KR20100138638A - Vacuum interrupter of vacuum circuit breaker and method for detecting the degree of vacuum in the same - Google Patents

Abstract

PURPOSE: A vacuum interrupter of a vacuum circuit breaker and a method for detecting a vacuum state are provided to easily detect the deterioration of the vacuum state in the vacuum interrupter by detecting the rise of vacuum pressure in the vacuum circuit breaker in a live line without breaking the inner circuit of the vacuum circuit breaker. CONSTITUTION: A cylindrical body receives a fixed electrode(104) and a movable electrode(102). A movable seal cup(109) is coupled with one end of the body unit. A fixed seal cup(107) is coupled with the other end of the body unit. A detecting pin(200) for monitoring the deterioration of the inner vacuum state of the vacuum interrupter is attached to the movable seal cup. An optical sensor(120) and a detector(130) are positioned on the upper side of the movable seal cup to measure the position variation of the detecting pin.

Description

Vacuum interrupter of vacuum breaker and its vacuum degree detection method {VACUUM INTERRUPTER OF VACUUM CIRCUIT BREAKER AND METHOD FOR DETECTING THE DEGREE OF VACUUM IN THE SAME}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vacuum interrupter used in a vacuum circuit breaker, and more particularly, to a monitoring means capable of monitoring a deterioration of a vacuum breaker by detecting an increase in the vacuum pressure inside the vacuum breaker. .

In general, a circuit breaker is an electrical protection device that protects a load device and a line from such an accident current in the event of a short circuit or ground fault that may occur in an electric circuit. The breaker is an inlet breaker that uses oil as the SOHO medium, a gas circuit breaker that uses hexafluoride hexafluoride (SF ₆ ) gas, an air circuit breaker that uses air as the SOHO medium, a circuit breaker using magnetism, and vacuum insulation. It is divided into a vacuum circuit breaker using a load capacity. The vacuum interrupter is the core extinguishing part applied to vacuum breaker, vacuum switch and vacuum contactor to cut off load current or fault current in power system. The vacuum circuit breaker, which is in charge of power transportation control and protection of the power system, has many advantages such as high breaking capacity, high reliability and safety, and it can be mounted in a small installation space. The scope of application is increasing. In addition, most power equipment products use sulfur hexafluoride gas having excellent arc extinguishing and insulation performance as an insulating medium. However, sulfur hexafluoride gas has a greenhouse effect of 23,900 times that of carbon dioxide, and is designated as a global warming gas by the Kyoto Protocol. In Korea, the development of eco-friendly power equipment products that can replace the sulfur hexafluoride gas has been actively developed, and the demand for vacuum circuit breakers is rapidly increasing as one of the eco-friendly power equipment products. The key component is a vacuum interrupter.

This vacuum interrupter has a normal breaking force at a pressure having a vacuum degree of 5x10 ^-4 Torr or less. As long as the vacuum breaker is used for a long time, the vacuum pressure inside the vacuum interrupter increases due to internal and external factors such as the gas discharged inside the vacuum interrupter and the leakage of the junction of each component. There is a problem. As such, when the breaker operates without detecting the deterioration of the insulation protection capability due to the decrease in the vacuum degree of the vacuum interrupter, it may cause a serious loss in the power system, so the vacuum degree of the vacuum interrupter may be very important.

1 shows a schematic configuration of a conventional vacuum interrupter. The movable side contact 3b is connected to the end of the movable electrode 2 of the vacuum interrupter 1 provided in the conventional vacuum circuit breaker 1, and the fixed side contact 3a is connected to the end of the fixed electrode 4. . The metal side corrugated pipe 10 is connected to the movable electrode 2 so as to be able to open and close while maintaining a vacuum tightness, and the shield 11 protects the metal airtight corrugated pipe 10 from the metal vapor generated at the time of blocking. give. One of the metal hermetic corrugated pipes 10 is supported by the movable side seal cup 9, and the movable side seal cup 9 is coupled to the ceramic insulating container 8. The fixed electrode 4 is supported by the fixed side seal cup 7, and the fixed side seal cup 7 is coupled to the ceramic insulating container 9. In the middle of the vacuum interrupter, an arcing shield 12 is provided between the upper and lower ceramic insulating containers 8.

