KR20140006413A - Valuation apparatus for soundness of gis breaker - Google Patents

Abstract

The present invention relates to a soundness evaluation apparatus of a GIS circuit breaker which can evaluate the soundness of a GIS circuit breaker by sensing a light of an arc generated during circuit breaking. In order to achieve the objective of the present invention, the soundness evaluation apparatus of a GIS circuit breaker desirably includes: a stroke sensor which is installed in a driving axis, and measures stroke during driving of a circuit breaker; a coil current sensor which is installed in the circuit breaker, and measures a coil current; a bushing-type current transformer (BCT) current sensor which is installed in the circuit breaker, and measures a BCT current; an ultraviolet ray sensor which is installed in the circuit breaker, and senses the arc light generated at an arc contact point; a control part which evaluates the soundness of the GIS circuit breaker by using information inputted from the sensors, measures accurate arcing time by using the sensing value applied from the ultraviolet ray sensor, calculates the intensity of an accumulated break current by using the measured arcing time, and calculates a weight loss of the arc contact point on the ground of the calculated intensity of the accumulated break current; and a display part which displays the weight loss of the arc contact point calculated in the control part under the control of the control part. Accordingly, the soundness evaluation apparatus of the present invention can know maintenance and replacement time of the GIS circuit breaker by calculating a contact point wear rate accurately by using the ultraviolet ray sensor, can reduce waste of maintenance costs generated due to the soundness evaluation error of the GIS circuit breaker, and can prevent malfunction in advance, by predicting the aging of the GIS circuit breaker accurately. [Reference numerals] (10) Stroke sensor; (20) Coil current sensor; (30) BCT current sensor; (40) Ultraviolet ray sensor; (50) Control part; (60) Display part

Description

VALUATION APPARATUS FOR SOUNDNESS OF GIS BREAKER}

The present invention relates to an apparatus for evaluating the integrity of a GIS blocking unit, and more particularly, to an apparatus for evaluating the integrity of a GIS blocking unit to sense the light of an arc generated when the blocking is performed.

Generally, gas insulated switchgear (hereinafter referred to as 'GIS') is a facility that has a high-voltage current-flowing circuit such as a substation. Refers to a device that protects the power system.

This GIS grounds the main components of the substation, such as Gas Circuit Breaker, Disconnecting Switch, Earthing Switch, Lightning Arrester, Main Bus and Feeder Bus. It is a product filled with SF6 gas, which is embedded in a metal tank, and has excellent insulation and blocking performance.

As described above, for the prevention and stable operation of the GIS, it is necessary to secure maintenance management and constant monitoring diagnosis technology.

Of these, the health assessment of the breaks in the GIS used to protect the load equipment and lines from large fault currents such as short circuits and ground faults is important.

The health assessment of the conventional GIS blocker evaluates the health based on product test information that is conducted during the initial GIS release test. That is, as shown in Figure 1, the input speed, breaking speed, opening time (Opening Time), break time (Break Time), arcing time (Arcing Time) is measured to evaluate the soundness, operating air pressure, compressor The integrity of the breaker is evaluated by determining the pressure, the number of operations, the cumulative breaking current and the coil current. Here, the arcing time of the GIS blocking part is the most important parameter of the contact wear rate, which is most important when evaluating the health of the GIS blocking part.

When the high voltage circuit breaker disconnects the main contact to cut off the fault current or fault current, and then disconnects the arc contact, an arc is generated between the contacts, and the generated arc is a hot / high pressure state in the arc area. And nozzles.

Figure 2 is a road showing the components of the area of the arc effect in the arc chamber during blocking, in order to determine the abnormality of the contact must first check whether the shape of the contact change, in the case of a breaker installed in the actual site arc chamber It is also very difficult to check the contact shape inside each time, and to grasp the overall performance only by the local change of the contact.

And, it can be seen from FIG. 3 that the wear state of the tulip arc contact is different for each individual contact. Because of this, it is also practically impossible for an algorithm to calculate the geometric change of a tulip arc contact to pick up different results for each individual contact, and to develop such an evaluation technique.

