KR102094870B1 - Gas circuit breaker of gas insulated switchgear - Google Patents

Abstract

According to the present invention, a gas circuit breaker for a gas insulation switchgear has a link mechanism (100) to transfer driving power from a driving source (80) to a second electrode unit (8) through an insulation rod (20) to realize an open electrode and a closed electrode of a first electrode unit (6) and the second electrode unit (8) stored in a gas container (12) with sealed insulation gas. The link mechanism (100) comprises: a first link (50) rotatably connected to the insulation rod (20) whose one end is connected to the second electrode unit through a connection member (52); a cylinder guide (54) having an upper slot formed on an upper portion thereof to guide a straight-line motion of the first link (50) and a channel-type slot on both sides thereof to guide a straight-line motion of the connection member (52) to guide the connection member (52) connecting the insulation rod (20) and the first link (50) to perform a straight-line motion; a lever (60) wherein one end thereof is rotatably connected to the other end of the first link (50), and a slot (62) of a long hole shape is formed on the other side thereof in a longitudinal direction; a second link (75) wherein one side thereof is connected to a first fixing connection point (A1) as a fixed link to form a right angle with the rear end of the cylinder guide (54), and a body of the lever (60) is rotatably connected to the first fixing connection point (A1); and a crank (70) wherein one side thereof is inserted into the slot (62) formed on the lever (60) to be slid and moved, and the other side thereof is rotatably connected to a second fixing connection point (A2) formed on the other end of the second link (75) and is driven by the driving source (80). A large-current shutoff operation can be performed at a high speed.

Description

Gas circuit breaker of gas insulated switchgear}

The present invention relates to a gas circuit breaker, and more particularly, to a gas circuit breaker for a gas insulated switchgear in which a link mechanism is applied to a power transmission mechanism in order to move the movable electrode part in the opening and closing directions.

Recently, a gas insulated switchgear (GIS) is a water substation facility that improves reliability by storing conductors and various protection devices by using an insulating gas that is excellent in insulation performance and extinguishing function in a metal sealed container as an insulation medium. Various components such as, circuit breaker, disconnector, and ground switch are composed in a complex manner.

In general, when a failure occurs in the power system, the fault current must be quickly and safely blocked to protect the system and various power devices. A device that blocks fault current is called a circuit breaker, and is classified into a gas circuit breaker, a vacuum circuit breaker, and an oil circuit breaker according to the extinguishing and insulating medium. The breaker interrupting the fault current means that the arc generated between the two contacts is interrupted when the fault current is interrupted. Classified in a manner. As the ultra-high voltage circuit breaker of 72.5 KV or higher, a gas circuit breaker of a paper extinguishing method that uses insulating gas (SF ₆ ) as an extinguishing and insulating medium is mainly used.

The breaker breaks the fault current. In the case of high voltage flow in the converter, an arc occurs when the electrodes are separated. In the circuit breaker, the fixed side arc electrode and the movable side arc electrode are placed separately from the fixed side main contact and the movable side main contact so that the arc occurs only between them. do. That is, the arc is configured to be concentrated locally in one place so that it can be easily extinguished.

The structure for the operation of the arc electrode of the circuit breaker is largely divided into a unidirectional driving method and a bidirectional driving method. In the case of the unidirectional driving method, the fixed portion maintains a fixed state and only the movable side retracts, so that the movable arc contactor of the movable portion is separated (opened) from the fixed arc contact of the fixed portion. The movable arc contactor is connected to the movable part via a link structure and interlocked together.

In recent years, the gas circuit breaker used in the ultra-high voltage power system has been widely used to transmit a driving force from a driving source using a link structure (mechanism) to move the electrode portion in the opening and closing directions.

In general, the link structure is disposed between the driving source and the insulator (rod) connected to the movable electrode part, and serves to open and close a pair of electrode parts.

As described above, a gas circuit breaker in which a link mechanism is applied to a power transmission mechanism for moving the movable electrode portion in the opening and closing directions is disclosed in Japanese Patent Laid-Open No. 2019-16570 (Patent Document 1).

The gas circuit breaker of Patent Document 1 is a gas circuit breaker having a link structure that transmits a driving force from a driving source to the electrode portion through an insulator to realize opening and closing electrodes of an electrode portion in which an insulating gas is enclosed in a sealed gas container. At the same time, the link structure is connected to the insulator to be rotated at one end, and a bell crank that can be moved by itself and the other end and one end of the bell crank are rotated to connect the other end to be rotated to a fixed connection point, thereby driving power from the driving source. It is configured at least from the link that delivers it.

In addition, the gas circuit breaker of Patent Literature 1 is a circuit breaker having a link structure that transmits a driving force from a driving source to the electrode portion through an insulator to realize opening and closing electrodes of an electrode portion in which an insulating gas is enclosed in a sealed gas container. As, the link structure is connected to the first moving connection point is rotated to the insulator, and at the same time, the bell crank that can move itself, and the second moving connection point of the bell crank and one end are connected to be rotated so that the other end is the first fixed connection point. A first link that is rotatably connected to the second link, and a second link that is connected to the third moving connection point of the bell crank and one end to be rotated to the second fixed connection point, and the first fixed connection point or the It is composed of a driving lever that is connected to the second fixed connection point to be rotated to transmit driving force from the driving source.

Patent Document 1 has a problem that the high-speed high-current blocking operation is not easy because the method directly drives the insulating rod by the bell crank. In addition, since Patent Document 1 lacks a separate guide structure for guiding the insulating rod, it is impossible to stably move the insulating rod linearly in the left and right directions, thereby causing vibration (shaking) of the insulating rod to generate gas. There is also a problem that the blocking performance of the circuit breaker is deteriorated.

: Japanese Patent Publication No. 2019-16570

An object of the present invention is to provide a gas circuit breaker for a gas insulated switchgear that can perform a large current blocking operation at high speed by simplifying a link mechanism of a gas circuit breaker.

