KR102186753B1 - Monitoring device of contacting point for a vacuum circuit breaker and vacuum circuit breaker having it - Google Patents

Abstract

The present invention relates to a contact monitoring device for a vacuum circuit breaker and a vacuum circuit breaker having the same. The present invention is a vacuum having a fixed electrode fixed in an insulating container and having a fixed contact at one end, and a movable electrode at one end provided with a movable contact contacting or separating the fixed contact and installed in the insulating container to be raised or lowered. A vacuum circuit breaker having an interrupter and a push rod assembly coupled to the other end of the movable electrode to raise or lower the movable electrode, wherein at least a plurality of pieces are attached to an outer peripheral surface of a cylindrical rod housing of the push rod assembly and have different reflectances. Differential stickers having an area of; And a sensor assembly installed adjacent to the identification sticker and monitoring the position of the identification sticker.

Description

Contact monitoring device for vacuum breaker, and vacuum circuit breaker having the same {Monitoring device of contacting point for a vacuum circuit breaker and vacuum circuit breaker having it}

The present invention relates to a contact monitoring device for a vacuum breaker capable of monitoring the amount of wear of a contact inside a vacuum interrupter, and a vacuum breaker having the same.

A vacuum circuit breaker is an electrical protector that protects load devices and lines from accidental currents in case of accidents such as short circuits or ground faults occurring in electric circuits using the dielectric strength of vacuum.

The vacuum circuit breaker controls power transport and protects the power system. The vacuum circuit breaker has a large breaking capacity and high reliability and safety. In addition, since it can be mounted in a small installation space, its application range is expanding from medium voltage to high voltage.

The vacuum circuit breaker includes a vacuum interrupter, which is a key component that blocks current, a power transmission device that transmits power to the vacuum interrupter, and a push rod that inputs or blocks a contact in the vacuum interrupter by making vertical reciprocation by the power transmission device. . An example of a vacuum interrupter, which is a core part of a vacuum breaker, is disclosed in Korean Patent Registration No. 10-1860348 (Registration Date May 16, 2018) (hereinafter, reference numerals cited in the description of the conventional vacuum interrupter are applied only to the description of the prior art. Sign).

The conventional vacuum interrupter 100 includes an insulating container 190, a fixed electrode 110, a movable electrode 150, and an arcing shield 210. The fixed electrode 110 and the movable electrode 150 have a fixed contact 130 and a movable contact 170, respectively. According to the vertical movement of the movable electrode 150, the movable contact 170 contacts or separates the fixed contact 130.

The fixed contact 130 and the movable contact 170 have a problem in that contact wear occurs as the current blocking operation is repeated. If the contact is worn over a certain period, it needs to be repaired or replaced. If the contact is not repaired or replaced in an appropriate time, it may cause the short-time performance, short-circuit performance, and energization performance of the vacuum interrupter to deteriorate. Therefore, there is a need for a method to accurately detect the wear condition of the contact point.

An object of the present invention is to provide a contact monitoring device for a vacuum breaker capable of monitoring the amount of wear of a contact inside a vacuum interrupter and a vacuum breaker having the same.

In addition, an object of the present invention is to provide a contact monitoring device for a vacuum circuit breaker capable of detecting a contact wear amount that is a displacement in a vertical direction using a photo sensor having a sensing direction in a horizontal direction, and a vacuum circuit breaker having the same.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention that are not mentioned can be understood by the following description, and will be more clearly understood by examples of the present invention. In addition, it will be easily understood that the objects and advantages of the present invention can be realized by the means shown in the claims and combinations thereof.

The contact monitoring device for a vacuum circuit breaker according to the present invention is provided with a fixed electrode fixed in an insulating container and provided with a fixed contact at one end, and a movable contact contacting or separating the fixed contact at one end, and rising or lowering in the insulating container A vacuum interrupter having a movable electrode installed so as to be installed, and a push rod assembly coupled to the other end of the movable electrode to raise or lower the movable electrode, comprising: on the outer peripheral surface of the cylindrical rod housing of the push rod assembly A discrimination sticker attached and having at least a plurality of regions having different reflectances; And a sensor assembly installed adjacent to the identification sticker and monitoring a position of the identification sticker. Includes.

The sensor assembly may include a light emitting unit disposed in a direction facing the identification sticker and emitting light toward the identification sticker; A light receiving unit disposed in a direction facing the discrimination sticker and receiving light reflected from the discrimination sticker; And a circuit unit coupled to the light emitting unit and the light receiving unit and outputting an output signal according to an amount of light received by the light receiving unit.