In order to solve the problems described above, conventionally, the amount of contact wear, that is, mass loss, is used. After the mass loss of the contact is obtained through many experiments, the correlation between the mass loss and the electrical stress is found. Hazard information was constructed to compare mass loss and electrical stress, and the contact wear rate was calculated based on the constructed information data to evaluate the integrity of the breaker.

As described above, since the contact wear rate is conventionally calculated based on the information data, even if a healthy breaker is operated, the breaker is unconditionally operated when a predetermined number of times (for example, 10 times or more) is operated at a specific breaker current (for example, 40 kA). There is a problem that makes an error that is considered to be unhealthy.

Korean Patent Publication No. 2010-49413

The present invention has been made to solve the above-described problems, by detecting the light of the arc generated by the ultraviolet sensor using the UV sensor to accurately measure the contact wear rate, the integrity of the GIS blocking part to accurately assess the health of the GIS blocking part The purpose is to provide an evaluation device.

According to a first aspect of the present invention, an apparatus for evaluating the soundness of a GIS breaking unit includes: a stroke sensor installed at a drive shaft of a breaker and measuring a stroke during driving of the breaker; A coil current sensor installed at the breaker to measure coil current; A BCT current sensor installed at the breaker to measure a BCT current; An ultraviolet sensor installed in the circuit breaker to detect arc light generated at the arc contact; Evaluate the integrity of the GIS cutoff unit using the information received from the sensors, measure the exact arcing time using the detection value applied from the ultraviolet sensor, and calculate the magnitude of the accumulated breaking current using the measured arcing time. And a controller configured to calculate a cutting amount of the arc contact based on the calculated magnitude of the cutoff current. Preferably, the control unit includes a display unit for displaying the cutting amount of the arc contact calculated by the control unit.

로 정의되는 것이 바람직하다.Furthermore, the cumulative blocking current is

It is preferred to be defined as.

The control unit preferably calculates the arc energy required for the cutting amount when calculating the cutting amount of the contact using the arcing time as an integral value of the current value of the arcing time.

According to the soundness evaluation device of the GIS cutout of the present invention, by accurately calculating the contact wear rate using the ultraviolet sensor, it is possible to accurately know the maintenance and replacement time of the GIS cutout. In addition, by accurately calculating the contact wear rate using the ultraviolet sensor, it is possible to reduce the waste of maintenance costs that may be caused by the failure of the GIS shield's health evaluation error, and to accurately predict the aging of the GIS shield, thereby preventing failures in advance. do.

1 is a view showing an exemplary operation time graph of the breaker used in the health evaluation of the conventional GIS block.
FIG. 2 shows the components of the area affected by the arc effect in the arc chamber upon blocking;
3 is an exemplary view showing the shape change of the tulip arc contact after the electrical durability test step.
4 is a view schematically showing the configuration of an apparatus for evaluating the health of the GIS blocking unit according to an embodiment of the present invention.
5 is a view showing a relationship between various diagnostic items in the blocking operation.
6 is a view showing an example of a block operation monitoring graph measured by using an ultraviolet sensor applied to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the soundness evaluation device of the GIS blocking unit according to a preferred embodiment of the present invention.

4 is a diagram schematically illustrating a configuration of an apparatus for evaluating the integrity of a GIS blocking unit according to an exemplary embodiment of the present invention.

In FIG. 4, the stroke sensor 10 is provided in the drive shaft of a breaker, and measures the stroke at the time of a breaker drive.

The stroke value is the total length of the moving part of the breaker mechanism. This stroke value is a very important factor that greatly affects the breaking performance of the breaker. In order to measure the stroke of such a breaker, the stroke sensor 10 is attached to the drive shaft of the breaker, the stroke at the time of driving is measured, and the measured stroke value is applied to the controller 50.

The controller 50 diagnoses the breaker by measuring the stroke length and the stroke speed at the time of opening / closing using the stroke value applied from the stroke sensor 10.

On the other hand, the coil current sensor 20 is installed in the circuit breaker to measure the coil current, and applies the measured coil current to the controller 50.

A BCT (Bushing-type Current Transformer) current sensor 30 is installed in the circuit breaker to measure the BCT current, and applies the measured BCT current to the controller 50.

