KR20170109842A - Power system - Google Patents

Abstract

The present invention relates to an IED (Inteligent Electrical Device) for generating a wave file corresponding to a power quality occurrence information and a power quality problem when a power quality problem occurs in a power network, And a Substation Automation System (SAS) for transmitting the power quality request information requesting the wave file to the IED and storing the received wave file.

Description

Power system

The present invention relates to a power system, and more particularly, to a power system that is easy to process and manage power quality information transmitted from an IED (Inteligent Electrical Device).

With the advancement of electric power technology, the domestic electric power technology market is gradually evolving.

However, the quality problem, which can be said to be the double aspect of technological growth, is hardly advanced.

As the equipment is diversified and numerous products are installed in one place, various power quality problems are occurring in the power equipment field.

To solve these problems, real-time monitoring of the on-site condition is required to monitor the power quality in order to provide safe and efficient power at all sites where power facilities are installed.

If there is an abnormality in the power quality, normal power can not be supplied and serious accidents can occur. Reliable protocols must be used because efficient power monitoring and verification is required to protect and manage these power quality.

Recently, in order to monitor and protect the abnormality of power quality, studies are underway to process and manage power quality information by applying IEC 61850, the international standard of power quality.

It is an object of the present invention to provide a power system that is easy to process and manage power quality information transmitted from an IED (Inteligent Electrical Device).

The power system according to the present invention includes an IED (Inteligent Electrical Device) that generates a wave file corresponding to power quality occurrence information and power quality problems when a power quality problem occurs in a power network, And a Substation Automation System (SAS) for transmitting the power quality request information requesting the wave file to the IED and storing the received wave file upon receiving the generated information.

The IED can change the wave flag value of the logical node class indicating the protection function upon completion of generation of the wave file.

Wherein the wave flag value is a changed value of at least one of values of an RcdMade element included in the RDRE class and indicating completion of generation of the wave file and an FltNum element counting the number of occurrences of the wave file, , The wave file, and the wave flag value, and upon receiving the wave flag value, the SAS can change the wave flag value to the set reference wave flag value.

When the IED receives a reset signal for transmitting the wave file and the wave flag value to the SAS and changing the wave flag value from the SAS to the reference wave flag value, Value.

The wave file may include an occurrence time, an occurrence end time, and a waveform type for the power quality problem.

Upon receipt of the wave file and the wave flag value, the SAS transmits a reset signal to the IED to change the wave flag value to the reference flag value, and transmits the wave file with Supervisory Control And Data Acquisition (SCADA) Can be transmitted.

The power system according to the present invention is advantageous in that efficiency of power quality monitoring, processing and management can be improved by sharing power quality information only when a power quality problem occurs in IED, SAS and SCADA.

In addition, the power system according to the present invention has an advantage that it can efficiently process and manage massive power quality information acquired from the IED by transmitting a wave file to the SCADA when the SAS has a power quality problem.

In addition, the power system according to the present invention has the advantage of increasing the reliability of power quality by using IEC 61850, which is an international standard for power quality.

1 is a system diagram illustrating a power system in accordance with the present invention.
FIG. 2 is a timing diagram illustrating a power quality processing procedure when a power quality problem occurs in the power system according to the present invention.
3 is an illustration of an example of a logical node class of IEC 61850, an international standard in a power system according to the present invention.
4 is a flowchart illustrating an operation method of an IED included in a power system according to the present invention.
5 is a flowchart illustrating an operation method of the SAS included in the power system according to the present invention.

Hereinafter, a power system and an operation method thereof according to the present invention will be described in detail with reference to the drawings. The suffix "module" or "part" for components used in the following description is given or mixed in consideration of ease of specification, and does not have a meaning or role that distinguishes itself.

1 is a system diagram illustrating a power system in accordance with the present invention.

Referring to FIG. 1, a power system may include an IED (Inteligent Electrical Device) 110, a Substation Automation System (SAS) 120, and a Supervisory Control And Data Acquisition (SCADA)

In an embodiment, IED 110, SAS 120, and SCADA 130 may transmit information based on IEC 61850, an international standard for power quality.

