KR101191571B1 - An air circuit breaker - Google Patents

Abstract

PURPOSE: An air circuit breaker is provided to simplify an assembly process by applying a guide pin and removing a guide member for guiding a second link. CONSTITUTION: A first link(51) rotates around a rotation shaft. A second link(52) is connected to one end of the first link and rises and falls. A guide pin(53) is inserted into a lateral plate of an opening and closing device. A first protrusion part(521) protrudes cross a link body. A second protrusion part(522) is formed on the lower side of the link body. A guide hole(523) is vertically cut and is formed in the second protrusion part. A guide pin passes through the guide hole and is fixed to the lateral plate.

Description

Air circuit breaker

The present invention relates to an air circuit breaker.

Generally, an air breaker is a power device that selectively opens and closes an electric circuit between a power supply side and a load side in the atmosphere. In detail, the air circuit breaker is capable of drawing out the circuit breaker main body from a cradle having a fixed type fixedly connected to circuit connection terminals on the power supply side and the load side, and circuit connection terminals on the power supply side and the load side. There is a withdrawable type. Recently, the drawer type air circuit breaker has been widely used due to the maintenance difficulty of the fixed air circuit breaker.

These draw-out circuit breakers protect the safety of the operator or maintenance inspector from the risk of accidents by accidental release of energy storage devices, such as spring charging devices, in accordance with applicable domestic and international power equipment standards. It is prescribed to secure the withdrawal interlock device for.

1 is a perspective view of a conventional spring automatic release device of the air circuit breaker, Figure 2 is a side view of the air circuit breaker equipped with the automatic release device, Figure 3 is a side view showing a state of the main body of the air circuit breaker withdrawn from the cradle to be.

1 to 3, a conventional air circuit breaker includes a circuit breaker main body and a cradle C for releasably receiving the circuit breaker main body.

In detail, the circuit breaker main body is rotatable to an outer surface of the opening and closing mechanism 1 in a state of being connected to a switching mechanism 1 and a cam shaft 21 protruding through the side plate of the opening and closing mechanism 1. And a camshaft rotation stopping mechanism 37 and a camshaft rotation blocking mechanism 37 which are connected to the charging handle H1 and the camshaft 21 to prevent rotation of the camshaft 21. The breaker body includes a release device 30 that interlocks according to the position from which the cradle C is drawn out.

More specifically, the release device 30 performs a function of selectively releasing the camshaft rotation preventing mechanism 37 so that the camshaft 21 rotates by the elastic restoring force of the closing spring.

The camshaft rotation preventing mechanism 37 is provided on the camshaft 21 and is ratchet wheel 372 rotating in one body with the camshaft 21 and accumulated in the closing spring 13. And a plurality of ratchets 371 and 373 that allow or inhibit rotation of the ratchet wheel 372 and the camshaft 21 so that elastic energy is discharging. The ratchetes 371 and 373 may include a main ratchet 373 and an auxiliary ratchet 371.

The release device 30 also includes a lever 36, a link member and a return spring 34. The release device 30 is connected to the outer surface of the opening and closing mechanism side plate 1a so as to be linkable.

In detail, the lever 36 is coaxially connected to the axis of rotation of the main ratchet 373, allowing the main ratchet 373 to rotate the ratchet wheel 372 and the camshaft 21 by a rotational operation. Rotate to position

The link member includes a first link 31 and a second link 32. In addition, the first link 31 is connected to the side plate 1a so as to be rotatable by a rotation shaft 311 at a central portion thereof. One end of the first link 31 selectively rotates an on link 81 that releases the closing latch (to be described later). The other end of the first link 31 is linked to an upper end of the second link 32 by a connection pin 312. That is, it rotates clockwise or counterclockwise about the central axis 311 in association with the vertical movement of the second link 32.

On the other hand, the second link 32 extends a predetermined length downward, and at some point extends downward again after bending and inclining. At some point of the second link 32, the first protrusion 321 protrudes in a direction crossing the extending direction of the second link 32. The second protrusion 35 protrudes in a substantially triangular shape at the lower end of the second link 32.

In addition, the interlocking protrusion 361 protruding from the end of the lever 36 is fitted into the recessed portion formed below the first protrusion 321. Therefore, when the second link 32 is moved up and down, the lever 36 rotates clockwise or counterclockwise. In addition, a hook end 322 on one end of the return spring 34 protrudes from a lower portion of the second link 32.