The ultraviolet sensor 40 is installed in the circuit breaker to directly detect the arc light generated from the arc contact, and applies the detection value to the controller 50.

The controller 50 evaluates the integrity of the GIS cutoff unit using information received from the stroke sensor 10, the coil current sensor 20, the BCT current sensor 30, the ultraviolet sensor 40, and the like. When the arc light detection value is applied to the arc, the arcing detection time is accurately measured using the applied detection value. Arcing time is an important parameter for calculating the amount of cut of the arc contact, and as shown in FIG. 5, the amount of cut of the arc contact is calculated by measuring the cumulative breaking current appearing on the same time axis according to the arcing time.

That is, the controller 50 measures the arcing time using the sensed value applied from the ultraviolet sensor 40, calculates the magnitude of the cumulative breaking current using the measured arcing time, and calculates the magnitude of the calculated cumulative breaking current. Based on the calculation, the amount of cut of the arc contact is calculated.

As described above, in the present invention, in addition to the stroke sensor 10, the coil current sensor 20, and the BCT current sensor 30, an ultraviolet sensor 40 is added, and at the arc contact using the added ultraviolet sensor 40. By directly measuring the generated arc light, the arcing time can be measured more accurately.

6 is a road showing an exemplary operation monitoring graph of the blocking unit measured using the ultraviolet sensor applied to the present invention, the vibration wave sensor from above, the coil current sensor 20, the stroke sensor 10, the BCT current sensor ( 30) The measurement result of the ultraviolet sensor 40 is shown.

As illustrated in FIG. 6, the ultraviolet sensor 40 accurately knows the arcing time at which the arc is generated. The controller 50 measures the cumulative breaking current by using the arcing time accurately measured. The cumulative blocking current is calculated based on Equation 1.

As described above, the controller 50 that calculates the cumulative breaking current calculates the cutting amount of the arc contact based on the calculated cumulative breaking current, and maintains and replaces the GIS breaking part based on the calculated cutting amount of the arc contact. You will know exactly when.

In addition, the controller 50 measures the arcing time by using the sensed value applied from the ultraviolet sensor 40, calculates the arc energy using the measured arcing time, and uses the calculated arc energy to calculate the GIS blocking unit. Know exactly when to maintain and replace.

Here, the arc energy is calculated as the product of the integrated value of the arc voltage and the arc current of arcing time, as shown in equation (2).

As described above, the ultraviolet sensor 40 further installed in the present invention is preferably installed in the monitoring window of the GIS blocking unit.

Meanwhile, the display unit 60 displays the cutting amount of the arc contact calculated by the controller 50 and the replacement timing of the GIS blocking unit under the control of the controller 50.

The apparatus for evaluating the soundness of the GIS blocking unit of the present invention is not limited to the above-described embodiment, and can be variously modified and implemented within the range permitted by the technical idea of the present invention.

10. Stroke sensor, 20. Coil current sensor,
30.BCT current sensor, 40.UV sensor,
50. Control unit, 60. Display unit

Claims (4)

A stroke sensor mounted to the drive shaft of the breaker and measuring a stroke during driving of the breaker;
A coil current sensor installed at the breaker to measure coil current;
A BCT current sensor installed at the breaker to measure a BCT current;
An ultraviolet sensor installed in the circuit breaker to detect arc light generated at the arc contact;
Evaluate the integrity of the GIS cutoff unit using the information received from the sensors, measure the exact arcing time using the detection value applied from the ultraviolet sensor, and calculate the magnitude of the accumulated breaking current using the measured arcing time. And a controller configured to calculate a cutting amount of the arc contact based on the calculated magnitude of the cutoff current.
And a display unit for displaying the cutting amount of the arc contact calculated by the controller under the control of the controller.
The method of claim 1, wherein the cumulative blocking current,

Integrity evaluation device of the GIS cut off, characterized in that defined as.
The apparatus of claim 1,
The arc energy is calculated using the arcing time, wherein the arc energy is calculated by multiplying the arc value by the arc value of the arcing time.
The method of claim 1, wherein the ultraviolet sensor,
Integrity evaluation device of the GIS blocking unit, characterized in that installed in the monitoring window of the GIS blocking unit.

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