KR200247021Y1 - Trip core of a circuit protector - Google Patents

Abstract

The present invention relates to a trip core of a circuit breaker inserted into a coil of a circuit breaker to prevent an overload state of a circuit, to operate by attracting an armature which acts to apply or cut a power by magnetic force.

In the trip core of the circuit breaker according to the present invention, in order to apply or cut off the power on the electric circuit by the operation of the armature hinged to the yoke, the end of the core around which the coil is wound is located at the end of the armature to the excitation of the coil. A trip core of a circuit breaker configured to attract and operate an armature, comprising: a contact portion located opposite the end of the armature and attracting the end portion of the armature to the excitation of the coil; and an excitation of the coil located at the center of the coil. At the time of the contact portion is characterized in that the iron core portion is provided integrally to provide a suction force by the magnetic field.

Therefore, there is no effect of temperature, it is possible to maintain the stability of the operation and to improve the operation speed against overload, and to reduce the manufacturing cost and improve the productivity.

Description

Trip core of a circuit protector

The present invention relates to a trip core of a circuit breaker, and more particularly, to improve the structure of a core inserted into a coil of a circuit breaker which prevents an overload condition of a circuit, by driving an armature which operates or applies a power source by magnetic force. The present invention relates to a trip core of a breaker, which can improve the operation speed against breaker overcurrent.

1 is a partial cutaway cross-sectional view showing a trip core of a conventional circuit breaker.

In general, a conventional circuit breaker used to block overcurrent flowing on an electric circuit has a coil 3 wound around the core 4 and a yoke at one end of the core 3 as shown in FIG. The end of the armature 2 hinged to (1) is positioned so that the armature 2 is operated on the principle that magnetic attraction force is formed in the core 3 as power is applied to the coil 3. have.

Of course, the armature 2 is not shown in the accompanying drawings, but since it is structurally connected to a link in a breaker, a pair of contacts respectively connected to an input terminal and an output terminal, the breaker is an armature by the suction force of the core 3. According to the operation of (2), the power is applied or cut off on the circuit in such a manner that the pair of contacts come into contact with and detach from each other.

Meanwhile, when the structure of the core for armature operation of the circuit breaker is described in more detail, the conventional core 4 is commonly referred to as an ODP (Oil Dash Pot) structure, and the plunger 6 is inserted into the cylinder 9, and the plunger 6 is provided. A spring 7 is interposed on one side of the cylinder 9, and a working fluid 8 is injected into the cylinder 9 for flow in the cylinder 9 of the plunger 6, so that one end of the cylinder 9 is a pole 5. The armature is operated in a structure sealed by

That is, when an overcurrent occurs on the circuit and a suction force is formed in the core 4 by excitation of the coil 3, the plunger 6 overcomes the repulsive force of the spring 7 and approaches in the direction in which the pole 5 is located. When the plunger 6 reaches the pole 5, the magnetoresistance decreases so that the armature 2 is attracted to the position of the pole 5, and as a result, a tripping operation is performed in the breaker.

The problem, however, lies in the working fluid which causes the plunger in the cylinder to react according to the strength of the current flowing in the coil. The trip core of the conventional circuit breaker is usually a silicon oil (silicon oil) is commonly used as a working fluid to facilitate the operation of the plunger according to the strength of the current by braking the plunger due to the viscosity of the silicone oil, but the physical and chemical stability Since high silicon oil has a characteristic of changing viscosity depending on temperature, the existing core having such a structure has a problem that the armature cannot be operated as desired since the operation time of the plunger also changes according to the change of ambient temperature. .

In the case of a circuit breaker, it is very important to respond quickly to overcurrent generated in an electric circuit, but the core structure that causes problems such as temperature rise inside the circuit breaker and viscosity change of silicone oil due to long use of the circuit breaker On the contrary, there is a risk that the breaker's original function will be lost. In particular, if the breaker includes such a problem in tripping an electric device located at a long distance in the electric circuit, there is a possibility that the breaker may not operate.

