KR20150092628A - The extinguishing structure for circuit breaker - Google Patents

Abstract

The present invention relates to an extinguishing structure for a circuit breaker in which a thermal deformation preventing member is inserted between a grid of an extinguishing unit and a cap grid, to prevent a swelling phenomenon of the cap grid caused by arc generated in a circuit breaker by the thermal deformation preventing member when a short-circuit accident occurs. An extinguishing structure of a circuit breaker (100) including a current application unit and an extinguishing unit in a contact base (110) comprises: a grid (210) in which an arc chamber (200) constituting the extinguishing unit is formed in the contact base (110), the arc chamber (200) dividing and extinguishing arc when a short circuit occurs; a cap grid (220) which fixes the grid (210), keeps a distance from the grid (210), and maintains insulation with a current application operation base (132) of the current application unit; and a thermal deformation preventing member (230) which is inserted between the grid (210) and the cap grid (220), to prevent heat from being transferred from the grid (210) being at a high temperature due to the induction of the arc when an arc occurs, to the gap grid (220).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an extinguishing structure for circuit breakers,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a structure of a circuit breaker for a wiring breaker, and more particularly, The present invention relates to a soho structure of a circuit breaker for preventing a swelling phenomenon of a grid.

Generally, in low-voltage (commonly abbreviated as low-voltage) electrical systems, circuit breakers provide protection against loads and equipment from fault currents, such as overcurrent and short-circuit currents, that are several tens to several hundred percent greater than rated currents.

The fault current is largely divided into overload current and short circuit current. When each current flows above the reference value, the circuit breaker opens the line.

In particular, the amount of current when short-circuit current flows flows from a few hundred amperes to several tens of thousands of amperes depending on the facility capacity, and the instantaneous circuit breaker operates to open (block) the circuit.

In the operation mechanism due to the short circuit current of the circuit breaker for wiring, the contacts (movable contact and fixed contact) inside the circuit breaker are opened to each other at the moment of opening of the line, an arc is generated between the contacts, Is formed several ms (milliseconds) between the contacts even after the contact is fully opened.

The arc has heat and pressure, which can cause mechanical burnout of the circuit breaker, which is directly related to the safety of the operator.

The operating time of the circuit breaker for wiring, that is, the opening time for the mechanical contact drops is about 2 to 3 ms, and the time from when the arc is generated to when it is extinguished is about 5 ms to 10 ms.

Therefore, the short-circuit breaking time of the wiring breaker can be expressed by the sum of the mechanical operation time of the wiring breaker and the time until the arc is extinguished.

Accordingly, if the arc is rapidly extinguished, the short-circuit breaking time of the circuit breaker can be shortened to greatly reduce the electrical / mechanical damage of the circuit breaker.

In order to prevent the mechanical and electrical burnout of the circuit breaker from the short circuit current, research for reducing the mechanical operation time and researching the arc as quickly as possible have been carried out actively. In particular, in order to arc extinguishing the arc as quickly as possible, arc grids are installed in front of the contact points to increase the arc voltage and flow rate, the structure inside the circuit breaker to efficiently exhaust gas by arc, and the research on materials that can withstand arc heat. It is progressing.

In particular, an arc chamber, which is a plurality of arc grid assemblies, is widely used as a typical apparatus commonly used for arc extinguishing. In order to improve the driving force of the generated arc (discharge speed), a grid The shape optimization of the shape is required.

1, the stationary contact 1 and the movable contact 2 are constituted by a contact part and a soho grid.

When the circuit is in a normal state, the stationary contact 1 and the movable contact 2 are in contact with each other as shown in FIG. 1, so that a normal current is supplied. When a short circuit current occurs due to a failure of the circuit, So that an arc is generated between the two contact points 1 and 2. As a result,

The SOHO grid (3) is a structure in which a plurality of metal plates are arranged at regular intervals. An arc generated between the stationary contact (1) and the movable contact (2) flows into the arc so as to increase the arc length. The arc voltage is greatly increased by maximizing and cooling the arc by the metal plate.

