KR101203775B1 - Mechanical operating cell switch for circuit breaker - Google Patents

Abstract

PURPOSE: An external contact driving apparatus for a circuit breaker is provided to enable a user to easily check an open or closed loop operation of a circuit breaker body in a test position and a run position. CONSTITUTION: A main axis lever part(100) is installed in a circuit breaker body and includes a main axis(110), a main axis lever(120), and a driving pin(130). An output lever part(200) is formed in one side of a cradle(90) and includes a first output lever part(210), a second output lever part(220), and a connection link(230). The first output lever part is located in the test position. The second output lever part is located in a run position.

Description

External contact drive device for circuit breaker {MECHANICAL OPERATING CELL SWITCH FOR CIRCUIT BREAKER}

The present invention relates to an external contact driving device of a circuit breaker, and more particularly, to an external contact driving device of a circuit breaker capable of confirming an operation state of the circuit breaker main body in both a test position and a run position where the circuit breaker body is located.

In general, a circuit breaker is a device that protects lines and devices in a power system by blocking an accident current when an abnormal accident current such as an overload, a short circuit, or a ground fault occurs in a line, and for this purpose, is connected to a line of a power system to conduct current. It is a device to cut off the current by closing the movable contactor connected to the switchgear when the accident current is generated or to close the movable contactor for energizing the current.

On the other hand, although the output contact is basically configured inside the main body of the circuit breaker, there is a problem in that the number of contacts can not be limited because there is a limitation on the volume inside the main body.

In order to solve this problem, an external contact drive device of a circuit breaker is mounted outside the main body so that the number of output contacts can be used as necessary.

The external contact drive device of such a circuit breaker displays the state of the circuit breaker by opening and closing the circuit breaker, and the required output contact is used as an output contact of a switch for controlling various devices according to the open / closed state of the circuit breaker.

1 is a view illustrating an external contact driving device of a conventional circuit breaker, and shows a state in which a switch of a switch unit is not pressed in an open state of a main body (not shown).

Referring to Figure 1, the main body has a main shaft lever portion 100 that is rotated by the mechanism operation during opening and closing of the main circuit. The main shaft lever unit 100 includes a main shaft 110 and a main shaft lever 120 connected to the main shaft 110. In addition, a driving pin 130 is formed on the spindle lever 120.

Here, the main body is movable position to achieve a test (TEST) and a run position (RUN) in the cradle (90). Therefore, the position of the spindle lever 120 provided in the main body may vary according to the test or run position of the main body.

One, the conventional external contact drive device of the breaker is installed at a predetermined position of the cradle 90, and is implemented to interlock with the main shaft lever 120 of the main body to reach the test or run position.

The conventional external contact driving device is installed in the cradle 90, the link assembly unit 10 is interlocked with the spindle lever 120, and the switch unit connected to the link assembly unit 10 to operate the switch ( 20). The link assembly 10 has a groove 11 into which the driving pin 130 is fitted.

FIG. 2 shows that the main shaft lever 120 and the link assembly unit 10 interlock with each other in the open position of the main body in the open state.

As shown in FIG. 2, when the main body is located at the test position, the main shaft lever 120 installed on the main body is physically separated from the link assembly 10 by a predetermined distance, and the main shaft lever 120 is assembled to the link. It cannot be linked with the unit 10. Therefore, conventionally, when the main body reaches the test position, there is a problem in that the opening or closing state of the main body cannot be confirmed through the external contact driving device.

However, conventionally, as shown in FIGS. 1 and 2, only when the main body reaches the run position, the drive pin 130 of the spindle lever 120 may be connected to the link assembly 10.

Therefore, when the main shaft is rotated clockwise or counterclockwise while the main body is open or closed, the main shaft lever 120 connected to the main shaft 110 is rotated, and the rotational force is linked by the driving pin 130. Can be delivered to the assembly. Therefore, conventionally, when the main body reaches the run position, the open or closed state of the main body can be switched out by the external contact drive device.

In conclusion, in the related art, an operation state such as opening or closing of the breaker body can be confirmed only at the run position, and there is a problem that cannot be confirmed at both the test position and the run position.

The present invention has been made to solve the above problems, and an object of the present invention is to provide an external contact driving device of a circuit breaker that can confirm the operating state of the circuit breaker body in both the test position and the run position where the circuit breaker body is located. have.

In a preferred aspect, the present invention provides an external contact drive of the breaker.

The external contact drive device of the circuit breaker is installed in the circuit breaker main body is selectively linearly moved to the test position and the run position of the cradle, the main shaft lever portion is rotated in a predetermined direction in accordance with the opening or closing operation of the breaker body; And an output lever unit interlocked with the spindle lever to reach the test position or the run position of the cradle.

Here, the output lever unit, a pair of output levers installed in the cradle so as to rotate in the test position and the run position, and the driving pins provided in each of the pair of output levers, the main shaft lever portion A pair of engaging plates that form a movement path and are formed to engage the drive pins in the test position or the run position, and linking the pair of output levers so that the pair of output levers interlock with each other; It is desirable to have a link.