In order to measure whether the vacuum interrupter deteriorates the vacuum interrupter, first, the vacuum circuit breaker 1 is disconnected from the power system and the terminals are connected to the terminals 5a and 5b from the top of the circuit breaker while the vacuum circuit breaker is opened. The voltage is applied to the withstand voltage tester (6). At this time, the leakage current flowing through the vacuum interrupter is measured to determine whether or not the internal pressure of the vacuum interrupter is abnormal.

2 is a graph showing the insulation strength according to the degree of vacuum inside the vacuum interrupter. As can be seen from the graph, when the degree of vacuum inside the vacuum interrupter decreases and the internal pressure increases, the insulation resistance inside the vacuum interrupter decreases according to Paschen's law. Therefore, when voltage is applied to the withstand voltage tester 6, a current flows in the vacuum interrupter, and the leakage current is measured at this time to determine whether the internal pressure of the genuine certified interrupter is abnormal.

However, such a conventional method of diagnosing the pressure degradation inside the vacuum interrupter has a disadvantage in that it is difficult to measure the vacuum circuit breaker in the live state of the circuit, so that the circuit breaker must be disconnected from the power system. Therefore, it is a reality that there is a lot of opportunity loss cost and time constraints to separate and inspect the circuit in operation normally, and it is actually difficult to inspect until regular inspection or special abnormality is detected.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and provides a means for easily detecting a vacuum deterioration state inside a vacuum interrupter of a vacuum breaker without disconnecting a circuit inside the vacuum breaker, that is, in a live state of the circuit. For the purpose of

The present invention provides a vacuum interrupter of a vacuum circuit breaker having a fixed electrode and a movable electrode that is in contact with and detachable from the fixed electrode, the cylindrical body portion for receiving the fixed electrode and the movable electrode; A movable side seal cup fastened to one end of the body portion; And a fixed side seal cup fastened to the other end of the body portion, wherein the movable side seal cup provides a vacuum interrupter having a detection pin attached to the inside of the vacuum interrupter for monitoring the degree of vacuum degradation.

According to the above configuration, the vacuum interrupter of the present invention can easily know whether the internal vacuum is deteriorated by monitoring the state of the detection pin even when the circuit is energized.

In addition, the detection pin is in the shape of a thin metal plate having a predetermined length, both ends of the detection pin is attached to the movable side seal cup, the detection pin is the upper surface of the movable side seal cup in a direction perpendicular to the cylindrical body portion It provides a vacuum interrupter attached to the.

Further, when the internal vacuum of the vacuum interrupter is in a good vacuum state, the detection pin provides a vacuum interrupter with a central portion bent toward the inside of the vacuum interrupter along the curved surface of the upper side of the movable seal cup.

When the internal vacuum of the vacuum interrupter is deteriorated and rises to a predetermined pressure value, the detection pin provides a vacuum interrupter whose center portion is bent in a direction away from the inside of the vacuum interrupter.

And, it provides a vacuum interrupter further comprises a sensor for detecting a change in the state of the detection pin, the sensor is an optical sensor for detecting the position of the center portion of the detection pin, or when the vacuum interrupter is under pressure Provides a vacuum interrupter which is a detection sensor in contact with the center portion of the detection pin.

The detection pin attached to the movable side seal cup to monitor the vacuum degree deterioration in the vacuum interrupter includes: a first member having two members having a predetermined length coupled to each other at a first point and a second point; And a second member coupled to the first position of the first member.

The first member is formed of a thin metal plate, and the two members provide a vacuum interrupter coupled to each other in a bent state.

The first member of the detection pin is attached to the movable side seal cup at first and second points, and is attached in a direction perpendicular to the cylindrical body portion, and one end of the second member is formed of the first member. Provides a vacuum interrupter coupled at one point.

