KR102017210B1 - Interlocking operation mechanism for disconnector with earth - Google Patents

Abstract

The present invention relates to a grounding type disconnecting device interlocking operation device that can improve the insulation performance using double insulation and increase the safety of the grounding circuit user by using an opening and closing device in which a main circuit (vacuum valve) is used. And a main circuit operation unit installed at one inner side of the body case and configured to input and open a main circuit (vacuum valve), and a ground circuit operation unit installed at the other side of the body case and configured to input and open a ground circuit; A disconnector power transmission unit connected to the furnace control unit and the ground circuit control unit to vertically move the disconnector circuit, and an operation shaft connected to the main circuit control unit and the ground circuit control unit and rotated according to the operation of the main circuit control unit and the ground circuit control unit. A power transmission unit, a manipulator power transmission unit rotated in connection with the operation shaft power transmission unit, and the operation A driving unit connected to the power transmission unit to operate by the power received from the main circuit operation unit or the ground circuit operation unit, and a vacuum valve drive shaft connected to the drive unit to operate the main circuit (vacuum valve) by the power transmitted from the drive unit It includes.

Description

Grounding Type Disconnector Interlock Manipulator {INTERLOCKING OPERATION MECHANISM FOR DISCONNECTOR WITH EARTH}

The present invention relates to a grounding type disconnecting device interlocking operation device, and more particularly, using an open / close device using a vacuum valve to improve the insulation performance using double insulation and to increase the safety of the grounding circuit user. It relates to a manipulator.

Generally, electricity generated at a voltage of about 20,000 V in various power plants (heat, hydro, nuclear power, etc.) is boosted to ultra high voltage suitable for power transmission, and is transmitted to primary substations through ultra high voltage lines.

The primary substation drops the supplied power and supplies it to the secondary substation or to each consumer in general. That is, the power supplied from the primary substation is supplied to the power receiving facilities of each customer through a distribution system composed of overhead distribution lines and underground distribution lines, and is supplied to low voltage consumers through special high pressure consumers, high pressure consumers, and various outdoor transformers.

At this time, the load breaker (LBS) is widely used to supply and stop power for a wide range of customers by being installed at a suitable position on the power distribution system such as the line division, branch, and transformer primary side of the high-voltage consumer power distribution panel (hydraulic equipment). It is used.

These load breakers are used to minimize the blackout zone by blocking certain sections according to the utility's plan.

Such a load switch controls the power supply by driving the connection to three positions of opening, closing, and grounding, and a conventional load switch has an insulating gas inside the gas tank to insulate the arc generated in the case of opening or closing a high voltage line. Is injected. SF6 is mainly used as the insulation gas, and SF6 is nonflammable, so there is little danger of fire, it can be used anywhere indoors and outdoors, and it is harmless to the human body. However, when a gas such as SF6 leaks into the atmosphere outside the gas tank, it causes a much higher global greenhouse effect than carbon dioxide. Therefore, there is a problem that adversely affects the global environment. Accordingly, SF6 gas is regulated worldwide. It is a trend.

In recent years, as safety and eco-friendliness of electric power equipment is important, in the gas-insulated load switchgear in which the global electric power equipment market is insulated using SF6 gas, recently, polymers insulated using epoxy and blocked using vacuum valves Epoxy is rapidly changing to isolated load breakers.

Conventional polymer (epoxy) insulated load switch requires expensive internal epoxy and requires complicated internal structure and advanced molding technology, which requires excessive molding cost, and basic insulation does not use SF6 gas using epoxy. However, a vacuum valve is always used to shut off.

The vacuum valve has excellent breaking performance and excellent insulation performance in a short distance. However, since the opening distance (insulation distance) inside the vacuum valve is too close, many changes in insulation performance occur depending on the use conditions.

The vacuum valve is made of a vacuum to maintain insulation at a short distance (150kV: about 12mm). In order to allow current to flow, it must be pushed with a certain amount of load to reach the electrode and maintain electrical strength. .