In addition, the release device 30 further includes a guide member 33 fixed to the maximum rising height point of the second protrusion 35. In detail, the guide member 33 is formed to cover a straight portion of the second link 32 to guide the vertical movement of the second link 32. In other words, the second link 32 is bent a number of times to form a space in which the second link 32 can move. A fixed end 331 protrudes from both ends of the guide member 33, and a fastening member such as a screw penetrates the fixed end 331 to be fixed to the side plate of the opening and closing host 1. Then, at one end of the guide member 33, a hook end 332 is applied to the other end of the return spring (34).

As shown in FIG. 2, when the breaker body is retracted into the cradle C, the second protrusion 35 is raised by the bottom of the cradle C, and the return spring 34 ) Is kept in tension. In this state, since one end of the on-link 81 and the first link 31 are in contact with each other, the closing of the on-lever (not shown) connected to the on-link 81 is possible. ) Operation is possible. In addition, since the linkage protrusion 361 is not in contact with the first protrusion 321, a manual charging operation by the charging handle H1 may be performed.

On the other hand, as shown in Figure 3, in the state in which the breaker body is drawn out, the second protrusion is separated from the bottom of the cradle (C). Accordingly, the return spring 34 is retracted while returning to its original position. In addition, the second link 32 is lowered by the contraction of the return spring 34, and the first link 31 is rotated clockwise about the rotation shaft 311. One end of the first link 31 rotates the on link 81 to automatically release the energy of the branched closing spring. In addition, the lever 36 rotates by the lowering of the first protrusion 321 by the linkage protrusion 361, and as a result, the main ratchet 373 is separated from the ratchet wheel 372. do. As a result, the manual charging operation by the charging handle H1 becomes impossible.

Conventional release device 30 to achieve the above structure has the following problems.

First, since the guide member 33 must be fixed to the side plate of the opening and closing mechanism 1 by two screws in order to guide the second link 32 of the release device 30 to move linearly in the vertical direction. The assembly process is complicated.

Second, there is a disadvantage in that the manufacturing cost due to the manufacturing cost of the guide member 33 is increased.

Third, when the circuit breaker main body is completely separated from the cradle, that is, when the circuit breaker main body is transported alone, the second protrusion 35 remains protruding from the lower surface of the circuit breaker main body. The second protrusion may cause product damage that is warped or cut.

The present invention has been proposed to improve the above problems, and an object of the present invention is to provide an air circuit breaker that can simplify the manufacturing process and reduce the manufacturing cost by improving the structure of the release device.

In addition, an object of the present invention is to provide an air circuit breaker that can prevent the link member constituting the release device from being damaged by an external force when the breaker body is transported alone.

The air circuit breaker according to the embodiment of the present invention for achieving the above object, the breaker body including a fixed contactor and the opening and closing mechanism is provided with a movable contact that is in contact with or separated from the fixed contact, and the breaker body can be pulled out In the air circuit breaker comprising a cradle that is inserted into the slot, and an injection spring for providing a driving force to contact the fixed contact, and the release device for the release of the elastic energy of the injection spring, the release device, A first link that rotates to the center, a second link connected to one end of the first link to move up and down, and one end connected to a point of the second link, and the other end connected to a side plate of the opening / closing mechanism. And a guide pin inserted into the side plate of the opening and closing mechanism through a spring and the second link. The second link may include a link body extending downward in a predetermined length, a first protrusion protruding in a direction crossing the link body at some point of the link body, and a second protrusion formed at a lower end of the link body. It includes, and the inner side of the second protrusion is formed with a guide hole which is cut in the vertical direction, the guide pin is characterized in that it is fixed to the side plate through the guide hole.

According to the release device of the air circuit breaker according to the embodiment of the present invention constituting the above configuration has the following effects.

First, there is an advantage that the assembly process is simplified by removing the guide member for guiding the movement of the second link constituting the release device and applying the guide pin.

Second, manufacturing cost is reduced by removing the conventional guide member for guiding the movement of the second link.

Third, when the circuit breaker main body is transported alone, the second link does not protrude from the lower surface of the circuit breaker main body, thereby removing the phenomenon in which the second link is broken by external force.

