KR830000249Y1 - Undervoltage tripping device for circuit breaker - Google Patents

Abstract

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Description

Undervoltage tripping device for circuit breaker

1 is a side view showing the negative voltage tripping device according to the present disclosure in a ratchet lock state.

2 is a view of the undervoltage tripping device of FIG. 1 in the direction of arrow II.

3 is a view of the undervoltage tripping device of FIG. 4 viewed from two directions in which angled levers are orthogonal to each other.

5 and 6 show the support for the functional portion of the undervoltage tripping device in two directions perpendicular to each other.

7 shows a bending spring with two parts wound in opposite directions.

8 is a view showing a state in which the undervoltage tripping device according to the present invention is coupled to a low voltage circuit breaker.

The present invention is a ratchet lever which can be driven by a moving core of an electromagnet, an inertial accumulator which can be restrained in a stress-producing state by the ratchet lever, and can be started by an elastic accumulator, and cooperates with a tripping device of a breaker. And an undervoltage tripping device for a circuit breaker, in particular a low voltage circuit breaker, having a drive element for cooperating with a return element operable in relation to the opening and closing position of the breaker.

A conventional undervoltage tripping device is known from, for example, printed sheet GET-2779 D, issued by General Electric. In this case, the elastic accumulator device acts on the push rod guided to enable the linear movement, and the elastic accumulator device can be restrained in a stressed state by the ratchet lever coupled with the movable iron core of the electromagnet. The return lever, which is installed separately, serves to put the elastic accumulator into a stress generating state and to return the movable iron core of the electromagnet to its initial position.

The purpose of this high arm is to reduce the number of parts while maintaining the above functions in the undervoltage tripping device as described above, thereby miniaturizing the dimensions.

The object is that, according to the present invention, the drive element and the return element are configured to be integrated as an angle lever which can be started by the resilient accumulator and swings around the support shaft, and one leg is formed from the breaker. The lever arm, which is the other leg, has a working surface which cooperates with the moving core of the electromagnet and the tripping device of the breaker, and also has a ratchet locking face which cooperates with the ratchet lever. It is achieved by an undervoltage tripping device for a circuit breaker characterized by having. Two elements that were conventionally needed, namely the ratchet lever, the drive element and the return element, are replaced by two elements, one of which fulfills a plurality of functions. The reduction of the number of parts leads to the miniaturization of the dimension of the undervoltage tripping device, thereby expanding its application range.

The angle webber of the undervoltage tripping device may have a transmission element under elastic action for return force transmission. This transfer element compensates for the tolerance between the breaker's switchgear and the undervoltage tripping device so that no adjustment is necessary when the undervoltage tripping device is coupled to a place prepared for the transfer element in the breaker. The transmission element receives a portion exceeding the stroke necessary for the return of the undervoltage tripping device during the movement of the breaker opening and closing mechanism. The transmission element under the action of the elasticity is configured as a return lever supported coaxially with the angle lever, and a transmission spring may be disposed between the angle lever and the return lever. Coaxial support can be realized for example by using a common support pin.

It is advantageous that the return lever is arranged to be movable in the cutout of the window of the angle lever, and in a stationary state, it is advantageously pressed against the stop bottom of the angle lever under the action of the transmission spring. The angle lever and the return lever move together by the presence of the knitting force until the movable core of the electromagnet reaches its end position. Subsequently, if the driving force continues to act on the return lever, the stop bottom falls from the angle lever, and continues the motion irrespective of it.

The ratchet lever which serves to restrain the angle lever and the elastic accumulator in the stressed state may be combined with the movable core of the electromagnet. Coupling here is not a hard coupling, but a mechanical following. This combination provides the advantage of eliminating the pins, links, levers, or the like that are otherwise required. This coupling can be achieved by a bending spring, and as the support portion for the coil of the bending spring, a cylindrical protrusion concentrically arranged on the side with respect to the support shaft of the angle lever can be used.

