KR102508804B1 - Magnetic blow out device for direct current breaker - Google Patents

Abstract

The present invention provides a self-extinguishing device for a DC circuit breaker. The self-extinguishing device for the DC circuit breaker includes a fixed contact portion; a movable contact part that is rotated to be in contact with or separated from the fixed contact part; a coil part disposed behind the movable contact part and connected to the first auxiliary contact part and the second auxiliary contact part; and a first body in which the coil unit is installed, and a pair of second bodies extending parallel to each other at both ends of the first body to be located on both sides of an arc generating region between the movable contact part and the fixed contact part. and a core part, wherein the first auxiliary contact part of the coil part is connected to the fixed contact part, and the second auxiliary contact part is connected to one side surface of the movable contact part in a state where the movable contact part is separated from the fixed contact part. do.

Description

Magnetic extinguishing device for DC circuit breakers {MAGNETIC BLOW OUT DEVICE FOR DIRECT CURRENT BREAKER}

The present invention relates to a self-extinguishing device for a DC circuit breaker, and more particularly, to a self-extinguishing device for a DC circuit breaker capable of efficiently extinguishing an arc generated when a main current is opened even at a rated current or less.

In general, when a fault current occurs in a direct current (DC) line, research on a DC circuit breaker for immediately blocking it is being continuously conducted.

In particular, DC breakers in high-voltage HVDC systems combine very fast mechanisms and power electronics to cut off the power flow of large-scale power plants in 5/1000th of a second.

Since this direct current (DC) current flows at a constant level unlike alternating current (AC) current, the fault current does not become a zero point by itself when a short circuit fault occurs in the load, so the DC breaker controls the flow of fault current through high arc current. Therefore, it has a disadvantage that it is relatively difficult to block compared to the fault current of alternating current.

Disclosed is a conventional DC circuit breaker that instantly reduces a fault current immediately before blocking by using magnetic field switching.

In particular, since DC has no current zero point, an arc may exist even after contact opening. At more than the rated current, the arc can be moved to the arc shoe with the magnetic field generated at the main contact point to block it, but in the low current (less than 400A) region, the generated magnetic field is not large, so the arc cannot be moved effectively.

In other words, the DC circuit breaker, in spite of its advantages of low induced disturbance of DC current, high circuit stability, and high power transmission efficiency, does not sufficiently control the arc current and continues to allow the fault current of DC current, resulting in a large-scale fire accident. There are possible problems.

In order to solve this problem, a technique of applying an arc extinguishing device to a DC circuit breaker has been proposed.

In this case, at least one pair of magnets are disposed with the switch interposed therebetween to increase resistance to the arc current so as to block the arc current.

However, in the case of a high-voltage DC circuit breaker, since arc current is generated by high current, the volume of the magnet must be increased to increase the resistance to the arc current, and there is a limit to increasing the size of the resistance. There is a problem with being late.

As prior literature related to the present invention, there is Republic of Korea Patent Publication No. 10-2014-0036111 (published date: March 25, 2014), and in the prior literature, a technology for an arc extinguishing mechanism of a DC switch is disclosed.

An object of the present invention is to provide a self-extinguishing device for a DC circuit breaker capable of efficiently extinguishing an arc generated when the main current is opened even at a rated current or less.

In addition, the present invention is to provide a self-extinguishing device for a DC circuit breaker that can easily cut off arc extinguishing in a low current region.

In a preferred embodiment, the present invention provides a self-extinguishing device for a DC circuit breaker.

The self-extinguishing device for the DC circuit breaker includes a fixed contact portion; a movable contact part that is rotated to be in contact with or separated from the fixed contact part; a coil part disposed behind the movable contact part and connected to the first auxiliary contact part and the second auxiliary contact part; and a first body in which the coil unit is installed, and a pair of second bodies extending parallel to each other at both ends of the first body to be located on both sides of an arc generating region between the movable contact part and the fixed contact part. It includes; a core part to be.

The first auxiliary contact part of the coil unit is connected to the fixed contact part, and the second auxiliary contact part is connected to one side surface of the movable contact part in a state where the movable contact part is separated from the fixed contact part.

Preferably, when the second auxiliary contact unit is connected to one side of the movable contact unit, main circuit power is transmitted to the coil unit.

The second auxiliary contact part includes a second auxiliary contact disposed on a rotation path of the movable contact part and a second connection line connecting the second auxiliary contact point and the coil part, the second auxiliary contact point, It is preferable to contact one side of the movable contact part.