When the inside of the vacuum interrupter is in a vacuum state, the two members constituting the first member are each bent toward the inside of the vacuum interrupter along the curved surface of the upper side of the movable cup, and the inside of the vacuum interrupter is pressurized. In the case of the state, the two members constituting the first member provide a vacuum interrupter, each of which is bent in a direction away from the inside of the vacuum interrupter.

Further, when the inside of the vacuum interrupter is in a vacuum state, the other end of the second member is supported by the first member in contact with the second point, and when the inside of the vacuum interrupter is under pressure, the other end of the second member. Provides a vacuum interrupter spaced apart from the second point.

The apparatus may further include a sensor capable of detecting a change in position of the other end of the second member, wherein the sensor is an optical sensor for detecting a position of the other end of the second member, or the sensor is configured to be used when the vacuum interrupter is under pressure. Provided is a vacuum interrupter which is a detection sensor in contact with the other end of the second member.

In addition, the present invention to detect the change in the shape of the detection pin attached to the vacuum interrupter, in order to detect the deterioration of the vacuum degree inside the vacuum interrupter of the vacuum interrupter; And a display step of displaying the vacuum degree deterioration inside the vacuum interrupter to the outside when the shape change is sensed in the sensing step.

When the inside of the vacuum interrupter reaches a predetermined pressure value, a portion of the detection pin may change in shape of the detection pin protruding outward of the vacuum interrupter. The method may further include a vacuum degradation detection method in the vacuum interrupter.

In the sensing step, the optical sensor recognizes a portion of the protruding detection pin to detect a shape change of the detection pin or a contact sensor contacts a portion of the protruding detection pin to detect the shape change of the detection pin.

In addition, the display step provides a vacuum degradation detection method inside the vacuum interrupter to display the vacuum degradation to the outside using a warning alarm.

The present invention has the advantageous effect of easily monitoring the degree of vacuum deterioration inside the vacuum interrupter even in the live state in which the circuit inside the vacuum breaker is not interrupted.

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

Looking at the configuration of a vacuum interrupter 100 according to an embodiment of the present invention shown in Figure 3 as follows. A movable side contact 102a is provided at the movable electrode 102 of the vacuum interrupter, and a fixed side contact 104a is provided at the tip of the fixed electrode 104. The movable electrode 102 is connected to the metal airtight corrugated pipe 110 to enable the opening and closing operation while maintaining the vacuum airtight, and to protect the metal airtight corrugated pipe 110 from the metal vapor generated during the blocking operation of the vacuum circuit breaker. The shield 111 is provided. One side of the metal hermetic corrugated pipe 110 is supported by one end of the movable side seal cup 109, and the other end thereof is coupled to a body portion 108 made of a ceramic insulated container. The fixed electrode 104 is supported by the fixed side seal cup 107, and the fixed side seal cup 107 is coupled to the body portion 108. In addition, an arcing shield 112 is fixed to the upper and lower ceramic insulating containers 108 at the middle of the vacuum interrupter.

4, a detection pin 200 according to an embodiment of the present invention is attached to the upper surface of the movable side seal cup 109. Shape and attachment of the detection pin will be described in detail below. An optical sensor 120 and a detector 130 are provided to measure a change in position of the detection pin 200 attached to the upper surface 109a of the movable side seal cup 109.

The detection pin 200 is illustrated in detail in FIGS. 5A to 5C. Referring to FIG. 5A, the detection pin is formed of a metal plate having a thin thickness and a predetermined width to have a predetermined length. In addition, in the longitudinal direction, the shape is curved not as a straight line but as a whole. In other words, the detection pin has a curved shape and a central depth is deeper than an outer portion. In addition, the detection pin may have a shape that is bent in the longitudinal direction and may also be bent in the thickness direction.

In other words, the detection pin of Figure 5a is not only bent to have a constant curvature in the longitudinal direction (direction connecting both ends (200a, 200b) of the detection pin), but also in the thickness direction (detection of the detection pin according to an embodiment) The pins may be curved to have a predetermined curvature even in a direction perpendicular to a direction connecting the both ends 200a and 200b of the pin. Thus, since the detection pin has a shape curved in the longitudinal direction and the thickness direction, elastic deformation of the detection pin described below may effectively occur.

