KR102458674B1 - Method and apparatus for preliminary diagnosis of substation using substitution virtualization - Google Patents

Abstract

The present invention relates to a method and device for a substation pre-diagnosis using a substation virtualization that generates a virtual model of a substation based on a plurality of packets transmitted from a plurality of existing IEDs, updates a virtual model of the substation by adding, to the virtual model of the substation, a virtual model of each of at least one new IED planned to be installed in the substation, and enables a communication state of the substation in a state where the new IED is installed in the substation to be diagnosed in advance before installing the new IED in the substation on site by pre-diagnosing a substation communication status with at least one new IED installed in the substation using the same updated substation virtual model. Therefore, the present invention is capable of minimizing a communication error.

Description

{Method and apparatus for preliminary diagnosis of substation using substitution virtualization}

It relates to a method and apparatus for diagnosing a communication state of a substation.

IEC (International Electronical Commission) proposed the standardization of substation automation (SA, Substation Automation) in 1995 to solve the interoperability problem caused by the mixing of substation automation protocols, and the standard number was designated as "IEC 61850". The first edition was completed between 2002 and 2005, and it is still being supplemented and revised. The core of substation automation based on the IEC 61850 standard is that the overall configuration of the substation is expressed using SCL (Substation Configuration Description Language) and can be used for substation automation design. The substation automation system based on the IEC 61850 standard has an IED (Intelligent Electronic Device), which is a server that manages on-site facilities, and an upper operating client that collects IED information as a basic configuration.

When a new IED is additionally installed in a substation, communication setting for the new IED is generally performed by referring to the IET (IED Engineering Table) written in a format that the user can easily understand in the SCL file. Because SCL files and IETs are written by hand, they are prone to errors. For this reason, in the process of additionally installing a new IED in the substation and conducting on-site communication tests, communication errors frequently occurred between the existing facilities of the substation and the new IED. Communication errors of new IEDs are caused by a mixture of various causes such as hardware errors in addition to software errors such as SCL file and IET. It was difficult.

Republic of Korea Patent No. 10-1730267 "Apparatus and method for conformity inspection of substation automation facility standards" checks for errors in information standardization table and SCL file A substation automation facility standard conformity inspection device and method are presented. However, this prior art relates to a standard conformity check for existing facilities of a substation, and there is a limit in minimizing a communication error during on-site installation of a new IED.

Communication errors during on-site installation of new IEDs can be minimized by diagnosing substation communication errors in the state where new IEDs are installed before on-site installation of new IEDs and allowing users to resolve communication errors and then proceed with on-site installation of new IEDs. To provide a substation pre-diagnosis method and apparatus that can It is not limited to the technical problem as described above, and another technical problem may be derived from the following description.

A substation pre-diagnosis method according to an aspect of the present invention includes: capturing a plurality of packets transmitted from a plurality of existing IEDs installed in a substation; generating a virtual model of the substation based on the captured plurality of packets; generating a virtual model of each of the at least one new IED to be installed in the substation; updating the virtual model of the substation by adding the virtual model of each new IED to the virtual model of the substation; and pre-diagnosing a substation communication state in a state in which the at least one new IED is installed in the substation by using the updated substation virtual model.

The substation pre-diagnosis method further includes extracting the information of each of the existing IEDs from the captured plurality of packets, and the generating of the virtual model of the substation is based on the extracted information of each of the existing IEDs. A virtual model of the substation can be created.

The generating of the virtual model of the substation may generate a virtual model of the substation by generating a virtual model of each existing IED based on the extracted information of each existing IED.

The generating of the virtual model of the substation may include generating a virtual model of each of the at least one higher-level client of the substation together with the virtual model of each existing IED based on the extracted information of each existing IED, thereby creating a virtual model of the substation. can create

The step of generating the virtual model of the substation includes setting MMS communication with the at least one upper client for each existing IED based on the extracted information of each existing IED and GOOSE communication with other existing IEDs among the plurality of existing IEDs. creating a virtual model of each existing IED by generating data representing the settings; and generating data representing MMS communication settings with the plurality of existing IEDs for each higher level client based on the extracted information of each existing IED, thereby generating a virtual model of each higher level client.

The generating of the virtual model of each new IED may include generating data indicating the MMS communication setting with the at least one upper client and the GOOSE communication setting with the plurality of existing IEDs for each new IED by generating the virtual model of each new IED. You can create a model.

The pre-diagnosing includes diagnosing the MMS communication state of each new IED in such a way that it is diagnosed whether the MMS communication setting of the virtual model of each new IED matches the MMS communication setting of the virtual model of each of the at least one higher-level client. And, by diagnosing the GOOSE communication state for each new IED in a way of diagnosing whether the GOOSE communication setting of the virtual model of each new IED matches the GOOSE communication setting of the virtual model of each of the plurality of IEDs, the substation communication state is determined can be diagnosed in advance.

The step of generating the virtual model of each new IED includes an IP layer defining an IP communication setting of each new IED, an RCB layer defining an RCB setting of an MMS report message of each new IED, and an MMS report of each new IED. In a hierarchical structure including a data layer defining a data set setting corresponding to a data transmission rule through a message, data representing the MMS communication setting may be generated for each new IED.

The step of pre-diagnosing includes an IP communication setting defined in the IP layer of the virtual model of any one of the at least one new IED and the IP layer of the virtual model of any one of the upper clients among the at least one upper client. diagnosing whether there is an error in the IP communication setting defined in the IP layer of the virtual model of the one new IED by comparing the defined IP communication settings; And if it is confirmed that there is no error in the IP communication setting defined in the IP layer of the virtual model of the one new IED, the RCB setting defined in the RCB layer of the virtual model of the one new IED and the upper one and diagnosing whether the RCB setting defined in the RCB layer of the virtual model of any one of the new IEDs is in error by comparing the RCB settings defined in the RCB layer of the virtual model of the client.

If it is confirmed that there is no error in the RCB setting defined in the RCB layer of the virtual model of the one new IED, the pre-diagnosis includes setting the dataset defined in the data layer of the virtual model of the one new IED and Comparing the data set settings defined in the data layer of the virtual model of the one upper client, the step of diagnosing whether there is an error in the data set setting defined in the data layer of the virtual model of the one new IED can

The generating of the virtual model of each new IED has a hierarchical structure further including a location layer defining an acquisition location of data to be transmitted by each existing IED, and data representing the MMS communication setting is generated for each new IED. And, the step of prediagnosing is a data acquisition location defined in the location layer of the virtual model of the any one new IED by attempting to access the data acquisition location defined in the location layer of the virtual model of the one new IED. It may further include the step of diagnosing whether there is an error.

The step of generating the virtual model of each new IED includes an Ethernet layer defining Ethernet communication settings of each new IED, a GCB layer defining a GCB setting of the GOOSE message of each new IED, and a GOOSE message of each new IED. With a hierarchical structure including a data layer defining a data set setting corresponding to a data transmission rule through data transmission, data representing the GOOSE communication setting may be generated for each new IED.

The pre-diagnosis is defined in the Ethernet communication setting defined in the Ethernet layer of the virtual model of any one of the at least one new IED and the Ethernet layer of the virtual model of the existing IED of any one of the plurality of existing IEDs. diagnosing whether there is an error in the Ethernet communication setting defined in the Ethernet layer of the virtual model of any one of the new IEDs by comparing the established Ethernet communication settings; And if it is confirmed that there is no error in the Ethernet communication setting defined in the Ethernet layer of the virtual model of the one new IED, the GCB setting defined in the GCB layer of the virtual model of the one new IED and the one existing Comparing the GCB settings defined in the GCB layer of the virtual model of the IED may include diagnosing whether the GCB settings defined in the GCB layer of the virtual model of any one of the new IEDs are in error.

If it is confirmed that there is no error in the GCB setting defined in the GCB layer of the virtual model of the one new IED, the pre-diagnosis includes setting the dataset defined in the data layer of the virtual model of the one new IED and Comparing the data set settings defined in the data layer of the virtual model of the one existing IED, further comprising the step of diagnosing whether there is an error in the data set setting defined in the data layer of the virtual model of the one new IED can

The generating of the virtual model of each new IED is a hierarchical structure further including a location layer defining an acquisition location of data to be transmitted by each existing IED, and data representing the GOOSE communication setting is generated for each new IED. And, the step of prediagnosing is a data acquisition location defined in the location layer of the virtual model of the any one new IED by attempting to access the data acquisition location defined in the location layer of the virtual model of the one new IED. It may further include the step of diagnosing whether there is an error.

