KR101824004B1 - Arc extinguish device for circuit breaker - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a circuit breaker of a circuit breaker. According to the present invention, an arc runner for transferring an arc generated between a stationary contactor and a movable contact to an arc chamber direction is formed on at least one of a plurality of grids, so that the arc runner can be easily formed, And it is possible to increase the melting point of the arc runner to improve the durability against burnout.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a circuit breaker,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a circuit breaker for a wiring breaker, and more particularly to a circuit breaker of a circuit breaker for eliminating an arc generated when a short circuit current is generated.

The arc in the circuit breaker occurs when a short-circuit current occurs when the power-side contact terminal (hereinafter referred to as the fixed contact) and the movable-side contact terminal (hereinafter referred to as the movable contact) are disconnected and is caused by the inertia of the current at the contact between the two contacts .

A commonly used SOHO apparatus includes a V-shaped magnetic plate called a grid, which is housed in several layers at appropriate intervals in an arc chamber, which is a flameproof insulating plate, to move the arc to the end of the grid to cool the arc, The arc is divided into a short arc and a short arc.

The stationary contactor is provided with an arc runner for quickly transferring the arc to the arc chamber direction. The arc runner is fastened to the fixed contact by using rivets or screws.

Fig. 1 shows the internal structure of a conventional wiring breaker. In the wiring breaker, a stationary contactor 1 and a movable contactor 2 for receiving power from a converter and transmitting the load to the load contactor, A detection mechanism section 4 for detecting an abnormal current such as a short circuit current and the like for detecting a detection signal of the detection mechanism section 4 to a link mechanism section 3, And a small-diameter portion 6 for suppressing the arc generated when the stationary contactor 1 and the movable contactor 2 are opened. The stationary contactor 1 and the movable contactor 2 are provided with a fixed contact 11 and a movable contact 21 which are in contact with or separated from each other.

The arc extinguishing unit 6 includes an arc chamber 61 having a predetermined internal space and a plurality of grids 62 housed at an appropriate interval in a vertical direction in the arc chamber 61 at an appropriate interval.

When a current exceeding the rated current is applied to the circuit breaker in the closed state for the wiring breaker, the detection mechanism section 4 detects the abnormal current, and the attracting force is generated by the principle of the electromagnet, . When the armature 7 is sucked, the crossbar 5 rotates and the link mechanism 3, which has been restrained by the crossbar 6 at this time, is released from the constraint of the crossbar 5, (2) and the stationary contactor (1).

When the stationary contactor 1 and the movable contactor 2 are opened, the converter is switched to the open state to prevent the abnormal current from being continuously energized. When the stationary contactor 1 is opened from the movable contactor 2, . The generated arc stays between the movable contactor 2 and the stationary contactor 1 in an initial state, which is referred to as an arc-contact state.

The applied arc is moved toward the arc chamber 61 of the soot portion 6 by the electromagnetic driving force generated as the distance between the movable contact 2 and the fixed contact 1 increases and the arc chamber 61 And is completely extinguished at the zero point of the current to be in the closed state of the current.

In the above-described conventional wiring breaker, an arc runner 8 for rapidly transferring an arc to the arc chamber direction is separately manufactured as shown in FIG. 2 and is fastened to the stationary contactor 1 by a rivet or a screw, or the arc runner 9 Is formed integrally with the stationary contactor 1 as shown in Fig.

However, when the arc runner 8 is separately manufactured and assembled to the stationary contactor 1, a separate assembling process must be added, resulting in an increase in manufacturing cost.

When the arc runner 8 is formed integrally with the stationary contactor 1, the arc runner 8 is formed of a copper-based material having a low melting point, such as the stationary contactor 1, There is a problem that the deep-sea durability is deteriorated.

SUMMARY OF THE INVENTION An object of the present invention is to provide a wiring breaker which can easily form an arc runner to reduce manufacturing costs.

Another object of the present invention is to provide a wiring breaker capable of increasing durability by forming an arc runner on a member having a high melting point.

In order to accomplish the object of the present invention, there are provided a fixed contact and a movable contact for receiving power from a converter and transmitting the power to the load side; An arc chamber provided on one side of the stationary contactor; And a plurality of grids stacked on the arc chamber to extinguish an arc, wherein at least one of the plurality of grids is provided with an arc runner portion corresponding to the stationary contactor, and is generated between the stationary contactor and the movable contactor There is provided an arc extinguisher for a circuit breaker for transferring an arc in the direction of the arc chamber.

Here, a portion of the grid may be bent to form the arc runner portion.

And a grid on which the arc runner part is formed is secured to the arc chamber and fixed to the arc chamber; An arc runner portion extending between the fixing portions; And an extended contact portion bent toward the stationary contactor such that an end of the arc runner portion is in contact with an upper surface of the stationary contactor.

And a grid on which the arc runner part is formed is secured to the arc chamber and fixed to the arc chamber; An arc runner portion extending between the fixing portions; And an extended contact portion protruding in the direction of the fixed contact so that one side of the arc runner portion is in contact with the upper surface of the fixed contactor.