Another object of the present invention is to improve the vibration suppression and power transmission efficiency by the vibration of the upper, lower and left and right direction of the insulating rod during the forward and backward driving of the insulating rod to drive the opening and closing of the electrode portion by a link mechanism. It is to provide a gas circuit breaker for a gas-insulated switchgear.

Another object of the present invention is to set the reverse travel distance of the insulating rod for opening the electrode portion to be shorter than the moving forward distance of the insulating rod for closing the gas circuit breaker for a gas insulated switchgear capable of performing a large current blocking operation at high speed. To provide.

The gas circuit breaker for a gas insulated switchgear according to an embodiment of the present invention insulates the driving force from a driving source to realize opening and closing of the first electrode part and the second electrode part in which insulating gas is contained in a sealed gas container. A gas circuit breaker for a gas insulated switchgear having a link mechanism that is transmitted through a rod to the second electrode part, wherein the link mechanism is rotatably interconnected with an insulating rod connected to the second electrode part through a connecting member. First link; An upper slot for guiding the linear motion of the first link is formed at the top, and a channel type slot for guiding the linear motion of the connecting member is provided on both sides to guide the connecting member connecting the insulating rod and the first link to linear motion. Cylinder guide; One end is rotatably connected to the other end of the first link and a lever having a slot-shaped slot along the longitudinal direction on the other side; A second link that is connected to a first fixed connection point such that one side forms a right angle with the rear end of the cylinder guide as a fixed link, and the body of the lever is rotatably connected to the first fixed connection point and is integrally formed with the cylinder guide; And a crank rotatably connected to a second fixed connection point formed at the other end of the second link, and crank driven by the driving source, wherein one side is slidably inserted into a slot formed in the lever 60 and the other side is rotatably connected to the second fixed connection point formed at the other end of the second link. When the driving source applies a counterclockwise rotational force to the crank at the opening, when the crank rotates counterclockwise, the lever is rotated around a first fixed connection point to reverse the first link connected to the lever and connect the member And the insulating rod are retracted along the cylinder guide, the second electrode part is separated from the first electrode part, a connecting member is movably coupled to one side of the cylinder guide, and a side wall of the connecting member and the second link is connected to the other side. In order to alleviate the collision, a cushioning member supported by an elastic member is built in.

The gas circuit breaker for a gas insulated switchgear according to another embodiment of the present invention insulates the driving force from a driving source to realize opening and closing electrodes of the first electrode part and the second electrode part in which insulating gas is contained in a sealed gas container. A gas circuit breaker for a gas insulated switchgear having a link mechanism that is transmitted through a rod to the second electrode part, wherein the link mechanism is rotatably interconnected with an insulating rod connected to the second electrode part through a connecting member. First link; An upper slot for guiding the linear motion of the first link is formed at the top, and a channel type slot for guiding the linear motion of the connecting member is provided on both sides to guide the connecting member connecting the insulating rod and the first link to linear motion. Cylinder guide; One end is rotatably connected to the other end of the first link and a lever having a slot-shaped slot along the longitudinal direction on the other side; A second link that is connected to a first fixed connection point such that one side forms a right angle with the rear end of the cylinder guide as a fixed link, and the body of the lever is rotatably connected to the first fixed connection point and is integrally formed with the cylinder guide; A crank rotatably connected to a second fixed connection point formed at the other end of the second link, the other side being slidably inserted into a slot formed in the lever and the other side being driven by the drive source; And a crank moving mechanism inserted between the drive source and the crank to convert a linear motion force provided from the drive source into a rotational motion force, wherein the drive source applies a counterclockwise rotational force to the crank at the opening, thereby reducing the crank half When rotating in the clockwise direction, the lever is rotated around the first fixed connection point to reverse the first link connected to the lever, and the connecting member and the insulating rod are reversed along the cylinder guide, so that the second electrode portion is the first electrode. Separated from the part, a coupling member is movably coupled to one side of the cylinder guide, and a cushioning member supported by an elastic member is built in to the other side to alleviate the collision between the connecting member and the side wall of the second link, and the crank The moving mechanism includes a rotating plate and an L-shaped connecting rod having a slot so that one side is connected to the pin of the rotating plate, Characterized in that the side is a drive lever which is connected with L-shaped connecting rod and the other end is connected to a driving source to enable the rotation to provide a linear locomotion.

In this case, the connecting member includes a bolt and a nut, and after matching the holes formed in the insertion holes formed in the insulating rod and the '⊃' shaped connection portions formed on one side of the first link, then insert the bolts into the holes Ugo nuts can be tightened.

A gas circuit breaker for a gas insulated switchgear according to another embodiment of the present invention uses a driving force from a driving source to realize opening and closing electrodes of a first electrode part and a second electrode part in which insulating gas is contained in a sealed gas container. A gas circuit breaker for a gas insulated switchgear having a link mechanism for transmitting it to the second electrode part through an insulating rod, wherein the link mechanism is rotatably interconnected with an insulating rod connected to the second electrode part through a connecting member. A first link to be connected; One end is rotatably connected to the other end of the first link and a lever having a slot-shaped slot along the longitudinal direction on the other side; A second link to which the other end of the lever is rotatably connected to one side that is a third fixed connection point as a fixed link; It includes; and a crank rotatably connected to the fourth fixed connection point formed at the other end of the second link and the other end is slidably inserted into a slot formed in the lever and driven by the driving source. On the one side, a female screw portion is formed which is screwed to the male screw portion of the insulating rod, and an insertion portion is formed on the other side to which the connection portion of the first link is fitted, and when the opening is applied, the driving source applies a counterclockwise rotational force to the crank, thereby reducing the crank half. When rotating clockwise, the lever is rotated around a third fixed connection point to reverse the first link connected to the lever, and the connecting member and the insulating rod are reversed according to the reverse of the first link, so that the second electrode portion It is characterized in that it is separated from the first electrode portion.