A substation advance diagnosis apparatus according to another aspect of the present invention includes: a communication unit for capturing a plurality of packets transmitted from a plurality of existing IEDs installed in a substation; a first virtualization unit for generating a virtual model of the substation based on the captured plurality of packets; a second virtualization unit generating a virtual model of each of at least one new IED to be installed in the substation; an update unit for updating the virtual model of the substation by adding the virtual model of each new IED to the virtual model of the substation; and a diagnosis unit configured to pre-diagnose a substation communication state in a state in which the at least one new IED is installed in the substation by using the updated substation virtual model.

A virtual model of a substation is created based on a plurality of packets transmitted from a plurality of existing IEDs, and a virtual model of each of at least one new IED scheduled to be installed in the substation is added to the virtual model of the substation using the substation virtual model. By pre-diagnosing the substation communication state in the state in which at least one new IED is installed, it is possible to diagnose the substation communication state in the state in which the new IED is installed in the substation in advance before installing the new IED in the substation on site. In particular, prior to on-site installation of a new IED, the on-site installation of a new IED by diagnosing communication errors related to the SCL file and IET in the state in which the new IED is installed in advance and allowing the user to resolve the communication errors and then proceed with the on-site installation of the new IED Communication errors in the city can be minimized.

Furthermore, the virtual model of the new IED is expressed in a hierarchical structure such as location layer, Ethernet layer, IP layer, RCB layer, GCB layer, and data layer, and by performing diagnosis for each layer of the virtual model of the new IED, users It is possible to easily find the cause of the communication error that may occur during the field installation process of the IED and to solve it in advance. As a result, the field installation work of the new IED can be completed quickly. It is not limited to the effect as described above, and another effect may be derived from the following description.

1 is an exemplary view of a usage environment of a bushing monitoring facility diagnosis apparatus 1 according to an embodiment of the present invention.
FIG. 2 is a configuration diagram of the bushing monitoring facility diagnosis apparatus 1 shown in FIG. 1 .
3 is an external view of the bushing monitoring facility diagnosis apparatus 1 shown in FIG. 2 .
FIG. 4 is a diagram illustrating a menu tree structure of the user interface 20 shown in FIG. 3 .
5 is a flowchart of a method for diagnosing a bushing monitoring facility according to an embodiment of the present invention.
FIG. 6 is a diagram illustrating another example of a user operation on the user interface 20 shown in FIG. 3 .
7 is a flowchart of a method for diagnosing a bushing monitoring facility according to another embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. The embodiment of the present invention described below diagnoses a substation communication error in a state in which the new IED is installed before the on-site installation of the new IED, and allows the user to solve the communication error and then proceeds with the on-site installation of the new IED. It relates to a substation pre-diagnosis method and apparatus that can minimize communication errors during on-site installation of Hereinafter, such a substation pre-diagnosis method and apparatus may be briefly referred to as "pre-diagnosis method" and "pre-diagnosis apparatus".

1 is a block diagram of a substation according to an embodiment of the present invention. 1, the substation according to the present embodiment is a HMI client (Human Machine Interface Client) (1), a plurality of IED (Intelligent Electronic Device) (2), SCADA (Supervisory Control And Data Acquisition) (3) ), a gateway 4 , a network switch 5 , and a pre-diagnosis device 6 . The components shown in FIG. 1 are components to be related to the substation automation system according to the International Electronical Commission (IEC) 61850 standard among the components of the substation. Various field facilities such as, HMI client 1, a plurality of IEDs 2, and an SNTP server (Simple Network Time Protocol Server) for time synchronization between SCADA 3 may be further included.

The HMI client (1) is a higher level client of the substation automation system according to the IEC 61850 standard, and serves to interface between various power facilities such as a plurality of IEDs (2) and users. The HMI client 1 may receive monitoring information of each field facility from each IED 2 serving as a server, and visualize the monitoring information of various field facilities and provide it to the user. The monitoring information of each field facility means information for monitoring each field facility. HMI client 1 can transmit control information of each field facility to each IED 2 . The control information of each field facility means information for controlling each field facility. The user can monitor and control various on-site facilities located in remote areas using the visualized monitoring information. Examples of the information of each field facility include status information and measurement information of each field facility. A plurality of gateways 5 and network switches 6 may be installed according to substation site conditions.

Each of the plurality of IEDs (2) is installed in each field facility so that each field facility can be monitored and controlled, and each field facility is managed according to the IEC 61850 standard so that interworking between the plurality of field facilities can be made. Each IED 2 may transmit monitoring information of each field facility to the HMI client 1 according to the request of the HMI client 1 . Each IED 2 may receive control information of each field facility from the HMI client 1 and can control each field facility according to the control information of each field facility. In addition, each IED(2) may receive interworking information of field facilities managed by the other IED(2) from the other IED(2). Each IED2 can transmit interworking information of the field equipment it manages to another IED2. Interworking information of a certain field facility means information for enabling the field facility to interwork with other field facilities.

SCADA (3) receives information of various field facilities from each IED (2), and analyzes information of various field facilities. The SCADA 3 may provide information analysis results of various field facilities to the HMI client 1 . SCADA (3) is only given as an example of a representative device constituting the substation automation system, and since it is not related to the characteristics of the present embodiment, further detailed description will be omitted.

Gateway (4), network switch (5) is HMI client (1), a plurality of IEDs (2), It serves to connect the SCADA (3). A plurality of gateways 5 and network switches 6 may be installed according to substation site conditions. Since each of the gateway 5 and the network switch 6 is not related to the characteristics of the present embodiment, further detailed description thereof will be omitted. Hereinafter, the advance diagnosis apparatus 6 corresponding to the characteristics of the present embodiment will be described in detail.

The IEC 61850 standard uses SCL (Substation Configuration Description Language) based on XML (eXtensible Markup Language), and is not dependent on the manufacturer, and the entire configuration of the substation such as the substation automation system and various field facilities shown in FIG. 1 is in the form of a file. allowing it to be expressed. The SCL file is composed of a System Specification Description (SSD) file, an IED Capability Description (ICD) file, a Substation Configuration Description (SCD) file, and a Configured IED Description (CID) file.

The SSD file expresses the physical structure of the entire substation and the physical arrangement of various power facilities like a substation single-line diagram. The ICD file expresses data, communication services, etc. that can be provided by each IED 2 . The SCD file contains connection information between a plurality of IEDs (2) and HMI client (1) for data transfer between a plurality of IEDs (2) and HMI client (1), and a plurality of IEDs for data transfer between a plurality of IEDs (2). (2) Express connection information between. The CID file expresses a data set that can be transmitted for each IED 2 , a transmission rule of a Message Manufacturing Specification (MMS) report message, a transmission rule of a Generic Object Oriented Substation Event (GOOSE) message, and the like.

According to the IEC 61850 standard, each IED (2) sends and receives monitoring control information of each field facility with the HMI client (1), which is a higher level client of the substation automation system, by using an MMS message. The MMS message is usually sent as a response of the IED 2 to the request of the HMI client 1 . When any event occurs, an MMS message can be sent in the form of a report without a request from the HMI client 1 . A message transmitted in this way is called an MMS report message. Interworking information of each field facility is exchanged between multiple IEDs(2) by using GOOSE message.

RCB (Report Control Block) defines the MMS report message transmission rule of each IED (2). For example, the RCB defines the name of the IED that transmits the MMS report message, the name of the dataset transmitted through the MMS report message, and the name of the upper client corresponding to the destination of the MMS report message. GCB (Goose Control Block) defines the GOOSE message transmission rule of each IED(2). For example, GCB defines the name of the IED that transmits the GOOSE message, the name of the dataset transmitted through the GOOSE message, and the like. Since the GOOSE message is transmitted in a multicast method, the destination information is not recorded in the GCB.

FIG. 2 is a block diagram of the advance diagnosis apparatus 6 shown in FIG. 1 . Referring to FIG. 2 , the advance diagnosis apparatus 6 according to the present embodiment includes a communication unit 61 , a packet processing unit 62 , an IET generator 63 , a virtualization unit 64 , a diagnosis unit 65 , and a user interface. 66 , and storage 67 . The virtualization unit 64 includes a first virtualization unit 641 , a second virtualization unit 642 , and an update unit 643 . Hereinafter, each of the plurality of IEDs 2 already installed in the substation will be referred to as an “existing IED”, and each of the at least one IED 20 to be installed in the substation will be referred to as a “new IED”. The novel IED 20 in FIG. 1 is shown by a dotted line.

