WO2022083069A1 - Method and apparatus for automatically associating primary and secondary equipment models of smart substation - Google Patents

Abstract

Disclosed in the present invention are a method and apparatus for automatically associating primary and secondary equipment models of a smart substation: for a cross-interval secondary equipment model, configuring a specific interval prefix for each interval LN (logic node) in the model to implement interval LN grouping, and establishing interval association LN to provide a primary and secondary interval association interface; configuring an SCD file to implement the instantiation of each secondary equipment model, importing an SSD file into the SCD file, directly associating a single-interval secondary equipment CID file with a related primary interval in the SSD, and assigning each interval DO of the interval association LN in a cross-interval secondary equipment CID file to complete interval association; specifying a secondary equipment LN association relationship for a primary equipment object type; and, on the basis of the association relationship between the primary equipment object type and the secondary equipment LN, associating the primary equipment in each interval with the related secondary equipment LN in each single-interval and cross-interval secondary equipment model. The present invention implements the automatic association of primary and secondary equipment models of a smart substation.

Description

A method and device for automatic association of primary and secondary equipment models in smart substations technical field

The invention relates to the technical field of intelligent substations, in particular to a method and device for automatically associating primary and secondary equipment models of an intelligent substation.

Background technique

The IEC61850 standard is the basis for the construction of smart substations. The standard defines the configuration system specification description SSD (system specification description) file, which describes the primary system structure and the relationship between primary and secondary equipment. Association relationship, you can obtain useful information such as which secondary equipment logical nodes (LN, the abbreviation of logical node) are associated with a primary device, and which secondary equipment logical nodes are associated with the same interval, but take a medium-scale 220kV smart substation as an example , Hundreds of secondary devices need to be associated with thousands of LNs with primary devices. Objectively, this also brings great obstacles to the application of SSD files. At present, during the integration process of smart substations, SSD files are basically not associated with secondary devices. For the secondary device LN, many stations do not even have an SSD file configured at all.

In recent years, the advanced application technology of smart substation operation and maintenance has been continuously developed. The functions based on secondary equipment information include the homologous comparison analysis of analog quantities and switch quantities originating from the same primary equipment, and the corresponding monitoring of the status of primary and secondary equipment. Due to the unclear relationship between the primary and secondary equipment, the data foundation of advanced applications based on the status of the primary and secondary equipment and the status information between the secondary equipment in the interval is very poor. All configuration processes directly face the instantiated specific device models. The configuration work results of a single interval cannot be reused at all. It is necessary to configure signals one by one for each application function in each interval. The configuration efficiency is extremely low, and the configuration correctness is difficult to guarantee. Once the model of a certain device changes, the related configuration work needs to be completed again.

Therefore, it is urgent to study how to realize the automatic association of primary and secondary equipment models of smart substations, and promote the practical level of intelligent advanced application functions based on primary and secondary equipment information in smart stations.

SUMMARY OF THE INVENTION

In order to solve the deficiencies in the prior art, the present invention provides a method and device for automatically correlating primary and secondary equipment models of an intelligent substation, which solves the problem of the unclear relationship between primary and secondary equipment leading to the configuration of advanced application function modules based on secondary equipment status information. The process directly faces the instantiated specific device model, the configuration efficiency is extremely low, and the configuration correctness is difficult to guarantee.

In order to achieve the above goals, the present invention adopts the following technical solutions: a method for automatically associating primary and secondary equipment models of an intelligent substation, comprising:

For the cross-interval secondary equipment model, configure and set the interval prefix for each interval logical node LN in the model to complete the interval LN grouping, and establish the interval association LN to provide a secondary interval association interface;

Configure the SCD file to complete the instantiation of each secondary equipment model, import the SSD file into the SCD file, directly associate the single-interval secondary equipment CID file with the relevant primary interval in the SSD, and associate the interval in the cross-interval secondary equipment CID file with each LN of the secondary equipment. Interval DO assignment to complete interval association;

Specify the LN association relationship of secondary equipment for the primary equipment object type;

According to the relationship between the primary equipment object type and the secondary equipment LN, the primary equipment in each bay is associated with the relevant secondary equipment logical nodes LN in each single bay and cross bay secondary equipment models.

Further, the interval association LN is constituted by each interval name DO.