Therefore, even though the switchgear is open, many accidents have occurred recently due to abnormal voltage flow or insulation deterioration during the maintenance work of the rear stage, and alternative measures are prepared.

In addition, since the insulation covering the blocking part is made of only epoxy, when the ground fault occurs due to a failure of the blocking part, there is a problem in that the epoxy housing is exploded and human injury occurs.

Therefore, in the switchgear using the vacuum valve as a blocking portion, the need for additional insulation devices other than the vacuum valve is increasing.

In addition, while the insulation performance of the disconnector type switchgear in the switchgear that is driven only the main circuit without the ground portion is confirmed, there is a lot of user requests to attach the disconnector to the grounded switchgear. Therefore, even in the switchgear with a ground, it is practically necessary to develop an operation mechanism in which the disconnecting device is interlocked during the operation of the main circuit and the ground circuit of the compact structure.

Republic of Korea Patent Publication No. 10-2010-0059372

Therefore, the present invention has been made to solve the above problems, the object of the primary primary insulation is to isolate the main valve and the ground circuit with the main valve and the vacuum valve is open and the secondary insulation is interlocked disconnector In addition, the present invention provides a grounding-type disconnector interlock actuator that can further insulate the insulation performance.

Ground attachment type disconnector interlocking manipulator according to an embodiment of the present invention for achieving the above object is installed on the inner side of the body case, and the main body (vacuum valve) for the main circuit (vacuum valve) input and opening the main circuit An operation unit, a ground circuit operation unit installed at the other inner side of the body case and connected to the main circuit operation unit and the ground circuit operation unit for inputting and opening the ground circuit, and a disconnector power transmission unit for vertically moving the disconnector circuit; An operation shaft power transmission unit connected to the main circuit operation unit and a ground circuit operation unit and rotated according to an operation of the main circuit operation unit and the ground circuit operation unit, a manipulator power transmission unit connected to the operation shaft power transmission unit and rotated; Drive unit connected to the power transmission unit and operated by the power transmitted from the main circuit control unit or the ground circuit control unit And connected to the drive section may include a vacuum valve to the drive shaft by receiving a power transmission from the drive unit to be operated (vacuum valve) to the main circuit.

The main circuit operation unit is installed across the inside of the body case and is rotated for the main circuit (vacuum valve) input and opening operation, and the main circuit operating shaft is attached to the main circuit operating shaft and connected to the disconnector power transmission section It may include a main circuit shaft lever for transmitting power to the disconnector power transmission while rotating in accordance with the rotation of the operating shaft.

The ground circuit operating unit is installed across the inside of the body case and is rotated for the ground circuit input and opening operation, and the ground circuit operating shaft attached to the ground circuit operating shaft and connected to the disconnector power transmission unit to rotate the ground circuit operating shaft. The rotary circuit may include a ground circuit shaft lever for transmitting power to the disconnecting power transmission unit.

The disconnector power transmission unit is connected to the main circuit operation unit and is rotated in a direction opposite to the rotation direction of the main circuit operation unit, and a ground circuit connected to the ground circuit operation unit and rotated in a direction opposite to the rotation direction of the ground circuit operation unit. It may include a disconnect gear and a disconnect gear vertically connected between the main circuit disconnect gear and the ground circuit disconnect gear to be moved by the power transmitted from the main circuit disconnect gear and the ground circuit disconnect gear to vertically move the disconnect circuit. have.

The operation shaft power transmission unit is attached to the main circuit operation shaft of the main circuit operation unit and rotated according to the rotation of the main circuit operation shaft, and the ground circuit operation shaft is attached to the ground circuit operation shaft of the ground circuit operation unit. It may include a ground circuit operation shaft gear rotated according to, and a manipulator connection shaft gear connected to the main circuit operation shaft gear and the ground circuit fixing shaft gear to transfer power to the manipulator power transmission unit.

The main circuit operating shaft gear has no gear teeth (gear type) in the portion engaged with the manipulator connecting shaft gear so that the manipulator connecting shaft gear can be idle for a predetermined time without rotation of the manipulator connecting shaft gear when the main circuit is open and the ground circuit is inserted. The main circuit idle surface can be formed.

