to monitor and diagnose the operation status of the on-site power equipment regardless of the place in real time. The timely action is also taken, which makes it possible to carry out abnormal diagnosis of on-site power facilities more efficiently and reliably.

1 is a block diagram of an abnormal diagnosis device of a field power equipment using a smart terminal according to a first embodiment of the present invention
2 is a flowchart illustrating a diagnosis process of a fault diagnosis method of an on-site power facility using a smart terminal according to a first embodiment of the present invention.
3 is a state of the frequency and phase of the on-site power equipment by analyzing the presence or absence of the on-site power equipment included in the local unit 100 on the error display unit 303 by using the app software of the smart terminal of the present invention. Drawing showing example displayed
4 is a view showing an abnormal point of the field power equipment on the display by analyzing the presence or absence of the site power equipment included in the local unit on the error display unit using the app software of the smart terminal of the present invention.

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

1 is a block diagram of an abnormal diagnosis device of the on-site power equipment using a smart terminal according to the first embodiment of the present invention, referring to Figure 1, the abnormal diagnosis device of the on-site power equipment using a smart terminal is a local unit (site Information processing unit), a data communication device 300, a diagnostic server 400, a web server 500, and a smart terminal 600 with embedded app software.

The local unit 200 includes a signal receiver 210, a signal processor 220, a wireless communication unit 230, and a wired communication unit 240.

The on-site power equipment 100 is a variety of power equipment installed in the field, the on-site power equipment 100 may include a circuit breaker, disconnectors, taps, gas insulated switchgear (GIS), but the present embodiment In the following description, only the gas insulated switchgear (GIS) will be described.

When the site power equipment 100 is a gas insulated switchgear, the site power equipment 100 is provided with an external sensor 110 and a built-in sensor 120 for detecting whether the gas insulated switchgear is partially discharged. The detected signal is transmitted to the signal receiver 210 of the local unit 200.

The local unit 200 is an external sensor 110 that is a signal detection sensor of the field power equipment 100, a signal receiver 210 for receiving a signal from the built-in sensor 120 and a signal processor 220 for processing the received signal. ), And a wired communication unit 240 for transmitting and receiving the signal processed by the signal processing unit and the wired communication unit 310 of the data communication device 300 through the optical communication cable and wirelessly transmits and receives with the wireless communication unit 640 of the smart terminal 600 It includes a wireless communication unit 230.

The field signal processed by the signal processor 220 of the local unit 200 is transmitted from the wired communication unit 240 to the diagnostic server 400 through the wired communication unit 310 of the data communication device 300 in a wired manner. At 400, the diagnosis algorithm may be used to determine the presence of an error (partial discharge), and the location of the error may be determined by tracking a sensor in which the error occurs.

The local unit 200 may transmit the collected data to the smart terminal 600 at the remote location through the wireless communication unit 230.

In addition, by connecting to the wireless communication unit 360 of the data communication device 300 through the app software installed in the smart terminal 600, the waveform and equipment state of the event data and trend data stored in the data storage unit 350 You can check and analyze the event data and trend data to diagnose the presence of errors.

In the above description, an error may include various terms such as a malfunction, an abnormality, and a failure of the field power equipment 100. Specifically, the error of the on-site power equipment 100 may include partial discharge, energization abnormality, foreign matter mixing, etc., but in the GIS that is the on-site power equipment 100 of the present embodiment, the partial discharge usually occurs most frequently. Can be seen as.

The local unit 200 may be arranged in a single configuration together with the site power facility 100 installed in the actual site. Or, it may be arranged in a remote configuration in a separate configuration from the on-site power equipment 100.

The wireless communication unit 230 of the local unit 200 may have a built-in function module capable of performing wireless communication such as WiFi or Bluetooth. Specifically, the wireless communication unit 230 may implement the above-described functional module in hardware or software using an application specific integrated circuit (ASIC) or an application.

The data communication device 300 is a wired communication unit 310 for transmitting and receiving data received from the local unit 200 with the diagnostic server 400 and the control unit 320 by wire, and wirelessly transmitting and receiving with the control unit 320. Wireless communication unit 360 for transmitting and receiving to and from the smart terminal 600 with the app software, the input unit 330, the display unit 340, the data storage unit 350, and the control unit 320 for controlling their respective functions It includes.

The data communication device 300 has a function of transmitting and receiving the signal processed data received from the local unit with the smart terminal 600 through the transmission and reception function, the control unit 320, and the wireless communication unit 360 and the diagnostic server 400. .

The wireless communication unit 360 may perform wireless communication with the smart terminal 600 based on the WiFi or Bluetooth protocol. In detail, the wireless communication unit 360 may have a function module capable of performing wireless communication such as WiFi or Bluetooth, similar to the wireless communication unit 230 of the local unit 200 described above.