It is preferable that a pair of magnetic field induction plates formed to face each other are provided at an upper end of the pair of second bodies.

Preferably, each of the pair of magnetic field induction plates includes a neck extending upward from an end of the pair of second bodies, and an amplifying plate formed at an upper end of the neck.

The second auxiliary contact is formed in a roller shape, and is preferably in rolling contact with one side of the movable contact part.

The present invention has an effect of efficiently extinguishing an arc generated when the main current is opened even at a rated current or less.

In addition, the present invention has an effect of facilitating and blocking arc extinguishing in a low current region.

1 is a perspective view showing the configuration of a self-extinguishing device for a DC circuit breaker according to the present invention in the present main circuit input state.
2 is a perspective view showing the configuration of a self-extinguishing device for a DC circuit breaker of the present invention when an abnormal current occurs.
3 is a plan view showing the configuration of a self-extinguishing device for a DC circuit breaker of the present invention when an abnormal current occurs.
4 is a side view showing the configuration of a self-extinguishing device for a DC circuit breaker of the present invention when an abnormal current occurs.
5 is another perspective view showing the configuration of a self-extinguishing device for a DC circuit breaker of the present invention when an abnormal current occurs.
6 is another perspective view showing the configuration of a self-extinguishing device for a DC circuit breaker of the present invention when an abnormal current occurs.
7 is another perspective view showing the configuration of a self-extinguishing device for a DC circuit breaker of the present invention when an abnormal current occurs.
8 is a perspective view showing a state of a self-extinguishing device for a DC circuit breaker according to the present invention in a main circuit input state.
9 is a perspective view showing a state of the self-extinguishing device for a DC circuit breaker of the present invention in an open state of the main circuit.
10 is a plan view showing a state of a self-extinguishing device for a DC circuit breaker according to the present invention in a main circuit input state.
11 is a plan view showing a state of a self-extinguishing device for a DC circuit breaker of the present invention in an open state of the main circuit.

Hereinafter, the configuration of the self-extinguishing device for a DC circuit breaker of the present invention will be described with reference to the accompanying drawings.

1 is a perspective view showing the configuration of a self-extinguishing device for a DC circuit breaker according to the present invention when the main circuit is turned on, and FIG. 2 is a perspective view showing the configuration of the self-extinguishing device for a DC circuit breaker according to the present invention when an abnormal current occurs.

1 and 2, the self-extinguishing device for a DC circuit breaker of the present invention largely includes a fixed contact part 100, a movable contact part 200, a coil part 300, a core part 400, and a first , 2 includes auxiliary contact parts 510 and 520.

Hereinafter, each configuration and arrangement state will be described. For other configurations, FIGS. 3 to 7 will be added.

fixed contact (100)

1 to 4, the fixed contact portion 100 according to the present invention is disposed in a fixed state along one direction.

Movable contact (200)

The movable contact part 200 according to the present invention is disposed on one side of the fixed contact part 200 and is composed of a member having a length along the top and bottom.

In addition, one side of the upper end of the movable contact part 200 is in contact with one side of the fixed contact part 100, and an operation of being in contact with or separated from one side of the fixed contact part 100 through rotation may be performed.

That is, the movable contact part 200 can achieve an energized state (inserted state) in a state of being in contact with the fixed contact part 100, and can achieve an open state in a state of being rotated to be separated from the fixed contact part 100.

Coil part 300

The coil part 300 according to the present invention is disposed behind the movable contact part 200 and is connected to the first auxiliary contact part 510 and the second auxiliary contact part 520 . The configuration of the first auxiliary contact unit 510 and the second auxiliary contact unit 520 will be described later.

Core part (400)

The core part 400 according to the present invention is composed of a first body 410 and a pair of second bodies 420.

The first body 410 is disposed behind the movable contact part 200 and the coil part 300 is installed.

The pair of second bodies 420 are parallel to each other at both ends of the first body 410 and extend to be located on both sides of the arc generation area between the movable contact part 200 and the fixed contact part 100. do.

Therefore, the core part 400 may be formed in a shape in which a space is formed inside as a whole.

Also, both sides of the movable contact part 200 are located between the pair of second bodies 420 .

In addition, a pair of magnetic field induction plates 430 are formed to face each other at an upper end of the pair of second bodies 420 .

One end of each of the pair of magnetic field induction plates 430 has a neck 431 extending upward from the end of the pair of second bodies 420, and an amplification plate formed on top of the neck 421. (432).