1 is a perspective view of the automatic spring release device of the conventional air circuit breaker.
Figure 2 is a side view of the air circuit breaker with the automatic release device.
3 is a side view showing a state in which the main body of the air circuit breaker is drawn out from the cradle.
Figure 4 is a side view showing a connection position state of the air circuit breaker according to the embodiment of the present invention.
5 is a side view showing a test position state in which the main circuit terminal is disconnected and the control circuit terminal is connected.
6 is a side view showing a disconnected position state in which the main circuit and the control circuit are separated;
Fig. 7 is a side view showing a pull out position state of the breaker body withdrawn from the cradle;
Figure 8 is a front perspective view showing the appearance of the pull-out air circuit breaker according to an embodiment of the present invention.
9 is a perspective view of a cradle constituting the air circuit breaker;
Figure 10 is a left side view of the opening and closing mechanism showing a blocking state of the air circuit breaker according to an embodiment of the present invention.
11 is a sectional view showing a state in which the closing spring of the air circuit breaker is charged.
12 is a cross-sectional view showing a state in which the closing spring is released.
Figure 13 is a perspective view showing the configuration of the opening and closing mechanism of the air circuit breaker.
14 is a perspective view of the closing spring release device according to an embodiment of the present invention.
15 is a side view of the breaker body with the release device removed;
16 and 17 are views showing the operating state of the release device according to an embodiment of the present invention in the process of the breaker body is withdrawn from the cradle.
18 is a side view of the air circuit breaker showing a state immediately before being inserted into the cradle in a state where the breaker body is kept alone.

Hereinafter will be described in detail with reference to the drawings with respect to the air circuit breaker and the release device of the closing spring provided in the air circuit breaker according to an embodiment of the present invention. Hereinafter, the same parts as the structure of the circuit breaker described in the prior art will be described with the same reference numerals.

Figure 4 is a side view showing a connection position state of the air circuit breaker according to an embodiment of the present invention, Figure 5 is a side view showing a test position state that the main circuit terminal is disconnected and the control circuit terminal is connected, Figure 6 is a main circuit and FIG. 7 is a side view showing the disconnected position state in which the control circuit is separated, and FIG.

Referring to FIG. 4, the air circuit breaker according to the embodiment of the present invention includes a breaker body 20 and a cradle C for receiving the breaker body 20. The breaker main body 20 can be pulled out in the front-rear direction by the pull-out rail PL from the cradle C.

In detail, according to FIG. 4, an electrical connection is made between the main circuit terminal C2 of the cradle C and the main circuit terminal 202 of the breaker main body 20, so that the power supply side and the load side of the main circuit are the air circuit breakers. The state is electrically connected through.

That is, the control signal receiving terminal 201 of the circuit breaker main body 20 for receiving the opening / closing control signal of the air circuit breaker is connected to the cradle control signal terminal C1 for transmitting the opening / closing control signal from the outside. Corresponds to the location.

Referring to FIG. 5, the main circuit terminal C2 of the cradle C and the main circuit terminal 202 of the breaker main body 20 are separated, and the control signal terminal C1 of the cradle is controlled by the breaker main body 20. Corresponds to the state of the withdrawal initial stage of the draw-out air circuit breaker connected to the signal receiving terminal 201. At this time, the main circuit terminal C2 of the cradle C and the main circuit terminal 202 of the breaker main body 20 are separated so that the power supply side and the load side of the main circuit are electrically disconnected.

In addition, the control signal terminal C1 of the cradle C and the control signal receiving terminal 201 of the circuit breaker main body 20 are still connected. The state of Figure 5 corresponds to the test position to test the opening and closing operation by giving only the opening and closing control signal to the air circuit breaker in the state that the main circuit is blocked.

FIG. 6 is an operational state diagram showing a state in which the main circuit terminals C2 and 202 are separated and the control circuit terminals C1 and 201 are also separated in the draw-out air circuit breaker, which is called a disconnection position.

FIG. 7 is an operational state diagram illustrating a state in which the breaker main body 20 is drawn out from the cradle C by the drawing rail PL in the drawer type air circuit breaker. In this case, the main circuit terminals are separated and the control circuit terminals are also separated. In this state, the breaker main body 20 is completely pulled out from the cradle C and maintained.

Figure 8 is a front perspective view showing the appearance of the pull-out air circuit breaker according to an embodiment of the present invention, Figure 9 is a perspective view of the cradle constituting the air circuit breaker.

