KR102540402B1 - performance evaluation system for remanufacturing of switchgear usign digital twin - Google Patents

Abstract

The present invention relates to a digital twin performance evaluation system for remanufacturing of a switchboard which comprises: a detection unit that collects structure information, state information, and environment information of a switchboard; and an evaluation server that receives the state information and the environment information collected from the detection unit, models the switchboard, evaluates performance of the modeled switchboard, and evaluates a deterioration degree of components that configure the switchboard to determine whether to remanufacture.

Description

Digital twin performance evaluation system for remanufacturing of switchgear {performance evaluation system for remanufacturing of switchgear usign digital twin}

The present invention relates to a digital twin performance evaluation system for remanufacturing switchgear, and more particularly, to an evaluation system capable of evaluating the performance of a remanufactured switchgear as well as predicting its life by monitoring the state of the switchgear.

In general, power equipment has a lifespan determined to guarantee performance and reliability, and obsolete power equipment whose lifespan has elapsed are neglected or simply disposed of as scrap metal.

Since it is discarded without accurate performance evaluation, there is a problem in that resources are wasted.

In particular, switchgear including various devices such as switches, fuses, insulators, circuit breakers, relays, current transformers, transformers, etc., in the case of equipment that operates only in special situations, not always operating, has problems in use even if the set life span of the switchgear is reached There are cases where there is no

Registered Patent No. 10-2030697 (registered on October 2, 2019, switchboard management system) transmits the status of a plurality of circuit breakers in a switchboard to an external server through a gateway and predicts the remaining life of the circuit breakers. .

However, such a prior art has limitations in that it is difficult to check the overall state of the switchgear and whether or not the switchgear is remanufactured because the life expectancy is predicted only for circuit breakers among various components of the switchgear.

Therefore, in the current market, there is a demand for the development of a system capable of checking the overall state of the switchgear, determining whether or not to remanufacture, and evaluating the performance of the remanufactured switchgear.

The technical problem to be solved by the present invention in consideration of the market demand as described above is to provide a digital twin performance evaluation system that can check the remanufacturability through replacement of appropriate parts by checking the deterioration state of each part of the switchgear. .

Another object of the present invention is to provide a performance evaluation system capable of evaluating the performance of a remanufactured switchgear.

The digital twin performance evaluation system for remanufacturing switchgear of the present invention to solve the above problems is a detection unit that collects structural information, status information, and environmental information of the switchgear, and the status information and environment information collected by the detection unit. It may include an evaluation server that receives the received switchgear, models the switchgear, evaluates the performance of the modeled switchgear, and evaluates deterioration degrees of components constituting the switchgear to determine whether to remanufacture the switchgear.

In an embodiment of the present invention, the evaluation server includes a component database for storing models of components of the switchgear, and a digitizing unit that models the switchgear according to structural information of the switchgear and performs a simulation according to state information and environment information. and an evaluation unit that determines whether to remanufacture the switchgear by evaluating the performance of the switchgear and the degree of deterioration of components using the simulation results, and a life span of the remanufactured switchgear using the evaluation result of the evaluation unit It may include a remanufacturing management unit that determines.

In an embodiment of the present invention, the evaluation unit may evaluate the performance of component models of the switchgear model of the digitization unit with respect to the switchgear determined to be remanufactured, and may specify a component model having the lowest performance evaluation result.

In an embodiment of the present invention, the digitization unit may replace a component model with the lowest performance evaluation result with a standard component model of the component database, and then perform a simulation.

In an embodiment of the present invention, the evaluation unit checks the simulation result after replacing the component model, displays the component to be replaced if the standard performance is satisfied, and evaluates the performance of the component again if the standard performance is not satisfied. After finding a low component model and replacing it with a standard component model in the digitization unit, the simulation may be repeated.

