KR101722336B1 - Accident prevention systems and methods of prevention transformers - Google Patents

Abstract

The present invention relates to a system of preventing various accidents for a transformer capable of reducing man-hour and increasing service life the transformer. The system of preventing various accidents for a transformer comprises: a collecting module which records quantitative data which is classified into categories according to external factors such as internal temperature, humidity and load as well as weather in areas in which transformers have been installed, and internal factors such as the manufacturer of parts, quality status, number of inspections and inspection history, and records causes of accidents based on the causal relationship between external and internal factors depending on accident types, and operation information on operating power, an external appearance, and ambient temperature and humidity of all components constituting the managed transformer; an analysis module calculating the number of malfunctions by components, a component which frequently malfunctions before an accident, and a major component satisfying seriousness that generally spreads at the time of malfunction based on the quantitative data; an evaluation module selecting a dangerous component inappropriate for reference information by comparing and analyzing the operation information on the components with normal operation information on the calculated components; and a management module informing of inspection time, inspection tips, and replacement time of the components based on the recorded accident factors by predicting a potential malfunction according to an accident type corresponding to the operation information based on the quantitative data corresponding to the selected components.

Description

Technical Field [0001] The present invention relates to an accident prevention system for a transformer,

The present invention relates to a system for preventing various accidents of a transformer and a method of preventing the transformer, and more specifically, by diagnosing and evaluating components constituting a transformer, a potential failure is predicted, The present invention relates to an accident prevention system and a preventive method for a transformer.

Typically, power is transferred to the final customer through the substation and transformer in the intermediate stage in transmission to the final customer of the home, office, factory, etc. Generated power from the power plant is usually supplied to the substation at a high voltage of 154kV or 345kV. In a substation, a high pressure of 154 kV or 345 kV is normally down to a high pressure of 22.9 kV and supplied to the transformer, just before the final consumer. In the transformer, a voltage of 110V or 220V corresponding to the voltage suitable for use on the final customer side is supplied to the final customer side.

These transformers vary in degree of aging depending on the installation environment and operating load conditions. However, since the replacement of the transformer is carried out all at once by the same time-base due to the lack of the degree of deterioration and the failure measuring method, there is a problem that the transformer can not be used efficiently and replaced even if the state of the transformer is good.

To solve this problem, Korean Patent Registration No. 10-1160775 entitled " Transformer Integrity Evaluation System and Method therefor "is disclosed. The disclosed literature does not replace the transformer uniformly under the same conditions, but rather evaluates the integrity corresponding to the performance and the degree of deterioration of each transformer, so that a differentiated replacement period can be applied for each transformer.

However, it is difficult to expect the effect of cost reduction because it is necessary to replace all the transformers at the limit starting point, since it is merely to determine the time of replacement only according to the deterioration of the transformer. In other words, it is an inefficient system and method because it has a significantly lower effect compared to the airborne cost for evaluating soundness.

Korean Patent Registration No. 10-1160775 "Transformer integrity evaluation system and method thereof"

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the conventional problems as described above, and it is an object of the present invention to provide a transformer which does not entirely evaluate the transformer itself but diagnoses and evaluates the components constituting the transformer individually to prevent various accidents, The present invention is directed to providing an accident prevention system and a preventive method for a transformer which can reduce the power consumption of the transformer and increase the lifetime of the transformer.

To this end, one aspect of the present invention is a system for preventing various accidents to a transformer,
It is classified into categories according to the external factors due to the internal temperature, humidity and load, the manufacturer of the parts, the quality status, the number of inspections and the internal history by inspection history, and the external and internal A collection module for recording quantitative data in which an accident cause is recorded on the basis of a causal relation to a factor and operation information in which an operating power source and an appearance state and surrounding temperature and humidity are detected for all components constituting the controlled transformer; An analytical module for calculating critical parts satisfying severity of failures of parts and failures of parts frequently and failures of failures according to the quantitative data; An evaluation module for comparing and analyzing operation information of a corresponding part based on normal operation information corresponding to the calculated part to select a dangerous part unsuitable for the reference information; And a management module for predicting a potential failure according to an accident type coinciding with the operation information based on the quantitative data corresponding to the selected part and notifying the inspection time, ; And
According to another aspect of the present invention, there is provided a method for preventing various accidents to a transformer,
It is classified into categories according to the external factors due to the internal temperature, humidity and load, the manufacturer of the parts, the quality status, the number of inspections and the internal history by inspection history, and the external and internal A collection step of recording quantitative data in which an accident cause is recorded on the basis of a causal relation to a factor and operation information in which an operating power source and an appearance state and surrounding temperature and humidity are detected for all the components constituting the controlled transformer; An analyzing step of calculating the number of failures of each part and the number of failures before the accident based on the quantitative data and the parts satisfying the severity of the failure when the failure occurs; An evaluation step of comparing and analyzing operation information of a corresponding part based on normal operation information corresponding to the calculated part to select a dangerous part which is equal to or lower than the reference information; And a management step of predicting a potential failure according to an accident type consistent with the operation information based on the quantitative data corresponding to the selected part and notifying the inspection time, ; And

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It should be understood, however, that the terminology or words of the present specification and claims should not be construed in an ordinary sense or in a dictionary, and that the inventors shall not be limited to the concept of a term It should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be properly defined. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, It is to be understood that equivalents and modifications are possible.