The discrimination sticker is disposed along a moving direction of the push rod assembly and is divided into a first area and a second area having different reflectances.

A sensor holder accommodating and supporting the photo sensor module, and a sensor bracket for coupling the sensor holder to a housing accommodating the vacuum interrupter.

In addition, the present invention provides a fixed electrode fixed in an insulating container and provided with a fixed contact at one end, and a movable electrode provided at one end with a movable contact contacting or separating the fixed contact and installed in the insulating container to be raised or lowered. Having a vacuum interrupter; A main circuit unit having a housing accommodating the vacuum interrupter; A push rod assembly coupled to the other end of the movable electrode to raise or lower the movable electrode; And a discrimination sticker attached to the outer circumferential surface of the cylindrical rod housing of the push rod assembly and having at least a plurality of regions having different reflectances, and a sensor assembly installed adjacent to the discrimination sticker and monitoring the position of the discrimination sticker. It provides a vacuum circuit breaker comprising a; monitoring device.

The sensor assembly may include a light emitting unit disposed in a direction facing the identification sticker and emitting light toward the identification sticker; A light receiving unit disposed in a direction facing the discrimination sticker and receiving light reflected from the discrimination sticker; And a circuit unit coupled to the light emitting unit and the light receiving unit and outputting an output signal according to an amount of light received by the light receiving unit.

The discrimination sticker is disposed along a moving direction of the push rod assembly and is divided into a first area and a second area having different reflectances.

It further includes a sensor holder accommodating and supporting the photo sensor module, and a sensor bracket for coupling the sensor holder to the housing of the main circuit part.

The contact monitoring device for a vacuum circuit breaker according to the present invention can determine an appropriate maintenance time by monitoring the wear amount of the contact in real time using a photo sensor.

In addition, since the contact monitoring device for a vacuum breaker according to the present invention can determine the contact wear amount before the contact wear amount proceeds above the threshold value using a photo sensor, the reliability and performance of the vacuum breaker can be improved.

In addition, the contact monitoring device for a vacuum circuit breaker according to the present invention can detect a wear amount of a contact having a displacement in a vertical direction using a photo sensor having a sensing direction in a horizontal direction. Therefore, it is possible to accurately detect the contact wear amount and determine the appropriate maintenance time.

In addition to the above-described effects, specific effects of the present invention will be described together while describing specific details for carrying out the present invention.

1 is a partial cross-sectional view showing a vacuum circuit breaker to which a contact monitoring device according to a first embodiment of the present invention is applied.
2 is a perspective view showing an installation state of the contact monitoring device according to FIG. 1.
3 is an exploded perspective view illustrating a photo sensor of the contact monitoring device according to FIG. 1.
4 is a schematic diagram showing a discrimination sticker of the contact monitoring device according to FIG. 1.
5 is a perspective view showing an operating state of the contact monitoring device according to FIG. 1.

The above-described objects, features, and advantages will be described later in detail with reference to the accompanying drawings, and accordingly, one of ordinary skill in the art to which the present invention pertains will be able to easily implement the technical idea of the present invention. In describing the present invention, if it is determined that a detailed description of known technologies related to the present invention may unnecessarily obscure the subject matter of the present invention, a detailed description will be omitted. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to indicate the same or similar elements.

Hereinafter, it means that an arbitrary component is disposed on the "top (or lower)" of the component or the "top (or lower)" of the component, the arbitrary component is arranged in contact with the top (or bottom) of the component. In addition, it may mean that other components may be interposed between the component and any component disposed on (or under) the component.

In addition, when a component is described as being "connected", "coupled" or "connected" to another component, the components may be directly connected or connected to each other, but other components are "interposed" between each component. It is to be understood that "or, each component may be "connected", "coupled" or "connected" through other components.

1 is a partial cross-sectional view showing a vacuum circuit breaker to which a contact monitoring device according to a first embodiment of the present invention is applied. 2 is a perspective view showing an installation state of the contact monitoring device according to FIG. 1. 3 is an exploded perspective view illustrating a photo sensor of the contact monitoring device according to FIG. 1. 4 is a schematic diagram showing a discrimination sticker of the contact monitoring device according to FIG. 1. 5 is a perspective view showing an operating state of the contact monitoring device according to FIG. 1.

As shown in Figure 1, the vacuum breaker contact monitoring device (B) according to an embodiment of the present invention is installed under the main circuit portion 100 of the vacuum breaker (A) to prevent contact wear of the vacuum interrupter (130). Watch.

