KR820001150Y1 - Breaker handler - Google Patents

Abstract

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Description

Breaker Mechanism

1 and 3 is an embodiment of the present invention,

1 is the input state.

2 is a tripped free state.

3 shows the reset states, respectively.

Figure 4 is another embodiment of the present invention.

5 and 6 are mechanism diagrams showing conventional ones.

5 is a reset state.

6 shows the input state,

7 is a view for explaining that the force in the rotational direction is applied to the lever.

The present invention relates to an operation mechanism of a circuit breaker, the main purpose of which is to reduce the number of parts of the operation mechanism and to simplify the structure.

An embodiment of the present invention will be described with reference to the drawings.

FIG. 1 shows the operating state of the circuit breaker, which is a combination of a solenoid type driving device B and a switch C, for example.

FIG. 2 shows the tripping state and FIG. 3 shows the reset state thereof. In FIG. 1, the frame fixed to the operation shaft 2 having an annular shape at both ends and a square shape at the center thereof, (3) is a half-moon latch held by the frame 1 as the pin 3a, and is rotatable about the pin 3a. (4) is a tripping lever fixed to the latch (3), (5) is a stopper of the latch (3) fixed to the frame (1).

6 is a lever held by the pin 6a in the frame 1, and is rotatable about the pin 6a. (7) is a stopper of the lever (6) fixed to the frame (1), (8) is a link connecting the lever (6) and the furanza (9) of the input drive device B with pins (8a) and (8b), 10 is a hook for holding the closing state, and is rotatable with the pin 10a as a point. Furthermore, the roller 10b is attached to this hook 10.

(11) is a lever fixed to the operating shaft (2) connected to the movable contact (12) of the switch (C) by a pin (11a), and (13) is a fixed contact of the switch (C). (14) is a tension spring that imparts a rotational force in the clockwise direction to the operation shaft (2), and has elasticity sufficient to extend both of the springs (16) and (17) to be described later. Reference numeral 15 is a tension spring that imparts rotational force in the counterclockwise direction to the latch 3, and is attached to the lever 4. Numeral 16 denotes a tension spring that imparts a clockwise rotational force to the hook 10, and numeral 17 denotes a reset spring housed in a hole 9a formed in the furanza 9 of the input drive device B. The reset spring 17 has a function of pushing the furanza 9 to the left and turning the lever 6 counterclockwise so as to be in the reset state of FIG. 3 from the tripping state of FIG. 18 is a stopper of the operation shaft (2).

Next, the operation state of the operating mechanism A of the circuit breaker will be described. In the closing state of FIG. 1, when the lever 4 in the tripping state is rotated clockwise with the pin 3a as the point, the latch 3 also moves in the same direction. Rotated, but sufficiently rotated, the latch 3 is released from the tip 6b of the lever 6, the engagement of the operating mechanism A is released. Since the rotational force in the clockwise direction is imparted to the operation shaft 2 by the tension spring 14, the operation shaft 2 rotates in the clockwise direction and is stopped by the stopper 18. Since the frame 1 and the lever 11 fixed to the operation shaft 2 are also rotated at the same time as the operation shaft 2 as a point, the movable contact 12 is dissociated so that the switch C is blocked.

In the state of FIG. 1, the force of the spring 14 acts in the direction of rotating the operation shaft 2 clockwise so that the force to rotate in the machine direction with the operation shaft 2 as the point in the frame 1 also is It's working.

On the other hand, the line connecting the pins 8a, 8b and 10a is <shaped, and the pins 8a abut on the free end of the hook 10 and are coupled to the lever 6 at the same time. Therefore, the force acting in the clockwise direction on the frame 1 is also applied to the link nose 8 and the hook 10 via the pin 6a, the lever 6, and the pin 8a, and the link 8 and the hook ( 10, the force to bend again is applied to the pin (8a) as a point. That is, the rotational force in the clockwise direction with the pin 6a acting on the lever 6.

The description is as follows. The reason why the lever 6 does not rotate counterclockwise is because the rotational force of the force generated by the spring 14 is incomparably larger than the rotational force of the spring 17. When the engagement between the latch 3 and the lever 6 is released, it is evident that the frame 1 is instantaneously rotated clockwise by the spring 14.

At this time, since the force of the spring 17 is very small, the frame 1 may be ignored during rotation. That is, assuming that the furanza 9 does not move, the pin 6a is rotated clockwise so that the lever 6 is rotated clockwise relative to the frame 1 around the pin 6a. This will be described according to FIG. 7.

The solid line indicates the input position. The angle θ formed by the straight line connecting the pins 6a and 8a and the link 8 is discarded to 180 ° when the frame 1 is rotated further clockwise (if there is no stopper 18).

However, in the state of FIG. 1, since the latch 3 is engaged with the tip 6b of the lever 6, the lever 6 becomes impossible to rotate clockwise, and thus the frame 1 and the operation shaft ( Since rotation in the clockwise direction is impossible even up to 2), the fixed and movable conduits 13 and 12 are kept in a closed state.

Thus, when the latch 3 is detached from the tip 6b of the lever 6 as described above, the lever 6 rotates clockwise with the pin 6a as the point and at the same time the link 8 and the hook 10 Is bent again with the pin 8a as the point, and the frame 1, the pin 6a, the stopper 5, the lever 4, the latch 3, and the pin 3a are the operating shaft 2 Rotate clockwise to the point, while the springs 15, 16, 17 are extended and the movable conductors 12 are separated from the fixed conductors 13.