The IED 110 is an intelligent electronic device and, in the present invention, represents a power quality monitoring system, but is not limited thereto.

The IED 110 may monitor whether a power quality problem arises for the power of the system.

The IED 110 can detect the power quality problem by detecting the current and voltage of the power.

In addition, the IED 110 may generate power quality generation information PQ_1 and transmit it to the SAS 120 when a power quality problem occurs.

At this time, the IED 110 may generate the wave file WF corresponding to the wave shape of the current and voltage after transmitting the power quality occurrence information PQ_1.

In the embodiment, the wave file WF can be generated only when a power quality problem occurs because the wave file capacity is large and the transmission amount during transmission is very high.

Thereafter, when the IED 110 receives the power quality request information PQ_2 transmitted from the SAS 120, when the generation of the wave file WF is completed, the IED 110 completes the generation of the wave file WF and the wave file WF Changes the wave flag value (WFV) of the logical node class indicating the protection function of the IEC 61850 as described above.

The IED 110 may transmit power quality information (not shown) including the wave file WF and the wave flag value WFV to the SAS 120. [

Here, the wave file WF may include, but is not limited to, a file of the occurrence time, the generation end time, and the waveform type for the power quality problem.

In addition, the logical node class is an RDRE (Disturbance recorder function) class for performing the protection function, and the wave flag value includes an RcdMade element included in the RDRE class and indicating completion of generation of the wave file, And may be a modified value of at least one of the values of the FltNum element counting the number, but is not limited thereto.

Thereafter, the IED 110 monitors the power from the point of time when the power quality problem is removed, and when receiving the reset signal SF transmitted from the SAS 120, the IED 110 can change the wave flag value WFV to the reference wave flag value have.

SAS 120 receives power quality generation information PQ_1 transmitted from IED 110 and transmits power quality request information PQ_2 requesting wave file WF and wave flag value WFV to IED 110. [ And waits until the power quality information is received.

Then, upon receiving the power quality information transmitted from the IED 110, the SAS 120 may read and store the wave file (WF) and the wave flag value (WFV) included in the power quality information.

The SAS 120 may send a reset signal SF to the IED 110 to change the wave flag value WFV to the reference wave flag value.

At this time, the SAS 120 may transmit the information including the wave file WF and the wave flag value WFV to the SCADA 130 when the reset signal SF is transmitted.

The SCADA 130 can display a wave form included in the wave file WF using an FTP (File Transfer Protocol) method when an operator inputs a command.

That is, the SCADA 130 may monitor the IED 110 and the SAS 120.

FIG. 2 is a timing diagram illustrating a power quality processing procedure when a power quality problem occurs in a power system according to the present invention, and FIG. 3 is an example of a logic node class of an international standard IEC 61850 in the power system according to the present invention.

2 shows a process sequence performed between the IED 110 and the SAS 120 when a power quality problem occurs during the power monitoring of the system in the IED 110. FIG.

That is, when the power quality problem occurs during the power monitoring, the IED 110 transmits the power quality occurrence information PQ_1 to the SAS 120, receives the power quality request information Q_2 transmitted from the SAS 120 , The waveform type can be extracted from the occurrence time to the generation end time for the power quality problem (S1).

After the interval S1, the IED 110 monitors the power again from the point of time when the power quality problem ends, and stores the waveform type (S2).

The IED 110 generates the wave file WF and the wave flag value WFV and transmits the wave file WF and the wave flag value WFV to the SAS 120 which waits for the wave file WF and the wave flag value WFV (S3).

After the interval S3, the SAS 120 stores the wave file WF and the wave flag value WFV and outputs the reset signal SF (SF) to the IED 110 to change the wave flag value WFV to the reference wave flag value , And transmits information including the wave file WF and the wave flag value WFV to the SCADA 130 (S4).

Figure 3 is an example of a logical node class of the IEC 61850 international standard in a power system.