A brief description of the main configuration of the vacuum circuit breaker A is as follows (the configuration of the vacuum circuit breaker will be briefly described only for the configuration necessary for the description of the present invention).

The vacuum circuit breaker (A) includes a main circuit unit 100 including a vacuum interrupter 130, a push rod assembly 200 and a main shaft 300 for transmitting power to a contact point of the vacuum interrupter 130, and a driving force. It generates and is connected to the main shaft 300 and includes a mechanism assembly 400 for transmitting a driving force.

The main circuit unit 100 has a vacuum interrupter 130 installed inside the housing 110. The vacuum interrupter 130 includes an insulating container 132 forming an accommodation space, a fixed electrode 134 fixed on the inner upper portion of the insulating container 132, and a fixed contact 134a provided at an end of the fixed electrode 134. ), and a movable electrode 136 installed to be movable up and down in the inner lower part of the insulating container 132, and a movable contact 136a provided at an end of the movable electrode 136. Inside the insulating container 132, an arc shield 132a forming a vacuum is accommodated, and the arc shield 132a includes the fixed electrode 134 and the fixed contact 134a, the movable electrode 136 and the movable contact 136a. Wrap around The movable contact 136a is in contact with the fixed contact 134a by the movable electrode 136 (in the inserted state) or separated from the fixed contact 134a (in the cut-off state). The movable electrode 136 is raised or lowered by the push rod assembly 200.

The push rod assembly 200 inserts or blocks the movable electrode 136. The push rod assembly 200 is composed of several shafts and springs that transmit the power of the main shaft 300 to the movable electrode 136. A partial configuration of a contact monitoring device B, which will be described later, is installed on the rod housing 210 of the push rod assembly 200. The main shaft 300 is connected to the lower end of the push rod assembly 200.

The main shaft 300 is connected to the mechanism assembly 400 to transmit power generated from the mechanism assembly 400 to the push rod assembly 200.

2 and 3, the contact monitoring device (B) according to an embodiment of the present invention includes a sensor assembly 500 installed under the main circuit unit 100 and an outer peripheral surface of the rod housing 210 It includes a discrimination sticker 700 attached to.

The sensor assembly 500 includes a photo sensor module 510 for detecting the position of the identification sticker 700, a sensor holder 530 accommodating the photo sensor module 510, and the sensor holder 530 as a main circuit unit 100 ) And a sensor bracket 550 coupled to the lower side.

The photosensor module 510 includes a light emitting unit 512 and a light receiving unit 514, and a circuit unit 516 processing signals from the light emitting unit 512 and the light receiving unit 514. The light emitting part 512 and the light receiving part 514 are installed side by side on one surface of the circuit part 516. The photo sensor module 510 is installed so that the light emitting part 512 and the light receiving part 514 face the housing 110 of the push rod assembly 200. The meaning of the installation direction of the photo sensor module 510 will be described later.

The photo sensor module 510 is a type of optical sensor that emits light from the light emitting unit 512 and senses the amount of light returned by the emitted light reflected on the surface of the discrimination sticker 700 by the light receiving unit 514.

Since the photocurrent proportional to the intensity of light detected by the light receiving unit 514 flows in the circuit unit 516, the generated current increases as the amount of reflected and returned light increases. Since the photo sensor module 510 detects the amount of light emitted from the light emitting unit 512 is reflected and incident, the amount of light reflected and incident to the light receiving unit 514 decreases as the distance from the photo sensor module 510 increases. As the amount of incident light decreases, the photocurrent decreases, so that the distance from the photo sensor module 510 can be known.

Therefore, the photo sensor module 510 emits light and the direction in which the reflected light is reflected becomes the sensing direction. The photosensor module 510 may sense a moving displacement in the same direction as the sensing direction.

The circuit unit 516 may process the photocurrent and output a signal to the outside. The output signal becomes smaller or larger according to the amount of light sensed, and the amount of light varies according to the displacement. Therefore, if the signal output from the circuit unit 516 is processed, the resulting displacement can be calculated. The signal output from the circuit unit 516 may be transmitted to an external data processing device not shown in the drawing or an administrator's smart terminal.

The sensor holder 530 accommodates the photo sensor module 510. The sensor holder 530 may have a box shape with one side open. The light emitting part 512 and the light receiving part 514 of the photo sensor module 510 are exposed to the open side of the sensor holder 530. The sensor holder 530 may be provided with a coupling portion 532 coupled to the sensor bracket 550 on the open side and the other side or side portions of the opposite side. The coupling part 532 may be provided in the form of a hole into which a bolt is inserted.

