KR101994828B1 - Electric power system fault recording system - Google Patents

Abstract

The present invention discloses a power system failure recording system. The power system fault recording system of the present invention is connected to a DSP (Digital Signal Processor) module and a DPS module for detecting a fault in a power system and generating a fault waveform file for the detected fault, ), Receives a fault waveform file when a fault in the power system is detected from the DSP module, stores the received fault waveform file, and requests the DSP module for system monitoring information including current instantaneous information of the power system (Central Processing Unit) module for transmitting the request signal and receiving the system monitoring information corresponding to the first request signal.

Description

[0001] Electric power system fault recording system [0002]

The present invention relates to a fault recording system, and more particularly, to a power system fault recording system that actively stores a fault waveform file by performing power system information transfer in an asynchronous manner.

The conventional power system failure recording apparatus is required to be improved in terms of compatibility and complexity in order to generate information by sending information depending on an application program of a device equipped with a general-purpose operating system (OS) such as Windows, Linux and the like.

1, the conventional power system failure recording apparatus 200 includes a DSP module 210, a CPU module 230, and an output unit 250. [ Here, the DSP module 210 and the CPU module 230 synchronize with each other at predetermined intervals. When the CPU module 230 confirms occurrence of a power system failure through synchronization, the DSP module 210 requests the DSP module 210 to generate a fault waveform file. The DSP module 210 generates a fault waveform file upon request, . The CPU module 230 stores the delivered fault waveform file and controls it to be outputted through the output unit 250.

At this time, since the DSP module 210 and the CPU module 230 transfer information based on the general-purpose OS application program, there is a problem that information can be transferred only when the general-purpose OS application programs are the same, It has a problem in that efficiency is low in that it not only increases the load on the system but also generates a faulty waveform file manually.

Korean Patent Registration No. 10-1452980 (Apr. 14, 2014)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a power system failure recording system and method for increasing compatibility with various heterogeneous systems and reducing the complexity of a system by performing power system information transfer in an asynchronous manner.

In order to achieve the above object, a power system fault recording system according to the present invention comprises: a DSP (Digital Signal Processor) module for detecting a fault in a power system and generating a fault waveform file for the detected fault; And receives the fault waveform file when the power system fault is detected from the DSP module, stores the received fault waveform file, and transmits the fault waveform file to the DSP module A plurality of CPU (Central Processing Unit) modules for transmitting a first request signal for requesting system monitoring information including current instant information and receiving system monitoring information corresponding to the first request signal, A failure detection unit for detecting an error signal of the power system to detect a failure, an FTP-client for transferring the fault waveform file to the CPU module and an HTTP-server (hypertext transfer protocol-server) unit for receiving a first request signal from the CPU module and transmitting system monitoring information corresponding to the first request signal to the CPU module, And a control unit operable to generate the fault waveform file when the fault detecting unit detects a fault in a state of being unsynchronized with the CPU module and to control the generated fault waveform file to be transmitted to the CPU module via the FTP- Wherein the system monitoring information is generated by measuring instantaneous information of at least one of a current, a voltage, a frequency, and an accident state of the power system to generate system monitoring information and stores the generated system monitoring information, Only the current instantaneous information on the current, voltage and frequency requested in the first request signal among the information is searched and detected And a DSP control unit for controlling the detected system monitoring information to be transmitted to the CPU module via the HTTP-server unit, wherein the CPU module is connected to the FTP-client unit, Server unit, which is connected to the HTTP-server unit, transmits the first request signal to the HTTP-server unit, and receives the detected system monitoring message from the HTTP- And a hypertext transfer protocol-client (HTTP-client) unit for receiving the fault waveform file and receiving identification information from the received fault waveform file, When receiving the fault waveform file, when receiving the user input, and when the system monitoring information is required in the calculation process, And a CPU control unit for controlling the first request signal to be transmitted to the DSP module via the HTTP-client when a first event including the case is generated, wherein the DSP control unit controls the plurality of CPU modules The control unit controls the selected CPU module so that the fault waveform file is transferred to the selected CPU module, and transmits the detected system monitoring information to the CPU module that has transmitted the first request signal among the plurality of CPU modules .