 5B is a side view of FIG. 5A. It is preferable that the degree of bending of the detection pin is approximately equal to the curvature of the upper surface 109a of the movable seal cup 109 to which the detection pin is attached. When the inside of the vacuum interrupter becomes a vacuum, the upper surface 109a of the movable seal cup takes a curved shape in which the center portion is directed toward the inside of the vacuum interrupter by atmospheric pressure, where the curved shape of the detection pin 200 is excited. To be attached to. In addition, the detection pin is elastic, the bending direction is configured to be easily changed when a constant force is applied to the center portion from the outside. That is, as shown in FIG. 5B, when an external force is applied at the center of the detection pin in the direction of arrow 'A', the detection pin is bent in a curved direction as shown in FIG. 5C.

Hereinafter, a method of detecting internal pressure degradation in the vacuum interrupter configured as described above will be described.

As shown in FIG. 6, when the internal pressure of the vacuum interrupter is in a normal state, that is, in a state where the vacuum inside the vacuum interrupter is maintained well (this is referred to as a 'vacuum state of the vacuum interrupter'), the autism force and Due to the pressure difference between the inside and the outside of the vacuum interrupter, the upper surface 109a of the movable side seal cup 109 is deformed and bent toward the inside of the vacuum interrupter. To this end, the upper surface of the movable side seal cup has elasticity that can be deformed and restored. The detection pin 200 is attached to the top surface 109a of the movable side seal cup of the vacuum interrupter in which assembly is completed in this manner. At this time, both ends of the detection pin is fixed to the upper surface of the movable side seal cup, and the detection pin is attached to the upper surface of the movable side seal cup in a direction substantially perpendicular to the cylindrical body portion. In addition, an optical sensor 120 and a detector 130 capable of measuring a state change of the attached detection pin 200 are disposed.

In FIG. 7, the internal pressure of the vacuum interrupter increases to deteriorate the degree of vacuum inside the vacuum interrupter (this is referred to as a 'pressure state of the vacuum interrupter'). When the internal pressure of the vacuum interrupter rises to reach a constant pressure value, the autism force of the metal hermetic corrugated pipe 110 is lost, and the upper surface of the movable side seal cup 109 is restored to its original state. At this time, the upper surface of the movable side seal cup is restored to press the center portion bent downward as seen in the figure of the detection pin 200, so that the center portion of the detection pin protrudes upward. At this time, the control unit recognizes that the vacuum sensor inside the vacuum interrupter is deteriorated by the optical sensor 120 recognizing the position change of the protruding portion of the detection pin and sending it to the detector 130, and the control unit of the circuit detects a warning alarm, etc. By means of this, an alert can be sent to an external user.

8 and 9 illustrate a detection sensor 140 having a shape of a vacuum interrupter according to another embodiment of the present invention and capable of detecting a state change of the detection pin 200.

FIG. 8 illustrates a state in which the internal vacuum of the vacuum interrupter is maintained well, and FIG. 9 illustrates a case where the internal vacuum degree is deteriorated due to an increase in the internal pressure of the vacuum interrupter. When the internal pressure of the vacuum interrupter rises and the upper surface of the movable side seal cup 109 is restored to its original state, the detection pin 200 is bent downward toward the upper side by the deformation that the upper surface of the movable side seal cup is restored. As a result, the center of the detection pin protrudes upward. In this case, the detection sensor 140 contacts the center portion protruding upward of the detection pin 200 to detect the same. Then, the control unit of the vacuum circuit breaker receives a signal from the detection sensor 140 to warn the user.

Hereinafter, a shape of the detection pin 300 according to another embodiment of the present invention and a method of detecting the deterioration of the vacuum degree inside the vacuum interrupter using the same will be described.