Here, one end of the amplification plate 432 extends along the side of the first body 410, and the other end of the amplification plate 432 protrudes along the opposite direction of the first body 410. do.

The first auxiliary contact unit 510 according to the present invention is connected to the fixed contact unit 100 .

The first auxiliary contact portion 510 is composed of a first auxiliary contact point 511 and a first connection line 512 .

The first auxiliary contact 511 is installed on one side of the fixed contact part 100 . The first connection line 512 connects the first auxiliary contact 511 and the coil unit 300 .

And, the second auxiliary contact portion 520 is configured to be connected to one side of the movable contact portion 200 in a state in which the movable contact portion 200 is spaced apart from the fixed contact portion 100 .

The second auxiliary contact part 520 connects the second auxiliary contact 521 disposed on the rotation path of the movable contact part 200 and the second auxiliary contact 521 and the coil part 300. It is composed of a second connection line 522.

The second auxiliary contact 521 is disposed on a rotation path of the movable contact 200 at one side of the movable contact 200 .

And, the second connection line 522 is configured to connect the second auxiliary contact 521 and the coil part 300 .

Here, the second auxiliary contact 521 may be in contact with one side of the movable contact part 200 .

That is, the second auxiliary contact 521 is disposed on the rotation path of the movable contact 200, and one side surface of the movable contact 200 only when the movable contact 200 is rotated to be separated from the fixed contact 100. placed in a position in contact with

The second connection line 522 may be fixed so that the position of the second auxiliary contact 521 is maintained.

Also, the first and second connection lines 512 and 522 are preferably formed of metal pieces capable of maintaining their original shapes.

Therefore, when the movable contact part 200 and the second auxiliary point 522 are repeatedly contacted, the second connection line 521 is deformed due to the repeated contact and cannot be contacted with one side of the movable contact part 200. Defects caused by this can be resolved.

Also, the second auxiliary contact 521 is formed in a flat shape, and may be electrically connected to the movable contact part 200 by being in surface contact with one side surface of the movable contact part 200 .

Meanwhile, although not shown in the drawing, the second auxiliary contact according to the present invention may be formed in a roller shape.

In this case, the roller-shaped auxiliary contact may come into rolling contact with one side of the pivoting movable contact part 200 . Therefore, stable contact can be achieved.

Next, with reference to the above configuration, the action of the self-extinguishing device for a DC circuit breaker according to the present invention will be described.

Main circuit input state

8 is a perspective view showing a state of the self-extinguishing device for a DC circuit breaker of the present invention in a state of being turned on to the main circuit, and FIG.

Referring to FIGS. 8 and 9 , in a state in which the main circuit power is turned on, the movable contact part 200 is in an upright state and forms a state in contact with one side of the upper end of the fixed contact part 100 .

Therefore, an energization state can be achieved by forming an energization path (arrow) through the movable contact portion 200 and the fixed contact portion 100 that are in contact with each other.

At this time, the first auxiliary contact 511 connected to the coil unit 300 through the first connection line 512 comes into contact with one side of the fixed contact unit 100 .

Here, the second auxiliary contact 521 connected to the coil unit 300 through the second connection line 522 is spaced apart from one side of the movable contact unit 200 in a state before rotation.

Accordingly, since the second auxiliary contact 521 connected to the coil unit 300 is not in contact with the movable contact unit 200 in the main circuit input state, a closed circuit is not formed and power is supplied to the coil unit 300. not supplied

main circuit open state

10 is a perspective view showing a state of the self-extinguishing device for a DC circuit breaker of the present invention in an open state of the main circuit, and FIG. 11 is a plan view showing a state of the self-extinguishing device for a DC circuit breaker of the present invention in an open state of the main circuit.

Referring to FIGS. 10 and 11 , in the state shown in FIGS. 8 and 9 , when an abnormal current is generated, the main circuit power is opened.

In a state where the main circuit power is opened, the movable contact part 200 is rotated to be spaced apart from one side of the upper end of the fixed contact part 100.

Therefore, the upper end of the movable contact part 200 and one end of the fixed contact part 100 form a predetermined gap G with each other.

Also, an arc is generated in an arc generating region between the gap G, that is, between the movable contact part 200 and the fixed contact part 100.

At the same time, the first auxiliary contact 511 connected to the coil unit 300 through the first connection line 512 comes into contact with one side of the fixed contact unit 100 .

In addition, the second auxiliary contact 521 connected to the coil unit 300 through the second connection line 522 is brought into contact with one side surface of the movable contact unit 200 that is rotated.