The power system failure recording system and method according to the present invention can improve the compatibility with various heterogeneous systems and improve the load caused by the system by performing power system information transfer using an asynchronous method using standard protocols such as FTP and HTTP have.

Also, if a power system failure is detected, a fault waveform file can be actively generated, and a fault waveform file can be stored at a desired point and position using FTP.

1 is a diagram for explaining a conventional power system failure recording apparatus.
2 is a view for explaining a power system failure recording system according to an embodiment of the present invention.
3 is a block diagram illustrating the DSP module of FIG.
4 is a block diagram for explaining the CPU module of FIG.
5 is a flowchart for explaining a power system failure recording method according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals as used in the appended drawings denote like elements, unless indicated otherwise. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather obvious or understandable to those skilled in the art.

2 is a view for explaining a power system failure recording system according to an embodiment of the present invention.

Referring to FIGS. 1 and 2, a power system fault recording system 100 (hereinafter, referred to as a 'fault recording system') performs power system information transfer asynchronously, and when a fault in the power system is detected, And stores it. The fault recording system 100 improves compatibility with various heterogeneous systems by transmitting information in a synchronous method based on a general-purpose OS and by using an asynchronous method using a standard protocol in a conventional fault recording system 200, The system load can be reduced. The fault recording system 100 includes a DSP (Digital Signal Processor) module 10 and a CPU (Central Processing Unit) module 20, and further includes an output unit 31.

The DSP module 10 is formed in a chip form and mounted on the power system unit to detect a failure of the power system unit in real time. The DSP module 10 detects a power system failure and generates a fault waveform file for the detected fault. Here, the fault waveform file includes a record in which detailed waveform information is stored before and after the fault point. The DSP module 10 transmits the generated fault waveform file to be stored in the CPU module 20. At this time, the DSP module 10 can actively store the fault waveform file at a desired point and position.

The DSP module 10 real-time measures system monitoring information including current instantaneous information of the power system. Here, the system monitoring information includes instant information such as current, voltage, frequency, and accident state, and is written in the form of XML (extensible markup language). When the DSP module 10 receives the first request signal for requesting the system monitoring information from the CPU module 20, the DSP module 10 transmits the system monitoring information corresponding to the first request signal to the CPU module 20.

The CPU module 20 may be formed in the form of a chip, and may be formed as a single device with the DSP module 10 and may be mounted on the power system unit or separately from the DSP module 10 and mounted on a separate device. At this time, the CPU module 20 communicates with the DSP module 10 and manages the overall information on the failure and state of the power system. At least one CPU module 20 is communicatively coupled with the DSP module 10 to perform 1: n (n is a natural number of 1 or more) communication. That is, the CPU module 20 may include a first CPU module 21, a second CPU module 22, and an nth CPU module 23. The CPU module 20 receives the fault waveform file and the system monitoring information through communication with the DSP module 10, and outputs the received information through the output unit 30.

The output unit 30 is connected to the CPU module 20 and displays information requested to be output by the CPU module 20. The output unit 30 may be connected to each CPU module 20 when the CPU module 20 has a plurality of CPU modules 20. That is, the first output unit 31 is connected to the first CPU module 21, the second output unit 32 is connected to the second CPU module 22, and the n-th output unit 33 is connected to the nth And is connected to the output unit 23.

Here, when the DSP module 10 and the CPU module 20 are separated from each other, the CPU module 20 may be coupled to the output unit 30 and installed in the user terminal. Here, the user terminal may include a desktop, a laptop, a smart phone, a tablet PC, a handheld PC, and the like.

Meanwhile, the communication network 90 may be established between the DSP module 10 and the CPU module 20 so that communication between the DSP module 10 and the CPU module 20 is performed. Here, the communication network 90 may be a file transfer protocol (FTP) network and a hypertext transfer protocol (HTTP) network, which are standard protocols. In some embodiments, the communication network 90 may be an Internet network, an intranet network, or a mobile communication network.

FIG. 3 is a block diagram for explaining the DSP module of FIG. 2, and FIG. 4 is a block diagram for explaining the CPU module of FIG. 2. Referring to FIG.

Referring to FIGS. 2 to 4, the DSP module 10 and the CPU module 20 perform asynchronous communication with each other using a standard protocol, thereby enhancing compatibility and improving the load of the system.