The present invention collects information on the insulation performance, seismic performance, and performance of each component of the switchgear, and determines whether to remanufacture by checking the degree of deterioration of each component, thereby reducing costs through recycling of resources and causing environmental pollution. has the effect of reducing

In addition, the present invention has an effect of facilitating management of the remanufactured switchgear by evaluating the performance of the remanufactured switchgear and determining the lifespan by comparing the performance with the performance of a new switchgear that is not remanufactured.

1 is a block diagram of a digital twin performance evaluation system for remanufacturing switchgear according to a preferred embodiment of the present invention.
FIG. 2 is a block diagram of a detection unit in FIG. 1 .
3 is a flowchart of a remanufacturing decision process.

Hereinafter, the digital twin performance evaluation system for remanufacturing the switchgear of the present invention will be described in detail with reference to the accompanying drawings.

The embodiments of the present invention are provided to more completely explain the present invention to those skilled in the art, and the embodiments described below may be modified in many different forms, and the embodiments of the present invention The scope is not limited to the examples below. Rather, these embodiments are provided so that this invention will be thorough and complete, and will fully convey the spirit of the invention to those skilled in the art.

Terms used in this specification are used to describe specific embodiments and are not intended to limit the present invention. As used herein, the singular form may include the plural form unless the context clearly indicates otherwise. Also, when used herein, "comprise" and/or "comprising" specifies the presence of the recited shapes, numbers, steps, operations, elements, elements, and/or groups thereof. and does not exclude the presence or addition of one or more other shapes, numbers, operations, elements, elements and/or groups. As used herein, the term "and/or" includes any one and all combinations of one or more of the listed items.

Although terms such as first and second are used in this specification to describe various members, regions, and/or regions, it is obvious that these members, parts, regions, layers, and/or regions are not limited by these terms. . These terms do not imply any particular order, top or bottom, or superiority or inferiority, and are used only to distinguish one element, region or region from another element, region or region. Thus, a first element, region or region described in detail below may refer to a second element, region or region without departing from the teachings of the present invention.

Hereinafter, embodiments of the present invention will be described with reference to drawings schematically illustrating embodiments of the present invention. In the drawings, variations of the depicted shape may be expected, depending, for example, on manufacturing techniques and/or tolerances. Therefore, the embodiments of the present invention should not be construed as being limited to the specific shape of the region shown in this specification, but should include, for example, a change in shape caused by manufacturing.

1 is a block diagram of a performance evaluation system for remanufacturing switchgear according to a preferred embodiment of the present invention.

Referring to FIG. 1, the performance evaluation system for remanufacturing switchgear according to the present invention includes a detection unit 20 that detects state information and environmental information of the switchgear 10, and the state of the switchgear 10 through the detection unit 20. An evaluation server that receives information and environmental information, checks the overall performance of the switchgear 10 and the performance of components constituting the switchgear 10, determines whether to remanufacture, and determines the lifespan of the remanufactured switchgear ( 30) may be included.

The evaluation server 30 includes a digitization unit 31 that models the switchgear 10 and performs a simulation using the state information and environment information detected by the detection unit 20, and the power line of the switchgear 10. A component database 32 that stores a component model including the digitization unit 31 and replaces the component selected from the switchgear model digitized by the digitization unit 31, and the performance of the switchgear model of the digitization unit 31 and the replaced component It is configured to include an evaluation unit 33 that evaluates the performance of the included switchgear model, and a remanufacturing management unit 34 that determines the life span of the remanufactured switchgear using the evaluation result of the evaluation unit 33.

Hereinafter, the configuration and operation of the digital twin performance evaluation system for remanufacturing the switchgear of the present invention configured as described above will be described in more detail.

First, the detection unit 20 detects structure information, state information, and environment information of the switchgear 10 or the remanufactured switchgear 11 .

The structure information is for grasping the type of switchgear 10 and confirming the connection relationship of components.

At this time, the status information may include the number of occurrences of arcs within a set period, vibration information, and current and voltage information of each component.

Also, the environment information may be temperature and humidity information.