The sensor holder 530 may have a frame shape such as a'b' shape, a'b' shape, and a'c' shape instead of a box shape if the photo sensor module 510 is inserted and not separated.

The sensor bracket 550 is mounted on a lower side of the housing 110 forming the exterior of the main circuit part 100. The sensor bracket 550 is not limited to its shape as long as it can support the sensor holder 530. However, in the present invention, the installation position of the photo sensor module 510 must face the rod housing 210. Therefore, the sensor bracket 550 has an inverted'L' shape, and the sensor holder 530 is coupled to a surface extending downward from the housing 110 of the main circuit unit 100. A plurality of fastening holes for fastening the sensor holder 530 and a plurality of fastening holes for fastening to the housing 110 may be formed on the plate surface of the sensor bracket 550. The sensor bracket 550 may be coupled to the sensor holder 530 and the housing 110 by bolting or the like.

In the above-described embodiment, the sensor holder 530 and the sensor bracket 550 are separately provided as an example. However, as long as the photo sensor module 510 can be accommodated and coupled to the housing 110 of the main circuit unit 100, one fixing means may be used. The photo sensor module 510 installed in this way is used to measure a displacement in a direction different from the sensing direction using the discrimination sticker 700.

As shown in FIG. 4, the discrimination sticker 700 is a sticker attached to the outer peripheral surface of the rod housing 210. The discrimination sticker 700 has a rectangular shape having a predetermined size. The discrimination sticker 700 is attached in a direction toward the photo sensor module 510.

The discrimination sticker 700 may have a partial region of white color and a partial region of black color. For example, the discrimination sticker 700 may have a black upper area and a white lower area. Alternatively, the upper region divided into two may be white and the lower region may be black. Since black is a color that absorbs light, and white is a color that reflects light, the reflectance of each divided area is different. That is, the discrimination sticker 700 is formed so that the reflectance in a certain area is different from that in other areas so that the photo sensor module 510 can distinguish and sense it. Hereinafter, an upper area of the identification sticker 700 is defined as a first area 710 and a lower area is defined as a second area 730.

The white and black areas of the discrimination sticker 700 may be disposed in a vertical direction with reference to FIG. 2. As shown in FIG. 4, the discrimination sticker 700 is configured in which the first area 710 is black and the second area 730 is white, or conversely, the first area 710 is white and the second area 730 is black. It could be.

The discrimination sticker 700 is used to discriminate the amount of contact wear, which is a displacement perpendicular to the sensing direction of the photo sensor module 510.

That is, the discrimination sticker 700 is a sticker for discriminating whether or not the fixed contact 134a and the movable contact 136a are worn by a certain amount or more and the elevation height of the push rod assembly 200 is changed (in the present invention, the'contact wear amount The term'is defined as the displacement by which the push rod assembly rises due to wear of the fixed and movable contacts by input).

Therefore, in the state in which the contact point is not inserted (open state), the detection position of the photo sensor module 510 (the position at which light is reflected from the light emitting unit) is a specific position of the first region 710 Can be Although not shown in the drawing, the positions where light emission and light are received in the open state are always the same.

Thereafter, each time the contact is inserted, the contact is worn and the push rod assembly 200 gradually rises, so that the discrimination sticker 700 also gradually rises. Accordingly, the detection position of the photo sensor module 510 is moved toward the lower end of the identification sticker 700. However, when the contact wear amount is less than or equal to a preset threshold, the detection position of the photo sensor module 510 is continuously located within the first area 710 of the discrimination sticker 700. However, the detection position of the photo sensor module 510 is located below the first region 710 rather than the open position.

When the number of inputs increases and the push rod assembly 200 rises above a preset contact wear amount, the sensing position of the photo sensor module 510 may be set to pass to the second region 730. That is, when the contact wear amount exceeds a pre-stored threshold value, the position of the discrimination sticker 700 is set so that the reflectance is different, so that the amount of light sensed by the photo sensor module 510 may be different. Therefore, since the output signal of the photo sensor module 510 is different, it is possible to know whether the contact wear amount has exceeded the threshold value.

The threshold value of the contact wear amount may be set in advance based on the amount of wear that may cause a problem in the reliability of the device by lowering the contact pressure according to the contact wear.

In the contact monitoring apparatus according to an embodiment of the present invention having the above-described configuration, a method of detecting a contact wear amount using a photo sensor module will be described in detail as follows.