3 is a flowchart of a pre-diagnosis method according to an embodiment of the present invention. Referring to FIG. 3 , the pre-diagnosis method according to the present embodiment includes steps that are time-series processed by the pre-diagnosis apparatus 6 shown in FIG. 2 . Hereinafter, the advance diagnosis apparatus 6 will be described in detail with reference to FIGS. 2 and 3 .

In step 31 , the communication unit 61 of the advance diagnosis device 6 captures a plurality of packets transmitted from a plurality of existing IEDs 2 installed in the substation through the network switch 5 . The communication unit 61 transmits between a packet including an MMS report message transmitted between each existing IED 2 and the HMI client 1 among a plurality of packets transmitted from the existing IED 2 and a plurality of existing IEDs 2 . Captures the packet containing the GOOSE message being sent. The packet including the MMS report message is transmitted between the HMI client 1 and each existing IED 2 through the network switch 5 . Accordingly, the communication unit 61 may capture a packet including the MMS report message through the network switch 5 . The packet including the GOOSE message is transmitted between a plurality of existing IEDs (2) through the network switch (5). Accordingly, the communication unit 61 may capture a packet including the GOOSE message through the network switch 5 .

The communication unit 61 captures a plurality of packets transmitted from a plurality of existing IEDs 2 through the network switch 5 for a time preset by the user. If the length of the time preset by the user is too short, the information of the plurality of existing IEDs 2 may not be sufficiently collected, so that the substation pre-diagnosis according to the present embodiment may not be possible or the pre-diagnosis range may be narrowed. If the length of the time preset by the user is too long, the communication unit 61 continues to capture packets even though a number of packets that can sufficiently collect information of a plurality of existing IEDs 2 are captured, which is required for substation advance diagnosis It can be a huge waste of time. It is desirable that the user set the time appropriately in consideration of the number of IEDs in the substation.

In step 32, the packet processing unit 62 of the pre-diagnosis apparatus 6 extracts information of each of the plurality of existing IEDs 2 from the plurality of packets captured by the communication unit 61 in step 31 . The information of each existing IED(2) consists of function information of the existing IED(2), data set setting information, RCB setting information, and GCB setting information. Here, the data set setting information of a certain existing IED(2) means setting information of the data set corresponding to the data transmission rule through the MMS report message or GOOSE message of the existing IED(2). RCB configuration information of a certain existing IED(2) means RCB configuration information corresponding to the transmission rule of the MMS report message transmitted by the existing IED(2). The GCB setting information of a certain existing IED(2) means the setting information of the GCB corresponding to the transmission rule of the GOOSE message transmitted by the existing IED(2).

FIG. 4 is a diagram illustrating a format of a packet captured by the communication unit 61 shown in FIG. 2 . The packet captured by the communication unit 61 is classified into an Ethernet packet and an IP (Internet Protocol) packet, a GOOSE message is transmitted using an Ethernet packet, and an MMS report message is transmitted using an IP packet. 4 (a) shows the format of an Ethernet packet including a GOOSE message, and (b) shows the format of an IP packet including an MMS report message. A packet including the GOOSE message is transmitted using Ethernet-based real-time communication between a plurality of existing IEDs (2).

Referring to (a) of FIG. 4 , the packet processing unit 62 sets the function information and data set of the existing IED 2 as information of the existing IED 2 that has transmitted the GOOSE message from the Ethernet packet including the GOOSE message. Extract information, GCB setting information. Since the GOOSE message is transmitted in an Ethernet packet, an IP address is not required and is multicast through a MAC (Media Access Control) address. In the Ethernet header of the packet including the GOOSE message, the MAC address of the existing IED(2) corresponding to the source and the multicast MAC address corresponding to the destination are recorded, and the GOOSE message multicast from the source is recorded in the payload. .

Most of the function information, dataset setting information, and GCB setting information of each existing IED(2) can be extracted from the Ethernet packet including the GOOSE message. However, if the purpose of a certain dataset is for GOOSE message transmission, the usage information can be extracted from the Ethernet packet, but if it is for MMS report message transmission, it can be extracted from the IP packet. Some of the function information, dataset setting information, and GCB setting information of each existing IED(2) may be difficult to extract from the Ethernet packet including the GOOSE message, but it is supplemented by the information extracted from the Ethernet packet including the MMS report message. This is possible.

Referring to FIG. 4B , the packet processing unit 62 transmits the MMS report message from an IP packet including the MMS report message to the existing IED 2 as information on the function information and data of the existing IED 2 . Extracts set setting information and RCB setting information. Since the MMS report message is transmitted in an IP packet, an IP address is required along with the MAC address, and it is transmitted according to the client-server model. In the Ethernet header of the IP packet including the MMS report message, the MAC address of the existing IED(2) corresponding to the source and the multicast MAC address corresponding to the destination are recorded. In the IP header, the existing IED(2) corresponding to the source is recorded. The IP address of the existing IED(2) corresponding to the destination and the IP address of the existing IED(2) are recorded, and the MMS report message transmitted from the source to the destination is recorded in the payload.

Most of the function information, dataset setting information, and RCB setting information of each existing IED 2 may be extracted from an IP packet including an MMS report message message. Function information and data set setting information of each existing IED 2 may overlap with information extracted from an Ethernet packet including a GOOSE message. Function information, dataset setting information, RCB setting information, and GCB setting information of each existing IED(2) collects information extracted from Ethernet packet including GOOSE message and information extracted from IP packet including MMS report message. and can be obtained by sorting. Some of the function information, dataset setting information, RCB setting information, and GCB setting information of each existing IED 2 may not be obtained, and this embodiment is extracted from a plurality of packets captured by the communication unit 61 in step 31 . Pre-diagnosis of substations is performed using only the received information.

In step 33, the IET generator 63 of the pre-diagnosis apparatus 6 expresses the information of each existing IED2 extracted by the packet processing unit 62 in a table format in step 32, thereby Create an IED (IED Engineering Table). IET is an Excel file that expresses the contents of a CID file written in XML not in a computer programming language, but in a human language such as English that users can easily understand. When a user wants to additionally install an IED in a substation, he/she can easily proceed with various setting work and operation tests of the IED by referring to the IET of the IED. Each IET of all existing IEDs (2) and new IEDs (20) is provided by the IED manufacturer along with a CID file.

As described below, this embodiment virtualizes the substation based on this IET. The IET provided by the IED manufacturer often has errors due to various causes, such as misconfiguration of IED information. Accordingly, conventionally, it was checked whether the IED was set normally using a packet analysis program such as WireShark based on the CID file together with the IET. Accordingly, the present embodiment virtualizes the substation based on the IET created based on a plurality of packets transmitted from the existing IED 2 rather than the IET provided by the IED manufacturer. As described above, in the present embodiment, since the IET is generated using the information of a plurality of packets captured in step 31, it is not necessary to manage a separate IET file for each substation.

FIG. 5 is an exemplary diagram of an IET generated by the IET generator 63 shown in FIG. 2 . Referring to FIG. 5 , the IET consists of a part defining the IED function, a part defining the data set setting, a part defining the RCB setting, and a part defining the GCB setting. IED function information includes IED name, IP address, maximum number of data, maximum allowable and currently used data sets, maximum allowable number of RCBs that support buffering, currently used number, and maximum number of instances, buffering supported. The maximum allowable number of RCBs not in use, the number currently in use, and the maximum number of instances, the maximum allowable number and the number currently in use of the GCB, the maximum allowable and currently used number of single-bit type GOOSE inputs, double-bit type GOOSE It consists of the maximum allowed number of inputs and the number currently in use.

The data set setting information of the IED is the IED name, the data set storage location, the data set name stored in the location, the number of data supported by each data set, the purpose of each data set, and the name of the control block connected to the IED. is composed The RCB setting information of the IED consists of the IED name, the storage location of the RCB, the name of the RCB stored in the location, the name of the dataset connected to the RCB, report ID, buffering status, the number of instances, and the purpose of each RCB. IED GCB setting information consists of IED name, GCB storage location, GCB name stored in that location, data set name connected to the GCB, App ID, MAC address, GOOSE ID, and setting revision information. Since the details of each of these elements of information are not related to the characteristics of the present embodiment, further description will be omitted.