2 is a block configuration diagram of the detection unit 20.

Referring to FIG. 2 , the detection unit 20 includes an arc detection unit 21, a voltage and current detection unit 22, and a vibration detection unit 23 to detect state information, and a temperature and humidity detection unit 24 to detect environmental information. detect

In addition, it is assumed that structural information of the switchgear 10 is detected by including the camera 26.

In addition, the detection unit 20 includes a communication unit 25 and transmits information detected through the arc detection unit 21, the voltage and current detection unit 22, the vibration detection unit 23, and the temperature and humidity detection unit 24 to a server ( 30) can be transmitted.

The information detected through the detection unit 20 is information on the type and connection degree of the switchgear, insulation performance, seismic performance, and deterioration of each component, and the server 30 uses the received information to determine the level of the switchgear 10. Performance is evaluated, and the degree of deterioration of the components constituting the switchgear 10 is confirmed.

The server 30 may evaluate the performance of the remanufactured switchgear 11 and check the degree of deterioration of components constituting the remanufactured switchgear 11 in the same manner as the case of the remanufactured switchgear 10 .

At this time, the digitization unit 31 of the server 30 models the switchgear using the information collected by the detection unit 20 .

Modeling at this time may be performed using a component model provided from the component database 32 .

The component database 32 classifies and stores components such as switches, fuses, insulators, circuit breakers, relays, current transformers, and transformers constituting the switchgear according to the year of production, discontinuation time, and capacity information.

The digitization unit 31 digitizes and models the old gas insulated switchgear using a component model corresponding to the year information of the corresponding switchgear.

The detecting unit 20 detects the input and output current and voltage of each component during operation of the switchgear 10 and provides the detected information to the digitizing unit 31 .

In addition, the detection unit 20 detects the temperature of each component during operation of the switchgear 10 and provides the detected information to the digitization unit 31 .

The digitization unit 31 that receives current and voltage information, which is electrical information, and temperature information, which is environmental information, from the detector 20 applies each information to the modeled switchgear model.

Through this process, the digitized switchgear is simulated to be compared with the performance of a standard gas insulated switchgear.

That is, operation state prediction simulation when overcurrent or overvoltage is supplied may be performed, and simulation of support, insulation performance, and seismic performance may be performed.

Such simulation results are provided to the evaluation unit 33, and the evaluation unit 33 first evaluates the overall performance of the switchboard 10.

3 is a flowchart of an evaluation process performed in the evaluation unit 33.

Referring to FIG. 3 , the evaluation unit 33 evaluates the performance of the switchgear using the simulation result as in step S10.

At this time, the evaluation can be expressed as a ratio of the performance of the normal (or standard) switchgear. The evaluation mainly evaluates insulation performance and seismic performance.

The performance of the switchgear may be determined as 80%, 60%, etc. of the normal switchgear performance.

Next, in step S20, it is checked whether the overall performance evaluation result is equal to or greater than the minimum standard performance.

As a result of the confirmation in step S20, if the evaluation unit 33 obtains a result of less than the minimum standard performance in the first evaluation, it is determined that the corresponding switchgear cannot be remanufactured as in step S30.

This can be understood as the fact that the replacement cost of parts for remanufacturing is excessive, and the present invention can determine whether or not to remanufacture considering economic feasibility.

The minimum reference performance may be set to less than 40% of the standard switchgear performance.

Next, if the performance is equal to or greater than the minimum standard performance in step SS40, the evaluation unit 33 evaluates each component.

At this time, the evaluation unit 33 checks the temperature, current, and voltage of each component to perform evaluation.

Evaluate the deviation of the temperature, current, and voltage of the detected component with respect to the standard temperature, current, and voltage as a ratio. That is, the performance of the component is evaluated by checking how many percent higher the temperature of the detected component is, how much higher or lower the current is, and the like with respect to the reference temperature.

Then, as in step S50, the evaluation unit 33 determines the component exhibiting the lowest performance by using the performance evaluation result of each component.