As described above, when the arc voltage increased by the Soho grid 3 is larger than the power supply voltage, the magnitude of the short-circuit current is reduced.

The blocking of the magnitude of the short-circuit current is referred to as blocking the current.

In order to improve the current blocking performance, the arc generated between the contact points must be rapidly introduced into the soho grid 3 so that a high arc voltage is induced in a short time.

2 shows a V-shaped Soho grid 4 as a first embodiment of the conventional Soho grid 3. The conventional V-shaped Soho grid 4 has a plurality of metal plates 5 as shown in FIG. A pair of protrusions 6 protrude at both ends of the metal plate 5 at a predetermined price and a side wall which is an insulator is inserted between the protrusions 6, (9) is inserted and supported.

At this time, the V-shaped soho grid 4 has a V-shaped groove as shown in FIG.

This V-shaped Soho grid 4 increases the arc voltage by extending, dividing, and cooling the arc to make it larger than the power supply voltage so as to block the current flow.

At this time, in order to improve the current blocking performance, it is necessary to allow the arc generated between the contacts to flow quickly into the Soho grid.

In other words, as the arc flows into the Soho grid, the arc voltage rising rate becomes higher as the time is shortened, thereby improving the current blocking performance.

In order for the arc to flow quickly into the Soho grid, the driving force to which the arc flows into the Soho grid must be increased.

In order to increase the driving force for introducing the arc into the Soho grid, a wing-shaped Soho grid 7 is formed by protruding a wing 8 having a long length at both ends of the V-shaped groove as shown in FIG.

On the other hand, the success of the short-circuit current interruption does not mean that the arc generated between the contact points is extinguished. When the recovery voltage is applied after the arc-arc, insulation breakdown between the contacts, that is, arc re- In order to do so, it is necessary to provide a gap between the soho grid and the contact so as not to cause an insulation breakdown.

As shown in FIG. 4, a cap (not shown) having a function of holding the soho grid 7 before and after the inside surface of the soho grid 7 and maintaining the distance between the soho grids 7 and insulating the same from the moving contact The grid 10 is coupled.

However, in the prior art wiring breaker of the wiring breaker, the cap grid 10, which is coupled to the soho grid 7 by the arc heat, is swollen while generating heat due to the arc generated in the wiring breaker at the time of a short- There is a problem that switching operation of the wiring breaker is not performed due to thermal deformation.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to provide a circuit breaker which prevents inflow of melts into a circuit breaker when a short circuit fault occurs in the circuit breaker, It is possible to prevent the phenomenon of rising and maximizing the safety of the product and the product.

Another object of the present invention is to minimize the time for shutting down the product by maximizing generation of arc extinguishing gas due to surface deterioration due to the arc generated in the conductive grid by inserting the heat deformation preventing member between the grid and the cap grid And to provide a soho structure of a circuit breaker.

According to another aspect of the present invention, there is provided a SOH of a circuit breaker having a conductive part and a SOH part formed in a contact base, wherein an arc chamber constituting a SOH part is formed in the contact base, A cap grid for holding insulation between the grid and the grid while maintaining insulation between the grid and the grid, and a cap grid which is inserted between the grid and the cap grid, And a heat deformation preventing member for preventing heat transfer from the grid, which has been brought into a high temperature state due to the organic heat, toward the cap grid.

A wing portion is formed at both ends of the grid, and a mounting groove is formed such that a wing portion is coupled to one side of the cap grid so that a cap grid can be mounted on the grid.

In addition, a charging part is formed on the inner surface of the cap grid so that the heat deformation preventing member can be charged and coupled.

As described above, according to the present invention, since the thermal deformation preventing member is inserted between the grid of the arc chamber and the cap grid constituting the small portion of the circuit breaker for the wiring breaker, the arc heat is not transmitted from the grid to the cap grid It is possible to prevent the swelling of the cap grid, thereby preventing the failure of the wiring breaker, thereby maximizing the performance and the blocking performance of the product.