In step 34 , the virtualization unit 64 of the pre-diagnosis device 6 generates a virtual model of the substation based on the IET of each existing IED 2 generated by the IET generator 63 in step 33 . Since the IET of each existing IED(2) is a tabular expression of the information of each existing IED(2) extracted in step 32, the virtualization unit 64 creates a virtual model of the substation based on the information of each existing IED(2). can be said to create As described above, since the IET of all IEDs including the new IED 20 scheduled to be added to the substation is provided from the IED manufacturer along with the CID file, this embodiment shows the efficiency of all virtualization processes such as the creation of a virtual model of the new IED 20 A virtual model of the substation is created based on the IET of each existing IED(2) in order to increase the .

The first virtualization unit 641 among the virtualization units 64 is responsible for generating a virtual model of the substation based on the IET of each existing IED (2). The first virtualization unit 641 generates a virtual model of each existing IED(2) based on the IET of each existing IED(2) generated by the IET generation unit 63 in step 33, and generates at least one upper level of the substation. By creating a virtual model of each client, a virtual model of the substation is created. Referring to FIG. 3 , step 34 includes steps 341 and 342 . In step 341, the first virtualization unit 641 establishes MMS communication with at least one higher-level client for each existing IED(2) based on the IET of each existing IED(2) generated in step 33 and sets up MMS communication with a plurality of existing IEDs ( In 2), a virtual model of each existing IED(2) is generated by generating data indicating the GOOSE communication setting with other existing IED(2).

FIG. 6 is an exemplary diagram of a substation virtual model generated by the first virtualization unit 641 shown in FIG. 2 . Fig. 6 (a) shows a virtual model of each IED. Referring to (a) of FIG. 6 , the first virtualization unit 641 defines a location layer defining an acquisition location of data to be transmitted by each existing IED 2 , and an IP communication setting of each existing IED 2 . Data defining the data set setting corresponding to the IP layer, the RCB layer defining the RCB setting of the MMS report message of each existing IED(2), and the transmission rule of data through the MMS report message of each existing IED(2) Data representing the MMS communication rule is generated for each existing IED(2) in a hierarchical structure consisting of layers. In addition, the first virtualization unit 641 includes a location layer defining an acquisition location of data to be transmitted by each existing IED 2 , an Ethernet layer defining Ethernet communication settings of each existing IED 2 , and each existing IED ( A hierarchical structure consisting of a GOOSE layer defining the GCB settings of the GOOSE message of 2), and a data layer defining the data set settings corresponding to the data transfer rules through the GOOSE message of each existing IED(2). 2) Generates data representing GOOSE communication rules for each.

As described above, the location layer and the data layer exist in common in the hierarchical structure of the MMS communication rule and the hierarchical structure of the GOOSE communication rule. According to this embodiment, the first virtualization unit 641 integrates the location layer in the hierarchical structure of the MMS communication rule and the location layer in the hierarchical structure of the GOOSE communication rule, and the data layer and the data layer in the hierarchical structure of the MMS communication rule. By integrating the data layers in the hierarchical structure of GOOSE communication rules, data representing MMS communication rules and GOOSE communication rules are generated. As such, the first virtualization unit 641 may minimize the amount of data for expressing the virtual model of each IED by integrating the location layer and the data layer and preventing overlapping data between different layers from being recorded. As a result, pre-diagnosis of the substation using the virtual model of each IED can be made quickly.

That is, the first virtualization unit 641 includes a location layer defining an acquisition location of data to be transmitted by each existing IED 2 , an Ethernet layer defining an Ethernet communication setting of each existing IED 2 , and each existing IED ( 2) the IP layer defining the IP communication settings of, the RCB layer defining the RCB settings of the MMS report message of each existing IED(2), the GOOSE layer defining the GCB settings of the GOOSE messages of each existing IED(2), and It is a hierarchical structure consisting of a data layer that defines the data set setting corresponding to the data transmission rule through the MMS report message or GOOSE message of each existing IED(2). A virtual model of each existing IED 2 is created by generating data representing it.

The location layer consists of an acquisition location of each dataset, an acquisition location of each RCB, and an acquisition location of each GCB. The acquisition position of each data set indicates the acquisition position of the data set for each event transmitted when each event occurs. The acquisition position of each RCB indicates the acquisition position of each RCB corresponding to the MMS transmission rule of the dataset for each event. The GCB acquisition position indicates the acquisition position of each GCB corresponding to the GOOSE transmission rule of the data set for each event. Each dataset, each RCB, and each GCB is stored at a specific address in the storage 67 shown in FIG. For example, the acquisition location of each dataset, the acquisition location of each RCB, and the acquisition location of each GCB may be a specific address of the storage 67 .

If a virtual model of an existing IED 2 is generated based on the IET shown in FIG. 5, the acquisition positions of three datasets, the acquisition positions of two RCBs, and the acquisition positions of one GCB are all "K2689_P677_87P" /LLN0", and it can be seen that three datasets, two RCBs, and one GCB are obtained from this same location. Several events occur in the substation. For example, an event of measuring an output voltage of a transformer, an event of monitoring a trip state of a circuit breaker, and the like may be mentioned. When any of these events occurs, the data transmitted when the event occurs is expressed in a specific data set format. The IED connects to a specific location where the data set is stored and reads the data set from that location. can

The Ethernet layer consists of the name and MAC address of each existing IED(2). If a virtual model of an existing IED 2 is generated based on the IET shown in FIG. 5, the name of the existing IED 2 becomes "K2689_P677_87", and its MAC address is "01-0C-CD -01-00-68".

The IP layer consists of the name and IP address of each existing IED(2). If a virtual model of an existing IED 2 is created based on the IET shown in FIG. 5, the name of the existing IED 2 becomes "K2689_P677_87", and its IP address is "10.62.54.104" do. Since the name of each existing IED2 exists in common in the Ethernet layer and the IP layer, the Ethernet layer and the IP layer may share the name of each existing IED2.

The RCB layer consists of the RCB name of each existing IED(2), the name of the dataset for each RCB name, the report ID for each RCB name, and whether or not buffering is supported for each RCB name. The RCB name of each existing IED(2) indicates the name of the RCB corresponding to the transmission rule of the MMS report message transmitted when each event occurs in each existing IED(2). The name of the dataset for each RCB name indicates the name of the dataset carried in the MMS report message transmitted according to each RCB. The report ID for each RCB name indicates an ID for identifying the MMS report message transmitted according to each RCB. Whether buffering is supported by each RCB name indicates whether buffering of an MMS report message transmitted according to each RCB is supported.

If a virtual model of a certain existing IED 2 is generated based on the IET shown in FIG. 5 , the RCB names for each name of the existing IED 2 are “urcb1”, “urcb2”, and “urcb1” The report ID becomes "K2689_P677_87P/LLN0.RP.urcb1". It can be seen that buffering is not supported for "urcb1". For "urcb2", it is set according to the IET shown in FIG. 5 in the same way as for "urcb1".

The GCB layer consists of the GCB name of each existing IED(2) and the name of the dataset for each GCB name. The name of the GCB by name of each existing IED(2) indicates the name of the RCB corresponding to the transmission rule of the GOOSE message transmitted when each event occurs in each existing IED(2). The name of the dataset for each GCB name indicates the name of the dataset carried in the GOOSE message transmitted according to each GCB. If a virtual model of an existing IED 2 is generated based on the IET shown in FIG. 5, the GCB name of the existing IED 2 becomes "Goose1", and the name of the dataset for each GCB name is " ds3". In this embodiment, depending on the number of items to be diagnosed in advance, each layer of the virtual model of the existing IED 2 as described above may be defined with a smaller number of elements or may be defined with a larger number of elements. may be

The data layer consists of the maximum number of data and the number of data for each dataset name. The maximum number of data means the maximum number of data that one existing IED 2 can transmit at a time. Depending on the type of event, the amount of data transmitted when an event occurs varies. According to the present embodiment, such a data amount is expressed as the number of unit data of a predetermined length. Depending on the performance of the IED, the maximum number of data it can transmit at one time is different. The number of data for each dataset name indicates the number of data transmitted through each dataset. If a virtual model of an existing IED 2 is generated based on the IET shown in FIG. 5, the maximum number of data is 417, the number of data in the dataset "ds1" is 79, and the data in the dataset "ds2" The number is 21, and the number of data in the dataset "ds3" is 4.