The ground circuit operation shaft gear is a gear tooth (gear type) that engages with the manipulator coupling shaft gear so that the manipulator connecting shaft gear can be idle for a predetermined time without rotation of the manipulator connecting shaft gear when the main circuit is open and the main circuit (vacuum valve) is inserted. There may be a ground circuit idling surface without some).

The manipulator power transmission unit is connected to the manipulator connecting shaft gear of the manipulator shaft power transmission unit and is rotated according to the rotation of the manipulator connecting shaft gear, and the power connected to the manipulator connecting shaft and received from the main circuit operating unit or the ground circuit operating unit. It may include a bevel gear for transmitting to the drive unit.

As described above, according to the grounding type disconnecting device interlocking actuator according to the present invention, the basic insulation is satisfied in the main circuit (vacuum valve), but additional insulation is secured in the disconnecting device to ensure safe insulation. It can raise up to 220㎸ or more, and it has the effect of maximizing safety even when the switch is opened and power failure or maintenance work is performed.

In addition, the present invention has the effect that the operation is convenient by maximizing convenience for the user by interlocking with the disconnector having a parallax during operation of the main circuit operation unit and the ground circuit operation unit without the need for a separate disconnector operation.

In addition, the present invention is used in conjunction with the drive unit does not require a separate ground drive operation unit has the effect of reducing the manufacturing cost and manufacturing time by the simplification of the structure.

In addition, the present invention is a method in which the main circuit (vacuum valve) is introduced into the main circuit (vacuum valve) and then the main circuit (vacuum valve) when the main circuit (vacuum valve) is inputted to the disconnector busbar part first, and then the main circuit (vacuum valve) is introduced. The valve is opened first and then the disconnecting device is opened. In the case of closing or opening, no electric shock is applied to the contacts of the disconnecting device. It is the structure to be applied, and all the electric shocks at the time of grounding and shut-off during the grounding operation are made by the main circuit (vacuum valve), which has the effect of excellent breaking performance and simple operation.

1 is a front view showing the entire internal structure of the grounding type disconnector interlock operation device according to the present invention.
Figure 2 is a front view showing the internal structure of the grounding-type disconnector interlock operation according to the present invention.
Figure 3 is a plan view showing the internal structure of the grounding type disconnector interlock operation according to the present invention.
4 is a side view illustrating the grounding type disconnector interlocking manipulator according to FIG. 3.
FIG. 5 is a side view illustrating a manipulator power transmission unit according to the internal structure of the 'A-A' part of FIG. 3.
6 is a side view illustrating a control shaft power transmission unit in the open state according to the internal structure of the 'B-B' portion of FIG.
FIG. 7 is a side view illustrating an operating state of the operating shaft power transmission unit at the time of inputting the main circuit and the ground circuit according to FIG. 6.
8 is a side view illustrating a main circuit control unit, a ground circuit control unit, and a disconnector power transmission unit in an open state according to the internal structure of the 'C-C' unit of FIG. 3.
FIG. 9 is a side view illustrating an operating state of the main circuit operation unit, the ground circuit operation unit, and the disconnector power transmission unit in the main circuit input state and the ground circuit input state according to FIG. 8.

As the invention allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

In the drawings, embodiments of the invention are not limited to the specific forms shown, and are exaggerated for clarity. Although specific terms have been used in the present specification, they are used for the purpose of describing the present invention and are not used to limit the scope of the present invention as defined in the meaning or the claims.

The expression 'and / or' is used herein to mean at least one of the components listed before and after. In addition, the expression 'connected / combined' is used in the sense of including directly connected to or indirectly connected to other components. In this specification, the singular forms also include the plural unless specifically stated otherwise in the phrases. Also, as used herein, components, steps, operations, and elements referred to as 'comprising' or 'comprising' refer to the presence or addition of one or more other components, steps, operations, and elements.

In the description of the embodiments, each layer, region, pattern, or structure may be “on” or “under” the substrate, each side, the region, the pad, or the patterns. "Formed in" includes both those formed directly or through another layer. Criteria for the top / bottom or bottom / bottom of each layer will be described with reference to the drawings.

