KR200193335Y1 - Structure of fuse - Google Patents

Abstract

A fuse structure is disclosed that is melted by overcurrent or short circuit (short circuit).

In order to prevent it from being impossible to check whether the fuse is caused by an overcurrent or a short circuit in the prior art, the main consumable body 22 which is melted by the overcurrent is cut by a short circuit between the upper terminal and the lower terminal. The auxiliary solubles 24 are respectively separated and connected, and the outer side of the main solubles 22 and the auxiliary solubles 24 is melted before any one of the main solubles 22 or the auxiliary solubles 24 is melted. A fuse structure in which the confirmation conductive line 30 is formed is provided.

Therefore, the present invention facilitates the design of a high current blocking fuse by separating the blow-out portion and the break-off portion by the main and auxiliary soluble bodies, and visually determine whether the fuse is caused by an overcurrent or a short circuit (short circuit). It is possible to check the system to prevent the loss of unnecessary materials, and to reduce the cost of physical and human waste in finding the cause of the failure.

Description

Structure of fuse

The present invention relates to a fuse structure, and more particularly, to a fuse structure that makes it easy to check whether the fuse is blown by an overcurrent or by a short circuit.

In general, a fuse is melted by heat generation when a current exceeding a specified level is passed in an electric circuit. In general, a fuse such as aluminum, tungsten wire, etc. is used for small currents in addition to alloys such as lead, tin, and antinium. Sometimes used alone.

Types of fuses include thin line fuses, plate-shaped plate fuses, ring-shaped fuses with screw hooks at both ends, cylindrical fuses placed in bakelite or fiber cylinders, and tube fuses embedded in glass tubes for small appliances. The thermal fuse is blown when the temperature becomes high and is used for a heater.

The present invention applies to wire fuses used for the purpose of protecting electrical appliances from overcurrent and for protecting pole transformers at the front of the load.

As shown in FIG. 1, a conventional fuse is connected to each other by an upper terminal 10 and a lower terminal 11 facing each other via a cylindrical soluble body 12, and a support 13 outside the soluble body 12. Glass tube 15 is installed on the inner side of the 14, the outer cylinder 16 is located on the outside of the support 13, 14, the outer cylinder 16 is the upper cap 17 and the lower cap 18 It is configured to be fixed by).

Therefore, the fuse 12 is melted in the glass tube 15 where the position blocked by the overcurrent or the excessive abnormal current such as a generator, a transformer or a lightning strike through the upper terminal 10 and the lower terminal 11 functions as a fuse. In this case, it is impossible to determine whether the fuse is blown due to an overcurrent or a short circuit, which causes a lot of physical loss.

Accordingly, the present invention has been devised to solve the above-described problems of the prior art, and an object of the present invention is to provide a fuse structure that facilitates the design of a fuse having a high electric current and a high breaking capacity.

Another object of the present invention is to provide a fuse structure that is very easy to check whether the blown fuse is due to overcurrent or short circuit.

1 is a cross-sectional view showing a conventional fuse structure.

2 is a cross-sectional view showing a fuse structure according to the present invention.

3 is a cross-sectional view illustrating a fuse melted by overcurrent in a fuse structure according to the present invention.

Figure 4 is a cross-sectional view showing a state in which the fuse is blown by a short circuit in the fuse structure according to the present invention.

Explanation of symbols on the main parts of the drawings

20: upper terminal 21: lower terminal

22: main soluble body 24: auxiliary soluble body

26: glass tube 28: ceramic tube

29: Sohojae 30: Confirmation Challenge

In the fuse structure according to the present invention for achieving the above object, between the upper terminal and the lower terminal, the main soluble body melted by overcurrent and the auxiliary soluble body cut by the short circuit are separated and connected, respectively, An outer side of the soluble body is provided with a fuse structure in which a confirmation conductive wire is formed that is melted before either the main soluble body or the auxiliary soluble body is melted.