Further, the single-interval secondary equipment CID file is directly associated with the relevant primary interval in the SSD, and each interval DO of the interval-associated LN in the cross-interval secondary equipment CID file is assigned to complete the interval association, including:

Directly associate the CID file of the secondary device with a single interval in each interval to the corresponding part of the interval of the SSD in the SCD file;

Assign the value of each interval name DO in the interval association LN in the cross-interval secondary device CID file to the corresponding actual interval name name in the SSD file to complete the interval association.

An automatic associating device for primary and secondary equipment models of an intelligent substation, comprising:

The interval association LN configuration module adopts the set interval prefix to distinguish the secondary equipment LN of each interval for the cross-interval secondary equipment model, and establishes the interval association LN to provide a secondary interval association interface;

The assignment module is used to configure the SCD file to complete the instantiation of each secondary device model, import the SSD file into the SCD file, directly associate the single-interval secondary device CID file with the relevant primary interval in the SSD, and transfer the inter-interval secondary device CID file to the middle Assign each interval DO of the interval associated LN to complete the interval association;

The association module is used to specify the LN association relationship of the secondary equipment for the primary equipment object type; according to the association relationship between the primary equipment object type and the secondary equipment LN, the primary equipment in each interval is associated with each single-interval and cross-interval secondary equipment models In the relevant secondary equipment logical node LN.

Further, the interval association LN is constituted by each interval name DO.

Further, the single-interval secondary equipment CID file is directly associated with the relevant primary interval in the SSD, and each interval DO of the interval-associated LN in the cross-interval secondary equipment CID file is assigned to complete the interval association, including:

Directly associate the CID file of the secondary device with a single interval in each interval to the corresponding part of the interval of the SSD in the SCD file;

Assign the value of each interval name DO in the inter-interval secondary device interval association LN to the corresponding actual interval name name in the SSD file to complete the interval association.

The beneficial effects achieved by the invention: the invention realizes the automatic association of the primary and secondary equipment models of the intelligent station, straightens out the data association relationship between the primary and secondary equipment of the intelligent station, and improves the configuration of intelligent advanced application functions based on the primary and secondary equipment information Efficiency and quality.

Description of drawings

Fig. 1 is the flow chart of the present invention;

FIG. 2 is a schematic diagram of the instantiated configuration of the interval-associated logical node project.

Detailed ways

The present invention will be further described below in conjunction with the accompanying drawings. The following examples are only used to illustrate the technical solutions of the present invention more clearly, and cannot be used to limit the protection scope of the present invention.

Example 1:

As shown in Figure 1, a method for automatically correlating primary and secondary equipment models of a smart substation includes the following steps:

Step 1, in the ICD (IED Capability Description File) file, for the cross-interval secondary device model, configure and set the interval prefix for each interval LN in the model to complete the interval LN grouping, and establish the interval association LN to provide a secondary interval association interface. In this way, the bay is associated with the LN in it, and the bay-associated LN interface is provided for the integration of the smart substation through the bay-associated LN;

Set specific interval prefixes for the functions, measurements, input and output, etc. LNs of different intervals in the cross-bay secondary equipment model in the ICD file; for example, the current amplitude of busbar guard interval 5 is B5MMXU1, the trip of interval 7 is B7PTRC1, etc., B5 and B7 is the set interval prefix;

The interval-related LN is composed of each interval name DO (data object). For example, the structure of a certain interval-related LN is defined as shown in Table 1.

DOs are data objects, and an LN is usually composed of multiple DOs. For example, the busbar protection can protect the busbars with 10 bays, and it is necessary to provide an interface associated with 10 bays. In this method, a bay-related LN is specially set for this purpose. This bay-related LN consists of DOs corresponding to 10 bays.

Table 1, a certain interval associated LN structure table

As shown in Table 2, the English description d of each interval name DO (d of DO is a data attribute of this data object) indicates the specific interval prefix name of the interval, as mentioned above, B5, B7, etc., the value of DO (the value of DO Another data attribute) is used to represent the name of the interval in the actual system in the SSD file (this name is the English name of the interval defined by the SSD standard), which is used to realize the association with each interval of the actual system.