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

1 is a front view showing the entire internal structure of the grounding-type disconnector interlock manipulator according to the present invention, Figure 2 is a front view showing the internal structure of the grounding-type disconnector interlock manipulator according to the present invention, Figure 3 is the present invention 4 is a plan view illustrating an internal structure of the grounding type disconnector interlocking manipulator according to FIG. 3, and FIG. 4 is a side view of the grounding type disconnecting unit interlocking manipulator according to FIG. 3, and FIG. 5 is an internal structure of the 'A-A' part of FIG. 3. FIG. 6 is a side view illustrating a manipulator power transmission unit according to FIG. 6, and FIG. 6 is a side view showing a control shaft power transmission unit in an open state according to the internal structure of the 'B-B' part of FIG. 3, and FIG. 7 is a main circuit according to FIG. 6. Fig. 8 is a side view showing the operating state of the operating shaft power transmission unit at the time of inputting and grounding circuit, and Fig. 8 is the main circuit control unit and the ground circuit control unit and disconnector power in the open state according to the internal structure of the 'C-C' part of Fig. 3. Delivery FIG. 9 is a side view illustrating an operation state of the main circuit operation unit, the ground circuit operation unit, and the disconnector power transmission unit in the main circuit input state and the ground circuit input state according to FIG. 8.

As shown in Figures 1 to 9, the grounding type disconnecting device interlocking manipulator according to the present invention, the body case 100, the main circuit operation unit 200, the ground circuit operation unit 300, the disconnector power transmission unit ( 400, the operation shaft power transmission unit 500, the manipulator power transmission unit 600, the driving unit 700, and the vibration valve driving shaft 800.

As shown in FIG. 1, the body case 100 serves as an external part of the manipulator to support internal components, and has a disconnecting device insulating rod 11, a disconnecting device grounding part 12, and a disconnecting circuit 13 at a lower portion thereof. And a main circuit including a main circuit insulating rod 21 and a main circuit (vacuum valve) 22 on the side of the circuit breaker circuit part 10 and the circuit breaker circuit part 10 having the circuit breaker part 14. The blocking unit 20 is to be installed integrally.

As shown in Figure 3 and 8, the main circuit operation unit 200 is installed on one side of the inner body case 100, is rotated for the main circuit (vacuum valve) 22 input and opening operation is disconnected power transmission unit. Power is transmitted to (400).

In addition, the main circuit operation unit 200 includes a main circuit operation shaft 210 and a main circuit shaft lever 220.

The main circuit operation shaft 210 is installed across the inside of the body case 100, and rotates for the main circuit (vacuum valve) 22 input and open operation.

The main circuit shaft lever 220 is attached to the main circuit operation shaft 210 and is connected to the disconnecting power transmission unit 400 is rotated for the main circuit (vacuum valve) 22 input and opening the main shaft operation shaft ( Rotated according to the rotation of 21 to transmit power to the disconnector power transmission unit 400.

That is, the main circuit shaft lever 220 is attached to the main circuit operation shaft 210 and the main circuit disconnector gear 410 of the disconnector power transmission unit 400 described below is connected to the main circuit operation shaft 210. While rotating with the rotation of the main circuit disconnector gear 410 to adjust the input state of the main circuit (vacuum valve) (22).

As shown in Figure 3 and 8, the ground circuit operation unit 300 is installed on the other side of the body case 100, rotated for the ground circuit input and opening operation to transfer power to the disconnector power transmission unit 400. Done.

In addition, the ground circuit operating unit 300 includes a ground circuit operating shaft 310 and a ground circuit shaft lever 320.

The ground circuit operating shaft 310 is installed across the inside of the body case 100, and rotated for the ground circuit input and opening operation.

The ground circuit shaft lever 320 is attached to the ground circuit operating shaft 310 and rotated in accordance with the rotation of the ground circuit operating shaft 310 which is connected to the disconnector power transmission unit 400 and rotated to insert and open the ground circuit. The power is transmitted to the disconnector power transmission unit 400.