A gas circuit breaker for a gas insulated switchgear according to another embodiment of the present invention uses a driving force from a driving source to realize opening and closing electrodes of a first electrode part and a second electrode part in which insulating gas is contained in a sealed gas container. A gas circuit breaker for a gas insulated switchgear having a link mechanism for transmitting it to the second electrode part through an insulating rod, wherein the link mechanism is rotatably interconnected with an insulating rod connected to the second electrode part through a connecting member. A first link to be connected; One end is rotatably connected to the other end of the first link and a lever having a slot-shaped slot along the longitudinal direction on the other side; A second link to which the other end of the lever is rotatably connected to one side that is a third fixed connection point as a fixed link; A crank rotatably connected to a fourth fixed connection point formed at the other end of the second link, one end of which is slidably inserted into a slot formed in the lever and the other end is driven by the driving source; And a crank moving mechanism inserted between the drive source and the crank to convert a linear motion force provided from the drive source into a rotational motion force, wherein the connecting member is formed with a female screw portion screw-coupled with a male screw portion of an insulating rod on one side An inserting portion is formed on the other side to which the connection portion of the first link is fitted, and when the opening is applied, the driving source applies a counterclockwise rotational force to the crank through the crank moving mechanism, and when the crank rotates in the counterclockwise direction, the lever is removed. 3 The first link connected to the lever is rotated around the fixed connection point, and the connecting member and the insulating rod are reversed according to the reverse of the first link, so that the second electrode part is separated from the first electrode part, and the crank moves. The mechanism includes a rotating plate, a connecting rod rotatably connected to one side of the rotating plate, and a rotating rod connected to the connecting rod on one side. Characterized in that it can be connected and that the other side is rotatably connected to the drive lever and the bell crank, and one end is connected to the bell crank and a drive lever the other side is linearly driven by a drive source.

In this case, the reverse movement distance of the insulating rod and the second electrode portion at the opening is set shorter than the forward movement distance at the closing, and the rotation direction of the crank is preferably counterclockwise.

The bell crank has a boomerang shape, and one side may be connected to the connecting rod and the other side may be connected to the driving lever around the fixed connection point.

The gas circuit breaker of the present invention has an advantage of performing a large current blocking operation at a high speed by simplifying the link mechanism of the circuit breaker.

In addition, in the present invention, it is possible to improve vibration suppression and power transmission efficiency due to vibrations in the upper, lower, and left and right directions of the insulating rods during forward and backward driving of the insulating rods that are driven to open and close the electrode portion by a link mechanism.

Moreover, in the present invention, a large current blocking operation can be performed at a high speed by setting the backward movement distance of the insulation rod for opening the electrode portion to be shorter than the forward movement distance of the insulation rod for the closure.

1 is a longitudinal cross-sectional view showing a state after a closed pole of a gas circuit breaker for a gas insulated switchgear according to the present invention,
Figure 2 is a longitudinal cross-sectional view showing a state after opening of the gas circuit breaker for a gas insulated switchgear according to the present invention,
3 and 4 are enlarged front views, respectively, showing steps of being closed using a link mechanism according to the first embodiment of the present invention,
5 and 6 are enlarged front views respectively showing steps opened using a link mechanism according to a first embodiment of the present invention,
7 is an enlarged front view showing a crank moving mechanism applied to the link mechanism according to the first embodiment of the present invention,
8 is an enlarged front view showing a state after a closed pole implemented using a link mechanism according to a second embodiment of the present invention,
9 is an enlarged front view showing a state after opening, which is implemented using a link mechanism according to a second embodiment of the present invention,
10 is an explanatory diagram for explaining the operation of the link mechanism according to the second embodiment of the present invention,
11 is an explanatory diagram for explaining the operation of the crank moving mechanism applied to the link mechanism according to the second embodiment of the present invention.

Hereinafter, embodiments of the gas circuit breaker of the present invention will be described with reference to the accompanying drawings.

1 is a longitudinal cross-sectional view showing the state after the closed pole of the gas circuit breaker for a gas-insulated switchgear according to the present invention, and FIG. 2 is a longitudinal cross-sectional view showing the state after opening of the gas circuit breaker for a gas-insulated switchgear according to the present invention. 3 and 4 are enlarged front views, respectively, showing steps of being closed using the link mechanism according to the first embodiment of the present invention, and FIGS. 5 and 6 are link mechanisms according to the first embodiment of the present invention. It is an enlarged front view which respectively showed the step opened by using.

1 and 2, a gas circuit breaker for a gas insulated switchgear according to a first embodiment of the present invention includes a first electrode part 6 which is housed in a gas container 12 in which insulating gas is sealed. In order to realize the opening and closing of the second electrode portion 8, a link mechanism 100 is provided that transmits the driving force from the driving source 80 to the second electrode portion 8 through the insulating rod 20. have. 1 and 2, reference numeral 14 is a movable side conductor, and reference numeral 16 is a fixed side conductor.

The link mechanism 100 includes a first link 50, a lever 60, a crank 70, and a second link 75, as shown in FIGS. 1 to 6. Here, the link mechanism 100 is an insulating rod moving mechanism for moving the insulating rod 20 connected to the second electrode portion 8 in the forward and backward directions.

One end of the first link 50 is rotatably connected to the insulating rod 20, and the other end is rotatably connected to a lever 60 to be described later. Here, the first link 50 is configured such that one end is interconnected with the insulating rod 20 by a connecting member 52 and the other end is connected with the lever 60, and the operation of the first link 50 ( By moving), the connecting member 52 and the insulating rod 20 are configured to move left and right along the cylinder guide 54. The first link 50 is rotatably connected to the first moving connecting point B1 of the connecting member 52 and the second moving connecting point B2, which is the front end of the lever 60, of the lever 60 described later. It is configured to move according to the movement.

The connecting member 52 is configured to be made of a bolt 42 and a nut 44, as shown in FIGS. 3 to 6, but the cylindrical housing (not shown) and the bolt ( 42) and the nut 44.