As a result, in some cases, in order to solve such a problem, a circuit breaker is sometimes used in a state in which only a working fluid is removed from a core having the structure described above.

The purpose of the present invention is to maintain the operational stability without the influence of temperature, improve the operating speed against overload, and trip the breaker that can reduce the cost and improve the productivity with a simple and robust structure In providing a core.

1 is a partial cutaway cross-sectional view showing a trip core of a conventional circuit breaker.

Figure 2 is a partial cutaway cross-sectional view showing a trip core of the breaker according to the present invention.

※ Explanation of symbols for main parts of drawing

1: york 2: amateur

3: coil 4, 10: core

5: contactor 6: plunger

7: spring 8: working fluid

9: cylinder 11: iron core

12: junction

The trip core of the circuit breaker according to the present invention for achieving the above object, the end of the core wound coil is located at the end of the armature to apply or cut off the power on the electrical circuit by the operation of the armature hinged to the yoke A trip core of a circuit breaker adapted to attract and operate the armature by the excitation of the coil, the tripping portion being located opposite the end of the armature and sucking the end of the armature by the excitation of the coil; It is characterized in that the iron core is integrally formed to provide a suction force by the magnetic field in the contact portion when the coil is excited.

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

Figure 2 is a partial cutaway cross-sectional view showing a trip core of the breaker according to the present invention.

The trip core of the circuit breaker according to the present invention is characterized in that the contact portion 12 positioned at the end of the armature and the iron core 11 positioned at the center of the coil are integrally formed.

The operation principle of the armature shown in FIG. 2 will be briefly explained. The armature 2 is hinged to the yoke 1, and at the end of the armature 2, the core 4 on which the coil 3 is wound is located. When a suction force is generated in the core 4 by the excitation of the coil 3, the armature 2 is operated to apply or cut off the power supply.

Of course, when an overload occurs on the electrical circuit, the armature 2 operates as an excitation of the coil 3, and its end approaches the contact portion 12 of the core 10, and although not shown in the drawing, it is connected with the armature. When the armature reaches the junction, the pair of contacts come into contact with each other and the power is cut off. When no end of the armature is released from the contact portion, the pair of contacts are separated from each other and power is applied.

That is, the trip core 10 of the circuit breaker according to the present invention has a contact portion located at the end of the armature 2 so that the operation of the armature 2 can be quickly responded to the situation of the current flowing on the electric circuit. (12) and the iron core part 11 located in the center part of the coil are formed integrally.

As described above, the contact portion 12 functions to suck the end of the armature 2 by the suction force generated by the excitation of the coil 3.

The iron core part 11 is located in the center part of the coil 3, and becomes a magnetizing state when the coil 3 is excited, and functions to provide the suction part 12 with the suction force which attracts the armature 2 to it.

On the other hand, since the trip core of the circuit breaker according to the present invention is made of a single portion of the contact portion and the iron core, the material will be adopted as a single material. Of course, the permeability is higher than the permeability in vacuum, so it is natural that any paramagnetic or ferromagnetic material can be easily magnetized.

Therefore, according to the present invention, since the core is made of a solid integral structure, there is no influence of temperature, thereby maintaining stability of operation, and also improving the operating speed against overload, and in the present invention, which achieves a simple and robust structure. The trip core of the circuit breaker can reduce the cost required to produce the core and can increase productivity.

Although the present invention has been described in detail only with respect to the embodiments described, it will be apparent to those skilled in the art that various modifications and changes are possible within the technical spirit of the present invention, and such modifications and modifications belong to the appended utility model claims. will be.

Claims (1)

In order to apply or cut off the power on the electrical circuit by the armature of the armature hinged to the yoke, the end of the core on which the coil is wound is located at the end of the armature so that the armature of the coil is attracted to and operated by the circuit breaker. In the core, A contact portion located opposite the end of the armature to suck the end of the armature by the excitation of the coil, and an iron core portion located at the center of the coil to provide a suction force by the magnetic field to the contact portion when the coil is excited Trip core of the circuit breaker, characterized in that integral.