That is, the ground circuit shaft lever 320 is attached to the ground circuit operation shaft 310 and the ground circuit disconnector gear 420 of the disconnector power transmission unit 400 described below is connected to the ground circuit operation shaft 310. By rotating with the rotation of the ground circuit disconnector gear 420 to adjust the input state of the ground circuit.

8 to 9, the disconnector power transmission unit 400 is connected between the main circuit operation unit 200 and the ground circuit operation unit 300 of the main circuit operation unit 200 or the ground circuit operation unit 300 While moving according to the operation is to vertically move the disconnect circuit (13).

In addition, the disconnector power transmission unit 400 includes a main circuit disconnector gear 410, a ground circuit disconnector gear 420, and a disconnector vertical gear 430.

The main circuit disconnector gear 410 is connected to the main circuit shaft lever 220 of the main circuit operation unit 200 and rotates in a direction opposite to the main circuit shaft lever 220 that is rotated by the rotation of the main circuit operation shaft 210. By moving the disconnect gear vertical gear 430 to adjust the input state of the main circuit (vacuum valve) (22).

That is, as shown in (a) of FIG. 9, when the main circuit operating shaft 210 is rotated in the clockwise direction, the main circuit shaft lever 220 is also rotated in the clockwise direction and connected to the main circuit shaft lever 220. As the main circuit disconnector gear 410 is rotated in a counterclockwise direction, the main circuit (vacuum valve) 22 is introduced by moving the disconnector vertical gear 430.

The ground circuit disconnector gear 420 is connected to the ground circuit shaft lever 320 of the ground circuit operating unit 300 and rotates in a direction opposite to the ground circuit shaft lever 320 that is rotated by the rotation of the ground circuit operating shaft 310. By moving the disconnect gear vertical gear 430 to adjust the ground circuit input state.

That is, as shown in (b) of FIG. 9, when the ground circuit operating shaft 310 is rotated in the clockwise direction, the ground circuit shaft lever 320 is also rotated in the clockwise direction and connected to the ground circuit shaft lever 320. As the ground circuit disconnector gear 420 is rotated in a counterclockwise direction, the ground circuit is input by moving the disconnector vertical gear 430.

The disconnector vertical gear 430 is connected between the main circuit disconnector gear 410 and the ground circuit disconnector gear 420, but is connected to the main circuit disconnector gear 410 and the ground circuit disconnector gear 420, and the main circuit disconnector gear ( 410 and the ground circuit disconnector gear 420 is moved in accordance with the transmitted power to move the disconnector circuit 13 to move vertically.

3 to 4 and 6, the operation shaft power transmission unit 500 is connected to the main circuit operation unit 200 and the ground circuit operation unit 300, the main circuit operation unit 200 and the ground circuit operation unit It is operated according to the operation of the 300 to transmit power to the manipulator power transmission unit 600.

The manipulation shaft power transmission unit 500 includes a main circuit manipulation shaft gear 510, a ground circuit manipulation shaft gear 520, and a manipulator connection shaft gear 530.

The main circuit operation shaft gear 510 is attached to the main circuit operation shaft 210 of the main circuit operation unit 200 to rotate according to the rotation of the main circuit operation shaft 210 to rotate the manipulator connecting shaft gear 530. do.

That is, the main circuit operating shaft gear 510 is connected to the main circuit operating shaft 210 and rotated by the rotation of the main circuit operating shaft 210 to rotate the manipulator connecting shaft gear 530, the manipulator power described below. Power is transmitted to the manipulator connecting shaft 610 of the transmission unit 600.

In addition, the main circuit operation shaft gear 510 is a manipulator connecting shaft so that the manipulator connecting shaft gear 530 can be idled for a predetermined time without rotating the main circuit (vacuum valve) 22 and when the ground circuit is inserted. The main circuit idle surface 511 without part of the gear teeth (gear type) of the portion engaged with the gear 530 is formed.