The mechanically moving part of the known undervoltage tripping device is mainly made of a metallic material. However, when the angle lever and the ratchet lever are made of a suitable synthetic resin, it is advantageous in that a great degree of freedom in the shape can be obtained and the weight can be reduced. In addition, no additional measures to insulate the portion to which voltage is applied are necessary.

Within the scope of the present invention, the ratchet lever is made of thermosetting synthetic resin, and the angle lever is made of thermoplastic synthetic resin, so that the tripping force can be reduced, and further, the reproducibility can be improved. Thermoplastic synthetic resins are subjected to local forces and deform to some extent, but thermosetting synthetic resins do not deform. On the other hand, a kind of pot-shaped portion is formed at the contact point between the ratchet lever and the angle lever, where the ratchet lever can be rotated until it comes out without involving the relative movement of the angle lever. In this way, the ratchet lever and the angled lever are particularly small and evenly subjected to even tripping over several tripping processes.

In order to miniaturize the undervoltage tripping device, two projections, which fix or support an electromagnet, an angle lever, a ratchet lever, and an attached spring to one support, slide into the groove of the breaker's insulated case. It is also advantageous to form. This support can likewise be manufactured as a member integral with a suitable synthetic resin.

In addition, in order to further simplify the undervoltage tripping device, the elastic accumulator and the transfer spring are integrally provided as one bending spring having two legs and a spring arm for coupling both parts and two parts wound in opposite directions. Can be configured.

Hereinafter, the present invention will be described in detail by the embodiments shown in the drawings. The undervoltage tripping device 1 according to the present invention has one support 2 made of a synthetic resin material for all the movable members or all other active members which are constant later. The support 2 has a shape of an approximately right triangle in side views (FIGS. 5 and 6), and is substantially perpendicular to one triangular side thereof, and has a protrusion for attaching the tripping device 1 to the case of the breaker. 8) and (9) protrude. On the other triangular side 3 of the support 2, an electromagnet 6 is attached between the rib 4 and the rib 5, and the electromagnet has a fitting 7, a return spring 11 and a guide. It has the plunger core 10 provided with the pin 12. As shown in FIG. The support 2 and the hole 13 are used to receive the mounting element of the electromagnet 6. The electromagnet 6 is connectable with the voltage source to be monitored by the connecting lead 14. The contact point of the coil winding of the electromagnet 6 and the connection lead 14 is arrange | positioned in the vicinity of the triangular side surface 19 by the both sides 15 and 16 of the support tool 2. As shown in FIG. 1, the solder hole 17 is located in the side surface 16 of the support tool 2. As shown in FIG. Another solder hole 18 is shown on the side surface 15 on the opposite side to FIG. A protective plate 20 is installed in the support tool 2, and the protective plate has dust which may invade the guide pin 12 of the movable core 10 in the direction of the arrow 21 (FIG. 1), Protect from foreign objects or other influences.

In the third triangular side surface 22 on which the projections 8 and 9 protrude, the support tool 2 is comprised in a bifurcated form in order to form a support part in the range of both edges. In this case, the bifurcated arms 23, 24 having holes drilled in a straight line serve to support the angle lever 25 and the return lever 26 on the support pin 27 in common. The two arms 28 and 30 serve to support the latch lever 31 on the support pins 32, and at the same time, holes are formed in a straight line to receive the support pieces. . The latch lever 31 is made of a molding material mainly composed of a thermosetting synthetic resin, for example, a polyester resin. On the other hand, the angle lever 25 is made of thermoplastic synthetic resin.

One leg 35 of the angle lever, through which the support holes 33 and 34 are drilled, has side walls 36, 37 and a window-shaped hole 38 in which the return lever 26 Exercise is possible. The side wall 36 has a support portion 40 for supporting the legs of the bending spring 41 (FIG. 7) therein, and the ratchet lever 31 is electromagnet concentrically with respect to the support hole 34. It has the cylindrical projection 42 as a support part of the coil of the other bending spring 43 which serves to engage with the plunger core 10 of (6). The support part 40 acts as an operating surface for introducing a return force into the angle lever 25 as described later.