The fastening method of the connecting member 52 is a hole formed in the insertion hole 21 formed on one side of the insulating rod 20 and the '⊃' shaped connection portion 53 formed on one side of the first link 50 ( After matching 51, the bolts 42 are inserted into the holes 21 and 51, and then fastened with a nut 44. The connecting member 52 is preferably sealed outside using a cap or cover not shown in order to prevent the foreign matter from leaking.

The connecting member 52 and the insulating rod 20 connected to the connecting member 52 are configured to be horizontally movable left and right along the cylinder guide 54 according to the movement of the first link 50. In addition, the cylinder guide 54 may be configured to open a part of the three surfaces except the lower surface. That is, the upper surface of the cylinder guide 54 is formed with an upper slot (not shown) in the vertical direction to facilitate the movement of the first link 50, and both sides of the cylinder guide 54 are also connected members 52 A channel-type slot (not shown) is formed so as to facilitate the movement, and it is preferable to form a stepped portion (not shown) to prevent departure from the outside.

Although the cylinder guide 54 has been described as an example of a hollow square shape (that is, the inside is configured as a hollow cylinder to accommodate the insulating rod 20 corresponding to the shape (shape) of the insulating rod 20), the user It can be configured in a variety of forms, such as cylindrical according to the needs of. In addition, the reason for applying the cylinder guide 54 is to reduce vibration in the up, down or left and right directions of the insulating rod 20 when the insulating rod 20 connected to the first link 50 moves.

On the other hand, the connecting member 52 is disposed on one side of the cylinder guide 54, but on the other side, the cushioning member 58 connected to the elastic member 56 to alleviate the collision between the connecting member 52 and the side wall 55 ) Is placed. Here, the support member 58 is made of a rubber material.

The lever 60 has one end rotatably connected to the first link 50, and a slot 62 in the form of a long hole is formed along the longitudinal direction on the other side. The crank pin 72 of the crank 70 to be described later is inserted into the slot 62. The length of the slot 62 is preferably limited to a range that does not interfere with the movement of the crank pin 72 when the crank 70 is rotated. Then, the lever 60 is rotatably connected to a first fixed connection point A1 formed on the other side of the cylinder guide 54. Therefore, the lever 60 is configured to be rotatable around the first fixed connection point A1 according to the rotational movement of the crank 70 to be described later.

The crank 70 has one side fitted in the slot 62 formed in the lever 60 and the other side is rotatably connected to the second fixed connection point A2. That is, the crank pin 72 formed on one side of the crank 70 is fitted into the slot 62 formed in the lever 60, and the other side of the crank 70 is a second fixed connection point A2, that is, described later. It is rotatably connected to the second link 75 side.

When the crank 70 is rotated, the crank pin 72 of the crank 70 is configured to move along the slot 62 formed in the lever 60. In addition, the crank 70 is connected to a drive source 80, and the drive source 80 is a rotational drive source.

The second link 75 is configured such that one side is respectively connected to the cylinder guide 54 and the lever 60 and the other side is rotatably supported by the crank 70. The second link 75 is a fixed link, and may be installed separately from the cylinder guide 54, but is preferably formed integrally (ie, the second link 75 is a cylinder to reduce the total number of links). It may be formed integrally with the guide 54 to form a 'a' shape).

On the other hand, the drive source 80 may adopt a rotation drive source that provides a rotational force, or a linear drive source 88 that provides a drive force that moves in a linear direction instead of the rotational drive source. In this case, as illustrated in FIG. 7, a crank moving mechanism 200 that converts linear motion into rotary motion may be further installed.

The crank moving mechanism 200 includes a rotating plate 90, an L-shaped connecting rod 94 having a slot 92 formed so that one side is connected to a pin 82 of the rotating plate 90, and an L-shaped connecting rod on one side. It is composed of a drive lever 96 that is connected to the 94 and the other side is connected to the drive source 88. The pin 82 formed on the rotating plate 90 is a protruding pin, and the pin 82 is fitted into the slot 92 of the L-type connecting rod 94.

The crank moving mechanism 200 is configured to move the L-shaped connecting rod 94 connected to the driving lever 96 along the pin 82 disposed on the rotating plate 90 according to the linear motion of the driving source 88. . In addition, the L-type connecting rod 94 rotates the fixed connection point C1 in the left and right directions as a rotation axis when the driving lever 96 is operated. In addition, when the driving lever 96 is linearly operated, the pin 82 inserted into the slot 92 of the L-type connecting rod 94 rotates the rotating plate 90 according to the rotation of the L-type connecting rod 94. . That is, the crank moving mechanism 200 is moved by the pin 82 disposed on the rotating plate 90 along the slot 92 of the L-type connecting rod 94 in correspondence with the linear motion of the driving lever 96. It is configured to convert linear motion to rotary motion.

Therefore, when the rotating plate 90 is rotated by the operation of the crank moving mechanism 200, the link mechanism 100 also operates accordingly to move the insulating rod 20 forward and backward. That is, when the rotating plate 90 is rotated by the operation of the crank moving mechanism 200, the crank 70 is rotated while the crank pin 72 disposed on the opposite side of the rotating plate 90 is moved, and the crank 70 is rotated. By rotating the 70, the lever 60 and the first link 50 are moved to move the insulating rod 20 in the forward and backward directions (left and right directions).

When the crank moving mechanism 200 is applied to the gas circuit breaker of the first embodiment described above, the pin 82 disposed on the rotating plate 90 of the crank moving mechanism 200 and the crank pin 72 of the crank 70 In order to avoid interference with the crank, it is preferable to arrange the crank pin 72 of the crank 70 on the opposite side (opposite side) of the rotating plate 90.

The gas circuit breaker according to the first embodiment of the present invention configured as described above will be described.

In the gas circuit breaker according to the first embodiment of the present invention, the fixed-side conductor 16 and the movable-side conductor 14, which were in contact with the circuit breaker, are first separated and reversed, and then the first electrode part. The second electrode part 8 is separated from (6), and a reverse operation is performed. To this end, when the rotational driving force in the counterclockwise direction from the driving source 80 is transmitted to the insulating rod 20 through the link mechanism 100 at the time of opening, reversal of the insulating rod 20 and the second electrode portion 8 occurs. It is switched from the closed-pole state of Fig. 1 to the open-circuit state of Fig. 2.