Specifically, the storage unit 350 may include built-in data of the data communication device 300, data received from the local unit 200, and external devices such as laptops or wired or wirelessly connected to the data communication device. Various data such as data received from a smart phone, a smart pad, and the like can be stored. In detail, the storage 350 may store various data for wired / wireless communication with the web server 500 and the smart terminal 600 at a remote location.

The input unit 330 receives a user's command, and specifically, the input unit 330 may receive a user's command through an operation panel including a toggle switch, a lamp-type switch, and a numeric button.

The display unit 340 may display the state of the local unit 200 installed in the field, the communication state with the data communication device 300, and the like on an LCD window provided in one area of the data communication device 300.

The display unit 340 may include a touch screen function and may also perform an operation of the input unit 330 that receives a user's command.

For example, the display unit 340 displays a state of the local unit 200 installed in the field, and when a user's command to change the state of the local unit 200 is received by the display unit 340. In this case, the received command is transmitted to the controller 320 to be described later.

In the present embodiment, the display unit 340 uses a 4.3 "color TFT touch type.

The diagnostic server 400 analyzes each signal processed data received from the wired communication unit 310 of the data communication apparatus 300 using a diagnostic algorithm to determine whether an error occurs (partial discharge), and determines the generated sensor. Trace the error location. In addition, the diagnostic data stored in the diagnostic server 400 can be viewed on the web through the web server 500.

Web server 500 performs a function to check the diagnostic data on the Internet by connecting the data stored in the diagnostic server 400 with the Internet network.

 The smart terminal 600 includes a display unit 610, a diagnosis unit 620, a control unit 630, and a wireless communication unit 640.

The display unit 610 may display the state of the local unit 200 installed in the field, the communication state with the data communication device 300, and the like on the LCD window. The display unit 610 may include a touch screen function, and may also perform an operation of an input unit (not shown) that receives a user's command.

The diagnostic unit 620 includes app software for on-site power equipment diagnosis and wirelessly receives signal-processed data from the local unit 200 and the data communication device 300 using the app software to perform an algorithm of the app software diagnosis unit. Determine whether there is an abnormality and type of on-site power equipment and show the result through the display unit 610. This is a key function of the on-site power equipment diagnostic device using a smart terminal, the user possessing the smart terminal 600 can check the presence or absence of the error in the on-site power equipment 100 in real time, the on-site power equipment 100 When an error occurs, it can be immediately followed.

In addition, the smart terminal 600 may be equipped with an operating system (OS) for supporting the execution of the above-described app software, voice / data communication, and PC interworking. The operating system of the smart terminal 600 is 'Symbian' developed by the British Symbian, 'WindowsCE' developed by the US Microsoft, or 'Android' developed by the Google, 'Linux' which is distributed and used for free. May be used representatively. In addition, the smart terminal 600 may be mounted (porting) with a Wi-Fi (Wireless Internet Platform for Interoperability) in the middle of the operating system (eg, REX) layer and the application layer of the mobile communication terminal.

2 is a flowchart illustrating a method for diagnosing abnormalities of an on-site power facility using a smart terminal using an abnormal diagnosis device for an on-site power facility using a smart terminal according to a first embodiment of the present invention.

The smart terminal 600 performs the step S1 of attempting to connect to the local unit 200 or the data communication device 300, and when the connection is made, receives the diagnostic data and status information (S2). If the connection is not established, the process returns to the step of attempting to connect again. When the diagnostic data and the status information are received, the step S3 of analyzing the data through the diagnostic algorithm is performed and the display is performed in each type (trend, event, status information) in parallel. After the step S3, it is determined whether or not the partial discharge has occurred, and when NO is returned to the data analysis step (S3) through another diagnostic algorithm, the YES surface displays the partial discharge and abnormal symptoms display step (S4) and ends. As a method, through the data analysis through the algorithm of the app software diagnosis unit of the smart terminal, it can be seen that the diagnosis of the on-site power equipment is made by displaying the abnormal condition and type of the on-site power equipment on the LCD screen of the smart terminal.

3 shows the state of the frequency and phase of the external sensor 110 and the internal sensor 120 included in the local unit 200 on the display unit 610 of the smart terminal 600 of the present invention. This is a diagram showing an example of display of three-dimensional error detection states of frequencies and phases generated in GIS of switchboards on January 11, 2007 in a field facility installed at *** *** in ***, Republic of Korea. It is shown as shown. In FIG. 3, it may be recognized that an error has occurred by recognizing that the pulse value is rapidly increased to 0.7 or more at about 950 MHz, and the error is rapidly raised to 0.5 at a phase of 320 degrees. You will find out. The reason why the frequency and phase are drastically changed is ***, and the user can recognize that the partial discharge is in progress on the GIS, so that the follow-up action of removing the partial discharge can be taken, and the part of the GIS It is possible to prevent damage to the field equipment due to the discharge.