8 and 9, the air circuit breaker according to the embodiment of the present invention includes a circuit breaker main body 20, a cradle C supporting the circuit breaker main body 20 to be retractable, and the circuit breaker main body 20. ) The side plate 1a of the opening / closing mechanism 1 and the opening / closing mechanism 1, the ON button NB and the off button FB included in the opening / closing mechanism 1, and the opening / closing mechanism 1 By the main shaft 10 for simultaneously opening and closing the three-phase contact point, the main shaft lever 101 connected to the main shaft 10 to drive the movable contact 11 of the opening and closing mechanism 1, and the opening and closing A charging handle H1 for manually charging the closing spring 13 (see FIG. 10) in the instrument 1, and the breaker body 20 when withdrawing the breaker body 20 from the cradle C. The first drawing rail (PL1) and the second drawing rail (PL2) for guiding the step 20 in a multi-stage, and providing a driving force for drawing out the breaker body (20) A girder G including a top cover T of the transfer device and the transfer device, and an operation unit for driving the transfer device, and fixedly installed between both side plates of the front cradle C of the air circuit breaker; A feeder drive handle H2 and a feeder drive handle connector G1.

In detail, a polygonal part including a 4-8 square is formed at the front end of the transfer device drive handle H2 for manual driving of the transfer device, and the transfer device drive handle connection port G1 corresponds to a polygonal portion. This same polygonal inner circumferential surface is formed at the end of the drive shaft (not shown) of the device.

Meanwhile, in FIG. 9, the first withdrawal position S1 and the second withdrawal position S2 are respectively immediately after being separated from the disconnection position at the withdrawal of the circuit breaker main body, which will be described later, and the air circuit breaker according to the present invention is further drawn therefrom. The point where the 2nd protrusion part 522 (refer FIG. 14) which comprises a spring automatic release apparatus is located is shown.

Figure 10 is a left side view of the opening and closing mechanism showing a blocking state of the air circuit breaker according to an embodiment of the present invention, Figure 11 is a cross-sectional view showing a state of the closing spring of the air circuit breaker, Figure 12 is the release spring is released 13 is a perspective view showing the configuration of the opening and closing mechanism of the air circuit breaker.

Referring to FIG. 10, the opening / closing mechanism 1 of the air circuit breaker according to the embodiment of the present invention includes a fixed contact 12 and a closing position for closing the energization circuit in contact with the fixed contact 12. And a movable contact 11 separated from the fixed contact 12 and movable in a trip position to open the energizing circuit.

As shown in FIG. 10, the movable contactor 11 is connected to the main shaft lever 101 to contact or separate from the fixed contactor 12 according to the rotational direction of the main spindle lever 101.

In detail, since the air shaft breaker is normally used to open and close the three-phase conduction path, three spindle levers 101 are provided, one for each phase, and drive the movable contactor 11 of the phase. In order to drive the three spindle levers 101 simultaneously, each spindle lever 101 is coaxially connected to one spindle 10. Therefore, the main shaft 10 extends through both side plates 1a supporting the opening / closing mechanism 1 to be connected to the main shaft lever 101 of the other phase.

On the other hand, one of the main shaft lever 101 of the main shaft lever 101 which is connected to the opening and closing mechanism 1 is connected to the main shaft 10 and the other end is connected to the first link (6).

In detail, the first link 6 has a different rotation axis from the main shaft lever 101, and one end of the first link 6 is connected to the main shaft lever 101 like a gear engaged with each other. Thus, the spindle lever 101 and the first link 6 rotate in opposite directions. The first link 6 provides a driving force for driving the movable contact 11 to the open or closed position to the central spindle lever 101 of the three spindle levers.

One end of the second link 4 is connected to the other end of the first link 6, and the first link 6 and the second link 4 rotate in the same direction.

In detail, one end of the third link 3 is rotatably connected to the other end of the second link 4. The other end of the second link 4 and one end of the third link 3 are connected by a driving connecting pin P so that a driving force generated in the third link 3 is applied to the second link 4. Is delivered).

The closing spring section also includes a closing spring 13 which provides a driving force for driving the movable contact 11 to the closed position, and a closing spring seat (not shown). The charging spring 13 charges the elastic energy and then releases the charged elastic energy to provide a driving force for moving the movable contact 11 to the closed position.