10A to 1C are views of the coupling state of the detection pin 300 at various angles, and FIGS. 11A to 11C are views of the detection state of the detection pin 300 at various angles.

10A is a perspective view of the detection pin 300 in a coupled state, FIG. 10B is a plan view of the detection pin in a coupled state, and FIG. 10C is a side view of the detection pin in a coupled state. The detection pin 300 includes a first member 310 and 320 having two members connected to each other at an end and a second member 350 connected to the first member. The first member has a shape in which two thin metal plates are connected at ends, and the connected ends are referred to as a first point 330 and a second point 330. The second member 350 is connected to the first member at the first point 330. In addition, the two members constituting the first support member have a shape bent in the same direction, which is shown in the side view of FIG. 10C where the center portion of the detection pin connects the first point 330 and the second point 330. It can be seen that it is slightly spaced apart from an imaginary line, and it is bent upward in the figure. In other words, the center portion of the detection pin is formed deeper than both outer portions. In addition, the second member 350 is also coupled to bend in the same direction as the first member. As shown in FIGS. 10A to 10C, the first member and the second member are coupled to each other, and the first member and the second member are bent in the same direction, and one end 350a of the second member 350 may be formed. The first point 330 of one member is connected, and the other end 350b of the second member is in contact with the second point 340 of the first member and is supported by the second point.

11A is a perspective view of the detection pin 300 released, FIG. 11B is a plan view of the detection pin released, and FIG. 11C is a side view of the detection pin released. Here, the release state of the first member and the second member is as shown in FIGS. 11A to 11C, although one end of the second member 350 is connected at the first point 330 of the first member, but the second member The other end of the 350b means a state spaced apart from the second point 340 of the first member. Then, the bending direction of the first member in the release state of the detection pin becomes the opposite direction to the bending direction of the first member when the detection pin is in the engaged state. In other words, applying a constant force in the direction of the arrow 'F' to the center portion of the first member of the detection pin in the engaged state, as shown in Figure 10c, the bending direction of the first member is reversed to form the shape of Figure 11c, and at the same time The first member presses the second member so that the other end 350b of the second member is separated from the second point 340 of the first member.

When the internal pressure of the vacuum interrupter is in a normal state as shown in FIG. The upper surface 109a of the seal cup 109 is deformed and bent toward the inside of the vacuum interrupter. A detection pin 300 in a coupled state is attached to the upper surface 109a of the seal cup on the movable side of the vacuum interrupter. At this time, the first and second points of the detection pin is fixed to the upper surface of the movable side seal cup, and the detection pin is attached to the upper surface of the movable side seal cup in a direction substantially perpendicular to the cylindrical body portion. In addition, an optical sensor 120 and a detector 130 capable of measuring a state change of the attached detection pin 300 are disposed.

In FIG. 13, the internal pressure of the vacuum interrupter rises and the degree of vacuum inside the vacuum interrupter deteriorates. When the internal pressure of the vacuum interrupter rises to reach a constant pressure value, the autism force of the metal hermetic corrugated pipe 110 is lost, and the upper surface of the movable side seal cup 109 is restored to its original state. At this time, the upper surface of the movable side seal cup is restored to press down the center portion bent downward as seen in the drawing of the detection pin 300, so that the center portion of the first member of the detection pin 300 is forced upward. . As the bending direction of the first member is changed by this force (as shown in the figure, the bending direction is changed from the downward curved state to the upward curved state), the first member exerts a force on the second member, resulting in the other end 350b of the second member. ) Is separated from the second point 340 of the first member to protrude upwards. At this time, the control unit recognizes that the position of the other end 350b of the second detection member 300b is detected by the optical sensor 120 and sent to the detector 130 to deteriorate the degree of vacuum inside the vacuum interrupter. And, the control unit of the circuit can send a warning to the external user through the means such as warning alarm.

14 and 15 illustrate a detection sensor 140 capable of detecting a change in position of the other end 350b of the detection pin 300.