Table 2, example table of busbar guard interval associated LN

DO	Interval description	VALUE	d
BAY01	Bus 1	EBUS4#	BUS1
BAY02	Bus 2	EBUS5#	BUS2
BAY03	busbar interval	CBR1	BC
BAY04	Main change 1 interval	PTR1	TR1
BAY05	Main change 2 interval		TR2
BAY06	Main change 3 interval	PTR2	TR3
BAY07	Main change 4 interval		TR4
BAY08	Line 1 Interval	LIN1	LINE1
BAY09	Line 2 Interval	LIN2	LINE2
BAY10	Line 3 Interval		LINE3
...	...	...	...

Step 2, configure the SCD file (substation configuration description file), complete the instantiation of each secondary equipment model, import the configuration system specification description SSD file into the SCD file, and import the CID (IED instance configuration file) of the single-interval and cross-interval secondary equipment The file is associated with the relevant interval of the corresponding part of the SSD in the SCD file;

Specifically, associating the CID file of the secondary device with single-interval configuration in each interval directly to the corresponding part of the interval of the SSD in the SCD file; assigning the value of each interval name DO in the inter-interval secondary device interval association LN to the corresponding actual interval in the SSD file name name.

In the inter-interval protection ICD file, the interval is associated with LN, and the English description d of each interval DO carries the prefix name of the logical node related to the interval, such as: BUS1, TR1 and so on. Associate each interval DO in the LN of the cross-interval secondary equipment model with the corresponding interval in the SSD. The specific implementation method is to assign the value of each interval name DO to the corresponding actual interval name in the SSD file to complete the interval with the actual system. association.

As shown in Figure 2, the arrow in the figure is: assigning the value of each interval name DO as the action corresponding to the actual interval name in the SSD file, and the interval name is defined in the SSD file.

The busbar protection interval associated LN sets a total of 10 interval DOs BAY1-BAY10, of which:

1. BAY01 and BAY02 are bus bays, and d is BUS1 and BUS2 respectively, indicating that the prefix names of the logical nodes related to the bus bays are BUS1 and BUS2 respectively. The corresponding bus guard intervals in the SSD of this project are instantiated as EBUS4# and EBUS5 respectively. #;

2. BAY03 is the parent tie interval, and its d is BC, indicating that the prefix name of the logical node related to the parent tie interval is BC, and the corresponding parent tie interval in the SSD of this project is instantiated as CBR1;

3. BAY04-BAY07 are four main transformer intervals, the d of which are TR1-TR4 respectively, indicating that the prefix names of the logical nodes related to the main transformer interval are TR1-TR4, and the corresponding main transformer 1 and master transformer 3 in the SSD of this project The intervals are instantiated as PTR1 and PTR2, respectively;

4. BAY08-BAY10 is the line interval, and its d is LINE1-LINE3 respectively, indicating that the prefix names of the logical nodes related to the line interval are LINE1-LINE3, respectively. The corresponding line 1 and line 2 intervals in the SSD of this project are instantiated as LIN1 respectively. and LIN2.

The main transformer protection interval is associated with LN to set a total of 10 intervals DO from BAY1-BAY10, of which:

1. BAY01 and BAY02 are the main transformer high voltage side intervals, and their d are HI1 and HI2 respectively, indicating that the prefix names of the logical nodes related to the main transformer high voltage side interval are HI1 and HI2 respectively. The corresponding main transformer high voltage side interval in the SSD of this project 1 is instantiated as PTR1;

2. BAY03 is the main transformer high voltage side interval, and its d is HIBC, indicating that the prefix of the logic node related to the main transformer high voltage side bus tie interval is named HIBC, and the corresponding bus tie interval in the SSD of this project is instantiated as CBR1;

3. BAY04 and BAY05 are the main transformer low-voltage side bays, and their d are LO1 and LO2 respectively, indicating that the prefix names of the logical nodes related to the main transformer low-voltage side bays are LO1 and LO2 respectively. The corresponding main transformer low-voltage side bays in the SSD of this project 1 and interval 2 are instantiated as CBR01 and CBR02, respectively;

4. BAY06 is the main variable body interval, and its d is PTR, indicating that the prefix of the logical node related to the main variable body interval is named PTR, and the corresponding main variable body interval in the SSD of this project is instantiated as PTR;

5. BAY07-BAY10 interval is not defined.

Step 3, specify the LN association relationship of the secondary equipment for the primary equipment object type;

This step is to specify the default relationship between the primary equipment object and the secondary equipment LN, such as the switch equipment is fixedly associated with the PTRC (trip) logical node.