In detail, an injection spring support bracket 131 is provided at an end opposite to an end (right end in the drawing) of the injection spring 13 corresponding to a side for transmitting driving force to the link members 3, 4, 6. The closing spring supporting bracket 131 serves to prevent the closing of the closing spring 13 and to support the rotation of the closing spring sheet.

In addition, the opening and closing mechanism 1 of the air circuit breaker includes a charging cam 2 for providing a driving force for charging the closing spring 13, and the charging cam 2 includes a cam shaft ( 21) and rotate with one body. The charging cam 2 is provided with a cam roller 22 shown at a dotted line in FIG. 13. The third link 3 is coaxially connected with the rotation shaft 21 of the charging cam 2 to be rotatable together.

In Fig. 13, a driving lever 16 is connected to the second link 4 by a driving lever pin 162. Then, the driving lever pin 162 is connected to each other. It consists of a pair of drive levers 16 and 16 which are spaced apart, and the 2nd link 4 and the 3rd link 3 intervene between the pair of drive levers 16 and 16. As shown in FIG. The driving lever 16 is connected to the input spring part to provide a driving force for charging the elastic energy to the input spring part, or may be rotated by receiving the elastic energy charged from the input spring part.

As shown in FIG. 10, one end is supported by the spindle lever 101, and the other end is provided with a blocking spring 14 supported by a spring support pin 141 fixed on the side plate 1a. The blocking spring 14 is tensioned by the clockwise rotation of the spindle lever 101 during the closing operation to charge the elastic energy, and releases the charged elastic energy during the circuit breaking to counterclockwise the spindle lever 101. Provides driving force to rotate.

As shown in FIG. 13, the third link bias spring 15 may be configured in a pair. One end of each third link bias spring 15 is supported by the drive lever pin 162 and the other end is supported by the drive connecting pin P.

The driving connecting pins P pass through the second link 4 and the third link 3 and protrude to support the pair of third link bias springs 15 at both ends. In order to prevent interference with the protruding drive connecting pins P, the pair of drive levers 16 and 16 are spaced apart by the drive lever pins 162 so as to have a considerable distance from each other.

The closing latch 5 extends in the vertical direction to have one surface positioned on the movement trajectory of the cam roller 22 provided on one surface of the charging cam 2, so that the charging cam 2 is extended. You can restrain your meeting. The upper end of the closing latch 5 is located on the rotation path of the on lever 8 and can be restrained or released by the on lever 8. An end link of the on lever 8 is provided with an on link 81 for rotating the on lever 8 to a position to release the closing latch 5.

The on lever 8 is connected to the on button NB, and can be automatically rotated manually or by a separate electric drive control device and actuator.

On the other hand, the upper part of the third link (3) is provided with a blocking latch (7) which can be rotated around the rotation axis (72). In detail, an opening latch roller 71 is provided at any point of the blocking latch 7. In addition, a groove portion 301 is provided at an upper portion of the third link 3, and the blocking latch roller 71 enters or leaves the groove portion 301 of the third link 3. Move to the position.

One end of the blocking latch 7 is connected to the blocking latch spring 73 by a pin, so that the blocking latch 7 receives an elastic biasing force from the blocking latch spring 73 to rotate counterclockwise in the drawing.

In addition, the front end of the blocking latch 7 is provided to be in contact with the off shaft (9). The rotation of the blocking latch 7 is restrained or released by the off shaft 9.

The operation of the opening / closing mechanism 1 of the air circuit breaker according to the embodiment of the present invention as described above will be described by dividing the charging (elastic force charging) operation, the closing operation and the opening (opening) operation of the closing spring 13 as follows. same.

First, the charging operation of the closing spring 13 will be described with reference to FIG.

The rotating shaft 21 of the charging cam 2 is rotated counterclockwise on the drawing through the charging handle H1 or a driving motor (not shown). Then, the drive lever roller 161 in contact with the outer circumferential surface of the charging cam 2 is compressed as the radius of curvature of the outer circumferential surface of the charging cam 2 decreases. And the said spring seat of the said injection | pouring spring part which is contacted in the direction pressed by the said drive lever roller 161 is pressed, and the said injection | pouring spring 13 is compressed.

In this case, as the charging cam 2 rotates, the driving lever roller 161 rolls along the outer circumferential surface of the charging cam 2, and the charging cam 2 is a cam roller provided on one surface of the charging cam 2. It rotates until it hits the said latching latch 5.