Accordingly, when connected to one side of the movable contact part 200 through the second auxiliary contact 521 , main circuit power is transmitted to the coil part 300 .

Therefore, the coil part 300 generates a magnetic field, and the second auxiliary contact 521 is in contact with one side of the movable contact part 200, thereby enclosing the area where an arc is generated, that is, the area where the gap G is formed. A magnetic field (arrow) is formed in the region.

At this time, the magnetic field is formed in a region surrounded by the core part 400 according to the present invention.

Also, an arc generated due to the separation between the fixed contact part 100 and the movable contact part 200 is guided upward by a pair of magnetic field induction plates 430 included in the core part 400 . Here, an arc chute (not shown) is preferably disposed above the pair of magnetic field induction plates 430 .

Accordingly, the arc generated in the gap G region can be easily moved toward the arc chute.

Meanwhile, the above-described first auxiliary contact 511 and the second auxiliary contact 521 are connected to the coil unit 300 through first and second connecting lines 512 and 522 that are metal pieces having elasticity. good night.

In addition, although not shown in the drawing, the second auxiliary contact 522 may be formed in a roller shape and electrically connected to the movable contact 200 by rolling in contact with one side of the movable contact 200. .

In this case, although not shown in the drawings, the second auxiliary contact point 521 is configured to roll in a roller shape, and is spaced apart from one side of the movable contact part 200 that is rotated so that there is no contact and a problem occurs during contact. Contact defects can be solved in advance by mitigating the impact.

According to the configuration and operation as described above, the embodiment according to the present invention has the advantage of simplifying the device configuration by not requiring an external power source configuration using the main circuit power source.

In addition, the embodiment according to the present invention has the effect of reducing the operating time delay rather than using an external power source.

In addition, the embodiment according to the present invention has an effect of efficiently extinguishing the arc generated when the main current is opened even at a rated current or less.

In addition, the embodiment according to the present invention has the advantage of being able to easily block low current (400A or less) arc extinguishing and medium current (400A or more) arc extinguishing.

In the above, specific embodiments of the self-extinguishing device for a DC circuit breaker of the present invention have been described, but it is obvious that various modifications are possible within the limits that do not deviate from the scope of the present invention.

Therefore, the scope of the present invention should not be limited to the described embodiments and should not be conveyed, and should be defined by not only the claims to be described later, but also those equivalent to these claims.

That is, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive, and the scope of the present invention is indicated by the claims to be described later rather than the detailed description, and the meaning and scope of the claims and All changes or modified forms derived from the equivalent concept should be construed as being included in the scope of the present invention.

100: fixed contact
200: movable contact
300: coil part
400: core part
410: first body
420: second body
430: magnetic field induction plate
510: first auxiliary contact unit
511: first auxiliary contact
512: first connection line
520: second auxiliary contact unit
521: second auxiliary contact
522: second connection line

Claims (6)

fixed contact;
a movable contact part that is rotated to be in contact with or separated from the fixed contact part;
a coil part disposed behind the movable contact part and connected to the first auxiliary contact part and the second auxiliary contact part; and
A first body in which the coil unit is installed, and a pair of second bodies extending parallel to each other at both ends of the first body to be located on both sides of an arc generating region between the movable contact part and the fixed contact part Including; core part;
The first auxiliary contact part is connected to the fixed contact part, and the second auxiliary contact part is connected to one side of the movable contact part in a state where the movable contact part is spaced apart from the fixed contact part,
The second auxiliary contact part,
a second auxiliary contact disposed on a rotation path of the movable contact unit;
A second connection line connecting the second auxiliary contact and the coil unit,
The second auxiliary contact is a self-extinguishing device for a DC circuit breaker, characterized in that in contact with one side surface of the movable contact portion.
According to claim 1,
When the second auxiliary contact part is connected to one side of the movable contact part, the main circuit power is transmitted to the coil part.
delete According to claim 1,
A magnetic extinguishing device for a DC circuit breaker, characterized in that a pair of magnetic field induction plates formed to face each other are provided at the top of the pair of second bodies.
According to claim 4,
Each of the pair of magnetic field induction plates,
A neck extending upward from the ends of the pair of second bodies;
Self-extinguishing device for a DC circuit breaker, characterized in that it comprises an amplification plate formed at the top of the neck.
According to claim 1,
The second auxiliary contact is formed in a roller shape,
Self-extinguishing device for a DC circuit breaker, characterized in that the rolling contact to one side of the movable contact portion.

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