Specifically: set the functions, measurements, input and output interfaces, etc. in the relevant secondary equipment models for switches, knife gates, lines, transformers, and current mutual inductance primary equipment, as shown in Table 3.

Table 3, the relationship between primary equipment object types and secondary equipment LN

one-time equipment	Secondary equipment LN
Current Transformer CTR	TCTR
Voltage Transformer VTR	TVTR
switch VBR	XCBR, PTRC, RREC, CSWI, CBGGIO
Knife Gate DIS	XSWI, SWGGIO
Line LIN	PDIF, PDIS, PTOC, PVOC, PPDP, MMXU
Transformer PTR	PDIF, PVOC, PVPH
Bus EBUS	PDIF, RBRF, MMXU

Step 4: Automatically associate the primary equipment in each bay with the relevant LNs in each single bay and cross bay secondary equipment models according to the relationship between the primary equipment object type and the secondary equipment LN.

Specifically, based on the relationship between the primary equipment object type and the secondary equipment LN, the LN in the single-bay secondary equipment and each sub-interval LN in the cross-bay secondary equipment are automatically associated with each primary equipment in the relevant bay.

According to the above steps, the association relationship between the primary interval and the single-interval secondary equipment model (step 2), and the association between the primary interval and the relevant sub-interval models in the cross-interval secondary equipment (step 2), are based on the primary equipment object. The type is associated with the secondary equipment LN (step 3), and the LN in the single-interval secondary equipment and each sub-interval LN in the cross-interval secondary equipment are automatically associated to each primary equipment in the relevant interval, and the interval one-second equipment association is indicated, As shown in Table 4. For example, MMXU1 in the line protection model and B3MMXU1 in the busbar protection model are associated with the line primary equipment LIN.

Table 4, the automatic association relationship table of primary and secondary equipment

Example 2:

An automatic association device for primary and secondary equipment models of an intelligent substation, comprising:

The interval association LN configuration module adopts the set interval prefix to distinguish the secondary equipment LN of each interval for the cross-interval secondary equipment model, and establishes the interval association LN to provide a secondary interval association interface;

The assignment module is used to configure the SCD file to complete the instantiation of each secondary device model, import the SSD file into the SCD file, directly associate the single-interval secondary device CID file with the relevant primary interval in the SSD, and transfer the inter-interval secondary device CID file to the middle Assign each interval DO of the interval associated LN to complete the interval association;

The association module is used to specify the LN association relationship of the secondary equipment for the primary equipment object type; according to the association relationship between the primary equipment object type and the secondary equipment LN, the primary equipment in each interval is associated with each single-interval and cross-interval secondary equipment models In the relevant secondary equipment logical node LN.

Further, the interval association LN is composed of each interval name DO.

Further, the single-interval secondary equipment CID file is directly associated with the relevant primary interval in the SSD, and each interval DO of the interval associated LN in the cross-interval secondary equipment CID file is assigned to complete the interval association, including:

Directly associate the CID file of the secondary device with a single interval for each interval configuration to the corresponding part of the interval of the SSD in the SCD file;

Assign the value of each interval name DO in the inter-interval secondary device interval association LN to the corresponding actual interval name name in the SSD file to complete the interval association.

In the present invention, for the cross-interval secondary equipment model, each interval LN is configured with a specific interval prefix, and a primary interval association LN is established to provide a primary interval association interface. In the intelligent station integration process, the CID file of the single-interval secondary device is directly associated with the relevant primary interval in the SSD, and the value of each interval name DO in the LN associated with the primary interval of the cross-interval secondary device is assigned as the relevant interval name in the SSD file. Based on the relationship between the primary interval and the secondary equipment model and the relationship between various types of primary equipment and the LN type of the secondary equipment, the primary equipment in the interval is automatically associated with the relevant LN in each single-interval and cross-interval secondary equipment models . This method can realize the automatic association of primary and secondary equipment models of smart stations, straighten out the relationship between primary and secondary equipment models and data associations of smart stations, and significantly improve the configuration efficiency and quality of intelligent advanced application functions based on primary and secondary equipment information.

As will be appreciated by those skilled in the art, the embodiments of the present application may be provided as a method, a system, or a computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment, or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, etc.) having computer-usable program code embodied therein.

