KR100823829B1 - Operator for gas insulated switchcgear - Google Patents

Abstract

An operator for a gas insulated switchgear is provided to reduce an occupied space by operating the gas insulated switchgear with one operator without an additional operator. An operator for a gas insulated switchgear includes an upper bus operator(20), and a lower bus operator(50). The upper bus operator operates a first contactor to a connection position, a cutting off position, or a grounding position by operating a first operating link(30) which is coupled to the first contactor. The lower bus operator operates a second contactor to a connection position, or a cutting off position by operating a second operating link(60) which is linked to the second contactor. The upper bus operator includes a first driving motor(21), a first driving wheel(24), a first Geneva gear, and a first driving link(27). The first driving wheel is rotated by the first driving motor. The first Geneva gear is operated with the first driving wheel. The first driving link is installed with the first Geneva gear. An end of the first operating link is linked with the first driving link. The other end of the first operating link is linked with the first contactor.

Description

Operator for Gas Insulated Switchgear {Operator for Gas Insulated Switchcgear}

1 is a front view of a gas insulated switchgear equipped with a manipulator for a gas insulated switchgear according to an embodiment of the present invention.

Figure 2 is a front view showing the operating relationship of the upper bus control unit and the three-position switch in Figure 1;

3 is a conceptual diagram showing a driving principle of the upper bus control unit in FIG.

4 is a plan view of the manipulator for the gas insulated switchgear of FIG.

5 is a side view of the manipulator for the gas insulated switchgear of FIG.

Description of the main symbols in the drawings

1: Gas insulation switchgear 2: Upper bus

2a: connection terminal 2b: ground terminal

3: lower bus 3a: connection terminal

10: operation box 20: upper bus control unit

21: first drive motor 22: first sprocket

23: chain 24: first drive wheel

25: first geneva gear 26: first drive shaft

27: first drive link 30: first operation link

40: three-position switch 41: the first driven link

42: first connector 50: lower bus operating unit

51: second drive motor 52: second sprocket

53: chain 54: second drive wheel

55: second geneva gear 56: second drive shaft

57: second driving link 60: second operating link

70: 2-position switch 71: Second driven link

72: second connector 80: control unit

The present invention relates to a manipulator of a gas insulated switchgear, and more particularly, to a manipulator of a gas insulated switchgear which can be operated by integrating the upper bus and the lower bus.

In general, a gas insulated switch charger (GIS) is provided in a power transmission line or a distribution line, and is a device that protects a power system by opening and closing a line in an abnormal state such as a ground fault or a short circuit as well as opening and closing by a normal state. to be.

The gas insulated switch is a circuit breaker, a disconnecting switch, an earthing switch, a lightning arrester, a main bus, a feeder bus, and a branch bus to a grounded metal housing. Built-in and filled with insulating gas inside.

The gas insulated switchgear is operated to connect, cut off, or ground a circuit through a manipulator provided on one side.

The manipulator for the gas insulated switchgear according to the prior art is provided with a bus provided in the gas insulated switchgear as an upper bus and a lower bus, and the manipulators for the gas insulated switchgear for opening and closing each bus are respectively provided. Open and close power transmission and distribution lines.

However, since the manipulator for the gas insulated switchgear according to the prior art has a manipulator for the upper bus and a manipulator for the lower bus separately, the structure becomes complicated and the space occupied by the manipulator in the gas insulated switchgear is increased, and thus There is a problem that the production cost increases.

The present invention has been invented to solve the above problems, and an object of the present invention is to provide a manipulator for a gas insulated switchgear that can be operated by integrating the upper bus and the lower bus.

In order to achieve the above object, the manipulator for the gas insulated switchgear according to the present invention is provided on one side of the upper bus so as to be selectively connected to the manipulator box, the upper bus, and a connection terminal or a ground terminal electrically connected to the upper bus. A three-position switch having a first connector rotatably provided, a lower bus, and a second connector rotatably provided on one side of the lower bus so as to be selectively connected to a connection terminal electrically connected to the lower bus. A gas insulated switchgear including a two-position switch provided, wherein the first operation link connected to the first connector is operated inside the operation box to operate the first connector at a connection position, a disconnection position, or a ground position. And an upper bus operation unit for operating the second bus and a second operation link connected to the second connector to operate the second connector. Is provided with a lower bus operation to operate in the cut off position.