The DSP module 10 includes a fault detection unit 11, a DSP communication unit 12, and a DSP control unit 13, and further includes a memory unit 14.

The failure detection unit 11 detects an error signal of the power system and detects a failure. The failure detection unit 11 detects an abnormal signal generated when the effective value of the voltage and the current exceeds or falls below a preset reference value.

The DSP communication unit 12 supports FTP and HTTP, which are standard protocols. The DSP communication unit 12 includes a file transfer protocol-client unit 15 and an HTTP-server (hypertext transfer protocol-server) unit 16.

The FTP-client unit 15 transmits the fault waveform file to the CPU module 20 using FTP. In detail, the FTP-client unit 15 can be connected to the FTP-server (file transfer protocol-server) 44 of the CPU module 20 to transmit the fault waveform file. In this case, when there are a plurality of CPU modules 20, the FTP-client unit 15 is connected to all of the FTP-server 44 included in each CPU module 20 so that 1: N (N is a natural number of 2 or more) Thereby enabling communication to be performed.

The HTTP-server unit 16 receives the first request signal from the CPU module 20 using HTTP, and transmits the system monitoring information to the CPU module 20. In detail, the HTTP-server unit 16 is connected to the HTTP-client (hypertext transfer protocol-client) unit 45 of the CPU module 20 to receive the first request signal and to transmit the system monitoring information . In this case, when there are a plurality of CPU modules 20, the HTTP-server unit 16 is connected to the HTTP-client unit 45 included in each CPU module 20 to perform 1: N communication.

The DSP control unit 13 generates a fault waveform file when the fault detection unit 11 detects a fault. Here, the fault waveform file is a large-capacity file having a large capacity. The DSP control unit 13 controls the generated fault waveform file to be transmitted to the CPU module 20 through the FTP-client unit 15. [ That is, the DSP control unit 13 actively controls the transmission of the fault waveform file to the CPU module 20 without being synchronized with the CPU module 20. [

Here, when there are a plurality of CPU modules 20, the DSP control section 13 can select at least one of the plurality of CPU modules and control so that the fault waveform file is transferred to the selected CPU module. For example, the DSP control unit 13 may control to transmit the fault waveform file to all the CPU modules 20, or to control that the fault waveform file is transmitted only to the predetermined CPU module 20. [

When the HTTP-server unit 16 receives the first request signal, the DSP control unit 13 searches for and detects system monitoring information requested in the first request signal. For example, if the first request signal includes information requesting current instant information on the current, voltage, and frequency, the DSP controller 13 searches only for the corresponding information. The DSP control unit 13 controls the detected system monitoring information to be transmitted to the CPU module 20 through the HTTP-server unit 16. [

Here, when there are a plurality of CPU modules 20, the DSP control unit 13 can control that the detected system monitoring information is transmitted only to the CPU module that transmitted the first request signal among the plurality of CPU modules. However, the present invention is not limited to this, and the DSP control unit 13 can control the system monitoring information to be transmitted to a CPU module other than the CPU module that has transmitted the first request signal.

The memory unit 14 stores information required for the operation of the DPS control unit 13. The memory unit 14 may be a low capacity storage medium such as a flash memory type, a multimedia card micro type, a card type memory (for example, SD or XD memory), a random access memory (ROM), an electrically erasable programmable read-only memory (EEPROM), and a programmable read-only memory (PROM). can do.

The CPU module 20 includes a CPU communication unit 41 and a CPU control unit 42 and further includes a storage unit 43. [

The CPU communication unit 41 supports FTP and HTTP, which are standard protocols. The CPU communication unit 41 includes an FTP-server unit 44 and an HTTP-client unit 45, and further includes an external communication unit 46.

The FTP-server unit 44 receives the fault waveform file from the DSP module 10 using FTP. In detail, the FTP-server unit 44 can be connected to the FTP-client unit 15 of the DSP module 10 to receive the fault waveform file. In this case, when there are a plurality of CPU modules 20, the FTP-server section 44 included in each CPU module 20 is connected to the FTP-client section 15 of the DSP module 10, Thereby enabling communication to be performed.