That is, when the main circuit idle surface 511 is located on the manipulator coupling shaft gear 530 when the main circuit operating shaft gear 510 is rotated, the main circuit operating shaft gear 510 and the manipulator coupling shaft gear 530 are rotated. ) Is not engaged so that the manipulator coupling shaft gear 530 does not rotate.

The ground circuit operation shaft gear 520 is attached to the ground circuit operation shaft 310 of the ground circuit operation unit 300 is rotated in accordance with the rotation of the ground circuit operation shaft 310 to rotate the manipulator connecting shaft gear 530. do.

That is, the ground circuit operating shaft gear 520 is connected to the ground circuit operating shaft 31 and rotated by the rotation of the ground circuit operating shaft 310 to rotate the manipulator connecting shaft gear 530 to operate the actuator power described below. Power is transmitted to the manipulator connecting shaft 610 of the transmission unit 600.

In addition, when the main circuit (vacuum valve) 22 is opened while the ground circuit operation shaft gear 520 is opened, the manipulator connecting shaft gear 530 does not rotate and idles for a predetermined time. The ground circuit idling surface 521 is partially formed so that the gear teeth (gear type) of the portion engaged with the manipulator link shaft gear 530 is partially formed.

That is, when the ground circuit idling surface 521 is located in the manipulator coupling shaft gear 530 when the ground circuit manipulating gear 520 is rotated, the ground circuit manipulation shaft gear 520 and the manipulator coupling shaft gear 530 are rotated. ) Is not engaged so that the manipulator coupling shaft gear 530 does not rotate.

The manipulator connecting shaft gear 530 is connected to the main circuit operating shaft gear 510 and the ground circuit operating shaft gear 520, and is connected to the manipulator power transmission unit 600 to connect the main circuit operating shaft gear 510 or the ground circuit. As the rotation of the operation shaft gear 520 is rotated to transmit power to the manipulator power transmission unit 600.

3 and 5, the manipulator power transmission unit 600 is connected to the manipulator coupling shaft gear 530 of the operation shaft power transmission unit 500 is rotated in accordance with the rotation of the manipulator coupling shaft gear 530. Power is transmitted to the driving unit 700.

The manipulator power transmission unit 600 includes a manipulator connecting shaft 610 and a bevel gear 620.

The manipulator connecting shaft 610 is connected to the manipulator connecting shaft gear 530 and rotates according to the rotation of the manipulator connecting shaft gear 530.

The bevel gear 620 is connected to the manipulator connecting shaft 610 and connected to the driving unit 700, the manipulator connecting shaft 610 is rotated by the power transmitted from the main circuit operation unit 200 or the ground circuit operation unit 300 Rotate together with the drive unit 700 to transmit power.

The driving unit 700 is connected to the bevel gear 620 of the manipulator power transmission unit 600 to rotate the bevel gear 620 that is rotated by the power transmitted from the main circuit operation unit 200 or the ground circuit operation unit 300. It is operated by receiving power.

The vacuum valve driving shaft 800 is connected to the driving unit 700 and connected to the main circuit (vacuum valve) 22 to receive power according to the operation of the driving unit 700 to operate the main circuit (vacuum valve) 22. You can do it.

Looking at the operation principle according to the grounding-type disconnector interlock operation device of the present invention having the above structure as follows.

First, referring to the driving principle for the main circuit operation, the input operation characteristic of the present invention is that when the main circuit (vacuum valve) 22 is input, the circuit breaker circuit 13 is first introduced into the circuit breaker 14 and the main circuit (vacuum valve). 22 will be added later.

When the main circuit operation shaft 210 is rotated in the clockwise direction during the closing operation, the main circuit shaft lever 220 rotates at the same time, and the main circuit disconnector gear 410 is counterclockwise by the rotation of the main circuit shaft lever 220. It rotates in the direction, the disconnecting device vertical gear 430 is moved vertically downwards, so that the disconnecting circuit 13 is inserted into the disconnecting bus bar 14.