That is, FIG. 3 shows an RDRE (Disturbance recorder function) class, and it is possible to change at least one of the values of the RcdMade element indicating the completion of generation of the WAV file WF and the FltNum element counting the number of occurrences of the WAV file.

In the IEC 61850 standard, the wave flag value WFV is set to 1 using the RDRE (Disturbance recorder function) class, which is a logical name indicating completion of generation of the wave file WF, and is sent to the SAS 120 as an upper client .

Here, the meaning that the wave flag value WFV is 1 means that RcdMade (Recording Made) of the DRE (Disturbance recorder function) class is 1, and RcdMade means that the generation of the wave file (WF) defined by IEC 61850 is completed It is stipulated as a Flag to inform.

In addition, the IED 110 may change the RcdMade $ stval variable from 0 to 1 when the wave file WF is created. At this time, the SAS 120 can determine whether the wave file WF is generated by viewing this variable.

4 is a flowchart illustrating an operation method of an IED included in a power system according to the present invention.

Referring to FIG. 4, the IED 110 monitors the power quality of the system (S110) and determines whether the power quality problem has occurred (S120).

Then, the IED 110 generates power quality generation information PQ_1 when the power quality problem occurs, transmits the generated power quality generation information PQ_1 to the SAS 120, and generates a wave file WF corresponding to the power quality problem (S130).

The IED 110 receives the power quality request information PQ_2 transmitted from the SAS 120 in step S140 and generates a logical node class indicating the protection function of the IEC 61850 for completion of generation of the wave file WF And transmits the wave file WF and the wave flag value WFV to the SAS 120 (S150).

After the step S150, the IED 110 changes the wave flag value WFV to the reference wave flag value when the reset signal SF transmitted from the SAS 120 is received, and continuously monitors the power quality S160).

5 is a flowchart illustrating an operation method of the SAS included in the power system according to the present invention.

5, when the SAS 120 receives the power quality generation information PQ_1 transmitted from the IED 110 (S210), the SAS 120 transmits to the IED 110 the wave file WF corresponding to the power quality problem, And transmits power quality request information PQ_2 requesting the flag value WFV (S220).

The SAS 120 stores the wave file WF and the wave flag value WFV transmitted from the IED 110 in S230 and changes the wave flag value WFV to the reference wave flag value in the IED 110 And transmits the reset signal SF (S240).

After step S240, the SAS 120 transmits the wave file WF to the Supervisory Control And Data Acquisition (SCADA) 130 (S250).

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention.

Claims (6)

An IED (Inteligent Electrical Device) that generates a wave file corresponding to a power quality occurrence information and a power quality problem when a power quality problem occurs in a power network; And
And a Substation Automation System (SAS) that, upon receiving the power quality occurrence information transmitted from the IED, transmits power quality request information requesting the wave file to the IED and stores the received wave file. The method according to claim 1,
The IED includes:
And changes the wave flag value of the logical node class indicating the protection function upon completion of generation of the wave file. 3. The method of claim 2,
The wave flag value,
An RcdMade element included in the RDRE class indicating completion of generation of the wave file, and a value of an FltNum element counting the number of occurrences of the wave file,
Wherein the power quality request information comprises:
Information requesting the wave file and the wave flag value,
The SAS comprises:
And upon receiving the wave flag value, changes the wave flag value to a set reference wave flag value. The method according to claim 1,
The IED includes:
When receiving the reset signal for changing the wave flag value from the SAS to the reference wave flag value after transmitting the wave file and the wave flag value to the SAS, changing the wave flag value to the reference wave flag value Power system. The method according to claim 1,
The wave file includes:
A generation time, an occurrence end time, and a waveform type for the power quality problem. The method according to claim 1,
The SAS comprises:
A power system that transmits a reset signal to the IED to change the wave flag value to the reference flag value upon receipt of the wave file and the wave flag value and transmits the wave file to Supervisory Control And Data Acquisition (SCADA) .

Images