The grid on which the arc runner is formed may be formed thicker than other grids.

And a grid on which the arc runner part is formed is secured to the arc chamber and fixed to the arc chamber; An arc runner portion extending between the fixing portions; And an extended contact portion protruding in the direction of the stationary contactor to be brought into contact with the upper surface of the stationary contactor on one side of the arc runner and assembled by separate fastening means.

The arc furnace unit for transferring the arc generated between the stationary contactor and the movable contactor in the direction of the arc chamber is formed on at least one of the plurality of grids, The manufacturing cost can be reduced and the melting point of the arc runner can be increased to enhance the durability against burnout.

1 is a schematic view showing the internal structure of a conventional wiring breaker,
Fig. 2 is a perspective view for explaining an example of an arc runner in the wiring breaker according to Fig. 1,
Fig. 3 is a perspective view for explaining another example of an arc runner in the circuit breaker according to Fig. 1,
4 is a perspective view for explaining an example of an arc runner in the circuit breaker of the present invention,
FIG. 5 is a longitudinal sectional view showing an example of the arc runner according to FIG. 4,
Figs. 6 to 8 are perspective views respectively showing other examples of the arc runner according to Fig. 4. Fig.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a circuit breaker of a circuit breaker according to the present invention will be described in detail with reference to an embodiment shown in the accompanying drawings.

FIG. 4 is a perspective view illustrating an example of an arc runner in the circuit breaker of the present invention, and FIG. 5 is a longitudinal sectional view showing an example of the arc runner according to FIG.

1, a wiring breaker according to the present invention includes a fixed contact 1, a movable contact 2, a link mechanism 3, a detection mechanism 4, a cross bar 5, (6) and the like.

4, the arc extinguishing unit 6 includes an arc chamber 61 having a predetermined internal space, a plurality of grids 62 housed diagonally at appropriate intervals along the vertical direction in the arc chamber 61, Lt; / RTI >

The arc chamber 61 is formed with a plurality of grid mounting slits 611 forward (the movable contactor direction is referred to as front) and rearward along the vertical direction. An arc discharge port (not shown) is formed at the rear of the arc chamber 61 or is open at the same time, and both upper and lower ends are opened. The stationary contactor 1 is disposed below the arc chamber 61. And is inserted into the contact end of the stationary contactor 1 by a predetermined depth in front of the arc chamber 61.

Here, the fixed contact 11 is welded to the contact end of the fixed contact 1 so as to selectively contact the movable contact 21 of the movable contact 2. The stationary contact 11 must be in complete contact with the movable contact point 21 to provide a safe circuit, reduce the contact resistance at the time of energization to reduce the heat generation, and completely block the current when it is closed. For this purpose, it is preferable that the stationary contact 11 has low contact resistance, wear resistance and weldability.

One side of the contact end of the stationary contactor 1, that is, one side of the stationary contact 11, is formed by a length that can be overlapped with the arc runner portion 628 which will be described later. Conventionally, an arc liner is fastened to one side of the stationary contact. However, since an arc liner is not separately provided in this embodiment, one side of the stationary contact may be flat.

The grid 62 may be divided into a plurality of small grids (hereinafter referred to as a first grid) 621 and at least one or more arc liner grids (hereinafter referred to as a second grid) 625. Of course, the second grid 625 also serves to extinguish the arc, but is divided into a grid for an arc runner because it additionally has a role of transferring an arc from the stationary contact 1 toward the arc chamber.

The first grid 621 is located on the upper side of the second grid 625 and the second grid 625 is installed on the lower side of the first grid 621, that is, closest to the fixed contact 1 .

The first grid 621 is formed of a ferromagnetic material. The rear end of the first grid 621 protrudes from the rear end of the first grid 621 so as to be inserted into the grid mounting slit 611 of the arc chamber 61 and extends in the forward direction of the receiving protrusion 622 A fixed portion 623 is formed to be inserted into and fixed to the arc chamber 61 and a space portion 624 is formed in a V shape toward the rear side between the fixed portions 623.

The second grid 625 is formed of a ferromagnetic plate similar to the first grid 621. The rear end of the second grid 625 protrudes from the rear end of the second grid 625 so as to be inserted into the grid mounting slit 611 of the arc chamber 61 and extends in the forward direction of the receiving protrusion 626 A fixed portion 627 is formed to be inserted into and fixed to the arc chamber 61 and an arc liner portion 628 is formed between the fixed portion 627 and the fixed contactor 62 so as to correspond to the upper surface of the stationary contactor 1, Is formed.

4 and 5, the second grid 625 may have the same thickness and size as the first grid 621. The arc liner portion 628 is formed to extend by a length that can overlap with the contact end of the stationary contactor 1 and corresponds to the upper end of the contact end of the stationary contactor 1 An extended contact portion 629 may be formed. The extended contact portion 629 may be bent toward the upper surface of the stationary contactor 1 such that the end of the arc runner portion 628 contacts the upper surface of the stationary contactor 1. [

In the drawings, the same reference numerals are given to the same parts as those in the prior art.