First, the lever 60 when the fixed-side conductor 16 and the movable-side conductor 14 are in a contact state and the first electrode part 6 and the second electrode part 8 are in a closed state in contact state 1 and 4 are set in an equilibrium state with the ground.

When the switch mechanism is switched to the open state according to the circuit interruption, the link mechanism 100 in the state of FIG. 4, when the rotational driving force is transmitted from the drive source 80 to the crank 70, the crank 70 is connected to the second fixed connection point A2 ) While rotating in the counterclockwise direction, the crank pin 72 moves along the slot 62 of the lever 60 to rotate the lever 60 counterclockwise. At this time, the lever 60 is rotated counterclockwise according to the counterclockwise rotation of the crank 70 based on the first fixed connection point A1, as shown in FIG. 5.

When the lever 60 is rotated relative to the first fixed connection point A1, the second moving connection point B2 of the lever 60 and the front end of the first link 50 connected thereto are also lowered in equilibrium with the ground. .

When the lever 60 is continuously rotated counterclockwise to be set in an equilibrium state with the ground, as shown in FIG. 6, the first link 50 connected to the lever 60 moves backward to set the equilibrium state with the ground Will be. At this time, since the connecting member 52 connected to the first link 50 moves backward along the channel type slot of the cylinder guide 54 together with the insulating rod 20, the front and rear directions of the insulating rod 20 are of course It is possible to move while minimizing up and down shaking (vibration).

In addition, the second electrode portion 8 connected to the insulating rod 20 according to the reverse of the insulating rod 20 is reversed and separated from the first electrode portion 6 to be in an open state, that is, a circuit blocking state.

As described above, the link mechanism 100 according to the first embodiment of the present invention can reduce the shaking (vibration) of the insulating rod 20 of the gas circuit breaker, and the movable side conductor 14 and the second electrode part generated thereby (8) Since there is no vibration in the back, the blocking performance of the gas circuit breaker is improved.

On the other hand, in the case of the closed electrode, the first electrode part 6 and the second electrode part 8 are moved from the state shown in FIG. 2 to the state shown in FIG. 1 by operating in opposition to the above-described open state.

That is, when the lever 60 is rotated clockwise by applying a clockwise rotational force from the drive source 80 to the crank 70, the insulating rod 20 and the second electrode portion 8 advance to move the first electrode portion ( 6) A steady-state circuit configuration is achieved by contact.

In the case of applying the driving source 88 providing the linear driving force instead of the driving source 80 providing the rotational force in the link mechanism 100 according to the first embodiment of the present invention, as illustrated in FIG. 7, the crank moving mechanism ( 200) can be applied.

In the crank moving mechanism 200, when the linear driving force from the driving source 88 is operated in a downward direction pulling the driving lever 96, the L-shaped connecting rod 94 connected to the driving lever 96 rotates clockwise and the rotating plate The pin 82 disposed at 90 also rotates clockwise. Here, the pin 82 disposed on the rotating plate 90 is fitted into the slot 92 of the L-type connecting rod 94, so that the L-shaped connecting rod 94 watches according to the up and down movement of the driving lever 96. The rotational movement is performed in a clockwise or counterclockwise direction, and the pin 82 disposed on the rotational plate 90 rotates according to the rotational movement of the L-type connecting rod 94, so that the rotational plate 90 rotates.

The crank moving mechanism 200 may be applied to rotate the crank 70 of the link mechanism 100 by converting the linear driving force of the drive source 88 into rotational motion.

On the other hand, since the crank pin 72 of the crank 70 of the link mechanism 100 is disposed on the opposite side (opposite side) of the rotating plate 90, the crank moving mechanism 200 interferes with the link mechanism 100 (overlapping) Each operation is performed without being). That is, since the crank moving mechanism 200 is disposed on one side of the rotating plate 90 and the link mechanism 100 is disposed on the other side (opposite side) of the rotating plate 90, the rotating plate 90 of the crank moving mechanism 200 rotates The crank 70 of the link mechanism 100 is also rotated. Therefore, the crank moving mechanism 200 and the link mechanism 100 operate to perform the role of moving the insulating rod 20 and the second electrode portion back and forth.

The gas circuit breaker according to the second embodiment of the present invention will be described with reference to FIGS. 8 to 11.

8 is an enlarged front view showing a state after the closed pole implemented using the link mechanism according to the second embodiment of the present invention, and FIG. 9 is after the opening implemented using the link mechanism according to the second embodiment of the present invention An enlarged front view showing the state, Figure 10 is an explanatory diagram for explaining the operation of the link mechanism according to the second embodiment of the present invention, Figure 11 is a crank moving mechanism applied to the link mechanism according to the second embodiment of the present invention It is an explanatory diagram for explaining the operation of.

8 and 9, the link structure 300 of the gas circuit breaker according to the second embodiment of the present invention is largely the first link 150 and the lever 160 as in the first embodiment described above. And, a crank 170 and a second link 175.

The link structure 300 of the gas circuit breaker according to the second embodiment of the present invention does not move from the cylinder guide 54 of the above-described embodiment to the left and right, but does not apply the cylinder guide, but instead applies the insulating rod 20 only with the link structure. It is configured to move forward and backward (left and right).

One end of the first link 150 is pivotally connected to the insulating rod 20 through a connecting member 152. In addition, since the operation of the first link 150 is similar to the first embodiment described above, a detailed description will be omitted.

The connecting member 152 is formed with a female screw portion 102 on one side and an insertion portion 104 on the other side. The female screw portion 102 is screwed to the male screw portion 22 formed on one side of the insulating rod 20, and the insertion portion 104 is configured to be fitted with a connection portion 155 of the first link 150.