Since the push rod assembly 200 is operated in the vertical direction, which is the vertical direction of FIG. 2, the sensing position of the photo sensor module 510 always maintains the same position in the open state. In the first input state, the push rod assembly 200 exhibits a certain amount of vertical displacement within the first region 710. After that, when the contact is repeatedly inserted, the push rod assembly 200 rises along the vertical direction by the amount of wear. That is, the increase in vertical displacement of the push rod assembly 200 becomes the contact wear amount.

In order to measure the amount of movement of the push rod assembly 200, the vertical displacement of the push rod assembly 200 must be sensed. To this end, it is preferable to install a sensor capable of detecting a vertical displacement under the push rod assembly 200. However, since the main shaft 300 is coupled to the lower side of the push rod assembly 200 and the lower components of the vacuum breaker A exist, it is difficult to secure a sufficient space for installing the sensor.

Therefore, the photosensor module 510 of the present invention is installed adjacent to the outer circumferential surface of the rod housing 210 and is installed on one side parallel to the vertical movement direction of the push rod assembly 200. In this case, the sensing direction of the photosensor module 510 is a direction perpendicular to the vertical movement direction of the push rod assembly 200. In addition, in order to minimize interference with the peripheral portion, the photosensor module 510 is installed at a portion close to the outside from the lower end of the housing 110 of the main circuit portion 100.

Since the push rod assembly 200 has only displacement in the vertical direction and does not move in the horizontal direction, the vertical displacement of the push rod assembly 200 cannot be detected even if the photo sensor module 510 is installed on one side. In order to solve this problem, in this embodiment, the photo sensor module 510 can be used by generating the same effect as converting the vertical displacement of the push rod assembly 200 into a horizontal displacement by applying the discrimination sticker 700. To be.

As shown in FIG. 2, the discrimination sticker 700 is attached on the outer circumferential surface of the rod housing 210 facing the photo sensor module 510. At this time, the detection position of the photo sensor module 510 at the position before the load housing 210 is inserted is located in the first region 710 of the identification sticker 700. Sensing position In addition, even if the contact wear amount gradually increases as the contact is repeatedly inserted, the sensing position of the photo sensor module 510 is located in the first area 710 of the discrimination sticker 700 when it is less than a preset threshold. However, as described above, the sensing position when contact wear occurs is located below the sensing position in the open state.

As the contact wear amount increases as the input is repeated, the rod housing 210 gradually rises as shown in FIG. 5. As the rod housing 210 rises, the discrimination sticker 700 also rises. Since the positions of the light-emitting unit 512 and the light-receiving unit 514 of the photo sensor module 510 are fixed, the light-emitting and light-receiving positions gradually decrease as the discrimination sticker 700 rises.

The discrimination sticker 700 is made so that the light-emitting and light-receiving positions of the photo sensor module 510 become the first area 710 from the state before the initial input is made to the state before the contact wear amount reaches a preset threshold. The same is the case where the identification sticker 700 is attached. Accordingly, even if the load housing 210 gradually rises until the contact wear amount reaches a preset threshold, the light emission and light reception positions of the photo sensor module 510 are located in the first region 710.

The contact wear amount gradually increases and the load housing 210 gradually rises, and when the contact wear amount reaches a preset threshold, the detection position of the photo sensor module 510 moves from the first area 710 to the second area 730. Will go.

In the present embodiment, the amount of reflected light emitted from the first region 710 of the discrimination sticker 700 and re-incident is much smaller than that of the reflected light re-incident from the second region 730. This is because black is a color that absorbs light. Accordingly, the magnitude of the photocurrent generated when the photosensor module 510 is positioned in the second region 730 than the sensing position in the first region 710 of the discrimination sticker 700 is rapidly increased.

Therefore, since the output signal output from the photosensor module 510 is different, the vertical displacement of the rod housing 210 can be known based on this output signal. Since the vertical displacement of the rod housing 210 is the contact wear amount, it can be known whether the contact wear amount has reached a preset limit value by analyzing the signal output from the photo sensor module 510. The determination of the contact wear amount may be determined by an operator, a manager, or a device receiving an output signal from the motor sensor module 510.

The photo sensor module 510 cannot directly detect a vertical displacement perpendicular to the sensing direction, but a change in reflectance according to a change in contrast of the discrimination sticker 700 exhibits an effect of converting a vertical displacement into a horizontal displacement. Therefore, by applying the photo sensor module 510, it is possible to indirectly monitor and detect the amount of contact wear.