And when the lever 6 contacts the roller 10b of the hook 10, the roller 10b rotates the arc shape of the lever 6, and the hook 10 counterclockwise by making the pin 10a the point. It rotates and becomes like the state of FIG.

Next, when the magnetic force of the electromagnetic coil of the input drive device B disappears in the state of FIG. 2, the furanza 9 is rotated counterclockwise while moving to the left side as shown in FIG. 3 by the reset spring 17. FIG. Let's go. At this time, the lever 6 rotates about the pin 6a through the link 8 and stops at the stopper 7. In the figure, when the lever 6 is released from the latch 3, the latch 3 is rotated counterclockwise by the spring 15 to the pin 3a and stopped by the stopper 5, and the In the reset state, when the feeding instruction is given, the furanza 9 is moved to the right by the feeding driving force. In the reset state, since the lever 6 is free to rotate around the pin 6a, it is tensioned by the furanza 9 through the link 8 and rotated clockwise, and the lever tip 6b is latched 3. ), The operation mechanism A is rotated counterclockwise with respect to the operation shaft 2, and the movable contact 12 is joined to the fixed contact 13 so that the switch C is input.

Since the rotation force in the clockwise direction is given to the hook 10 by the spring 16 to the hook 10 during the closing operation, the roller 16b rotates the arc image of the lever 6 while the hook 10 is clockwise. Direction, and in the final stroke of the closing operation, it is engaged with the pin 8a on the lever 6 to maintain the closing state. Moreover, in the above-described embodiment, the operating shaft 2 and the frame 1 are fixed, but the lever 11 is fixed to the frame 1, and the frame 1 and the operating shaft ( 2) can be rotated freely, and the operation shaft 2 can be formed in any shape. In the above embodiment, the engagement between the lever 6 and the latch 3 is engaged by the tip 6b of the lever 6, but as shown in FIG. 4, the roller 19 is installed at the lever tip 6b. The driving force of the latch 3 can be reduced when tripping by engaging the circumferential surface of the wool 19 and the latch 3.

As described above, the present invention is to obtain a control mechanism of a circuit breaker capable of accurate operation as a simple mechanism with a small number of parts. Next, a description will be given of a conventional operating mechanism. FIG. 5 is a view showing a reset state in a conventional mechanism of a circuit breaker, and FIG. In the reset state of FIG. 5, when the rod 32 connected to the input drive device (not shown) is raised in the direction of arrow D, the first link 21 rotates counterclockwise about the shaft 21a. The second link 22 also rises upward.

At this time, the fourth link 24 is tensioned in the direction of the arrow E so that the first latch 25 is rotated clockwise about the axis 25a and abuts on the roller 31b of the second latch 31. The second and third latches 31 and 30 rotate counterclockwise around the shafts 31a and 30a by the force. The third latch 30 is stopped by the trigger 29. Therefore, the pins 24a connecting the latch 25 and the fourth link 24 become the fixed rotation center axis of the fourth link 24, so that the second, third, and fourth links 22, 23, 24 are provided. And the chain state formed of the closing lever 26 is a constrained chain, so that the driving force transmitted by the lot 32 is transmitted to the closing lever 26 through the third link 23, The closing lever 26 is rotated clockwise about the axis 26a, the movable contact 27 is joined to the fixed contact 28 so that the switch C is closed and the hook 33 is engaged with the pin 32a. The input state is maintained.

This is shown in FIG. In the closing state of FIG. 6, when the trigger 29 is rotated counterclockwise about the axis 29a to disengage the engagement with the third latch 30, the third latch is centered on the axis 30a. Rotate the counterclockwise direction, the engagement between the third latch and the second latch is released, and then the second latch is rotated counterclockwise about the axis 31a, and the second latch 31 and the The engagement with the one latch 25 is released, and the pin 24 is brought into a disabled state. Therefore, the chain state composed of the second, third, and fourth links 22, 23, 24 and the closing lever 26 becomes a crippled state so that the closing lever 26 is half-centered about the shaft 26. It rotates clockwise, the movable contact 28 is dissociated, and the switch C is interrupted | blocked. During this operation, the hook 33 is disengaged from the pin 32a by the second link 22, so the lot 32 is lowered to the reset state of FIG.

As described above, the conventional engraving machine has a large number of parts and a complicated structure.

The present invention eliminates such inconvenience as described above, and can provide an operation mechanism of a circuit breaker having a small number of parts and a simple structure.

Claims (1)

The operation shaft 2 is connected to the operation spring 14, which is always added in the direction in which the contacts 12, 13 are disengaged, the frame 1 that rotates in accordance with the rotation of the operation shaft 2, and the frame 1. The latch 3 and the lever 6 held as pins 3a and 6a, and the hook 10, the lever 6 and the furanza rotated with the pin 10a as a point and mounted with the roller 10b. Input of breaker operation mechanism A made of link 8 etc. which connected 9 to pins 8a, 8b, and reset spring 17 housed in hole 9a of furanza 9 A breaker operating mechanism including a drive device (B).