The upper bus operating unit includes a first drive motor, a first drive wheel provided to be rotated by the first drive motor, a first Geneva gear provided to be intermittently engaged with the first drive wheel, and the first drive motor. And a first drive link provided coaxially with the Geneva gear, wherein the first operation link has one end linked to the first drive link, and the other end linked to the first connector.

Here, it is preferable that a first driven link is provided coaxially with the first connector on one side of the gas insulated switchgear, and the other end of the first operation link is linked to the first driven link.

In addition, the controller may be electrically connected to the first driving motor, and the first driving motor may be rotated by a driving signal of the control unit.

The lower bus operating unit includes a second drive motor, a second drive wheel provided to be rotated by the second drive motor, a second Geneva gear provided to be intermittently engaged with the second drive wheel, and the second drive motor. And a second drive link provided coaxially with the Geneva gear, wherein the second operation link has one end linked to the second drive link, and the other end linked to the second connector.

Here, it is preferable that a second driven link is provided coaxially with the second connector on one side of the gas insulated switchgear, and the other end of the second operation link is connected to the second driven link.

In addition, the controller may be electrically connected to the second driving motor, and the second driving motor may be rotated by the driving signal of the controller.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the manipulator for gas insulation switchgear of the present invention.

1 is a front view of a gas insulated switchgear equipped with a manipulator for a gas insulated switchgear according to the present invention, FIG. 2 is a front view showing an operation relationship between the upper bus control unit and the three-position switch in FIG. 2 is a conceptual view illustrating a driving principle of the upper bus operation unit, and FIGS. 4 and 5 are plan and side views of the manipulator for the gas insulated switchgear of FIG. 1.

The manipulator for gas insulated switchgear according to the present invention includes a manipulator box 10 provided in the gas insulated switchgear 1 and a three-sided housing provided in the manipulator box 10 and provided on one side of the upper bus 2. Linked with the position switch 40, the upper bus operating portion 20 to operate the three-position switch 40, the operation box 10 is accommodated as one side of the upper bus operating portion 20 and the upper bus ( 2) the lower bus operating unit 50 connected to the 2-position switch 70 provided in the link operation to operate the 2-position switch 70, and the upper bus operating unit 20 and the lower bus operating unit 50. It includes a control unit 80 for controlling.

The manipulator box 10 is provided at one side of the gas insulated switchgear 1 so that the upper bus operating unit 20 and the lower bus operating unit 50 described later are accommodated therein.

The upper bus operating unit 20 is provided inside the manipulator 10 to operate the 3-position switch 40 provided on one side of the upper bus 2.

To this end, the upper bus operating unit 20 is connected to the first driving motor 21, the first driving wheel 24 connected to the first driving motor 21 to rotate, and the first driving wheel 24. And a first drive link provided coaxially with the first Geneva gear 25 that rotates intermittently.

The first driving motor 21 is provided on one side of the manipulator 10 to generate a driving force when power is applied.

The first drive wheel 24 is connected to the first drive motor 21 by a power transmission means and rotatably provided in the manipulator box 10, thereby being rotated by the first drive motor 21. . As an example, the first sprocket 22 is provided coaxially with the first drive wheel 24, and the first drive motor 21 and the first sprocket 22 are connected through the chain 23. The first driving wheel 24 is rotated by the first driving motor 21.

The first Geneva gear 25 is fixed to the first drive shaft 26 rotatably provided in the manipulator box 10 so as to be intermittently engaged with the first drive wheel 24.

Here, the reason why the first Geneva gear 25 is used is that the continuous operation by the rotation of the first driving motor 21 does not directly act on the 3-position switch 40, but intermittently acts on the 3-position switch. To position the three-position switch 40 in the connection position, the disconnection position or the ground position, respectively.

A first drive link 27 is provided coaxially with the first Geneva gear 25, that is, the first drive shaft 26. The first drive link 27 is formed to have a predetermined length so that one end thereof is integrally fastened to the first drive shaft 26 so as to rotate together with the first drive shaft 26.

In the above structure, the first drive link 27 is intermittently rotated by the rotation of the first drive motor 21.

On the other hand, the three-position switch 40 is provided on one side of the upper bus (2) according to the operation of the upper bus operating unit 20, the state of the upper bus (2) is any one of the connection, disconnection, ground To be

The 3-position switch 40 includes a first driven link 41 rotatably provided in the gas insulated switchgear 1, and a first connector rotatably provided coaxially with the first driven link 41. 42).