1 is an internal structural view showing a conventional wiring breaker.
2 is a perspective view showing a conventional V-shaped Soho grid.
3 is a perspective view showing a conventional wing-type Soho grid.
Fig. 4 is an exemplary diagram showing a small portion of a conventional wiring breaker; Fig.
5 is an exploded perspective view showing a wiring breaker according to the present invention.
FIG. 6 is a perspective view showing a wiring breaker according to the present invention. FIG.
FIG. 7 is an exploded perspective view showing an arc chamber constituting a small portion of a circuit breaker according to the present invention; FIG.
8 is a cross-sectional view showing an arc chamber of a circuit breaker according to the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 5 is an exploded perspective view showing a wiring breaker according to the present invention, FIG. 6 is an assembled perspective view showing a wiring breaker according to the present invention, and FIG. 7 is a view showing an arc chamber constituting a so- And FIG. 8 is a cross-sectional view illustrating an arc chamber of the circuit breaker according to the present invention.

5 to 8, the present invention is a circuit breaker 100 for cutting off a current in the event of a short-circuit failure. The circuit breaker 100 includes a contact base 110 forming an external shape, And a small portion which is mounted inside the contact base 110 and extinguishes an arc when a short-circuit accident occurs.

The conductive unit includes first and second conductive fixing members 120 and 121 which are fixed to the left and right sides of the contact base 110 and have contact points 122 at their ends, A crossbar assembly 130 operated by a mechanism assembly (not shown) so as to be disconnected from the first and second current-carrying brackets 120 and 121 when the first and second current-carrying brackets 120 and 121 are short- .

The cross bar assembly 130 is formed with a connection hole 131 to be fixed to the contact base 110. The contact hole 122 of the first and second electric current fixing bars 120 and 121 is connected to both ends of the connection hole 131, A current-carrying movable base 132 which is operated when a short circuit occurs is formed.

On the other hand, a plurality of the conductive lifters 132 are stacked up and down.

The soot unit comprises an arc chamber 200 coupled to the interior of the contact base 110.

A plurality of arc chambers 200 are formed on the left and right sides of the contact base 110.

The arc chamber 200 includes a grid 210 to which the arc 210 is divided by an arc when a short circuit occurs and a conductive bar 132 of the conductive unit, And a cap grid 220 which is inserted between the grid 210 and the cap grid 220. When the arc is generated, the cap 210 is moved from the grid 210 to the cap grid 220, And a heat deformation preventing member 230 for preventing heat transfer.

The grid 210 is formed with a wing 211 so that the energizing lifting base 132 is seated on both upper and lower ends and the cap grid 220 is mounted.

At this time, a plurality of the grids 210 are arranged at regular intervals.

The cap grid 220 has a mounting groove 221 formed at one side thereof for coupling the wing portion 211 of the grid 210 and a cap grid 220 mounted on the grid 210, And a charging part 222 is formed so that the thermal deformation preventing member 230 can be charged and coupled.

The cap grid 220 may be mounted on a wing 211 of the grid 210 and may be formed on and under one side of the grid 210.

The cap grid 220 is formed of a nylon material.

It is preferable that the mounting groove 221 of the cap grid 220 is formed by the number of the grids 210 so that the wings 211 of the grids 210 can be coupled.

The thermal deformation preventing member 230 is inserted between the grid 210 and the cap grid 220 while being coupled to the charging part 222 of the cap grid 220.

At this time, the heat deformation preventing members 230 are coupled to each other between the cap grids 220 to form a plurality of heat deformation preventing members 230.

The heat deformation preventing member 230 is formed of a heat insulating material and a heat resistant material so as not to transfer heat from the grid 210 to the cap grid 220 due to the arc.

The operation state according to the present invention having the above-described configuration will be described below.

The current flows through the first and second electromagnet assemblies 120 and 121 while the first and second electromagnet assemblies 120 and 121 and the crossbar assembly 130 are grounded.