At this time, the main circuit operation shaft gear 510 which is connected to the main circuit operation shaft 210 also rotates, but a main circuit idling surface 511 is formed on the main circuit operation shaft gear 510 so that the manipulator connecting shaft While not engaged with the gear 530, while idling for a predetermined time, the manipulator coupling shaft gear 530 is rotated.

Due to such operation characteristics, the disconnecting circuit 13 is introduced into the disconnecting busbar 14 and then the main circuit (vacuum valve) 22 is introduced later.

In addition, the main circuit shaft lever 220 rotates in a clockwise direction at the position of the input state, and moves away from the main circuit disconnector gear 410 to be rotated further by a predetermined angle. (Figs. 7 (a) and 9). (A) of)

The opening operation characteristic of the present invention is that when the main circuit (vacuum valve) 22 is opened, the main circuit (vacuum valve) 22 is opened first and the disconnector is opened later.

When the main circuit operating shaft 210 rotates counterclockwise during the opening operation, the main circuit shaft lever 220 rotates simultaneously and the main circuit operating shaft gear 510 rotates to rotate the manipulator connecting shaft gear 530. It will rotate at the same time.

At this time, the main circuit shaft lever 220 is idling by a predetermined angle while rotating in the counterclockwise direction, but the disconnecting circuit 13 does not move and the driving unit 700 operates first to operate the main circuit (vacuum valve) 22. ) Is opened.

Then, the main circuit operation shaft 210 is continuously rotated to rotate the main circuit disconnector gear 410 while the main circuit shaft lever 220 is rotated to the open position, the disconnector vertical gear 430 is in the original position isolator The circuit 13 is opened (see FIGS. 6 and 8).

Second, referring to the driving principle for the operation of the grounding circuit, the input operation characteristics of the present invention is that when the grounding circuit is input, the circuit breaker circuit 13 is first introduced into the circuit breaker ground 12 and the main circuit (vacuum valve) 22 is later input. Will be.

When the ground circuit operation shaft 310 is rotated in the clockwise direction during the closing operation, the ground circuit shaft lever 320 rotates at the same time, and the ground circuit disconnector gear 420 is counterclockwise by the rotation of the ground circuit shaft lever 320. It is rotated in the direction, the disconnecting device vertical gear 430 is moved vertically upward, and the disconnecting circuit 13 is introduced into the disconnecting device ground portion 12.

At this time, the ground circuit operating shaft gear 520 also connected to the ground circuit operating shaft 310 also rotates, but a ground circuit idle surface 521 is formed on the ground circuit operating shaft gear 520 so that the manipulator connecting shaft While not engaged with the gear 530, while idling for a predetermined time, the manipulator coupling shaft gear 530 is rotated.

Due to such operation characteristics, the disconnecting circuit 13 is introduced into the disconnecting unit ground 12, and then the main circuit (vacuum valve) 22 is introduced later.

In addition, the ground circuit shaft lever 320 rotates in a clockwise direction at the position of the input state, and moves away from the ground circuit disconnector gear 420 to be rotated further by a predetermined angle. (Fig. 7 (b) and Fig. 9). (B) of)

The opening operation characteristic of the present invention is that when the ground circuit is opened, the main circuit (vacuum valve) 22 is opened first and the disconnector is opened later.

When the ground circuit operating shaft 310 is rotated counterclockwise during the opening operation, the ground circuit shaft lever 320 rotates simultaneously and the ground circuit operating shaft gear 520 rotates to rotate the manipulator connecting shaft gear 530. It will rotate at the same time.

At this time, the ground circuit shaft lever 320 is idling by a predetermined angle while rotating in the counterclockwise direction, but the disconnecting circuit 13 does not move, and the driving unit 700 operates first to operate the main circuit (vacuum valve) 22. ) Is opened.

In addition, the ground circuit operation shaft 310 is continuously rotated, while the ground circuit shaft lever 320 is rotated to the open position, the ground circuit disconnector gear 420 is rotated so that the disconnector vertical gear 430 is returned to its original position. The circuit 13 is opened (see FIGS. 6 and 8).

As described above, the present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by those skilled in the art without departing from the gist of the present invention claimed in the claims. Of course, such changes are within the scope of the claims.