When the component with the lowest performance is determined by the evaluation unit 33, as in step S60, the digitization unit 31 finds a component model compatible with the corresponding component in the component database 32 and has the lowest performance in the modeled switchboard model. Replace component.

Then, the digitization unit 31 performs the simulation again and provides the results of the simulation to the evaluation unit 33 .

The evaluation unit 33 may evaluate the performance of the gas insulated switch by checking the simulation result again, as in step S70, and check whether the performance is improved beyond the standard performance.

The standard performance at this time can be 80% or more of the standard switchgear performance.

When the standard performance is satisfied, information on the currently replaced component is displayed as in step S80 so that the operator can check the actual replacement component during recycling.

If the standard performance is not satisfied, the process returns to step S40 again, the component with the lowest performance is identified (S50), the model is replaced with another standard model, and the simulation process is repeated.

By the operation of the evaluation unit 33 as described above, it is possible to determine whether or not to remanufacture the switchgear and to easily check components to be replaced during remanufacturing.

In this way, information on the switchgear 10 for which remanufacturing is determined is provided to the remanufacturing management unit 34 .

At this time, the information provided to the remanufacturing management unit 34 may include performance information of the remanufactured switchgear 11 after remanufacturing determined by the evaluation unit 33 .

The remanufacturing management unit 34 may determine the lifespan of the remanufactured switchgear 11 by using the performance information of the remanufactured switchgear 11 .

At this time, the life span of the remanufactured switchgear 11 may be reduced by a ratio equal to the ratio of performance to the life span of the normal switchgear 11 .

Assuming that the lifespan of the normal switchgear 11 is 20 years, and the performance of the remanufactured switchgear 11 is 90% of that of the normal switchgear, the lifespan of the remanufactured switchgear 11 can be determined to be 18 years.

By determining the lifespan of the remanufactured switchgear 11 in this way, maintenance and maintenance can be performed in consideration of the lifespan of the remanufactured switchgear 11 later, so that maintenance and repair management becomes easier there is

It is obvious to those skilled in the art that the present invention is not limited to the above embodiments and can be variously modified or modified and implemented within the scope of the technical gist of the present invention. will be.

10: switchboard 11: remanufactured switchboard
20: detection unit 30: evaluation server
31: digitization unit 32: component database
33: evaluation unit 34: remanufacturing management unit

Claims (5)

a detection unit that collects structural information, status information, and environmental information of switchgear; and
Includes an evaluation server that receives the state information and environmental information collected by the detection unit, models the switchgear, evaluates the performance of the modeled switchgear, and evaluates the degree of deterioration of components constituting the switchgear to determine whether to remanufacture but
The evaluation server,
A component database that stores models for components of the switchgear;
a digitization unit modeling the switchgear according to the structure information of the switchgear and performing a simulation according to state information and environment information;
an evaluation unit that determines whether to remanufacture the switchgear by evaluating the performance of the switchgear and the degree of deterioration of components using the simulation results; and
A digital twin performance evaluation system including a remanufacturing management unit that determines the life span of the remanufactured switchgear using the evaluation result of the evaluation unit. delete According to claim 1,
The evaluation unit,
Regarding the switchgear determined to be remanufactured,
Evaluate the performance of the component model of the switchgear model of the digitization unit,
Digital twin performance evaluation system, characterized in that for specifying the component model with the lowest performance evaluation result. According to claim 3,
The digitization unit,
A digital twin performance evaluation system characterized by performing a simulation after replacing the component model with the lowest performance evaluation result with a standard component model of the component database. According to claim 4,
The evaluation unit,
After replacing the component model, check the simulation results, and if the standard performance is satisfied, the component to be replaced is displayed,
If the standard performance is not satisfied, the performance evaluation of the component is performed again to find the lowest component model, replace it with a standard component model in the digitization unit, and repeat the simulation. Digital twin performance evaluation system.

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