KR940003286Y1 - Circuit breaker - Google Patents

Abstract

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Description

Thermal Electronic Circuit Breakers

1 is a front view showing the main structure of the conventional thermoelectric circuit breaker.

Figure 2 is a front view showing the main structure of the circuit breaker for thermal electronic wiring in the present invention.

* Explanation of symbols for main parts of the drawings

1: body 3: terminal

4: Bimetal 5: Power Supply Line

10: second magnet 11: conductor

12, 12a: Contact 13: third magnet

The present invention relates to a circuit breaker for a thermal electronic wiring, in particular to have a high breaking capacity.

In general, a circuit breaker is used as a switch for overload and short circuit protection. It is divided into a thermoelectric type using bimetal and magnet as a detection element and a fully electronic type using a magnetic field of a coil as a detection element.

The thermal electronic circuit breaker is a recent trend of requiring a high breaking capacity in a compact size, but due to the relationship of the overall size is limited in nature, the size of the current-carrying part is limited, and accordingly, there are many difficulties in increasing the breaking capacity. Follow.

1 is a front view showing a main structure of a conventional thermal electromagnetic circuit breaker, which is installed at one side of the main body 21 to receive power and to a terminal 23 provided below the main body 21. A bimetal 24 connected to sense an overload, a magnet 26 fixed to the bimetal to detect an overcurrent when a current is supplied to the bimetal 24 through a power supply line 25, and an upper side of the terminal 23 A moving member 27 installed in the magnet 26 to selectively move as the magnet 26 senses an overcurrent, a trip bar 28 rotated according to the movement of the movable member, and a power source sliding along the rotation of the trip bar. It consists of a latch 29 for operating the mechanism (not shown) to block the.

Therefore, when power is applied to the terminal 22 provided on one side of the main body 21, current is supplied to the bimetal 24 through the power supply line 25 and then energized to the terminal 23.

In this way, when an overload is detected by the bimetal 24 when the current is energized or when an overcurrent is detected by the magnet 26 fixed to the bimetal 24, the mechanical part immediately operates to cut off the power supply.

That is, in the case of overload and overcurrent, suction force is generated in the magnet 26 installed in the bimetal 24 to attract the moving member 27 installed above the terminal 23, and thus the moving member 27 is moved. It is connected to the magnet 26, in which the movable member 27 rotates the trip bar 28, the latch 29 slides to operate the mechanism.

However, such a conventional thermal electronic circuit breaker is limited in size due to the limited outer size of the main body, and accordingly the breaking capacity in proportion to the bimetal's internal resistance (power supply of the highest point at which the bimetal can be operated) is limited. There was no choice but to.

The present invention was devised to solve the above problems, and when a current of a predetermined capacity or more is supplied, the current can be divided into bimetals and another conductor, thereby allowing a high breaking capacity even by the limited outer size of the main body. There is this.

According to the present proposal for achieving the above object, when a current having a predetermined capacity or more is supplied through a power supply line by installing a conductor having a third magnet fixed to the power supply line so as to face a bimetal that detects an overload installed in the main body. A circuit breaker for a thermal thermoelectric wiring is provided, in which a current flows separately in a bimetal and a conductor, and then merged by a contact so that it is energized to a terminal.

Hereinafter, the present invention will be described in more detail with reference to FIG. 2 of the accompanying drawings.

2 is a front view showing the main structure of the circuit breaker for the present invention, the terminal 2 is provided on one side of the main body 1 to receive power, and the terminal 3 installed below the main body 1. And a first magnet 6 for detecting an overcurrent when a current applied to the terminal 2 is fixed to the bimetal and is supplied through the power supply line 5. A moving member 7 installed above the terminal 3 and selectively moved when an overcurrent occurs, a trip bar 8 rotated according to the movement of the movable member, and a power source sliding while sliding according to the rotation of the trip bar. In the configuration consisting of a latch (9) for operating the mechanism (not shown) so that it can be made, the power supply line (5) is provided with a conductor (11) on which the second magnet (10) is fixed to face the bimetal (4) Connected installation and supply above a certain voltage As the first magnet 6 fixed to the immetal 4 attracts the second magnet 10 fixed to the conductor 11, the contacts 12 and 12a are connected to connect the power supply line 5. The current supplied through the bimetal 4 and the conductor 11 are divided and flowed, respectively, and then merged together so that the terminal 3 is energized.

In addition, the third magnet 13 is fixed to the upper end of the terminal 3 so that the trip bar 8 and the latch 9 operate as the third magnet 13 pulls the movable member 7 when an overcurrent occurs. To cut off the power supply.

The operation of the present invention configured as described above will be described below.

When the current applied to the terminal 2 provided on one side of the main body 1 and flowing through the power supply line 5 is equal to or less than a predetermined capacity, the current is energized through the bimetal 4 to the terminal 3.

In this way, if a current of a predetermined capacity or less is continuously supplied and a current of a predetermined capacity or more is supplied, the bimetal 4 detects this, and a suction force is generated in the first magnet 6 fixed to the bimetal 4. The conductor 11 is moved by attracting the second magnet 10 of the conductor 11 provided opposite to the contact 4 so that the contact 12 formed on the bimetal 4 and the contact formed on the conductor 11 12a are connected to each other.

Therefore, a constant capacitance current is divided into the bimetal 4 and the conductor 11, respectively, and then flows together by the contacts 12 and 12a to energize the terminal 3, thereby increasing the breaking capacity.

That is, when only one bimetal 4 is installed as in the prior art, assuming that the rated current is 20 A, when the bimetal 4 as well as another conductor 11 are installed to be connected to the power supply line 5 as in the present invention, In this case, the current flows into the bimetal 4 and the conductor 11, respectively, so that the rated current can be increased up to about 40A.

On the other hand, when an overcurrent or an overload is applied, that is, when a rated current or more is energized, the movable member 7 fixed to the upper end of the terminal 3 attracts the third magnet 13 and accordingly the third magnet 13 Rotates the trip bar 8 while moving, and the latch 9 slides to operate the mechanism to cut off the power supply.

Therefore, this proposal can have a high breaking capacity even by the limited external size of the main body can improve the user's purchase desire.

Claims (2)

The conductor 11 having the second magnet 10 fixed to the power supply line 5 is installed to face the bimetal 4 installed in the main body 1 so that when the current is supplied with a predetermined capacity or more, the current is bimetal 4. And the conductors (11) and the conductors (11), respectively, flowed together, and then joined together by the contacts (12) (12a) so as to be energized to the terminal (3). The inferior lamp of claim 1, wherein the third magnet 13 is fixed to the upper end of the terminal 3 so that the power is cut off as the third magnet 13 pulls the movable member 7 when an overcurrent occurs. Circuit breaker for electronic wiring.