In addition, Figure 4 shows an example showing an abnormal point of the on-site power equipment by analyzing the presence or absence of the on-site power equipment included in the local unit on the LCD using the app software embedded in the smart terminal of the present invention. have. In FIG. 4, the abnormal point is a **** point.

Although the preferred embodiments of the present invention have been illustrated and described above, those skilled in the art to which the present invention pertains should preferably practice the present invention without departing from the spirit and scope of the present invention. Of course, the examples can be changed in various ways. Therefore, various modifications may be made without departing from the spirit of the invention as claimed in the claims, and such modifications should not be individually understood from the technical spirit or outlook of the invention.

The fault diagnosis method and fault diagnosis device of the field power equipment using the smart terminal according to the present invention will be said that it is possible to manufacture and carry out the same products and methods repeatedly in a manufacturing plant for manufacturing general electrical appliances, so the industrial applicability is high. It will be called an invention.

100: field equipment 110: external sensor
120: built-in sensor 200: local unit (= field information processing unit)
210: signal receiver 220: signal processor
230: wireless communication unit 240: wired communication unit
300: data communication device 310: wired communication unit
320: control unit 330: input unit
340: display unit 350: data storage unit
360: wireless communication unit 400: diagnostic server
500: web server 600: smart terminal
610: display 620: diagnostic unit
630: control unit 640: wireless communication unit

Claims (4)

In the abnormal diagnosis device of the field power equipment using the smart terminal 600,
The abnormal diagnosis apparatus of the on-site power equipment using the smart terminal 600 receives a status signal indicating a state of the on-site power equipment and processes the received state signal to process the data communication device 300 and the smart terminal 600. Local unit 200 for transmitting to;
The data communication device 300 transmitting and receiving the signal-processed data to and from the diagnostic terminal 400 and the smart terminal 600, and the status signal through the diagnostic algorithm to determine the occurrence of the error and to determine the location of the sensor Web server 500 for enabling remote monitoring and diagnosis on the web by connecting the diagnostic server 400 and the stored data of the diagnostic server to the web server to the Web and the web;
The smart terminal 600 performing wireless communication with the local unit and the data communication device and diagnosing and displaying an error of the field power facility 100 through a diagnosis algorithm of embedded app software for receiving the received site diagnosis data. Error diagnosis device of the field power equipment using a smart terminal, characterized in that it comprises a The method of claim 1,
The local unit includes a site power equipment 100 and a local unit 200,
The local unit 200 and the external sensor 110 indicating the state of the on-site power equipment 100,
A built-in sensor 120, an external sensor 110 and a signal receiver 210 for receiving a signal received from the built-in sensor 120 and a signal processor 220 for analyzing the received signal;
The wired communication unit 240 for transmitting and receiving the signal processed by the signal processing unit 220 with the wired communication unit 310 of the data communication device 300 and the signal processed by the signal processing unit 220 wirelessly of the smart terminal 600. An abnormality diagnosis apparatus for an on-site power facility using a smart terminal, characterized in that it comprises a wireless communication unit 230 for transmitting and receiving with the communication unit 640. The method of claim 1,
The data communication device 300 includes a wired communication unit 310, a control unit 320, an input unit 330, a display unit 340, a data storage unit 350, a wireless communication unit 360,
The smart terminal 600 is a wireless communication unit 640 for transmitting and receiving a signal from the local unit 200, the data communication device 300,
A diagnosis unit 620 for diagnosing the received signal through a diagnosis algorithm;
A display unit 610 for displaying the error diagnosed from the diagnosis unit 620 in three dimensions;
The abnormal diagnosis device of the field power equipment using a smart terminal, characterized in that it comprises a control unit 630 for controlling each unit through the input control data In the error diagnosis method of the on-site power equipment using a smart terminal,
The abnormal diagnosis method of the on-site power facility using the smart terminal, the wireless communication unit 640 of the smart terminal 600 and the wireless communication unit 360 of the wireless communication unit 230 or data communication device 300 of the local unit 200 Connecting to;
Receiving the diagnostic data and the state reception data of the local unit 200 or the data communication device 300 and receiving the diagnostic data and the state reception data through the control unit 630 of the smart terminal;
The transferred data is to determine whether there is an error of the site power equipment and the location of the error through the diagnostic algorithm of the app software of the smart terminal 600;
On-site power equipment failure diagnosis method using a smart terminal, characterized in that it comprises the step of displaying on the display 610 of the smart terminal

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