FIG. 14 shows a state where the internal vacuum of the vacuum interrupter is maintained well, and FIG. 15 illustrates a case where the internal vacuum degree is deteriorated due to an increase in the internal pressure of the vacuum interrupter. When the internal pressure of the vacuum interrupter rises and the top surface of the movable side seal cup 109 is restored to its original state, the center portion of the first member of the detection pin 300 is bent downward due to the deformation of the top surface of the movable side seal cup. It is the same as described above that the upper member is bent and deformed, and the second member is released. At this time, in order to detect the other end 350b of the second member spaced apart from the first member of the detection pin 300, in this embodiment, the detection sensor 140 is provided. That is, the detection sensor detects and contacts the other end 350b of the second member protruding upward, and sends a signal to the control unit of the vacuum circuit breaker, and the vacuum circuit breaker control unit receives a signal from the detection sensor 140 to the user. Will warn of deterioration.

16 and 17 illustrate a method of detecting the deterioration of the vacuum degree inside the vacuum interrupter of the vacuum circuit breaker using the above configuration of the present invention.

The present invention provides a method for detecting a deterioration of a vacuum degree inside a vacuum interrupter of a vacuum circuit breaker, when the internal pressure of the vacuum interrupter reaches a predetermined pressure value, a portion of the detection pin protruding outwardly of the vacuum interrupter; A sensing step of detecting a shape change of a detection pin attached to the vacuum interrupter; And a display step of displaying the deterioration of the degree of vacuum inside the vacuum interrupter when the shape change of the detection pin is sensed in the sensing step. In the sensing step, the sensor detects the shape change of the detection pin by recognizing a portion of the protruding detection pin or the touch sensor detects the shape change of the detection pin by touching a portion of the protruding detection pin. Detects the deterioration of the vacuum degree inside the vacuum interrupter by displaying the deterioration of the vacuum degree using an alarm.

According to the configuration and method of the present invention, even when the vacuum circuit breaker is normally operated, the vacuum degree deterioration in the vacuum interrupter can be easily monitored even in the live state without disconnecting the circuit of the vacuum circuit breaker.

1 is a schematic configuration of a conventional vacuum interrupter,

2 is a graph showing the dielectric strength according to the vacuum degree inside the vacuum interrupter,

3 is a view of a vacuum interrupter 100 according to an embodiment of the present invention.

4 is a view in which the detection pin is attached to the upper surface of the movable seal cup 109 in the vacuum interrupter of FIG.

5a to 5c are views of the detection pin according to an embodiment of the present invention,

6 is a state in which the vacuum inside the vacuum interrupter is maintained well,

7 is a view of detecting a state in which the vacuum degree inside the vacuum interrupter is deteriorated.

8 is a view in which the vacuum inside the vacuum interrupter is maintained well.

9 is a view of detecting the deterioration of the vacuum degree inside the vacuum interrupter according to another embodiment of the present invention,

10a to 10c is a view of the shape of the coupling state of the detection pin according to another embodiment of the present invention from various angles,

11A to 11C are views of various shapes of the released state of the detection pin shown in FIGS. 10A to 10C.

12 is a view in which the vacuum inside the vacuum interrupter is maintained well.

13 is a view of detecting a state in which the vacuum degree inside the vacuum interrupter is deteriorated.

14 is a view in which the vacuum inside the vacuum interrupter is maintained well.

15 is a view of detecting the deterioration of the vacuum degree inside the vacuum interrupter according to another embodiment of the present invention,

16 is a method for detecting the deterioration of the vacuum degree inside the vacuum interrupter of the vacuum circuit breaker according to an embodiment of the present invention.

17 is a method for detecting the deterioration of the vacuum degree inside the vacuum interrupter of the vacuum circuit breaker according to another embodiment of the present invention.