In step 342 , the first virtualization unit 641 generates data representing MMS communication settings with a plurality of existing IEDs 2 for each upper client based on the IET of each existing IED 2 generated in step 33 , Create a virtual model of the client. Fig. 6(b) shows a virtual model of each upper level client. Referring to (b) of FIG. 6 , the first virtualization unit 641 includes an IP layer defining IP communication settings of each upper client, an RCB layer defining RCB settings of an MMS report message of each upper client, and an MMS report It is a hierarchical structure consisting of a data layer that defines the data set setting corresponding to the data transmission rule through the message, and creates a virtual model of each upper client by generating data representing the MMS communication rule for each upper client. Since data is transmitted through the MMS report message between the existing IED(2) and the upper client, the location layer, Ethernet layer, and GOOSE layer do not exist in the virtual model of each upper client.

The IP layer consists of the name and IP address of each upper client. When a virtual model of a certain upper client is generated based on the IET shown in FIG. 5 , an MMS report message including the data set “ds1” is transmitted to the HMI client 1 and the gateway 4 . The MMS report message containing the data set "ds2" is also sent to the HMI client 1 and the gateway 4 . In this case, the destination of a certain IP packet among the plurality of IP packets captured by the communication unit 61 in step 31 is the HMI client 1 , and the destination of another IP packet is the gateway 4 . The first destination IP address of the plurality of IP packets captured by the communication unit 61 becomes the IP address of the first upper client, "client1" is assigned to the name of the first upper client, and the second destination IP address is two It becomes the IP address of the second upper level client, and "client2" is assigned to the second upper level client's name.

The RCB layer consists of the RCB name of each upper client, the name of the dataset for each RCB name, the report ID for each RCB name, and whether or not buffering is supported by each RCB name. The RCB name of each upper level client indicates the name of the RCB corresponding to the transport rule of the MMS report message received to each upper level client when each event occurs. The name of the dataset for each RCB name indicates the name of the dataset carried in the MMS report message transmitted according to each RCB. The report ID for each RCB name indicates an ID for identifying the MMS report message transmitted according to each RCB. Whether buffering is supported by each RCB name indicates whether buffering of an MMS report message transmitted according to each RCB is supported.

When a virtual model of a certain higher-level client is generated based on the IET shown in FIG. 5, the RCB names for each upper-level client are "urcb1" and "urcb2", and the report ID of "urcb1" is "K2689_P677_87P/ LLN0.RP.urcb1". It can be seen that buffering is not supported for "urcb1". For "urcb2", it is set according to the IET shown in FIG. 5 in the same way as for "urcb1".

The data layer consists of the maximum number of data and the number of data for each dataset name. The maximum number of data means the maximum number of data that one upper level client can receive at one time. Depending on the type of event, the amount of data received when an event occurs varies. The number of data for each dataset name indicates the number of data received through each dataset. If a virtual model of a certain upper client is generated based on the IET shown in FIG. 5, the maximum number of data is 417, the number of data in the dataset "ds1" is 79, and the number of data in the dataset "ds2" is 21 it's a dog

In step 35, the virtualization unit 64 of the advance diagnosis device 6 generates a virtual model of each of the at least one new IED 20 to be installed in the substation based on the IET of each new IED 20 input by the user. do. As described above, the IET of the new IED 20 is provided by the IED manufacturer. The user may input the IET of the new IED 20 into the pre-diagnosis device 6 using the user interface 66 or the like. The second virtualization unit 642 among the virtualization units 64 is responsible for generating a virtual model of each new IED 20 based on the IET of each new IED 20 . The second virtualization unit 642 is based on the IET of each new IED 20 , indicating the MMS communication setting with at least one upper client for each new IED 20 and the GOOSE communication setting with the plurality of existing IEDs 2 . By generating data, a virtual model of each new IED 20 is created.

Fig. 6 (a) shows a virtual model of each IED. Referring to (a) of FIG. 6 , the first virtualization unit 641 defines a location layer defining an acquisition location of data to be transmitted by each new IED 20 , and an IP communication setting of each new IED 20 . Data defining the data set setting corresponding to the IP layer, the RCB layer defining the RCB setting of the MMS report message of each new IED 20, and the data transmission rule through the MMS report message of each new IED 20 Data representing the MMS communication rule is generated for each new IED 20 in a hierarchical structure consisting of layers. In addition, the second virtualization unit 642 includes a location layer defining an acquisition location of data to be transmitted by each new IED 20, an Ethernet layer defining an Ethernet communication setting of each new IED 20, and each new IED ( A hierarchical structure consisting of a GOOSE layer defining the GCB setting of the GOOSE message of 20) Generates data representing GOOSE communication rules for each.

That is, the second virtualization unit 642 includes a location layer defining an acquisition location of data to be transmitted by each new IED 20 , an Ethernet layer defining an Ethernet communication setting of each new IED 20 , and each new IED ( 20) IP layer defining the IP communication setting, RCB layer defining the RCB setting of the MMS report message of each new IED 20, the GOOSE layer defining the GCB setting of the GOOSE message of each new IED 20, and It is a hierarchical structure consisting of a data layer that defines the data set setting corresponding to the data transmission rule through the MMS report message or GOOSE message of each new IED 20, A virtual model of each new IED 20 is created by generating the data representing.

The IET of each new IED 20 is also prepared in the same table format as the IET shown in FIG. 5 . Accordingly, the virtual model generation of each new IED 20 by the second virtualization unit 642 proceeds in the same manner as the virtual model generation of each new IED 20 by the first virtualization unit 641 . A detailed description of the location layer, Ethernet layer, IP layer, RCB layer, GOOSE layer, and data layer of the virtual model of each new IED 20 is the location layer, Ethernet layer, IP layer of the virtual model of each existing IED 2 It will be replaced with a description of the layer, the RCB layer, the GOOSE layer, and the data layer.

In step 36, the virtualization unit 64 of the advance diagnosis device 6 updates the virtual model of the substation by adding the virtual model of each new IED 20 generated in step 35 to the virtual model of the substation created in step 34. . The update unit 643 of the virtualization unit 64 is responsible for updating the virtual model of the substation by adding the virtual model of each new IED 20 generated in step 35 to the virtual model of the substation created in step 34. . The virtual model of the substation generated in step 34 may be a set of virtual models of each of the plurality of existing IEDs 2 shown in FIG. 2 and virtual models of each of at least one higher-level client. The updated virtual model of the substation in step 36 is a set of virtual models of each of a plurality of existing IEDs 2 , a virtual model of at least one new IED 20 , and a virtual model of each of at least one higher-level client.

In step 37, the diagnostic unit 65 of the pre-diagnosis device 6 uses the substation virtual model updated by the update unit 643 in step 36 to the substation in a state in which at least one new IED 20 is installed in the substation. Diagnose communication status in advance. The diagnosis unit 65 diagnoses whether the MMS communication setting of the virtual model of each new IED 20 matches the MMS communication setting of the virtual model of each of at least one higher-level client for each new IED 20 MMS communication GOOSE for each new IED(20) by diagnosing the status and diagnosing whether the GOOSE communication setting of the virtual model of each new IED(20) matches the GOOSE communication setting of each virtual model of a plurality of existing IEDs(2) By diagnosing the communication status, the substation communication status is pre-diagnosed.

7 is a flowchart of an MMS communication diagnosis process between a new IED 20 and an upper client according to an embodiment of the present invention. The MMS communication diagnosis process between a certain new IED 20 and a certain upper client among the 37-step pre-diagnosis process shown in FIG. 3 is a diagnosis in the location layer of the virtual model of the new IED 20, the new IED 20 Diagnosis in the IP layer of the virtual model of the virtual model and the virtual model of the upper client, the diagnosis in the RCB layer of the virtual model of the new IED 20 and the virtual model of the upper client, and the virtual model of the new IED 20 and diagnosis in the data layer of the virtual model of the higher client.

In step 71 , the diagnosis unit 65 attempts to access the data acquisition location defined in the location hierarchy of the virtual model of the first new IED 20 among the at least one new IED 20 through the network switch 5 . It is diagnosed whether there is an error in the data acquisition location defined in the location layer of the virtual model of the first new IED 20 . The diagnosis unit 65 determines whether the connection to at least one of the data acquisition position defined in the position hierarchy of the virtual model of the first new IED 20, that is, the acquisition position of each dataset and the acquisition position of each RCB, fails. Accordingly, it is diagnosed whether there is an error in the data acquisition location defined in the location layer of the virtual model of the first new IED 20 .