10: disconnector circuit portion 11: disconnector insulated rod
12: disconnector ground portion 13: disconnector circuit
14: disconnecting busbar 20: main circuit breaker
21: main circuit insulation rod 22: main circuit (vacuum valve)
100: body case 200: main circuit operation unit
210: main circuit control shaft 220: main circuit shaft lever
300: ground circuit operation unit 310: ground circuit operation shaft
320: ground circuit shaft lever 400: disconnector power transmission unit
410: main circuit disconnector gear 420: ground circuit disconnector gear
430: vertical disconnect gear 500: control shaft power transmission unit
510: main circuit operation shaft gear 511: main circuit idle surface
520: ground circuit operation shaft gear 521: ground circuit idling surface
530: manipulator coupling shaft gear 600: manipulator power transmission unit
610: manipulator shaft 620: bevel gear
700: driving unit 800: vacuum valve drive shaft

Claims (4)

A body case forming an appearance;
A main circuit operation unit installed at one side of the body case and configured to input and open a main circuit (vacuum valve);
A ground circuit operating unit installed on the other side of the body case and configured to input and open a ground circuit;
A disconnector power transmission unit connected to the main circuit operation unit and the ground circuit operation unit to vertically move the disconnector circuit;
An operation shaft power transmission unit connected to the main circuit operation unit and the ground circuit operation unit and rotated according to operations of the main circuit operation unit and the ground circuit operation unit;
A manipulator power transfer unit connected to the operation shaft power transfer unit and rotated;
A driving unit connected to the manipulator power transmission unit and operated by power received from a main circuit operation unit or a ground circuit operation unit; And
A vacuum valve driving shaft connected to the driving unit to operate a main circuit (vacuum valve) by the power received from the driving unit;
In the grounding-type disconnector interlock actuator comprising a,
The operation shaft power transmission unit,
A main circuit operating shaft gear attached to the main circuit operating shaft of the main circuit operating unit and rotating according to the rotation of the main circuit operating shaft;
A ground circuit operating shaft gear attached to the ground circuit operating shaft of the ground circuit operating unit and rotated according to the rotation of the ground circuit operating shaft; And
A manipulator connecting shaft gear connected to the main circuit operating shaft gear and the ground circuit fixing shaft gear to transmit power to the manipulator power transmission unit;
Including,
The main circuit operation shaft gear is a gear tooth (gear type) that engages with the manipulator connecting shaft gear so that the manipulator connecting shaft gear can be idle for a predetermined time without rotation of the manipulator connecting shaft gear when the main circuit (vacuum valve) is opened and the ground circuit is turned on. A main circuit idling surface without part of) is formed,
The ground circuit operation shaft gear is a gear tooth (gear type) that engages with the manipulator coupling shaft gear so that the manipulator connecting shaft gear can be idled for a predetermined time without rotation of the manipulator connecting shaft gear when the main circuit (vacuum valve) is opened and the main circuit is turned on. There is no ground circuit idling surface without)
The main circuit idle surface and the ground circuit idle surface,
Adjust the order of input of the main circuit (vacuum valve) and the ground circuit and the disconnector circuit,
The main circuit operation unit,
Further comprising a main circuit shaft lever for transmitting power to the disconnector power transmission unit,
The disconnector power transmission unit,
It is further connected to the main circuit shaft lever and further comprises a main circuit disconnector gear for adjusting the input state of the main circuit (vacuum valve),
The main circuit disconnector gear,
It includes a part of the long hole, the main circuit shaft lever is connected to the long hole,
Ground Attachable Disconnector delete delete The method of claim 1,
The manipulator power transmission unit,
A manipulator linking shaft connected to a manipulator linking shaft gear of the manipulating shaft power transmission unit and being rotated according to rotation of the manipulator linking shaft gear; And
A bevel gear connected to the manipulator connecting shaft to transmit the power transmitted from the main circuit operation unit or the ground circuit operation unit to the driving unit;
Ground attachment type disconnector interlock manipulator including a.

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