The first connector 42 is selectively connected to any one of the connection terminal 2a and the ground terminal 2b provided on one side of the gas insulated switchgear 1 so as to be electrically connected to the upper bus 2. Or by being disconnected, i.e., by the first connecting terminal being in the connecting position or in the breaking position or the grounding position, the state of the upper bus becomes a connected state, a disconnected state or a grounded state.

At this time, the first operation link 30 is provided to transmit the operation force of the upper bus control unit 20 to the three-position switch 40. One end of the first operation link 30 is connected to the first drive link 27, and the other end is connected to the first connector 42, so that the rotational force of the first drive link 27 is the first connector. Is passed to 42.

Here, it is preferable to provide a first driven link 41 that rotates coaxially with the first connector 42, the other end of the first operation link 30 to the first driven link 41 do.

The lower bus operating unit 50 is provided inside the manipulator box 10 together with the upper bus operating unit 20.

The lower bus operating unit 50 is intermittently driven by the second drive motor 51, the second drive wheel 54 connected to the second drive motor 51, and the second drive wheel 54 to rotate. And a second driving link provided coaxially with the rotating second Geneva gear 55 and the second Geneva gear 55.

The second driving motor 51 is provided at one side of the manipulator 10 to generate rotational force when power is applied.

The second driving wheel 54 is connected to the second driving motor 51 through the power transmission means, similarly to the connection of the first driving motor 21 and the first driving wheel 24. In this example, the second sprocket 52 is provided coaxially with the second driving wheel 54, and the second sprocket 52 and the second driving motor 51 are connected by a chain 53. The rotational force of the second driving motor 51 is transmitted to the second driving wheel 54.

The second Geneva gear 55 is provided on the second drive shaft 56 provided with the manipulator 10 and is intermittently engaged with the second drive wheel 54. The second Geneva gear 55 is also used to intermittently operate the two-position switch 70 in the position of connection and disconnection.

The second drive link 57 is provided coaxially with the second Geneva gear 55. The second drive link 57 is formed to have a predetermined length and one end thereof is fixed to the second drive shaft 56 to which the second Geneva gear 55 is fastened, thereby having a structure rotatable with the second drive shaft 56. .

The two-position switch 70 is provided on one side of the lower bus 3 so that the state of the lower bus 3 may be either connected or disconnected according to the operation of the lower bus operating unit 50.

To this end, the two-position switch 70 is rotatably provided with the second driven link 71 and the second driven link 71 which are rotatably provided in the gas insulated switchgear 1. And 72.

The second connector 72 is electrically connected to the lower bus 3, and is connected to or spaced from the connection terminal 3a provided in the gas insulated switchgear 1 so that the second connector 72 is connected or disconnected. By the position, the state of the lower bus 3 is determined.

On the other hand, the lower bus operating unit 50 and the two-position switch 70 is connected via a second operation link (60). As in the connection of the upper bus operation unit 20 and the 3-position switch 40, both ends of the second operation link 60 are connected to the second drive link 57 and the second connector 72, respectively. The two-position switch 70 is operated, and preferably connected to the second driven link 71 provided coaxially with the second connector 72.

The controller 80 is electrically connected to drive the first driving motor 21 and the second driving motor 51. The controller 80 switches the upper bus 2 and the lower bus 3 to a specific state according to a signal input from a means for detecting an abnormality of a line provided separately.

For example, an accident current is generated in the track, so that the first drive motor 21 or the second drive motor 51 is rotated to block the upper bus 2 or the lower bus 3, and thus, the 3-position switch. The 40 or 2-position switch 70 is separated from the connecting terminals 2a and 3a so that the line is blocked.

The operation of the gas insulated switchgear of the present invention having the above configuration will be described.

In order to switch the state of the upper bus 2, the state of the upper bus 2 is adjusted by operating the 3-position switch 40 through the upper bus operating unit 20.

2 and 3, when the state of the upper bus 2 is operated in the disconnected state by connecting, the first driving wheel 24 is rotated in the direction of ① shown in FIG. 3. The first operation link 30 is advanced in the direction of ②. The pin 24a protruding from the surface of the first driving wheel 24 is the first Geneva gear 25 while the first driving wheel 24 is rotated in the direction of ① by the rotation of the first driving motor 21. When inserted into the groove formed in the groove, the first Geneva gear 25 is rotated by the rotation of the first driving wheel 24, the rotational force through the first drive shaft 26 when the first Geneva gear 25 is rotated The first operation link 30 is advanced in the direction of ② via the first drive link 27.