Therefore, the present invention facilitates the design of a high current blocking fuse by separating the blow-out portion and the break-off portion by the main and auxiliary soluble bodies, and visually determine whether the fuse is caused by an overcurrent or a short circuit (short circuit). Since it is possible to check, it is possible to prevent the loss of unnecessary materials, and to reduce the cost of physical and human waste in finding the cause of the failure.

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

2 is a cross-sectional view showing a fuse structure according to the present invention, in which the upper terminal 20 and the lower terminal 21 are positioned to face each other.

A main acceptor 22 is connected between the auxiliary terminal 23 at the tip of the lower terminal 21, and an auxiliary soluble body 24 is connected between the auxiliary terminal 23 and the upper terminal 20. It is.

The main soluble body 22 is made of a metal having a low melting point, such as lead, tin, zinc and alloys thereof, and the auxiliary soluble body 24 has a high conductivity and a high melting point, such as copper, silver, platinum, and tungsten. , Titanium and alloys thereof.

A support 25 is installed in the lower terminal 21, and a glass tube 26 is fixed inside the support 25.

An inner cap 27 through which the auxiliary terminal 23 penetrates the center portion is installed at the front end of the glass tube 26, and a support 25a installed outside the upper terminal 20 at the front end of the inner cap 27. A ceramic tube 28 is installed between the inner cap 27a and an arc extinguishing material 29 is filled inside the ceramic tube 28.

The lower terminal 21 and the inner cap 27a are connected to a confirmation conductive wire 30 wound around the outer side of the glass tube 26 and the ceramic tube 28.

The confirmation conductive wire 30 is cut at about 0.01 times the rated fuse current, so that the main soluble substance 22 is melted by an overcurrent or the auxiliary soluble substance 24 is melted by a short circuit or in any case. Done.

The outer cylinder 31 is inserted to the outside of the support (25) (25a), the outer cylinder 31 is configured to be fixed by the upper cap 32 and the lower cap (33).

In the fuse structure according to the present invention configured as described above, current flows through the upper terminal 20 and the lower terminal 21. In this case, when the overcurrent flows, as shown in FIG. At the same time as the molten metal is melted, the main consumable body 22 inside the glass tube 26 is melted by the overcurrent, thereby interrupting the current.

Therefore, the melting of the main filler metal 22 is confirmed through the glass tube 26 together with the melting of the confirmation conductive wire 30, so that it is possible to confirm that the melting of the fuse is caused by overcurrent.

In addition, when it is confirmed that the confirmation conductive wire 30 is melted, when it is confirmed that the main acceptor 22 body in the glass tube 26 of the transparent material is not melted, the auxiliary soluble substance in the ceramic tube 28 of opaque material Since (24) is melted, it is possible to know that the fuse is cut off due to a short circuit (short circuit) even without checking with a tester or the like.

As described above, according to the present invention, it is easy to design a fuse for cutting off the high current by separating the blow-off portion and the break-off portion by the main soluble body and the auxiliary soluble body, and according to the blow-off state of the fuse due to overcurrent or short circuit (short circuit). Since it is possible to check whether or not by the naked eye, it has various effects such as preventing the loss of unnecessary materials and the like, and reducing the cost of physical and human waste caused by finding the cause of the failure.

Claims (2)

Between the upper terminal and the lower terminal, the main soluble body 22 which is melted by overcurrent and the auxiliary soluble body 24 which are cut by a short circuit are separated and connected, respectively, and the main soluble body 22 and the auxiliary soluble body 24 are connected. The fuse structure, characterized in that the outer side of the main carrier body 22 or the auxiliary soluble body 24 is formed before confirmation of the melting of the conductive wire 30 is melted. According to claim 1, Glass tube 26 is provided on the outer side of the main acceptor 22, Ceramic tube 28 filled with an anti-fogging material 29 is provided on the outer side of the auxiliary soluble body (24). A fuse structure, characterized in that.