It is preferable that the female screw portion 102 of the connecting member 152 and the male screw portion 22 of the insulating rod 20 are screwed together to seal the outer portion (not shown) of the connecting member 152 ( That is, it is preferable to perform sealing to prevent foreign matters from flowing out after screwing the female screw portion 102 and the male screw portion 22).

The lever 160 is rotatably connected to the first link 150 and a slot 162 is formed on one side. The crank pin 172 of the crank 170 to be described later is inserted into the slot 162. The lever 160 is rotatably connected to a third fixed connection point A3 on the second link 175 side described later. Accordingly, the lever 160 is configured to rotate clockwise or counterclockwise along the fan arc direction around the third fixed connection point A3 along with the rotational movement of the crank 170 described later (for reference, here The arc length is set substantially equal to the moving distance of the insulating rod 20).

The crank 170 is one side is fitted in the slot 162 formed in the lever 160 and the other side is rotatably connected to the second link (175). Here, the crank pin 172 of the crank 170 is fitted into the slot 162 formed in the lever 160, and when the crank 170 is rotated, the crank pin 172 is a slot formed in the lever 160 ( 162).

The second link 175 is fixed as a fixed link, and the lever 160 is rotatably connected to one side and is configured to be connected to the crank 170 on the other side.

On the other hand, when applying the drive source 188 (i.e., linear drive source) instead of the drive source 180 (i.e., rotary drive source), as shown in FIG. 11, a crank moving mechanism for converting linear motion into rotary motion ( It may be configured by installing 400).

The crank moving mechanism 400 includes a rotating plate 190, a connecting rod 192 rotatably connected to one side of the rotating plate 190, and a connecting rod 192 connected to the connecting rod 192 and the other side driving lever ( It consists of a bell crank 194 rotatably connected to 196, and a driving lever 196 connected to the bell crank 194 on one side and the driving source 180 on the other side. The bell crank 194 has a boomerang shape, and one side is rotatably connected to the connection rod 192 around the fifth fixed connection point A5, and the other side is configured to be movably connected to the driving lever 196. . The pin 182 formed on the rotating plate 190 is a protruding pin, and the pin 82 is fitted to one side of the connecting rod 192.

The crank moving mechanism 400 rotates the bell crank 194 connected to the driving lever 196 according to the operation of the driving source 188 along the pin 182 disposed on the rotating plate 190. It is configured to. Here, when the drive lever 196 moves linearly, the bell crank 194 rotates around the fifth fixed connection point A5, and the connection rod 192 rotates the rotating plate 190 according to the rotation of the bell crank 194. It is rotated along the pin 182 disposed in.

Accordingly, when the rotating plate 190 is rotated by the operation of the crank moving mechanism 400, the link structure 300 also rotates accordingly to move the insulating rod 20 forward and backward. That is, when the rotating plate 190 is rotated by the operation of the crank moving mechanism 400, the crank 170 is rotated while the crank pin 172 disposed on the opposite side of the rotating plate 190 is rotated, and the crank ( By rotating the 170, the lever 160 and the first link 150 are moved to move the insulating rod 20 in the forward / reverse direction (left and right directions).

When the crank moving mechanism 400 is applied to the gas circuit breaker of the second embodiment described above, the pin 182 disposed on the rotating plate 190 of the crank moving mechanism 400 and the crank pin 172 of the crank 170 In order to avoid interference with the crank, it is preferable to arrange the crank pin 172 of the crank 170 on the opposite side (opposite side) of the rotating plate 190.

The gas circuit breaker according to the second embodiment of the present invention configured as described above will be described.

The gas circuit breaker according to the second embodiment of the present invention transmits the rotational driving force in the counterclockwise direction from the driving source 180 to the insulating rod 20 through the link structure 300 when the opening is similar to the first embodiment described above. As the insulating rod 20 and the second electrode portion 8 are reversed, they are switched from the closed-pole state as shown in FIG. 8 to the open-circuit state as shown in FIG. 9. As a result, the first electrode portion 6 and the second electrode portion 8 are separated, and the circuit is cut off.

In the link structure 300, when the rotational driving force in the counterclockwise direction from the driving source 180 is transmitted to the crank 170, the crank pin rotates counterclockwise around the fourth fixed connection point A4, and the crank pin ( 172) is moved along the slot 162 of the lever 160 to rotate the lever 160 clockwise. At this time, the lever 160 rotates clockwise according to the rotation of the crank 170 based on the third fixed connection point A3.

When the lever 160 is rotated clockwise, the first link 150 connected to the lever 160 is moved rearward. At this time, the connecting member 152 connected to the first link 150 is reversed together with the insulating rod 20.

The movement of the connecting member 152 and the first link 150 and the lever 160 connected to the insulating rod 20, as shown in Figure 10, with respect to the moving range of the lever 160 (No. S1), The upper rotation radius S2 in contact with the two tangent lines X1 and X2 of the rotation radius of the crank 170 is the forward movement distance of the connecting member 152, and the two tangent lines X1 in the rotation radius of the crank 170 are The lower rotation radius S3 in contact with X2) is the backward movement distance of the connecting member 152. Here, since the reverse movement distance (movement distance to close) is shorter than the forward movement distance (movement distance to open), the first electrode is fast at high speed as the insulation rod 20 and the second electrode portion 8 are reversed faster. An opening that separates the second electrode portion 8 from the portion 6 can be realized.

In the second embodiment of the present invention, the backward movement distance (the movement distance to close) of the insulating rod 20 and the second electrode portion 8 is set to be shorter than the forward movement distance (moving distance to open). ), For example, it is required to be rotated counterclockwise.

The link structure 300 according to the second embodiment of the present invention does not apply the cylinder guide 54 of the above-described first embodiment, so the lever 160 in order to reduce vibration (vibration) when the insulating rod 20 moves. The ratio of the moving range (No. S1), the upper rotation radius (S2) of the crank 170, and the lower rotation radius (S3) of the crank 170 should be properly maintained.