The circuit breaker of the circuit breaker according to the present invention has the following operational effects.

That is, when an abnormal current which is several tens times the rated current flows through the circuit breaker in the closed state, the detection mechanism section 4 senses the abnormal current and generates a suction force by the principle of the electromagnet and the attractor 7 causes the armature 7 to rotate at a high speed And is sucked. When the armature 7 is sucked, the link mechanism portion 3 which has been restrained in the closed state while the cross bar 5 is rotated by the operation is released from the constraint of the cross bar 5 and the movable contact 2 1), the converter is switched to the open state to prevent the abnormal current from being continuously energized.

Here, an arc is generated in the process of opening the stationary contactor 1 from the movable contactor 2. The generated arc stays between the stationary contactor 1 and the movable contactor 2 in the initial state and the arc is generated by the electromagnetic driving force as the distance between the movable contactor 2 and the stationary contactor 1 increases 6 to the arc chamber 61 side. And the arc moving into the arc chamber is cooled and cut between the grids 62 stacked in the arc chamber 61 to be completely extinguished at the zero point of the current.

The second grid 625 adjacent to the fixed contact 1 among the grids 621 and 625 stacked in the arc chamber 61 is provided with an arc runner 628 for transferring the arc to the arc chamber 61 The arc that stays between the stationary contactor 1 and the movable contactor 2 quickly moves to the arc chamber 61 and is extinguished.

When the above-mentioned arc runner is separately manufactured and assembled to the stationary contactor, the assembly process is added to increase the manufacturing cost. When the arc runner is integrally formed in the stationary contactor, the melting point of the arc runner is low, And the durability could be lowered.

However, since the arc liner portion 628 is formed integrally with the second grid 625 as in the present embodiment, it is not necessary to separately fabricate the arc runner, so that the manufacturing process can be simplified and the manufacturing cost can be reduced , The durability of the arc liner can be improved as the melting point of the arc liner is increased and there is less risk of burning.

Meanwhile, another embodiment of the arc runner in the arc extinguisher of the circuit breaker according to the present invention is as follows.

That is, in the above-described embodiment, the second grid is formed to have the same thickness as the first grid and the extended contact portion is bent at the end of the arc runner provided in the second grid. In this embodiment, The arc liner portion 628 is extended so as to correspond to the upper surface of the contact end of the stationary contactor 1 and the bottom surface of the extended arc runner portion 628 is connected to the contact end upper surface of the stationary contactor 1 May be formed to have a thicker thickness t than other portions.
7, the entirety of the second grid 625 may be thicker than the first grid 621, that is, the thickness of the arc liner 628 may correspond to the fixed contact 1 t < / RTI >

Even when the arc liner portion 628 is formed by using the thickness of the second grid 625 as described above, the basic structure and the operation and effect of the arc liner portion 628 are similar to those of the above embodiment. However, in the case of this embodiment, the arc liner portion 628 can be formed without bending a part of the second grid 625, unlike the above-described embodiment, so that the fabrication of the second grid is simplified compared to the above- And the surface area of the arc runner portion 628 can be adjusted.

8, the arc liner portion 628 may be separately manufactured, and the arc contact portion 629 may be formed on the second grid, so that the arc liner portion 628 may be assembled to the extended contact portion 629. In this case, since the extension contact portion must be separately formed in the arc runner portion, the manufacturing cost can be increased as compared with the above-described embodiments, but a material having a high melting point can be used as compared with the case of assembling the arc runner to the stationary contactor Durability can be improved. In addition, since the separate extended contact portion is not integrally formed in the arc runner portion of the second grid, the second grid can be easily manufactured and the surface area of the arc runner portion can be adjusted.

1: fixed contact 11: fixed contact
2: movable contactor 21: movable contact
6: Loop 61: Arc chamber
621: first grid 625: second grid
626: storage protrusion 627:
628: arc runner part 629: extension contact part

Claims (6)

A fixed contact and a movable contact for receiving power from a converter and transmitting the power to the load side;
An arc chamber provided on one side of the stationary contactor; And
And a plurality of grids stacked on the arc chamber to extinguish the arc,
Wherein a grid closest to the fixed contact among the plurality of grids is a grid,
A fixing unit that is seated and fixed to the arc chamber; And
And an arc runner portion extending between the fixed portions and transferring an arc generated between the stationary contactor and the movable contactor to the arc chamber,
One end of the arc runner portion extends integrally from the grid and the other end of the arc runner portion extends toward the fixed contactor and contacts the upper surface of the fixed contactor so that both ends of the arc runner portion are connected to the grid and the fixed contactor, Wherein the circuit breaker has a circuit breaker. delete The method according to claim 1,
And an extended contact portion in which an end of the arc runner portion is bent toward the stationary contactor. The method according to claim 1,
And an extended contact portion integrally formed so that one side of the arc runner protrudes toward the stationary contactor. The arc generator according to claim 1,
Wherein the entire grid is formed thicker than the other grids. The method according to claim 1,
And an extended contact portion which is assembled to one side of the arc runner portion by another fastening means so as to protrude toward the stationary contactor.

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