The main shaft lever unit is provided in the circuit breaker main body, the main shaft being rotated according to the operation of the opening and closing unit, the main shaft lever connected to the main shaft, and the drive protruding from the main shaft lever to be spaced apart from the main shaft by a predetermined distance. It is desirable to have a pin.

In addition, the pair of locking plate, the upper locking plate is located on the top of the drive pin, and the lower locking plate is located below the drive pin,

Both ends of the upper locking plate and the lower locking plate are disposed to be offset from each other to follow the rotation path of the spindle lever,

The driving path of the driving pin is preferably formed along the upper locking plate and the lower locking plate.

In addition, the upper locking plate or the lower locking plate may be movable in the output lever so that the width can be adjusted.

The present invention has the effect of confirming the operating state of the breaker body in both the test position and the run position where the breaker body is located.

1 is a view showing the operation of the external contact drive device when the test of the conventional circuit breaker and the open position in the run position.
2 is a view showing the operation of the external contact drive device when the test of the conventional circuit breaker and the closing in the run position.
3 is a view showing that the external contact drive device of the present invention is operated during the test of the breaker and the opening in the run position.
4 is a view showing that the external contact drive device of the present invention is operated when the breaker is tested and closed in the run position.
5 is a plan view illustrating a coupling relationship between a driving pin and an output lever unit according to the present invention.

Hereinafter, an external contact driving device of a circuit breaker of the present invention will be described with reference to the accompanying drawings.

The cradle is provided with a test position and a run position that can cut or apply power to the breaker body.

The breaker body can be moved linearly between the test position and the run position.

3 and 4, the external contact driving device of the present invention includes a main shaft lever unit 100 and an output lever unit 200.

The spindle lever unit 100 is installed in the breaker body. The spindle lever unit 100 is installed in the breaker body that is selectively linearly moved to the test position and the run position of the cradle 90, and is open or closed of the opening and closing portion (not shown) of the breaker body. It may be rotated in a predetermined direction according to the operation.

The breaker main body is provided with a main shaft 110 that rotates depending on whether the current is open or closed. At the end of the main shaft 110, the main shaft lever 120 is interlocked with the rotation of the main shaft 110 is installed. An end of the main shaft 110 is connected to one end of the main shaft lever 120, the main shaft lever 120 is preferably made of a member forming a predetermined length from the connecting portion connected to the end of the main shaft (110).

In addition, a driving pin 130 is protruded from the spindle lever 120. The position of the driving pin 130 is preferably formed to be spaced apart from the connecting portion to which the main shaft 110 is connected.

Therefore, when the breaker body is linearly moved between the test or run positions in the cradle 90, the driving pin 130 installed on the spindle lever 120 may also be moved along the linear movement path.

Meanwhile, the output lever part 200 is provided at one side of the cradle 90.

The output lever part 200 includes a first output lever part 210 and a second output lever part 220.

The first output lever portion 210 is disposed in the test position, and the second output lever portion 220 is disposed in the run position.

Accordingly, the output lever unit 200 includes first and second output levers 211 and 221 and the first and second output levers 211 and 221 which are installed in the cradle 90 so as to rotate in the test position and the run position, respectively. Installed in the first and second engaging plates formed to form a moving path of the driving pin 130 formed in the spindle lever 120 and the driving pin 130 in the test position or the run position. 212 and 222 and the first and second output levers 211 and 221 are linked to each other so as to link the first and second output levers 211 and 221.

In detail, the pair of output levers may include a first output lever 211 capable of receiving rotational force from the driving pin 130 in a test position and a rotational force from the driving pin 130 in a run position. The second output lever 221 is configured. Here, the first and second output levers 211 and 221 are formed in the same shape, and are arranged side by side in the test and run position with each other.

In addition, the connection link 230 is connected to the lower end of each of the first and second output levers 211 and 221 so that the first and second output levers 211 and 221 rotate.

Each of the first and second locking plates 212 and 222 may have a predetermined width up and down, and the width may be substantially the same as or larger than a diameter of the driving pin 130.

Therefore, the driving pin 130 formed on the spindle lever 120 may slide along the first and second locking plates 212 and 222 formed on the first and second output levers 211 and 221.

The first and second locking plates 212 and 222 may include upper locking plates 212a and 222a positioned above the driving pins 130 and lower locking plates 212b and 222b positioned below the driving pins 130. It is composed of Therefore, the width between the upper locking plates 212a and 222a and the lower locking plates 212b and 222b is an area for guiding the slide of the driving pin 130.

In addition, both ends of the upper locking plates 212a and 222a and the lower locking plates 212b and 222b may be disposed to be offset from each other so as to follow the rotation path of the spindle lever 120.