The present application is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the present application. It will be understood that each process and/or block in the flowchart illustrations and/or block diagrams, and combinations of processes and/or blocks in the flowchart illustrations and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to the processor of a general purpose computer, special purpose computer, embedded processor or other programmable data processing device to produce a machine such that the instructions executed by the processor of the computer or other programmable data processing device produce Means for implementing the functions specified in a flow or flow of a flowchart and/or a block or blocks of a block diagram.

These computer program instructions may also be stored in a computer-readable memory capable of directing a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory result in an article of manufacture comprising instruction means, the instructions The apparatus implements the functions specified in the flow or flows of the flowcharts and/or the block or blocks of the block diagrams.

These computer program instructions can also be loaded on a computer or other programmable data processing device to cause a series of operational steps to be performed on the computer or other programmable device to produce a computer-implemented process such that The instructions provide steps for implementing the functions specified in the flow or blocks of the flowcharts and/or the block or blocks of the block diagrams.

The above are only the preferred embodiments of the present invention. It should be pointed out that for those skilled in the art, without departing from the technical principle of the present invention, several improvements and modifications can also be made. These improvements and modifications It should also be regarded as the protection scope of the present invention.

Claims (6)

1. A method for automatically correlating primary and secondary equipment models of an intelligent substation, which is characterized by: comprising:

   For the cross-interval secondary equipment model, configure and set the interval prefix for each interval logical node LN in the model to complete the interval LN grouping, and establish the interval association LN to provide a secondary interval association interface;

   Configure the SCD file to complete the instantiation of each secondary equipment model, import the SSD file into the SCD file, directly associate the single-interval secondary equipment CID file with the relevant primary interval in the SSD, and associate the interval in the cross-interval secondary equipment CID file with each LN of the secondary equipment. Interval DO assignment to complete interval association;

   Specify the LN association relationship of the secondary equipment for the primary equipment object type;

   According to the relationship between the primary equipment object type and the secondary equipment LN, the primary equipment in each bay is associated with the relevant secondary equipment logical nodes LN in each single bay and cross bay secondary equipment models.
2. The method for automatically associating primary and secondary equipment models of an intelligent substation according to claim 1, wherein the interval association LN is composed of each interval name DO.
3. The method for automatically associating primary and secondary equipment models of an intelligent substation according to claim 1, wherein the single-interval secondary equipment CID file is directly associated with the relevant primary interval in the SSD, and the cross-interval secondary equipment CID file is directly associated with the SSD. Each interval DO assignment of the interval association LN in the file is performed to complete the interval association, including:

   Directly associate the CID file of the secondary device with a single interval for each interval configuration to the corresponding part of the interval of the SSD in the SCD file;

   Assign the value of each interval name DO in the interval association LN in the cross-interval secondary device CID file to the corresponding actual interval name name in the SSD file to complete the interval association.
4. A device for automatically associating primary and secondary equipment models of an intelligent substation, which is characterized by: comprising:

   The interval association LN configuration module adopts the set interval prefix to distinguish the secondary equipment LN of each interval for the cross-interval secondary equipment model, and establishes the interval association LN to provide a secondary interval association interface;

   The assignment module is used to configure the SCD file to complete the instantiation of each secondary device model, import the SSD file into the SCD file, directly associate the single-interval secondary device CID file with the relevant primary interval in the SSD, and transfer the inter-interval secondary device CID file to the middle Assign each interval DO of the interval associated LN to complete the interval association;

   The association module is used to specify the LN association relationship of the secondary equipment for the primary equipment object type; according to the association relationship between the primary equipment object type and the secondary equipment LN, the primary equipment in each interval is associated with each single-interval and cross-interval secondary equipment models In the relevant secondary equipment logical node LN.
5. The device for automatically associating primary and secondary equipment models of an intelligent substation according to claim 1, wherein the interval association LN is composed of each interval name DO.
6. The device for automatically associating primary and secondary equipment models of an intelligent substation according to claim 1, wherein the CID file of the single-interval secondary equipment is directly associated with the relevant primary interval in the SSD, and the cross-interval secondary equipment CID file is directly associated with the relevant primary interval in the SSD. Each interval DO assignment of the interval association LN in the file is performed to complete the interval association, including:

   Directly associate the CID file of the secondary device with a single interval for each interval configuration to the corresponding part of the interval of the SSD in the SCD file;

   Assign the value of each interval name DO in the inter-interval secondary device interval association LN to the corresponding actual interval name name in the SSD file to complete the interval association.

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