The HTTP-client unit 45 transmits the first request signal to the DSP module 10 using HTTP, and receives the system monitoring information from the DSP module 10. In detail, the HTTP-client unit 45 may be connected to the HTTP-server unit 16 of the DSP module 10 to transmit a first request signal and receive system monitoring information. At this time, when there are a plurality of CPU modules 20, the HTTP-client part 45 included in each CPU module 20 is all connected to the HTTP-server part 16 of the DSP module 10, Thereby enabling communication to be performed.

The external communication unit 46 performs communication with the external terminal. The external communication unit 46 receives a user input from an external terminal, and can transmit a fault waveform file, system monitoring information, and the like to an external terminal.

The CPU control unit 42 stores the fault waveform file received by the FTP-server unit 44 so as to be distinguished from other fault waveform files, and controls the output unit 30 to output the fault waveform file. That is, the CPU control unit 42 stores the identification information for each of the fault waveform files and stores them so that the fault detection unit can quickly detect and recall an arbitrary fault waveform file.

The CPU control unit 42 controls the HTTP-server unit 16 to transmit a first request signal for requesting system monitoring information through the HTTP-client unit 45 when a predetermined first event occurs. Here, the first event is a case in which the CPU module 10 receives the fault waveform file, the CPU module 10 receives the user input, and the CPU module 10 receives at least the system monitoring information One case may be included. When receiving the system monitoring information corresponding to the first request signal, the CPU control unit 42 does not store the received system monitoring information but controls the output from the output unit 30.

The storage unit 43 stores information necessary for the operation by the CPU control unit 42 and stores the fault waveform file. The storage unit 43 may be a mass storage medium, a hard disk type, a magnetic disk, or an optical disk.

The memory unit 14 of the DSP module 10 or the storage unit 43 of the CPU module 20 may further store system setting information including setting information on the power system. Here, the system setting information includes system-wide setting information such as current, voltage, bus, feeder, and calibration, and is written in XML format.

When the memory unit 14 of the DSP module 10 stores the system setting information, the CPU control unit 42 transmits a second request signal for requesting the system setting information to the HTTP-client unit 45 to the HTTP-server unit 16. Here, the second event is a case where the CPU module 10 receives the fault waveform file, the CPU module 10 receives the user input, and the CPU module 10 determines at least One case may be included. When receiving the system setting information corresponding to the second request signal, the CPU control unit 42 controls the output unit 30 to output the received system setting information without storing the received system setting information.

When the storage unit 43 of the CPU module 20 stores the system setting information, the CPU control unit 42 detects the corresponding system setting information in the storage unit 43 when the preset second event is generated, (30).

5 is a flowchart for explaining a power system failure recording method according to an embodiment of the present invention.

Referring to FIGS. 2 and 5, a power system failure recording method (hereinafter referred to as a 'failure recording method') performs power system information transmission using an asynchronous method using FTP and HTTP, which are standard protocols. This makes it possible to improve the compatibility with various heterogeneous systems and improve the load on the system. In addition, the fault recording method can actively generate a fault waveform file when a power system fault is detected, and store a fault waveform file at a desired point and position using FTP.

In step S51, the DSP module 10 determines whether a failure has been detected. The DSP module 10 detects an error signal in the power system and detects a failure. That is, the DSP module 10 determines that a fault has occurred when an abnormal signal generated when the effective value of the voltage and the current exceeds or falls below a preset reference value is detected. If a failure is detected, the DSP module 10 performs step S53, and if a failure is not detected, the DSP module 10 performs step S55.

In step S53, the DSP module 10 generates a fault waveform file and transmits the generated fault waveform file to the CPU module 20. [ At this time, if the power system failure is detected, the DSP module 10 can actively generate the fault waveform file even in the absence of an external request signal. The DSP module 10 transmits the generated fault waveform file to the CPU module 20 using FTP.

In step S55, the DSP module 10 determines whether or not a request signal for the system monitoring information is received. The DSP module 10 receives a request signal from the CPU module 20 using HTTP. If the reception is confirmed, the DSP module 10 performs step S57, and if the reception is not confirmed, the DSP module 10 performs step S51.

In step S57, the DSP module 10 detects information corresponding to the request signal and transmits the information to the CPU module 10. [ The DSP module 10 retrieves and detects the system monitoring information requested in the request signal. For example, if the request signal includes information requesting current instant information on current, voltage, and frequency, the DSP module 10 searches and detects only the corresponding information. The DSP module 10 transmits the system monitoring information detected using HTTP to the CPU module 20.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation in the embodiment in which said invention is directed. It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the scope of the appended claims.