The other leg 44 of the angle lever 25 extends substantially on the extension of the side wall 37 of the leg 35, and forms an angle of about 60 ° to this. At its front end, the leg 44 is bent to contact the end face 46 of the plunger core 10. The ratchet locking face 47 which acts in common with the ratchet lever 31 is located near the position where the leg 35 of the angle lever 25 moves to the other leg 44. This ratchet lever has a cylindrical portion 48 arranged concentrically about its support axis, which is angled. In addition, the ratchet lever 31 has a cam 51 as a supporting portion of the leg 52 of the bending spring 43, and the bending spring surrounds the cylindrical protrusion 42 of the angle lever 25 with a plurality of coils. It piles up and is supported by the support tool 2 by the other leg 53. As shown in FIG. The bending spring 43 serves to connect the ratchet lever 31 to the end face 46 of the plunger iron core 10 at its working surface 54 at all times.

The bending spring 41 (see FIG. 7) incorporates two parts 55, 56 with coils wound in opposite directions. In addition, these portions 55 and 56 have legs 60 and 61. The coiled portion 55 acts as an elastic accumulator, while the coiled portion 56 forms an effective return spring upon return.

In particular, in the assembled state as shown in FIG. 2, the bending spring 41 contacts the return lever 26 with the spring arm 57, while one leg 60 is supported by the support tool 2. The other leg 61 is supported by the support part 40 of the angle lever 25. Since the winding direction is different from the portion 55 having the coil and the winding direction at 56, and the number of windings is different, the angle lever (1) is in the direction of the stopper 62 of the protrusion 9 of the support 2 on one side. The knitting force is applied to 25), and the knitting force is applied to the return lever 26 toward the angle lever 25 so that the return lever 26 is in contact with the stopper surface 63 on the other side. The spring force is such that when the return force is applied on the operating surface 64 of the return lever 26, the angle lever 25 faces the plunger core 10 against the return spring 11 on the operating surface 45 thereof. It is selected so that a relative motion between the return lever 26 and the angle lever 25 does not occur until the return is terminated at the end position restricted by the stopper. During this relative movement, the support portion 40 of the angle lever 25 acts as an operating surface of the return force transmitted by the bending spring 41.

If the part of the breaker acting on the operating surface 64 then moves, the return lever 26 is released from the angle lever 25 at the stopper surface 63, and regardless of this, the circumference of the common support portion is continued. Move. 1 and 2 show the state of movement of the undervoltage tripping device 1, the electromagnet 6 is excited and the plunger core 10 is covered. The angle lever 25 supports the ratchet locking face 47 on the cylindrical portion 48 of the ratchet lever 31. In this way, the angle lever 25 under the operating state passes through the portion 55 having the coil of the bending spring 41 serving as the elasticity measuring device. Since the angle lever is adjacent to the electromagnet 6 while maintaining a constant distance, the return spring 11 of the plunger iron core 10 on the ratchet lever 31 is the latching force acting on the bending spring 43. The lever 31 acts until the end of the rotation, thus sliding off the ratchet locking face 47 of the angle lever 25 retreating from the cylindrical portion 48 of the ratchet lever 31. For this reason, the retracting angle lever 25 suddenly is released and rotates counterclockwise as shown in FIG. As the supporter 2 releases the stopper 62 of the projection 9, it limits the rotational movement. The leg 44 of the retracting angle lever 25 makes the leg of the power switch operable by the operating surface 65. In FIG. 8, the undervoltage tripping device 1 is shown together with the adjacent part of the low voltage circuit breaker to explain the trip and return process. The breaker has an insulating case 70, and the opening / closing shaft 71 insulated therein is rotatably supported, and the opening / closing support 72 is fixed on this shaft extending in the adjacent chamber of the insulating case. The opening and closing piece which can be perforated is attached to this support, and the movable opening / closing piece 73 is partially shown in FIG. The opening and closing shaft 71 for opening and closing is known per se, and is thus driven by an opening and closing mechanism not shown. This opening and closing mechanism is usually provided with a boost lever device, a tension spring acting on the boost link, and an open / close lever covered with an insulated operating handle.