In step 72 , the diagnosis unit 65 confirms the diagnosis result in step 71 . As a result of the check, if the diagnosis result in step 71 indicates that there is an error in the data acquisition location defined in the location hierarchy of the virtual model of the first new IED 20, step 73 is performed. If the diagnosis result in step 71 indicates that there is no error in the data acquisition location defined in the location hierarchy of the virtual model of the first new IED 20, step 74 is performed. For example, if the data acquisition location information of the IET of the first new IED 20 is incorrect or the data acquisition location disappears due to various causes such as storage removal, the access to the data acquisition location fails and proceeds to step 73 .

In step 73, the diagnosis unit 65 determines that the access to at least one of the data acquisition location defined in the location hierarchy of the virtual model of the new IED 20, that is, the acquisition location of each dataset and the acquisition location of each RCB has failed. An error report is generated to notify, and the generated error report is output through the user interface 66 . The user can check and repair the IET and substation parts related to the data acquisition location error according to the outputted pre-diagnosis report.

In step 74, the diagnosis unit 65 compares the IP communication setting defined in the IP layer of the virtual model of the first new IED 20 with the IP communication setting defined in the IP layer of the virtual model of the first upper client 1 By doing so, it is diagnosed whether there is an error in the IP communication setting defined in the IP layer of the virtual model of the first new IED 20 . For example, the diagnosis unit 65 checks whether the IP address of the first new IED 20 is set to the IP address system of the substation network identified from the IP address of the first upper client 1 by comparing as described above, and , the IP defined in the IP layer of the virtual model of the first new IED 20 in a way to check whether the IP address of the first new IED 20 is duplicated in the name of another IED or upper client of the substation virtual model It is possible to diagnose whether there is an error in the communication setting.

In step 75 , the diagnosis unit 65 confirms the diagnosis result in step 74 . As a result of the check, if the diagnosis result in step 74 indicates that there is an error in the IP communication setting defined in the IP layer of the virtual model of the first new IED 20 , the process proceeds to step 76 . If the diagnosis result in step 74 indicates that there is no error in the IP communication setting defined in the IP layer of the virtual model of the first new IED 20 , the process proceeds to step 77 . For example, if the IP address system of the IP address of the first new IED 20 is incorrect or the IP address is duplicated, step 76 is performed.

In step 76, the diagnostic unit 65 generates an error report indicating that there is an error in the IP communication setting of the first new IED 20 among the MMS communication settings of the first new IED 20 for the first upper level client 1 generated, and the generated error report is output through the user interface 66 . The error report may include a specific error cause, such as a duplicate IP address of the first new IED 20 . The user can check and repair the IET and substation parts related to the IP communication setting error according to the pre-diagnosis report printed in this way.

In step 77, the diagnostic unit 65 compares the RCB settings defined in the RCB layer of the virtual model of the first new IED 20 with the RCB settings defined in the RCB layer of the virtual model of the first upper client 1 to make the first 1 Diagnose whether there is an error in the RCB setting defined in the RCB layer of the virtual model of the new IED 20 . For example, the diagnosis unit 65 compares at least one RCB name defined in the RCB layer of the virtual model of the first new IED 20 in the RCB layer of the virtual model of the first upper client 1 by comparing as described above. It is possible to diagnose whether an error in the RCB configuration defined in the RCB layer of the virtual model of the first new IED 20 is made by checking whether it matches any one of the defined at least one RCB name.

In step 78 , the diagnosis unit 65 confirms the diagnosis result in step 77 . As a result of the check, if the diagnosis result in step 77 indicates that there is an error in the RCB setting defined in the RCB layer of the virtual model of the first new IED 20 , the process proceeds to step 79 . If the diagnosis result in step 74 indicates that there is no error in the RCB setting defined in the RCB layer of the virtual model of the first new IED 20 , the process proceeds to step 710 . For example, at least one RCB name defined in the RCB layer of the virtual model of the first new IED 20 is any one of the at least one RCB name defined in the RCB layer of the virtual model of the first upper client 1 If it does not match, proceed to step 79.

In step 79, the diagnostic unit 65 generates an error report indicating that there is an error in the RCB setting of the first new IED 20 among the MMS communication settings of the first new IED 20 for the first upper level client 1 and output the error report generated in this way through the user interface 66 . The error report may include a specific error cause, such as an RCB name mismatch between the first new IED 20 and the first upper client 1 . The user can check and repair the IET and substation parts related to the RCB setting error according to the pre-diagnosis report printed in this way.

In step 710 , the diagnosis unit 65 compares the dataset setting defined in the data layer of the virtual model of the first new IED 20 with the dataset setting defined in the data layer of the virtual model of the first upper client 1 . By doing so, it is diagnosed whether there is an error in the data set setting defined in the data layer of the virtual model of the first new IED 20 . For example, the diagnosis unit 65 compares at least one data set name defined in the data layer of the virtual model of the first new IED 20 to the data layer of the virtual model of the first upper client 1 by comparing as described above. It is possible to diagnose whether there is an error in the dataset setting defined in the data layer of the virtual model of the first new IED 20 by checking whether any one of the at least one dataset name defined in .

In step 711 , the diagnosis unit 65 confirms the diagnosis result in step 710 . As a result of the check, if the diagnosis result in step 77 indicates that there is an error in the data set setting defined in the data layer of the virtual model of the first new IED 20 , the process proceeds to step 79 . If the diagnosis result in step 74 indicates that there is no error in the dataset setting defined in the data layer of the virtual model of the first new IED 20 , the process proceeds to step 712 . For example, the at least one dataset name defined in the data layer of the virtual model of the first new IED 20 is among the at least one dataset name defined in the data layer of the virtual model of the first upper client 1 . If none of them match, proceed to step 713.

In step 712 , the diagnostic unit 65 generates an error report indicating that there is an error in the data set setting of the first new IED 20 among the MMS communication settings of the first new IED 20 for the first higher level client 1 . is generated, and the error report thus generated is outputted through the user interface 66 . The error report may include a specific error cause such as a data set name mismatch between the first new IED 20 and the first upper client 1 . The user can check and repair the IET and substation parts related to the data set setting error according to the pre-diagnosis report printed in this way.

In step 713 , the diagnosis unit 65 generates a matching report indicating that the MMS communication setting of the virtual model of the first new IED 20 matches the MMS communication setting of the virtual model of the first upper level client 1 , and thus The generated matching report is output through the user interface 66 . As such, when the matching report is output, the user installs the first new IED 20 in the substation and actually proceeds with the MMS communication setting operation of the first new IED 20 according to the IET.

In step 714 , the diagnosis unit 65 checks whether MMS communication diagnosis with all upper-level clients is completed for all of the at least one new IED 20 to be installed in the substation. As a result of the check, if the MMS communication diagnosis with all upper clients for all of the at least one IED 20 to be installed in the substation has not been completed, the process returns to step 71 . When there are a plurality of upper level clients, the MMS communication diagnosis process between the first new IED 20 and the second upper level client is performed while steps 71 to 713 are repeated. After the MMS communication diagnosis between the first new IED 20 and all upper clients is completed, if there are a plurality of new IEDs 20, steps 71 to 713 are repeated while MMS between the second new IED 20 and the first upper clients The communication diagnostic process is in progress. In this way, the MMS communication diagnosis process between all new IEDs 20 and all higher-level clients proceeds.

8 is a flowchart of a GOOSE communication diagnosis process between a new IED 20 and an existing IED 2 according to an embodiment of the present invention. The GOOSE communication diagnostic process between any new IED 20 and any existing IED 2 among the 37-step pre-diagnosis process shown in FIG. 3 is the diagnosis in the location layer of the virtual model of the new IED 20, the new IED Diagnosis in the Ethernet layer of the virtual model of (20) and the virtual model of the existing IED 2, the diagnosis in the GCB layer of the virtual model of the new IED 20 and the virtual model of the existing IED 2, and It consists of a diagnosis in the data layer of the virtual model of the new IED 20 and the virtual model of the existing IED 2 .