In addition, the upper locking plate (212a, 222a) or the lower locking plate (212b, 222b) may be installed to move from the first and second output lever (211,221) to adjust the width. Although not shown in the drawings, the upper locking plates 212a and 222a or the lower locking plates 212b and 222b may be formed in a plurality of fitting grooves that may be formed in the first output lever 211 or the second output lever 221. It can be fitted and coupled, and thus, by varying the position of the fitting, it is possible to arbitrarily adjust the width between the upper locking plate (212a, 222a) and the lower locking plate (212b, 222b).

Next, the operation of the external contact drive device of the circuit breaker having the above configuration will be described.

FIG. 3 shows that the breaker body is moved from the test position to the run position and is opened by the opening and closing part.

The breaker body can be moved straight from the test position to the run position. At this time, the opening and closing portion of the circuit breaker main body has opened.

In detail, the drive pin 130 of the main shaft lever part 100 which maintains the open state in a test position makes the state which fits between the 1st locking plate 212 of the 1st output lever 211. As shown in FIG. .

In such a state, when the opening and closing part in a closed state as shown in FIG. 4, the spindle lever 120 may be rotated downward in a counterclockwise direction. At this time, since the driving pin 130 formed on the spindle lever 120 is caught by the first catching plate 212 of the first output lever 211, the driving pin 130 is the first output lever 211. It can transmit the rotational force to Therefore, the left side of the first output lever 211 is rotated downward and the right side of the first output lever 211 is rotated upward.

At the same time, since the second output lever 221 is in a state capable of interlocking with each other through the first output lever 211 and the connection link 230, the second output lever 221 is substantially the same as the rotational operation of the first output lever 211. The same rotation operation may be achieved, and thus, the switching unit 240 connected to the end of the second output lever 221 may be operated to transmit an open signal to the outside at the test position.

On the other hand, referring to Figure 3, when the breaker body is moved to the run position, the drive pin 130 of the spindle lever unit 100 is sandwiched between the first engaging plate 212 of the first output lever 211. It slides in a state and is sandwiched between the second locking plate 222 of the second output lever 221 positioned on the side.

Therefore, the driving pin 130 formed on the spindle lever 120 may be in physical contact with the second output lever 221.

In this state, when the opening and closing portion is closed as shown in Figure 4, the main shaft lever 120 may be rotated downward in the counterclockwise direction. At this time, since the driving pin 130 formed on the main shaft lever 120 is caught by the second locking plate 222 of the second output lever 221, the driving pin 130 is the second output lever 221. It can transmit the rotational force to Accordingly, the left side of the second output lever 221 is rotated downward and the right side of the second output lever 221 is rotated upward.

At the same time, since the first output lever 211 is in a state capable of interlocking with each other through the second output lever 221 and the connection link 230, the first output lever 211 is substantially in a rotational motion of the second output lever 221. The same rotation operation may be achieved, and thus, the switching unit 240 connected to the end of the second output lever 221 may be operated to transmit a signal forming a closed state at the test position to the outside.

Therefore, the present invention can easily confirm the open or closed operation state of the breaker body at both the test position and the run position where the breaker body is located, as described in the above operation.

100: main shaft lever 110: main shaft
120: spindle lever 130: drive pin
200: output lever portion 210: first output lever portion
211: first output lever 212: first locking plate
220: second output lever portion 221: second output lever
222: second locking plate 230: connection link

Claims (5)

A main shaft lever unit installed in the breaker body which is selectively linearly moved to the test position and the run position of the cradle, and rotated in a predetermined direction according to the opening or closing operation of the breaker body; And
And an output lever part interlocked with the main shaft lever part to reach the test position or the run position of the cradle. The method of claim 1,
The output lever unit,
A pair of output levers installed in the cradle to rotate in the test position and the run position, and a movement path of the driving pins provided in each of the pair of output levers and formed in the spindle lever part, and the test And a pair of engaging plates that are formed to engage the drive pin in the position or the run position, and a link for linking the pair of output levers so that the pair of output levers interlock with each other. External contact drive of breaker. The method of claim 2,
The main shaft lever unit,
A main shaft provided in the circuit breaker main body, the main shaft being rotated according to the operation of the opening and closing unit, a main shaft lever connected to the main shaft, and the driving pin protruding from the main shaft lever to be spaced apart from the main shaft by a predetermined distance. External contact drive of breaker. The method of claim 2,
The pair of locking plates,
An upper locking plate positioned at an upper portion of the driving pin and a lower locking plate positioned at a lower portion of the driving pin,
Both ends of the upper locking plate and the lower locking plate are disposed to be offset from each other to follow the rotation path of the spindle lever,
The movement path of the drive pin is
External contact drive device of the circuit breaker, characterized in that formed along between the upper locking plate and the lower locking plate. The method of claim 4, wherein
The upper locking plate or the lower locking plate is an external contact driving device of the circuit breaker, characterized in that the movable movement from the output lever to the width adjustable.

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