One force lever is supported by the main ratchet which can be restrained by the trip side 74. All tripping devices mounted on the breaker, for example, bimetal tripping devices, an electronic tripping device in which the movable core 75 is indicated in FIG. 8, and the undervoltage tripping device 1 act on the trip shaft.

In the illustrated position, the electromagnet 6 is excited and the plunger core 10 is attracted. As a result, the angle lever 25 is bound by the ratchet lever 31 while the elastic accumulator (part 55 of the bending spring 41 is in a stress generating state). When the excitation of the electromagnet 6 falls below the value required for the support of the plunger core 10, the angle lever 25 is released as described above.

At this time, the angular moving surface 65 of the angle lever 25 collides with the lever arm 76 of the trip shaft 74, whereby the trip shaft 74 is rotated counterclockwise to FIG. The main ratchet of the breaker is released. Thereafter, the opening and closing shaft 71 is rotated clockwise under the influence of the elasticity accumulated in the opening and closing mechanism, and the movable opening and closing piece 73 is disengaged from the fixed opening and closing piece corresponding thereto. At this time, the angle lever 25 is pressed against the end face 46 of the plunger core 10 at its working surface 45 by the cooperative action of the opening and closing piece support 72 and the return lever 26. . At this time, the return spring 11 of the plunger iron core 10 and the portion 55 of the bending spring 41 serving as an elastic accumulator are stressed relatives. Since the ratchet lever 31 is coupled by the bending spring 43, the ratchet lever 31 follows the movement of the plunger core 10. In the course of this return movement, the ratchet locking face 47 of the angle lever 25 is pushed beyond the angle 50 of the ratchet lever 31, whereby the angle lever 25 is the elastic accumulator in a pressure generating state. Newly bound by However, this restraint is connected only when the excitation of the electromagnet 6 sufficient to support the plunger core 10 is performed again at the same time, that is, when there is a sufficient electric via again. In other cases, the breaker does not close again.

As described above, the return lever 26 compensates the tolerance between the movement of the opening and closing mechanism and the angle lever 25. That is, the return spring 26 swings around the common support portion [support pin 27] of the angle lever and the return lever even after the ratchet locking position is reached against the elasticity of the portion 56 of the bending spring 41. You can. Therefore, it is not necessary to make an adjustment when the undervoltage tripping device is coupled to the case 70 of the breaker.

As can be easily understood, the present invention can also be carried out by changing the size and shape of each part. In particular, the length and angle of both legs of the angle lever, the strength of the spring and the shape of the support are adapted to the circuit breaker to which the undervoltage tripping device should be mounted. At this time, there is also an advantageous way to make the support different from the triangle. Instead of the plunger core electromagnet, an electromagnet of any structure may be used as long as it is suitable for the undervoltage tripping device. In addition, even if the angle lever 25 and the ratchet lever 31 cooperate with each other, even if the range which acts directly on these members, ie, the ratchet locking face 47 and the cylindrical contact surface 48, is produced from the material according to the present invention, Similarly, it is performed well. This can be performed, for example, by inserting a part made of a material according to the present invention into a lever body made of another material.

Claims (1)

The ratchet lever which is driven by the plunger iron core of the electromagnet, the elastic accumulator which can be restrained in the stress-producing state by the ratchet lever, and the starter can be started by the elastic accumulator, and in the opening and closing position of the breaker In a circuit breaker having a drive element for cooperating with a return element operable in a relationship, in particular a low voltage tripping device for a low voltage circuit breaker, the drive element and the return element are provided by the resilient accumulator 55. It is startable and is integrally formed as an angle lever 25 swinging the circumference of the support pin 27, and one leg 35 has an operating surface 64 which serves to introduce a return force generated in the breaker. A lever arm, the other leg 44, has a working surface 45 which cooperates with the movable iron core 10 of the electromagnet 6 and the tripping devices 74, 76 of the breaker, and also ratchets. Weber (31) Undervoltage tripping device for a circuit breaker, characterized in that it has a ratchet chain face 47 cooperating with the.