In step 81 , the diagnosis unit 65 attempts to access the data acquisition location defined in the location hierarchy of the virtual model of the first new IED 20 among the at least one new IED 20 through the network switch 5 . It is diagnosed whether there is an error in the data acquisition location defined in the location layer of the virtual model of the first new IED 20 . The diagnosis unit 65 determines whether the connection to at least one of the data acquisition position defined in the position hierarchy of the virtual model of the first new IED 20, that is, the acquisition position of each dataset and the acquisition position of each GCB, fails. Accordingly, it is diagnosed whether there is an error in the data acquisition location defined in the location layer of the virtual model of the first new IED 20 .

In step 82 , the diagnosis unit 65 confirms the diagnosis result in step 81 . As a result of the check, if the diagnosis result in step 81 indicates that there is an error in the data acquisition location defined in the location hierarchy of the virtual model of the first new IED 20, step 83 is performed. If the diagnosis result in step 81 indicates that there is no error in the data acquisition location defined in the location hierarchy of the virtual model of the first new IED 20 , the process proceeds to step 84 . For example, if the data acquisition location information of the IET of the first new IED 20 is incorrect or the data acquisition location disappears due to various causes such as storage removal, access to the data acquisition location fails and proceeds to step 83 .

In step 83, the diagnosis unit 65 determines that the access to at least one of the data acquisition position defined in the position hierarchy of the virtual model of the new IED 20, that is, the acquisition position of each dataset and the acquisition position of each GCB has failed. An error report is generated to notify, and the generated error report is output through the user interface 66 . The user can check and repair the IET and substation parts related to the data acquisition location error according to the outputted pre-diagnosis report.

In step 84 , the diagnosis unit 65 compares the Ethernet communication settings defined in the Ethernet layer of the virtual model of the first new IED 20 with the Ethernet communication settings defined in the Ethernet layer of the virtual model of the first existing IED 2 . By doing so, it is diagnosed whether there is an error in the Ethernet communication setting defined in the Ethernet layer of the virtual model of the first new IED 20 . For example, the diagnosis unit 65 compares the first new IED in such a way as to check whether the MAC address of the first new IED 20 is duplicated in the names of other IEDs or higher-level clients of the substation virtual model by comparing as described above. It is possible to diagnose whether there is an error in the Ethernet communication setting defined in the Ethernet layer of the virtual model of (20).

In step 85 , the diagnosis unit 65 confirms the diagnosis result in step 84 . As a result of the check, if the diagnosis result in step 84 indicates that there is an error in the Ethernet communication setting defined in the Ethernet layer of the virtual model of the first new IED 20 , the process proceeds to step 86 . If the diagnosis result in step 84 indicates that there is no error in the Ethernet communication setting defined in the Ethernet layer of the virtual model of the first new IED 20 , the process proceeds to step 87 . For example, if the MAC address is duplicated, the process proceeds to step 86.

In step 86, the diagnostic unit 65 generates an error report indicating that there is an error in the Ethernet communication setting of the first new IED 20 among the GOOSE communication settings of the first new IED 20 for the first existing IED 2 generated, and the generated error report is output through the user interface 66 . The error report may include a specific cause of error, such as a duplicate MAC address of the first new IED 20 . The user can check and repair the IET and substation parts related to the Ethernet communication setting error according to the pre-diagnosis report printed in this way.

In step 87, the diagnostic unit 65 compares the GCB settings defined in the GCB layer of the virtual model of the first new IED 20 with the GCB settings defined in the GCB layer of the virtual model of the first existing IED 2 to make the first 1 Diagnose whether there is an error in the GCB setting defined in the GCB layer of the virtual model of the new IED 20 . For example, the diagnosis unit 65 compares the at least one GCB name defined in the GCB layer of the virtual model of the first new IED 20 in the GCB layer of the virtual model of the first existing IED 2 by comparing as described above. Whether or not an error in the GCB setting defined in the GCB layer of the virtual model of the first new IED 20 is diagnosed may be diagnosed by checking whether it matches any one of the defined at least one GCB name.

In step 88 , the diagnosis unit 65 confirms the diagnosis result in step 87 . As a result of the check, if the diagnosis result in step 87 indicates that there is an error in the GCB setting defined in the GCB layer of the virtual model of the first new IED 20 , the process proceeds to step 89 . If the diagnosis result in step 84 indicates that there is no error in the GCB setting defined in the GCB layer of the virtual model of the first new IED 20 , the process proceeds to step 810 . For example, at least one GCB name defined in the GCB layer of the virtual model of the first new IED 20 is any one of the at least one GCB name defined in the GCB layer of the virtual model of the first existing IED 2 If it does not match, proceed to step 89.

In step 89, the diagnostic unit 65 generates an error report indicating that there is an error in the GCB setting of the first new IED 20 among the GOOSE communication settings of the first new IED 20 for the first upper client 1 and output the error report generated in this way through the user interface 66 . The error report may include a specific error cause such as a GCB name mismatch between the first new IED 20 and the first existing IED 2 . The user can check and repair the IET and substation parts related to the GCB setting error according to the pre-diagnosis report printed in this way.

In step 810 , the diagnosis unit 65 compares the dataset settings defined in the data layer of the virtual model of the first new IED 20 with the dataset settings defined in the data layer of the virtual model of the first existing IED 2 . By doing so, it is diagnosed whether there is an error in the data set setting defined in the data layer of the virtual model of the first new IED 20 . For example, the diagnosis unit 65 compares at least one data set name defined in the data layer of the virtual model of the first new IED 20 to the data layer of the virtual model of the first existing IED 2 by comparing as described above. It is possible to diagnose whether there is an error in the dataset setting defined in the data layer of the virtual model of the first new IED 20 by checking whether any one of the at least one dataset name defined in .

In step 811 , the diagnosis unit 65 confirms the diagnosis result in step 810 . As a result of the check, if the diagnosis result in step 87 indicates that there is an error in the dataset setting defined in the data layer of the virtual model of the first new IED 20 , the process proceeds to step 89 . If the diagnosis result in step 84 indicates that there is no error in the dataset setting defined in the data layer of the virtual model of the first new IED 20 , the process proceeds to step 812 . For example, the at least one dataset name defined in the data layer of the virtual model of the first new IED 20 is among the at least one dataset name defined in the data layer of the virtual model of the first existing IED 2 . If none of them match, proceed to step 813.

In step 812, the diagnostic unit 65 generates an error report indicating that there is an error in the data set setting of the first new IED 20 among the GOOSE communication settings of the first new IED 20 for the first upper client 1 is generated, and the error report thus generated is outputted through the user interface 66 . The error report may include a specific error cause such as a data set name mismatch between the first new IED 20 and the first existing IED 2 . The user can check and repair the IET and substation parts related to the data set setting error according to the pre-diagnosis report printed in this way.

In step 813 , the diagnosis unit 65 generates a matching report indicating that the GOOSE communication setting of the virtual model of the first new IED 20 matches the GOOSE communication setting of the virtual model of the first existing IED 2 , and in this way The generated matching report is output through the user interface 66 . As such, when the matching report is output, the user installs the first new IED 20 in the substation, and actually proceeds with the GOOSE communication setting operation of the first new IED 20 according to the IET.

In step 814 , the diagnosis unit 65 checks whether GOOSE communication diagnosis with all existing IEDs is completed for all of the at least one new IED 20 to be installed in the substation. As a result of the check, if the GOOSE communication diagnosis with all the existing IEDs (2) for all of the at least one IED (20) to be installed in the substation is not completed, the process returns to step 81. When there are a plurality of existing IEDs, the GOOSE communication diagnosis process between the first new IED 20 and the second existing IED is performed while steps 81 to 813 are repeated. After the GOOSE communication diagnosis between the first new IED 20 and all existing IEDs is completed, if there are multiple new IEDs 20, steps 81 to 813 are repeated while GOOSE between the second new IED 20 and the first existing IEDs. The communication diagnostic process is in progress. In this way, the GOOSE communication diagnostic process between all new IEDs 20 and all existing IEDs is performed.

As such, according to the present embodiment, by using the substation virtual model to pre-diagnose the communication state of the substation in a state in which at least one new IED 20 is installed in the substation, the substation before installing the new IED 20 in the substation in the field. It is possible to diagnose in advance the substation communication state in the state in which the new IED 20 is installed. In particular, before the on-site installation of the new IED 20, the new IED 20 is installed on-site after diagnosing communication errors related to the SCL file, IET, and the like in advance to solve the communication errors by the user. It is possible to minimize the communication error during the field installation of the new IED (20) by allowing it to proceed.