The contact wear amount monitored by the photo sensor module 510 may be monitored in real time or at a preset time period. Accordingly, it is possible to determine the amount of wear of the contact before the amount of wear of the contact exceeds the threshold value, so that an appropriate maintenance time can be known. In addition, it is possible to improve the reliability and performance of the vacuum circuit breaker.

In the above-described embodiment, it has been described as an example that the photosensor module is installed in a position parallel to the rod housing of the push rod assembly. However, if interference with the periphery can be avoided, it may be installed under the push rod assembly. In this case, since the sensing direction of the photo sensor module and the moving direction of the push rod assembly are the same, the amount of contact wear, which is a vertical moving displacement, can be directly detected through the photo sensor without a discrimination sticker.

The above-described present invention is capable of various substitutions, modifications, and changes within the scope of the technical spirit of the present invention to those of ordinary skill in the technical field to which the present invention belongs. Is not limited by

A: Vacuum circuit breaker
100: main circuit unit 110: housing
130: vacuum interrupter 134: fixed electrode
136: movable electrode 200: push rod assembly
210: rod housing 300: main shaft
B: contact monitoring device
500: sensor assembly 510: photo sensor module
512: light emitting unit 514: light receiving unit
516: circuit part 530: sensor holder
550: sensor bracket 700, 700': identification sticker
710: first area 730: second area

Claims (8)

A vacuum interrupter having a fixed electrode fixed in an insulating container and provided with a fixed contact at one end, and a movable electrode provided at one end with a movable contact contacting or separated from the fixed contact and installed in the insulating container to be raised or lowered; In the vacuum circuit breaker having a push rod assembly coupled to the other end of the movable electrode to raise or lower the movable electrode,
A discrimination sticker attached to an outer peripheral surface of the cylindrical rod housing of the push rod assembly and having at least a plurality of regions having different reflectances; And
A sensor assembly installed adjacent to the identification sticker and monitoring a position of the identification sticker;
Including,
The discrimination sticker is characterized in that the position is set based on a preset threshold value of the contact wear amount
Contact monitoring device for vacuum breaker.
The method of claim 1,
The sensor assembly
A light emitting unit disposed in a direction facing the identification sticker and emitting light toward the identification sticker;
A light receiving unit disposed in a direction facing the discrimination sticker and receiving light reflected from the discrimination sticker; And
A circuit unit coupled to the light emitting unit and the light receiving unit, and outputting an output signal according to an amount of light received by the light receiving unit;
Including a photo sensor module having a
Contact monitoring device for vacuum breaker.
The method of claim 2,
The above differentiation sticker
It is arranged along the moving direction of the push rod assembly, characterized in that divided into a first region and a second region having different reflectance
Contact monitoring device for vacuum breaker.
The method of claim 2,
Further comprising a sensor holder accommodating and supporting the photo sensor module, and a sensor bracket for coupling the sensor holder to a housing accommodating the vacuum interrupter
Contact monitoring device for vacuum breaker.
A vacuum interrupter having a fixed electrode fixed in an insulating container and having a fixed contact at one end, and a movable electrode provided at one end with a movable contact contacting or separating the fixed contact and installed in the insulating container so as to be raised or lowered;
A main circuit unit having a housing accommodating the vacuum interrupter;
A push rod assembly coupled to the other end of the movable electrode to raise or lower the movable electrode; And
Contact monitoring including a discrimination sticker attached to the outer circumferential surface of the cylindrical rod housing of the push rod assembly and having at least a plurality of areas having different reflectivity, and a sensor assembly installed adjacent to the discrimination sticker and monitoring the position of the discrimination sticker Device;
Including,
The discrimination sticker is characterized in that the position is set based on a preset threshold value of the contact wear amount
Vacuum breaker.
The method of claim 5,
The sensor assembly
A light emitting unit disposed in a direction facing the identification sticker and emitting light toward the identification sticker;
A light receiving unit disposed in a direction facing the discrimination sticker and receiving light reflected from the discrimination sticker; And
A circuit unit coupled to the light emitting unit and the light receiving unit, and outputting an output signal according to an amount of light received by the light receiving unit;
Including a photo sensor module having a
Vacuum breaker.
The method of claim 6,
The above differentiation sticker
It is arranged along the moving direction of the push rod assembly, characterized in that divided into a first region and a second region having different reflectance
Vacuum breaker.
The method of claim 6,
Further comprising a sensor holder accommodating and supporting the photo sensor module, and a sensor bracket coupling the sensor holder to the housing of the main circuit unit
Vacuum breaker.

Images