According to the counterclockwise rotation of the charging cam 2, the third link 3, the second link 4 and the drive lever 16 interlock and rotate counterclockwise. In this case, since the rotation of the main shaft 10 is restricted by the blocking latch 7, the movable contact 11 is maintained in a state separated from the fixed contact 12 as shown in FIG. 10.

Further, the third latch 3 is rotated in the counterclockwise direction so that the third latch 3 enters the blocking latch roller 71 of the blocking latch 7 into the groove 301 of the third link 3. Counterclockwise rotation of the link 3 is constrained.

Further, the cam roller 22 provided on one surface of the charging cam 2 pushes the closing latch 5 while touching the closing latch 5, so that the closing latch 5 is clockwise about its rotational axis. Rotate In addition, while the clockwise rotation of the closing latch 5 is prevented by the on lever 8, the charging operation of the closing spring 13 is completed.

On the other hand, referring to Figure 12 describes the closing (closing) operation of the opening and closing mechanism of the air circuit breaker as follows.

When the on lever 8 is rotationally driven manually or connected to an on button and electrically driven, i.e., connected to a separate electric drive control device and an actuator, the closing latch 5 It is released from restraint by the on lever 8 and rotates clockwise. As the closing latch 5 is released, restraint of the cam roller 22 by the closing latch 5 is also released. As a result, the driving lever roller 161 which is in contact with the outer circumferential surface of the charging cam 2 and prevents the release of the injection spring 13 is out of the circumferential surface of the charging cam 2.

As the closing spring 13 is released, the driving lever 16 is pressed by the spring seat of the closing spring 13 to rotate the counterclockwise direction. Accordingly, the drive lever pin 162 pushes the second link 4 to rotate it counterclockwise in the drawing. The third link 3 also rotates counterclockwise by counterclockwise rotation of the second link 4. Thus, the first link 6 is pushed by the second link 4 and is rotated in the counterclockwise direction.

Since the spindle lever 101 and the first link 6 are linked to each other, the spindle lever 101 is connected to the first link 6 by counterclockwise rotation of the first link 6. Rotate clockwise in conjunction. At the same time, the main shaft 10 also rotates in a clockwise direction, and thus the movable contactor 11 connected to the main shaft lever 101 rotates counterclockwise in the drawing to come into contact with the fixed contactor 12. Therefore, the energization circuit is closed (input). At this time, the blocking spring 14 is in a tensioned state, which is in a state of charging or storing elastic energy.

Meanwhile, referring to FIG. 10, a circuit opening operation of the opening and closing mechanism of the air circuit breaker is described as follows.

When the off lever 9 is driven to rotate clockwise by manual force or by being connected to the off button FB and electrically, i.e., connected to a separate electric drive controller and actuator, The latch 7 is released from restraint by the off lever 9. The blocking latch 7 is rotated counterclockwise by the elastic force of the blocking latch spring 73, and is also released from restraint by the groove portion 301 of the third link 3.

As the third link 3 is released from restraint by the blocking latch 7, the second link 4 and the first link 6, which cooperate with the third link 3, are also released. The main shaft lever 101 side supporting end returns to the spring supporting pin side of the side plate 1a while the blocking spring 14 is tensioned at the time of closing, thereby releasing the charged elastic energy to release the main shaft lever 101. Rotate counterclockwise. Thus, the movable contact 11 is separated from the fixed contact 12 while rotating clockwise. As a result, the energization circuit is cut off.

Figure 14 is a perspective view of the closing spring release device according to an embodiment of the present invention, Figure 15 is a side view of the breaker body with the release device removed.

14 and 15, the release device 50 of the closing spring according to the embodiment of the present invention, like the conventional release device 30 shown in Figure 1, the lever 56, the link member and the return A spring 54. The link member includes a first link 51 whose one end is in contact with the on link 81 and a second link 52 which is connected to the other end of the first link 51. In addition, the return spring 54 may be a tension spring that is contracted to return to its original state when the external force is removed.

In detail, a rotation shaft 511 is formed below the central portion of the first link 51. In addition, the second link 52 moves up and down, and the first link 51 moves clockwise or counterclockwise about the rotation shaft 511 according to the lifting motion of the second link 52. Rotate in the direction. As the first link 51 rotates in the counterclockwise direction, one end of the first link 51 rotates the on link 81 so that the injection spring 13 is automatically released.