As described above, the link structure 300 according to the second embodiment of the present invention can reduce the vibration (vibration) of the insulating rod 20 of the gas circuit breaker and the movable side conductor 14 and the fixed side conductor ( 16) Since the vibration is reduced in the first electrode part 6 and the second electrode part 8, etc., the blocking performance of the gas circuit breaker is improved.

Meanwhile, in the case of the closed pole, the insulating rod 20 and the second electrode part 8 are moved from the state shown in FIG. 9 to the state shown in FIG. 8 by rotating the crank 170 in the counterclockwise direction, for example. It will move forward.

When the linear drive source 188 is applied instead of the rotary drive source 180 in the link structure 300 according to the second embodiment of the present invention, as illustrated in FIG. 11, the crank movement mechanism 400 is applied.

When the driving force of the crank moving mechanism 400 advances (rises) the driving lever 196 from the driving source 188 during opening, for example, the bell crank 194 connected to the driving lever 196 is fixed to the fifth. The connection rod 192 is rotated counterclockwise while rotating counterclockwise around the connection point A5. Since the connecting rod 192 is connected to the pin 182 disposed on the rotating plate 190, when the connecting rod 192 rotates counterclockwise, the pin 182 rotates counterclockwise along the rotating plate 190. You will exercise.

On the other hand, since the crank pin 172 of the crank 170 is disposed on the opposite side (opposite side) of the rotating plate 190, the crank moving mechanism 400 does not interfere (overlapped) with the link structure 300. You can play a role. That is, when the rotating plate 190 of the crank moving mechanism 400 rotates, the crank 170 of the link structure 300 also rotates, and according to the rotation of the crank 170, the lever 160 and the first link 150 ) Moves to move the insulating rod 20.

Although the embodiments of the present invention have been described as above, these embodiments are presented as examples and do not limit the scope of the invention. Accordingly, it is contemplated that other various forms of these new embodiments are possible, and these various forms are also included within the scope of the present invention.

The gas circuit breaker for a gas insulated switchgear (GIS) of the present invention can be widely applied to ultra-high voltage circuit breakers of 72.5 KV or higher.

6: first electrode portion 8: second electrode portion
12: gas container 14: movable conductor
16: Fixed side conductor 20: Insulated rod
50,150: first link 60,160: lever
70,170: crank 75,175: second link
80,88,180,188: drive source 90,190: rotating plate
94: L-type connecting rod 96,196: Driving lever
100,300: Link structure 200,400: Crank moving mechanism
194: Bell crank

Claims (7)