Claims (26)

A vacuum interrupter of a vacuum circuit breaker having a fixed electrode and a movable electrode contactable to and detachable from the fixed electrode, A cylindrical body part accommodating the fixed electrode and the movable electrode; A movable side seal cup fastened to one end of the body portion; And And a fixed side seal cup fastened to the other end of the body portion. And the detecting pin is attached to the movable side seal cup to monitor the degree of vacuum degradation inside the vacuum interrupter. The method of claim 1, The detection pin is a vacuum interrupter, characterized in that the shape of a thin metal plate having a predetermined length. The method of claim 2, And both ends of said detection pin are attached to said movable side seal cup. The method of claim 3, wherein And the detection pin is attached to an upper surface of the movable side seal cup in a direction perpendicular to the cylindrical body portion. The method of claim 4, wherein The vacuum interrupter is a vacuum interrupter, characterized in that the detection pin is the center portion is bent toward the inside of the vacuum interrupter along the curved surface of the upper side of the movable cup cup. The method of claim 4, wherein When the vacuum interrupter is under pressure, the detection pin is a vacuum interrupter, characterized in that the center portion is bent in a direction away from the inside of the vacuum interrupter. The method according to claim 5 or 6, And a sensor capable of sensing a change in state of the detection pin. The method of claim 7, wherein The sensor is a vacuum interrupter, characterized in that the optical sensor for detecting the position of the center portion of the detection pin. The method of claim 7, wherein The sensor is a vacuum interrupter, characterized in that the detection sensor in contact with the center portion of the detection pin when the vacuum interrupter is under pressure.  The method of claim 1, wherein the detection pin A first member having two members having a predetermined length coupled to each other at a first point and a second point; And a second member coupled to the first position of the first member. The method of claim 10, The first member is made of a thin metal plate, the vacuum interrupter, characterized in that the two members are coupled to each other in a curved state in the same direction. The method of claim 11, And the first member of the detection pin is attached to the movable side seal cup at a first point and a second point. 13. The method of claim 12, And the first member of the detection pin is attached in a direction perpendicular to the cylindrical body portion. The method of claim 13, One end of the second member is a vacuum interrupter, characterized in that coupled to the first point of the first member. The method of claim 14, When the vacuum interrupter is in a vacuum state, each of the two members constituting the first member is a vacuum interrupter, characterized in that the middle portion is bent toward the inside of the vacuum interrupter along the curved surface of the upper side of the movable seal cup. The method of claim 14, When the vacuum interrupter is in a pressure state, each of the two members constituting the first member is a vacuum interrupter, characterized in that the center portion is bent in a direction away from the inside of the vacuum interrupter. The method of claim 15, And the other end of the second member is supported by the first member in contact with the second point when the vacuum interrupter is in a vacuum state. The method of claim 16, And when the vacuum interrupter is under pressure, the other end of the second member is spaced apart from the second point. The method of claim 17 or 18, And a sensor capable of detecting a change in position of the other end of the second member. The method of claim 19, The sensor is a vacuum interrupter, characterized in that the optical sensor for sensing the position of the other end of the second member. The method of claim 19, The sensor is a vacuum interrupter, characterized in that the detection sensor in contact with the other end of the second member when the vacuum interrupter is under pressure. A sensing step of detecting a shape change of a detection pin attached to the vacuum interrupter in order to detect the deterioration of the degree of vacuum inside the vacuum interrupter of the vacuum interrupter; And And detecting a change in shape in the detecting step, and displaying the deterioration of the degree of vacuum inside the vacuum interrupter to the outside. The method of claim 22, When the inside of the vacuum interrupter is a predetermined pressure value, the step of changing the shape of the detection pin protruding in the outward direction of the vacuum interrupter; The vacuum degree degradation detection method further comprising a. The method of claim 23, In the sensing step, the vacuum sensor degradation detection method inside the vacuum interrupter, characterized in that for detecting the shape change of the detection pin by recognizing a portion of the detection pin protruding by the optical sensor The method of claim 23, In the sensing step, the vacuum sensor degradation detection method inside the vacuum interrupter, characterized in that the touch sensor detects the shape change of the detection pin by contacting a portion of the protruding detection pin. The method of claim 22, In the display step, the vacuum degree degradation detection method inside the vacuum interrupter, characterized in that to display the vacuum degree degradation to the outside using a warning alarm.

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