As described above, according to the present invention, it is possible to prevent various accidents by predicting a potential failure by calculating critical parts among the parts constituting the transformer and selecting only the hazardous parts among the important parts, It is possible to reduce the overall replacement cost by significantly increasing the lifespan of the transformer. In particular, it is possible to minimize the number of times that the prevention is consumed by checking only a few high-risk components.

1 is a block diagram generally showing a system according to the present invention;
2 is a flowchart showing an accident prevention method according to the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

One aspect of the present invention relates to a system for preventing various types of accidents of a transformer. The transformer includes a collection module 10, an analysis module 20, an evaluation module 30, and a management module 40, It is an accident prevention system. The accidents mentioned in the present invention comprehensively mean a malfunction caused by a fire or an electric shock followed by a break, a short circuit, a short circuit, a life span, or the like. In other words, the transformer transforms the power supplied from the power plant into the service area and re-supplies it. Therefore, even if the simple function failure occurs, the transformer includes damage caused to the human life or industrial property due to the failure.

The acquisition module 10 according to the present invention records quantitative data and operation information relating to a transformer on a recording medium. Quantitative data is divided into types of accidents per transformer. Types of accidents can be divided into simple stoppage, malfunction, overheating, explosion, fire, and electric shock. The operation information includes the operating power, the appearance condition, and the ambient temperature and humidity for all components constituting the controlled transformer.

Here, the quantitative data are classified according to the external factors due to the internal temperature, humidity and load, the manufacturer of the parts, the quality status, the number of inspections and the internal history of the inspection history and the external and internal factors Based on the causal relationship, the cause of the accident is recorded in detail. In other words, if a sudden fire occurs in the switchboard, it is possible to identify the fire-originating components, and the cause of the accident can be analyzed by tracing external and internal factors of the component for 3 to 6 months. On the other hand, the operating history of the parts to be inspected, the appearance state and the surrounding temperature and humidity are recorded in the inspection history. This quantitative data is used as important basic data in the analysis module 20 and the management module 40 described later.

In addition, the analysis module 20 according to the present invention calculates the critical parts on the basis of the quantitative data and the influence on the number of failures and failures of each part. In other words, parts that have frequent breakdowns before the accident and parts that satisfy the overall severity in the event of a breakdown are calculated. The degree of influence can be estimated from the damage result caused by any one of the components constituting the transformer.

For example, there is no need to pay much attention to components with fewer failures and less impact. Also, it is not necessary to pay close attention because it is a minor malfunction even for parts with high number of failures and low impact. Of course, careful attention should be given to a large number of failures, but it is virtually impossible to achieve complete prevention with limited air traffic. In other words, even if the number of failures is small, it is necessary to pay considerable attention to components that have a high impact on one failure.

In addition, the evaluation module 30 according to the present invention selects a dangerous component based on operation information corresponding to the calculated component. That is, the evaluation module 30 compares the normal operation information of the calculated component with the operation information of the corresponding component, and selects a component that is not suitable for the reference information. Here, the normal operation information is a theoretical value according to the specifications obtained from the manufacturer of the part, and the reference information means the most stable value obtained by comparing and analyzing actual values according to theoretical and quantitative data.

For example, there is no need to be selected because the operation information does not have a failure rate or is low for a part suitable for the reference information. However, for parts that are not suitable for the reference information, the failure rate is high and immediate action is required. Of course, as mentioned in the analysis module (20), it is necessary to check for suitable parts, but only parts that are not suitable for effective prevention with a limited number of air are selected.

Also, the management module 40 according to the present invention predicts and notifies the potential failure based on the quantitative data corresponding to the selected parts. In other words, in addition to the selected parts, the potential failure is predicted according to the type of accident that matches the operation information of the part, and the inspection timing, inspection point, and replacement period of the part are reported based on the recorded cause of the accident.