In addition, the second link 52 extends a predetermined length downward from one end to which the connection pin 512 is connected. In addition, a first protrusion 521 protruding in a direction orthogonal to an extending direction of the second link 52 is formed at a lower portion of the second link 52. do. In addition, a second protrusion 522 is formed at the other end of the second link 52. An inclined surface is formed below the point at which the first protrusion 521 protrudes. In addition, a guide hole 523 is formed in the vertical direction of the second protrusion 522, and a guide pin 53 is inserted into the guide hole 523. In addition, a hook protrusion 524 to which one end of the return spring 54 is connected to a lower portion of the second link 52 protrudes.

On the other hand, the lever 56 is coaxially connected to the rotation axis of the main ratchet 373, allowing the main ratchet 373 to rotate the ratchet wheel 372 and the cam shaft 21 by a rotation operation. Rotate to position In addition, the interlocking protrusion 561 of the lever 56 is accommodated between the inclined surface of the first protrusion 521 and the second link 52, the lifting and lowering movement of the second link 52 The first protrusion 521 is caught and rotated counterclockwise.

Hereinafter, the structure attached to the side plate 1a of the said opening / closing mechanism 1 with which the said release apparatus 50 is mounted is demonstrated.

First, the charging handle H1 is rotatably mounted on the outer surface of the opening / closing mechanism 1 in a state of being connected to the cam shaft 21 protruding through the side plate of the opening / closing mechanism 1. The release device 50 is coaxially connected to the camshaft 21, and the camshaft rotation stopping mechanism 37 for preventing rotation of the camshaft 21 is mounted in the same manner as the conventional structure.

Specifically, the camshaft rotation blocking mechanism 37 is provided on the camshaft 21, and a ratchet wheel 372 which rotates in one body with the camshaft 21 and the closing spring 13. And a plurality of ratchets 371 and 373 that allow or prevent rotation of the ratchet wheel 372 and the camshaft 21 so that the elastic energy accumulated therein is discharging. The ratchetes 371 and 373 may include a main ratchet 373 and an auxiliary ratchet 371. This is the same as described in the prior art.

The release device 50 according to the embodiment of the present invention has a difference in that the conventional guide member 33 is removed and the lifting motion of the second link 52 is guided by the guide pin 53. .

In detail, the side plate 1a is formed at a point where a pair of holes into which the guide pin 53 is inserted are spaced apart from each other in the vertical direction. The pair of holes includes a fixing part hole 102 formed on a relatively upper side and an operating part hole 103 formed on a lower side of the fixing part hole 102.

The fixing part hole 102 is formed at a point corresponding to the upper end of the guide hole 523 at a point where the lower end of the second protrusion 522 is at the same height as the upper cover T of the transfer part. In addition, the operating part hole 103 is formed at a point corresponding to the upper end of the guide hole 523 at a point where the return spring 54 returns to its original position and the second protrusion 522 descends to the lowermost side. . Therefore, in the state where the guide pin 53 is coupled to the operating portion hole 103, the second link 52 is movable up and down, but in the state coupled to the fixing portion hole 102, The lowering of the two links 52 becomes impossible.

On the other hand, the hook protrusion 104 which catches the other end of the return spring 54 protrudes in the position which adjoins the lower end part of the said side plate 1a. That is, one end of the return spring 54 is caught by the hook protrusion 524 formed in the second link 52, and the other end is caught by the hook protrusion 524 protruding from the side plate 1a. In addition, when the second link 52 is raised, the return spring 54 is stretched while the restoring force is accumulated, and when the external force that pushes up the second protrusion 522 is removed, the second link 52 is lowered. Done. The external force pushing up the second protrusion 522 is removed, and the breaker body is drawn out from the cradle C so that the second protrusion 522 is separated from the top cover T of the transfer part. Means status.

According to the structure of the release device 50 according to the embodiment of the present invention, to guide the lifting of the second protrusion 522 of the second link 52 in the vertical direction, to limit the maximum rise or maximum fall height In order to cover the upper portion of the second protrusion 522, the guide member 33 (see FIG. 1) fixed to the side plate 1a has been removed. Instead, the guide pin 53 and the guide hole 523 of the second link 52 take over this function.

16 and 17 are views showing the operating state of the release device according to an embodiment of the present invention in the process of the breaker body is withdrawn from the cradle.