Furthermore, the virtual model of each IED and each upper client is expressed in a hierarchical structure such as location layer, Ethernet layer, IP layer, RCB layer, GCB layer, and data layer, and diagnoses for each layer of the virtual model of the new IED 20 By performing this, it is possible for the user to easily find the cause of the communication error that will occur in the field installation process of the new IED 20 and to solve it in advance. As a result, the on-site installation work of the new IED 20 can be completed quickly.

So far, with respect to the present invention, the preferred embodiments have been looked at. Those of ordinary skill in the art to which the present invention pertains will understand that the present invention may be implemented in a modified form without departing from the essential characteristics of the present invention. Therefore, the disclosed embodiments are to be considered in an illustrative rather than a restrictive sense. The scope of the present invention is indicated in the claims rather than the foregoing description, and all differences within the scope equivalent thereto should be construed as being included in the present invention.

1 ... HMI client
2 ... conventional IEDs
20 ... new IEDs
3 ... Skada
4 ... gateway
5 ... network switch
6 ... advance diagnosis device
61 ... Ministry of Communications
62 ... packet processing unit
63 ... IET generator
64 ... virtualization department
641 ... first virtualization unit
642 ... the second virtualization unit
643 ... update
65 ... diagnostic department
66 ... user interface
67 ... storage

Claims (16)

capturing a plurality of packets transmitted from a plurality of existing IEDs installed in a substation;
generating a virtual model of the substation by generating a virtual model of each of the existing IEDs and a virtual model of each of the at least one upper client of the substation based on the captured plurality of packets;
generating a virtual model of each of the at least one new IED to be installed in the substation;
updating the virtual model of the substation by adding the virtual model of each new IED to the virtual model of the substation; and
and diagnosing a substation communication state in a state in which the at least one new IED is installed in the substation by using the updated substation virtual model. The method of claim 1,
Further comprising the step of extracting the information of each existing IED from the captured plurality of packets,
The generating of the virtual model of the substation includes generating a virtual model of the substation based on the extracted information of each existing IED. 3. The method of claim 2,
The generating of the virtual model of the substation includes generating a virtual model of the substation by generating a virtual model of each of the existing IEDs based on the extracted information of each existing IED. 4. The method of claim 3,
The generating of the virtual model of the substation may include generating a virtual model of each of the at least one higher-level client of the substation together with the virtual model of each existing IED based on the extracted information of each existing IED, thereby creating a virtual model of the substation. Substation advance diagnosis method, characterized in that for generating. 5. The method of claim 4,
The step of generating a virtual model of the substation is
By generating data indicating MMS communication setting with the at least one upper client and GOOSE communication setting with another existing IED among the plurality of existing IEDs for each existing IED based on the extracted information of each existing IED, each existing IED creating a virtual model of the IED; and
and generating a virtual model of each higher level client by generating data representing MMS communication settings with the plurality of existing IEDs for each higher level client based on the extracted information of each existing IED. Pre-diagnosis method. 6. The method of claim 5,
The generating of the virtual model of each new IED may include generating data indicating the MMS communication setting with the at least one upper client and the GOOSE communication setting with the plurality of existing IEDs for each new IED by generating the virtual model of each new IED. Substation advance diagnosis method, characterized in that for generating a model. 7. The method of claim 6,
The pre-diagnosing includes diagnosing the MMS communication state of each new IED in such a way that it is diagnosed whether the MMS communication setting of the virtual model of each new IED matches the MMS communication setting of the virtual model of each of the at least one higher-level client. And, by diagnosing the GOOSE communication state for each new IED in a way of diagnosing whether the GOOSE communication setting of the virtual model of each new IED matches the GOOSE communication setting of the virtual model of each of the plurality of IEDs, the substation communication state is determined Substation advance diagnosis method, characterized in that the advance diagnosis. 7. The method of claim 6,
The step of generating the virtual model of each new IED includes an IP layer defining an IP communication setting of each new IED, an RCB layer defining an RCB setting of an MMS report message of each new IED, and an MMS report of each new IED. A substation pre-diagnosis method, characterized in that the data representing the MMS communication setting is generated for each new IED in a hierarchical structure including a data layer defining a data set setting corresponding to a data transmission rule through a message. 9. The method of claim 8,
The preliminary diagnosis is
IP communication settings defined in the IP layer of the virtual model of any one new IED among the at least one new IED and the IP communication settings defined in the IP layer of the virtual model of any one upper client among the at least one upper client diagnosing whether there is an error in the IP communication setting defined in the IP layer of the virtual model of the one new IED by comparing; and
If it is confirmed that there is no error in the IP communication setting defined in the IP layer of the virtual model of the one new IED, the RCB setting defined in the RCB layer of the virtual model of the one new IED and the one higher client Substation pre-diagnosis method comprising the step of diagnosing whether the RCB setting defined in the RCB layer of the virtual model of any one of the new IEDs is in error by comparing the RCB settings defined in the RCB layer of the virtual model of 10. The method of claim 9,
The preliminary diagnosis is
If it is confirmed that there is no error in the RCB setting defined in the RCB layer of the virtual model of the one new IED, the dataset setting defined in the data layer of the virtual model of the one new IED and the one higher client By comparing the dataset settings defined in the data layer of the virtual model of diagnostic method. 10. The method of claim 9,
The generating of the virtual model of each new IED has a hierarchical structure further including a location layer defining an acquisition location of data to be transmitted by each existing IED, and data representing the MMS communication setting is generated for each new IED. do,
The step of pre-diagnosing is an error of the data acquisition position defined in the location layer of the virtual model of any one new IED by attempting to access the data acquisition location defined in the location layer of the virtual model of the one new IED. Substation advance diagnosis method, characterized in that it further comprises the step of diagnosing whether or not. 7. The method of claim 6,
The step of generating the virtual model of each new IED includes an Ethernet layer defining Ethernet communication settings of each new IED, a GCB layer defining a GCB setting of the GOOSE message of each new IED, and a GOOSE message of each new IED. A substation pre-diagnosis method, characterized in that the data representing the GOOSE communication setting is generated for each new IED in a hierarchical structure including a data layer defining a data set setting corresponding to a data transmission rule through the transmission. 13. The method of claim 12,
The preliminary diagnosis is
Compare the Ethernet communication setting defined in the Ethernet layer of the virtual model of the new IED among the at least one new IED and the Ethernet communication setting defined in the Ethernet layer of the virtual model of the existing IED of any one of the plurality of existing IEDs. diagnosing whether there is an error in the Ethernet communication setting defined in the Ethernet layer of the virtual model of any one of the new IEDs by doing so; and
If it is confirmed that there is no error in the Ethernet communication setting defined in the Ethernet layer of the virtual model of the one new IED, the GCB setting defined in the GCB layer of the virtual model of the one new IED and the one existing IED By comparing the GCB settings defined in the GCB layer of the virtual model of 14. The method of claim 13,
The preliminary diagnosis is
If it is confirmed that there is no error in the GCB setting defined in the GCB layer of the virtual model of the one new IED, the dataset setting defined in the data layer of the virtual model of the one new IED and the one existing IED By comparing the dataset settings defined in the data layer of the virtual model of diagnostic method. 14. The method of claim 13,
The generating of the virtual model of each new IED is a hierarchical structure further including a location layer defining an acquisition location of data to be transmitted by each existing IED, and data representing the GOOSE communication setting is generated for each new IED. do,
The step of pre-diagnosing is an error of the data acquisition position defined in the location layer of the virtual model of any one new IED by attempting to access the data acquisition location defined in the location layer of the virtual model of the one new IED. Substation advance diagnosis method, characterized in that it further comprises the step of diagnosing whether or not. a communication unit for capturing a plurality of packets transmitted from a plurality of existing IEDs installed in a substation;
a first virtualization unit for generating a virtual model of the substation by generating a virtual model of each of the existing IEDs and a virtual model of each of the at least one upper client of the substation based on the captured plurality of packets;
a second virtualization unit generating a virtual model of each of at least one new IED to be installed in the substation;
an update unit for updating the virtual model of the substation by adding the virtual model of each new IED to the virtual model of the substation; and
and a diagnosis unit configured to pre-diagnose a substation communication state in a state in which the at least one new IED is installed in the substation by using the updated substation virtual model.

Images