10, 210: DSP module 11:
12: DSP communication unit 13: DSP control unit
14: memory unit 15: FTP-client unit
16: FTP-server unit 20, 230: CPU module
21: first CPU module 22: second CPU module
23: nth CPU module 30, 250: output section
31: first output section 32: second output section
33: nth output section 41: CPU communication section
42: CPU control unit 43:
44: FTP-server unit 45: HTTP-client unit
46: external communication unit 90: communication network
100: fault recording system 200: fault recording apparatus

Claims (4)

A DSP (Digital Signal Processor), which is formed in a chip form, detects a failure of the power system, generates a fault waveform file for the detected failure, and real-time system monitoring information including current instantaneous information of the power system, Signal Processor) module;
(N is a natural number of 2 or more) communication structure with the DSP module and performs asynchronous communication using a standard protocol to enable compatibility with a heterogeneous system, Receives the fault waveform file, stores the received fault waveform file, and transmits a first request signal for requesting the system monitoring information to the DSP module, and transmits the first request signal corresponding to the first request signal A plurality of central processing unit (CPU) modules for receiving the system monitoring information and controlling the received system monitoring information to be output; And
And a plurality of output units connected to the plurality of CPU modules and separately displaying information requested to be output from the connected CPU module,
The DPS module includes:
A fault detection unit for detecting a fault in the power system by detecting an abnormal signal generated when an effective value of a voltage and a current exceeds or falls below a preset reference value;
A file transfer protocol-client (FTP) unit for transmitting the fault waveform file to the CPU module by using FTP; a second transfer unit for receiving a first request signal from the CPU module using HTTP, A DSP communication unit including an HTTP-server (hypertext transfer protocol-server) unit for transmitting the corresponding system monitoring information to the CPU module;
Wherein the failure waveform file is actively generated when the failure detection unit detects a failure of the power system in a state of being unsynchronized with the CPU module, and the generated failure waveform file is selected through the FTP- To the CPU module so that the fault waveform file is actively stored in the selected CPU module at a desired point and position,
Wherein the system monitoring information is generated by measuring instantaneous information of at least one of a current, a voltage, a frequency, and an accident state of the power system to generate system monitoring information and stores the generated system monitoring information, The detected instantaneous information corresponding to the first request signal is detected and detected, and the detected system monitoring information is transmitted to the CPU module that has transmitted the first request signal among the plurality of CPU modules through the HTTP-server unit A DSP control unit for controlling the DSP control unit; And
And a memory unit in which the DSP control unit stores information necessary for operation, system monitoring information, and system setting information,
The CPU module,
A file transfer protocol-server unit connected to the FTP-client unit and receiving a fault waveform file from the FTP-client unit using FTP, a file transfer protocol-server unit connected to the HTTP- An HTTP-client (hypertext transfer protocol-client) unit for transmitting the first request signal to the HTTP-server unit and receiving the detected system monitoring information from the HTTP-server unit, And an external communication unit for transmitting at least one of the fault waveform file and the system monitoring information to the external terminal;
The identification information is assigned to each of the received fault waveform files received by the FTP server and control is performed so that each fault waveform file is individually stored and output through the output unit using the provided identification information,
Wherein the control unit controls the first request signal to be transmitted to the DSP module via the HTTP-client when a predetermined first event occurs, and when receiving the system monitoring information corresponding to the first request signal, Information is not stored and is output through the output unit,
The second request signal for requesting the system setting information is transmitted to the DSP module via the HTTP-client when the predetermined second event is generated, and upon receiving the system setting information corresponding to the second request signal, A CPU control unit for temporarily storing the system setting information and controlling the output of the system setting information through the output unit; And
And a storage unit in which the CPU control unit stores information necessary for calculation and the fault waveform file,
The fault waveform file is a file including waveform information corresponding to before and after a fault point,
The system monitoring information includes instantaneous information of at least one of a current, a voltage, a frequency, and an accident state and is written in an extensible markup language (XML)
Wherein the system setting information includes at least one of a current, a voltage, a bus, a feeder, and a calibration, and is written in an XML format. delete delete delete

Images