In order to realize the opening and closing electrodes of the first electrode part 6 and the second electrode part 8, which are housed in the gas container 12 in which the insulating gas is sealed, the driving force from the driving source 80 is applied to the insulating rod 20 ) As a gas circuit breaker for a gas insulated switchgear equipped with a link mechanism (100) to the second electrode portion (8),
The link mechanism 100,
A first link 50 which is rotatably interconnected with an insulating rod 20 connected to the second electrode part through this connecting member 52;
The upper slot for guiding the linear motion of the first link 50 is formed on the upper side, and the channel-shaped slot for guiding the linear motion of the connecting member 52 is provided on both sides, so that the insulating rod 20 and the first link 50 Cylinder guide 54 for guiding the connecting member 52 connecting the linear motion;
A lever 60 having one end rotatably connected to the other end of the first link 50 and having a long hole-shaped slot 62 along the longitudinal direction on the other side;
As a fixed link, one side is connected to a first fixed connection point (A1) so as to form a right angle with the rear end of the cylinder guide 54, and the body of the lever 60 is rotatably connected to the first fixed connection point (A1), and the cylinder guide A second link 75 formed integrally with the 54; And
One side is slidably inserted into the slot 62 formed in the lever 60 and the other side is rotatably connected to the second fixed connection point A2 formed at the other end of the second link 75, and the drive source 80 Includes; crank 70 driven by);
When the driving source 80 applies the counterclockwise rotational force to the crank 70 at the opening, when the crank 70 rotates counterclockwise, the lever 60 centers on the first fixed connection point A1. The first link 50 connected to the lever 60 is rotated to reverse, and the connecting member 52 and the insulating rod 20 are reversed along the cylinder guide 54, so that the second electrode part 8 is Separated from the first electrode part 6,
The coupling member 52 is movably coupled to one side of the cylinder guide 54, and the elastic member 56 to alleviate collision between the connecting member 52 and the side wall 55 of the second link 75 on the other side. ) Is supported by a buffer member 58 is built,
The connection member 52 includes a bolt 42 and a nut 44, an '⊃' shaped connection portion formed on one side of the insertion hole 21 and the first link 50 formed in the insulating rod 20 The gas circuit breaker for the gas insulated switchgear, characterized in that the holes 51 formed in the 53 are matched, and then the bolts 42 are fitted to the holes 21 and 51 and the nuts 44 are fastened.
In order to realize the opening and closing poles of the first electrode portion 6 and the second electrode portion 8 in which the insulating gas is stored in the sealed gas container 12, the driving force from the driving source 88 is applied to the insulating rod 20 ) As a gas circuit breaker for a gas insulated switchgear equipped with a link mechanism (100) to the second electrode portion (8),
The link mechanism 100,
A first link 50 which is rotatably interconnected with an insulating rod 20 connected to the second electrode part through this connecting member 52;
The upper slot for guiding the linear motion of the first link 50 is formed on the upper side, and the channel-shaped slot for guiding the linear motion of the connecting member 52 is provided on both sides, so that the insulating rod 20 and the first link 50 Cylinder guide 54 for guiding the connecting member 52 connecting the linear motion;
A lever 60 having one end rotatably connected to the other end of the first link 50 and having a long hole-shaped slot 62 along the longitudinal direction on the other side;
As a fixed link, one side is connected to a first fixed connection point (A1) so as to form a right angle with the rear end of the cylinder guide 54, and the body of the lever 60 is rotatably connected to the first fixed connection point (A1), and the cylinder guide A second link 75 formed integrally with the 54;
One side is slidably inserted into the slot 62 formed in the lever 60 and the other side is rotatably connected to the second fixed connection point A2 formed at the other end of the second link 75 and the drive source 88 Crank 70 driven by); And
It includes a crank movement mechanism 200 that is inserted between the drive source 88 and the crank 70 to convert the linear motion force provided from the drive source 88 into a rotational motion force.
When the driving source 88 is applied to the crank 70 through the crank moving mechanism 200 during the opening, the lever 60 is rotated in the counterclockwise direction. 1 is rotated around a fixed connection point (A1) to reverse the first link 50 connected to the lever 60, and the connecting member 52 and the insulating rod 20 are reversed along the cylinder guide 54, the The second electrode portion 8 is separated from the first electrode portion 6,
The coupling member 52 is movably coupled to one side of the cylinder guide 54, and the elastic member 56 to alleviate the collision between the connecting member 52 and the side wall 55 of the second link 75 on the other side. ) Is supported by a buffer member 58 is built,
The crank moving mechanism 200 includes a rotating plate 90, an L-shaped connecting rod 94 having a slot 92 formed so that one side is connected to a pin 82 of the rotating plate 90, and an L-shaped connecting rod on one side. Gas breaker for a gas insulated switchgear, characterized in that it comprises a drive lever (96) which is connected to (94) and the other side is rotatably connected with a drive source (88) providing linear motion.
According to claim 2,
The connection member 52 includes a bolt 42 and a nut 44, an '⊃' shaped connection portion formed on one side of the insertion hole 21 and the first link 50 formed in the insulating rod 20 The gas circuit breaker for the gas insulated switchgear, characterized in that the holes 51 formed in the 53 are matched, and then the bolts 42 are fitted to the holes 21 and 51 and the nuts 44 are fastened.
In order to realize the opening and closing poles of the first electrode portion 6 and the second electrode portion 8 in which the insulating gas is stored in the sealed gas container 12, the driving force from the driving source 180 is applied to the insulating rod 20 ) As a gas circuit breaker for a gas insulated switchgear having a link mechanism (300) delivered to the second electrode part (8),
The link mechanism 300,
The first link 150 is rotatably connected to the insulating rod 20 connected to the second electrode part 8 through the connecting member 152;
A lever 160 having one end rotatably connected to the other end of the first link 150 and having a long hole-shaped slot 162 along the longitudinal direction on the other side;
A second link 175 to which the other end of the lever 160 is rotatably connected to one side which is a third fixed connection point (A3) as a fixed link; And
One end is slidably inserted into the slot 162 formed in the lever 160 and the other end is rotatably connected to the fourth fixed connection point A4 formed at the other end of the second link 175, and the driving source 180 Includes; crank 170 driven by);
The connecting member 152 is formed with a female screw portion 102 that is screwed with a male screw portion of the insulating rod 20 on one side and an insertion portion 104 into which the connecting portion 155 of the first link 150 is fitted on the other side. Is formed,
When the driving source 180 applies the counterclockwise rotational force to the crank 170 at the opening, when the crank 170 rotates counterclockwise, the lever 160 centers on the third fixed connection point A3. Rotating to the first link 150 is connected to the lever 160 and the connecting member 152 and the insulating rod 20 is reversed according to the reverse of the first link 150, the second electrode unit ( 8) is a gas circuit breaker for gas insulated switchgear, characterized in that separated from the first electrode (6).
In order to realize the opening and closing electrodes of the first electrode part 6 and the second electrode part 8, which are housed in the gas container 12 in which the insulating gas is sealed, the driving force from the driving source 188 is applied to the insulating rod 20 ) As a gas circuit breaker for a gas insulated switchgear having a link mechanism (300) delivered to the second electrode part (8),
The link mechanism 300,
The first link 150 is rotatably connected to the insulating rod 20 connected to the second electrode part 8 through the connecting member 152;
A lever 160 having one end rotatably connected to the other end of the first link 150 and having a long hole-shaped slot 162 along the longitudinal direction on the other side;
A second link 175 to which the other end of the lever 160 is rotatably connected to one side which is a third fixed connection point (A3) as a fixed link;
One end is slidably inserted into the slot 162 formed in the lever 160 and the other end is rotatably connected to the fourth fixed connection point A4 formed at the other end of the second link 175, and the driving source 188 Crank 170 driven by); And
It includes a crank movement mechanism 400 is inserted between the drive source 188 and the crank 170 to convert the linear motion provided from the drive source 188 to a rotational motion force;
The connecting member 152 is formed with a female screw portion 102 that is screwed with a male screw portion of the insulating rod 20 on one side and an insertion portion 104 into which the connecting portion 155 of the first link 150 is fitted on the other side. Is formed,
When the driving source 180 applies the counterclockwise rotational force to the crank 170 through the crank moving mechanism 400 at the opening, when the crank 170 rotates in the counterclockwise direction, the lever 160 is removed. 3 It rotates around the fixed connection point (A3) to reverse the first link 150 connected to the lever 160, and the connecting member 152 and the insulating rod 20 are reversed according to the reverse of the first link 150. The second electrode part 8 is separated from the first electrode part 6,
The crank moving mechanism 400 has a rotating plate 190, one side rotatably connected to the rotating plate 190 and a connecting rod 192, one side rotatably connected to the connecting rod 192 and the other side Characterized in that it consists of a bell crank 194 rotatably connected to the drive lever 196 and a drive lever 196 connected to the bell crank 194 on one side and linearly driven by the drive source 188 on the other side. Gas circuit breaker for gas insulated switchgear.
The method of claim 4 or 5,
In the opening, the reverse movement distance of the insulating rod 20 and the second electrode portion 8 is set shorter than the forward movement distance at the closing, and the rotational direction of the crank 170 is counterclockwise. Gas circuit breaker for gas insulated switchgear.
The method of claim 5,
The bell crank 194 has a boomerang shape, and one side is connected to the connecting rod 192 around the fixed connection point A5, and the other side is configured to be connected to the driving lever 196. Gas breaker.

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