For example, if the earth leakage breaker (ELB) is selected in the evaluation module 30, the same or similar type as the accident caused by the earth leakage breaker is indexed on the quantitative data, and the cause of the accident recorded in the indexed accident type is analyzed. That is, if the cause of the accident is recorded as 'the function is lost due to environmental factors such as corrosive gas or dust, causing a fire,' it is recommended to check the function every 3 months, replace the new product within 12 months, '.

Another aspect of the present invention relates to a method for preventing various types of accidents to a transformer. The method includes a collecting step (S10), an analyzing step (S20), an evaluating step (S30), and a managing step (S40). Since the present invention operates the acquisition module 10, the analysis module 20, the evaluation module 30, and the management module 40 in sequence, detailed processes to be performed in each step are omitted.

First, a quantitative data classified according to an accident type for each preceding transformer and a collecting step (S10) for recording operation information detected from the controlled transformer are performed. The quantitative data are classified according to the external factors due to the internal temperature, humidity and load, the manufacturer of the parts, the quality status, the number of inspections, and the internal factors by the inspection history, along with the climate of the area where the transformer is installed. · The cause of the accident is recorded based on the causal relationship to the internal factors. The operation information includes operating power, appearance, and ambient temperature and humidity for all components that make up the transformer.

Then, based on the quantitative data, the number of failures and the influence on the failure of each part are analyzed (S20). In other words, critical parts are calculated as parts with frequent breakdowns before the accident and parts that satisfy the severity of the overall breakdown in the event of a breakdown. Therefore, even if the number of failures is small, a part having a high degree of influence to be caused by one failure is calculated as a critical part.

And then an evaluation step (S30) for selecting a dangerous part based on operation information corresponding to the calculated part. That is, the parts that are equal to or smaller than the reference information are selected by comparing and analyzing the normal operation information of the calculated parts and the operation information of the corresponding parts. Here, the reference information is the most stable value obtained by comparing and analyzing actual values according to theoretical and quantitative data.

Finally, a management step (S40) for predicting and notifying a potential failure based on the quantitative data corresponding to the selected part is performed. In other words, in addition to the selected parts, the potential failure is predicted according to the type of accident that matches the operation information of the part, and the inspection timing, inspection point, and replacement period of the part are reported based on the recorded cause of the accident.

As described above, according to the present invention, not only accident prevention but also a small number of high-risk parts are checked, thereby minimizing the number of times spent for prevention.

Meanwhile, the present invention is not limited to a system and method limited to a transformer, but can be applied to both temporary and intermediate power devices such as an electric distribution panel, a switch, a lightning arrester, and a current transformer.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined by the appended claims. It is therefore intended that such variations and modifications fall within the scope of the appended claims.

10: Acquisition module 20: Analysis module
30: Evaluation module 40: Management module
S10: Collection step S20: Analysis step
S30: Evaluation step S40: Management step

Claims (12)

A system for preventing an accident to a transformer comprising:
It is classified into categories according to the external factors due to the internal temperature, humidity and load, the manufacturer of the parts, the quality status, the number of inspections and the internal history by inspection history, and the external and internal A collection module for recording quantitative data in which an accident cause is recorded on the basis of a causal relation to a factor and operation information in which an operating power source and an appearance state and surrounding temperature and humidity are detected for all components constituting the controlled transformer;
An analytical module for calculating critical parts satisfying severity of failures of parts and failures of parts frequently and failures of failures according to the quantitative data;
An evaluation module for comparing and analyzing operation information of a corresponding part based on normal operation information corresponding to the calculated part to select a dangerous part unsuitable for the reference information; And
A management module for predicting a potential failure according to an accident type coinciding with the operation information based on the quantitative data corresponding to the selected part, and for notifying the inspection time, inspection point and replacement time of the corresponding part based on the recorded cause of the accident; And an inverter connected to the transformer. delete delete delete delete delete A method of preventing an accident to a transformer comprising:
It is classified into categories according to the external factors due to the internal temperature, humidity and load, the manufacturer of the parts, the quality status, the number of inspections and the internal history by inspection history, and the external and internal A collection step of recording quantitative data in which an accident cause is recorded on the basis of a causal relation to a factor and operation information in which an operating power source and an appearance state and surrounding temperature and humidity are detected for all the components constituting the controlled transformer;
An analyzing step of calculating the number of failures of each part and the number of failures before the accident based on the quantitative data and the parts satisfying the severity of the failure when the failure occurs;
An evaluation step of comparing and analyzing operation information of a corresponding part based on normal operation information corresponding to the calculated part to select a dangerous part which is equal to or lower than the reference information; And
A management step of predicting a potential failure according to an accident type coinciding with the operation information based on the quantitative data corresponding to the selected part, and notifying the inspection time, inspection point and replacement time of the corresponding part based on the recorded cause of the accident; Wherein the transformer is a transformer. delete delete delete delete delete

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