Here, the structure of the first Geneva gear 25 is not continuously rotated when the first drive wheel 24 is rotated, but the pin 24a of the first drive wheel 24 is formed of the first Geneva gear 25. As the rotational force is input through the first driving wheel 24 while being inserted into the groove, the first Geneva gear 25 may rotate. That is, when the first driving wheel 24 rotates in the direction of ①, the first driving link 30 rotates only when the pin 24a is inserted into the groove formed in the first Geneva gear 25. Can be advanced in the direction of.

When the first operation link 30 is advanced in the direction of ②, the first operation link 30 rotates the first driven link 41 counterclockwise, and is coaxially connected with the first driven link 41. Since the 1st connector 42 also rotates counterclockwise, the said 1st connector 42 is connected to the connection terminal 2a, and a circuit is connected.

In this state, power transmission and distribution are performed through the upper bus 2.

In order to cut off the upper bus 2 for the purpose of generating or inspecting an accident current, the first connector 42 is rotated clockwise by connecting the first drive motor 21 in the opposite direction. The terminal 2a is separated from the upper bus 2 to be blocked. That is, when the first drive wheel 24 is rotated in the direction of ③ by rotating the first drive motor 21, the first operation link 30 is advanced in the direction of ④, so that it is connected to the connection terminal 2a. The upper bus 2 is cut off by rotating the first connector 42 clockwise.

When the upper bus is grounded, the first drive motor 21 is further rotated so that the first connector 42 continues to rotate clockwise, that is, the first drive wheel 24 rotates in the direction of ③. By rotating, the first connector 42 is rotated clockwise to be connected to the ground terminal 2b.

In this way, by rotating the first drive motor 21 through the control unit 80, the first connector 42 is connected, disconnected, and grounded.

On the other hand, since the operation of the lower bus operating unit 50 for switching the state of the lower bus 3 also corresponds to the upper bus operating unit 20, a detailed description thereof will be omitted.

According to the manipulator for the gas insulated switchgear according to the present invention as described above, by providing an integrated manipulator for the gas insulated switchgear for opening and closing the upper bus and the lower bus of the gas insulated switchgear, Can be.

In addition, since a separate manipulator does not have to be used, a space occupied by the manipulator in the gas insulated switchgear can be reduced.

In addition, the manufacturing cost can be reduced compared to the case of manufacturing a separate manipulator.

Claims (7)

A three-position switch having a manipulator box, an upper bus, a first connector rotatably provided on one side of the upper bus to be selectively connected to a connection terminal or a ground terminal electrically connected to the upper bus, and a lower bus And a two-position switch having a second connector rotatably provided on one side of the lower bus so as to be selectively connected to a connection terminal electrically connected to the lower bus. Inside the manipulator box, An upper bus operation unit which operates the first operation link connected to the first connector to operate the first connector to a connection position, a disconnection position, or a ground position; And a lower bus operating part configured to operate the second operation link connected to the second connection part to operate the second connection part at a connection position or a cutoff position. The method of claim 1, The upper bus operation unit, The first driving motor, A first driving wheel provided to be rotated by the first driving motor, A first Geneva gear provided intermittently with the first driving wheel; A first driving link provided coaxially with the first Geneva gear, One end of the first operation link is connected to the first drive link, the other end of the manipulator for the gas insulated switchgear, characterized in that the link is connected to the first connector. The method of claim 2, A first driven link is provided coaxially with the first connector on one side of the gas insulated switchgear, And the other end of the first operation link is linked to the first driven link. The method of claim 2, The control unit is electrically connected to the first driving motor, the manipulator for the gas insulated switchgear, characterized in that the first drive motor is rotated by the drive signal of the control unit. The method of claim 1, The lower bus operation unit, A second drive motor, A second driving wheel provided to be rotated by the second driving motor; A second Geneva gear provided intermittently with the second driving wheel; A second driving link provided coaxially with the second Geneva gear, And one end of the second operation link is connected to the second driving link, and the other end of the second operation link is connected to the second connector. The method of claim 5, A second driven link is provided coaxially with the second connector on one side of the gas insulated switchgear, And a second end of the second operation link is connected to the second driven link. The method of claim 5, The control unit is electrically connected to the second drive motor, the manipulator for the gas insulated switchgear, characterized in that the second drive motor is rotated by the drive signal of the control unit.

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