Referring to FIGS. 16 and 17, first, the guide pin 53 is fitted into the operating part hole 103 of the side plate 1a while the breaker body is coupled to the cradle.

In detail, as shown in FIG. 16, at the connection position, the test position, and the disconnection position of the air circuit breaker, the second protrusion 522 of the release device 50 is brought into contact with the upper cover T of the transfer device. Keep it. In this state, the second link 52 is in an elevated state, and the return spring 54 is in a tensioned state. In addition, the first link 51 is rotated counterclockwise by the rising of the second link 52 so that one end of the first link 51 is kept spaced apart from the on-link 81. do.

As shown in FIG. 17, when the breaker body 1 is further pulled forward and drawn out from the cradle C, the second protrusion 522 is separated from the top cover T of the transfer device. Then, the second link 52 is lowered while the return spring 54 is compressed by the restoring force. As the second link 52 descends, the first link 51 rotates the on link 81 while rotating clockwise. As a result, the on lever 8 connected to the on link 81 so as to be coaxially rotatable rotates, and the closing latch 5 is released from rotation by the on lever 8 and rotates. As the closing latch 5 is released, restraint of the cam roller 22 by the closing latch 5 is also released. As a result, the drive lever roller 161 which has prevented the release of the injection spring 13 while contacting the outer circumferential surface of the charging cam 2 is out of the circumferential surface of the charging cam 2. As a result, the closing spring 13 is released. Therefore, withdrawal is prevented from the cradle of the breaker body in the state where the closing spring 13 is charged for any reason.

18 is a side view of the air circuit breaker showing a state immediately before being inserted into the cradle in a state where the breaker body is kept alone.

Referring to FIG. 18, when the breaker body is stored or transported as a single article, the guide pin 53 is inserted into the fixing hole 102 of the side plate 1a.

In detail, in order for the guide pin 53 to be inserted into the fixing hole 102, first, the second protrusion 522 is pushed up so that the fixing hole 102 is positioned inside the guide hole 523. do. This state may be referred to as a state in which the second protrusion 522 is in contact with the top cover T of the transfer unit.

In this state, the guide pin 53 passes through the guide hole 523 to be inserted into the fixing part hole 102. Then, the second protrusion 522 is maintained in an elevated state, and one end of the first link 51 is also maintained in a state spaced apart from the on-link 81, that is, the state of FIG. 16.

In addition, since the lowering of the second link 52 is suppressed in the state where the guide pin 53 is inserted into the fixing hole 102, the charging spring 13 is maintained in the charged state, and the charging handle ( In addition to the manual charging of the closing spring 13 using H1), the phenomenon that the closing spring 13 is accidentally released is prevented.

Claims (7)

A breaker body including a fixed contactor and an opening / closing mechanism provided with a movable contact contacted to or separated from the fixed contactor, a cradle into which the breaker body is retractably inserted, and a driving force to allow the movable contactor to contact the fixed contactor In the air circuit breaker comprising an injection spring to be released and a release device to release the elastic energy of the injection spring,
The release device,
A first link rotating about the axis of rotation,
A second link connected to one end of the first link and lifting and lowering;
A return spring having one end connected to a point of the second link and the other end connected to a side plate of the opening and closing mechanism;
A guide pin penetrating through the second link and inserted into a side plate of the opening and closing mechanism;
The second link is,
A link body extending a predetermined length downward;
A first protrusion protruding in a direction intersecting the link body at any point of the link body;
A second protrusion formed at a lower end of the link body,
Inside the second protrusion is formed a guide hole which is cut in the vertical direction,
And the guide pin is fixed to the side plate through the guide hole. delete delete The method of claim 1,
And a pair of holes for inserting the guide pin into the side plate of the opening and closing mechanism corresponding to the movement path of the guide hole. The method of claim 4, wherein
The pair of holes,
Fixing hole and
The air circuit breaker including an operation part hole formed below the fixing part hole. The method of claim 5, wherein
The fixing part hole,
The air circuit breaker of claim 2, wherein the lower end of the second protrusion is formed at a point corresponding to the upper end of the guide hole at the maximum height. The method of claim 5, wherein
The operation unit hole,
And the return spring is returned to its original position and is formed at a point corresponding to the upper end of the guide hole at the point where the second protrusion descends.

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