In this case, when the short circuit of the wiring breaker 100 occurs, the cross bar assembly 130 is operated according to the operation of the mechanism assembly, and the current carrying band 132 is brought into contact with the contact portions 122, 122 of the first and second current- So that an arc is generated inside the circuit breaker 100.

An arc is divided by the grid 210 when an arc is generated due to a short circuit of the wiring breaker 100 and the cap grid 220 mounted on the grid 210 is separated from the crossbar assembly 130 and the grid 210) while providing arc extinguishing gas.

When an arc is generated in the circuit breaker 100 due to a short circuit of the circuit breaker 100, heat is transferred from the grid 210, which has been brought into a high temperature state due to the arc to the cap grid 220, The thermal deformation preventing member 230 of the heat insulating material and the heat resistant material is inserted between the grid 210 and the cap grid 220 and heat is transmitted to the cap grid 220 by the thermal deformation preventing member 230. [ It is not transmitted.

The thermal deformation preventing member 230 is inserted between the grid 210 and the cap grid 220 while being charged into the charging part 222 of the cap grid 220. Thus, The heat deformation preventing member 230 may block the arc heat and prevent the cap grid 220 from being swollen.

In addition, the arcing generated in the crossbar assembly 130 by the cap grid 220 by the heat deformation preventing member 230 can maximize the generation of arc extinguishing gas due to surface deterioration.

Accordingly, when the thermal deformation preventing member 230 is inserted between the grid 210 and the cap grid 220, when a short circuit fault current is generated in the wiring breaker 100, The thermal deformation preventing member 230 prevents the heat from being transmitted from the grid 210 to the cap grid 220 due to the swelling of the cap grid due to the transfer of the heat, So that thermal deformation of the cap grid 220 can be prevented.

In the present invention, arc heat is not transmitted to the cap grid 220 by the thermal deformation preventing member 230, thereby preventing swelling of the cap grid 220 and smooth rotation of the crossbar assembly 130 Since the present invention forms the heat deformation preventing member 230 as compared with the conventional circuit breaker for removing the cap grid in order to prevent the failure of the wiring breaker 100 and to prevent the failure of the cap grid 220, It is possible to increase the efficiency of the blocking performance because it is advantageous in generation of the soot gas.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

100: Circuit Breaker
110: a contact base
120: first energizing fixture
121: second energizing fixture
122:
130: Crossbar assembly
131:
132:
200: arc chamber
210: grid
211: wing portion
220: Cap grid
221: mounting groove
222:
230: heat deformation preventing member

Claims (6)

In a structure of a circuit breaker having a current-carrying portion that energizes the inside of a contact base and a so-called small portion that extinguishes an arc when a short-circuit fault occurs,
And an arc chamber constituting a soot unit is formed in the contact base, wherein the arc chamber is divided into a plurality of arcs by dividing an arc when an accident occurs, A cap grid which is interposed between the grid and the cap grid to prevent heat from being transmitted to the cap grid from the grid which is brought into a high temperature state due to the organic arc when an arc is generated, And a thermal deformation preventing member for preventing the thermal deformation of the circuit breaker. The method according to claim 1,
And a mounting groove is formed on one side of the cap grid so that a wing portion is coupled and a cap grid is mounted on the grid while the wing portion is coupled to one side of the cap grid. Of the soho structure. The method according to claim 1,
Wherein the cap grid has a charging portion formed on an inner surface thereof so that the thermal deformation preventing member can be charged and coupled therewith. The method according to claim 1,
Wherein a plurality of the cap grids are formed on one side of the grid, with a current carrying band therebetween. The method according to claim 1,
And the heat deformation preventing member is coupled between the respective cap grids. The method according to claim 1,
Wherein the heat deformation preventing member is formed of a heat insulating material and a heat resistant material so as to block heat transmitted from the grid that has been brought into a high temperature state due to the organic arc when an arc is generated to the cap grid.

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