KR101614123B1 - Fuse intergrated resistor - Google Patents

Abstract

The present invention provides a semiconductor device comprising: a resistor having a resistive load; A fuse having a fuse rod; And a connecting unit connecting the resistor rod and the fuse rod to the resistor rod and the fuse rod on both sides of the resistor rod and the fuse rod, respectively.

Description

A fuse-integrated resistor (FUSE INTERGRATED RESISTOR)

The present invention relates to a resistor in which a fuse is integrated.

In general, the electrical circuitry of an electronic device can be damaged by inrush currents generated when the power is turned on, internal temperature rises, and continuous overcurrent.

In order to prevent equipment failure caused by such damage, a resistor or a fuse is installed at the power input terminal of the electric circuit to protect the power circuit.

However, it is troublesome to install each of the fuse and the resistor. In other words, two welds are required.

To avoid this, the lead wires of each fuse and resistor must be welded in advance. This also makes it impossible to avoid troublesome welding operations.

In addition, when the welding is performed, the welding portion is easily broken, and there is a problem that the connection between the fuse and the resistor is not stable.

An object of the present invention is to provide a resistor integrated with a fuse, in which a resistor and a fuse are integrally manufactured so that a post-connection operation between them is unnecessary.

It is still another object of the present invention to provide a resistor integrated with a fuse, which eliminates welding during connection between a resistor and a fuse and makes a connection in a more simple and stable manner.

According to an embodiment of the present invention, there is provided a resistor integrated with a fuse, including: a resistance rod; a conductive resistance cap surrounding one end of the resistance rod; A resistor having a conductive resistance wire; A fuse having a fuse rod, a conductive fuse cap surrounding one end of the fuse rod, and a conductive shorting portion having one end connected to the fuse cap; A first fixing groove for receiving the other end of the resistor rod and a second fixing groove for receiving the other end of the fuse rod and connected to the other end of the resistance wire and the other end of the shorting portion, Conductive holder; And a cover unit formed to enclose the resistor, the fuse, and the conductive holder, the cover unit being integrated with the resistor, the fuse, and the conductive holder.

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Here, the holder may further include a partition wall separating the first fixing groove and the second fixing groove.

Here, the resistor may further include a protection portion formed of a silicone material so as to cover the wire.

The fuse may further include a triggering portion disposed to surround the shorting portion and configured to facilitate shorting of the shorting portion.

Here, the triggering portion may include an epoxy film disposed along the circumferential direction of the fuse rod and promoting the temperature rise of the short circuit portion.

Here, the short-circuit portion may include a silver nitrate silver film plated with silver nitrate on the outer circumferential surface of the fuse rod and a tin alloy plated with a tin alloy on the silver nitrate silver film.

Here, the cover unit may be formed of silicon having a hardness higher than that of the protective portion.

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According to the resistor having the above-described structure according to the present invention, the resistor and the fuse are integrally manufactured so that the post-connection operation between the resistor and the fuse is not required. As a result, the workability in the circuit configuration is improved.

In addition, it is possible to avoid the problems such as the inconvenience of welding and the short-circuit of the welded part by eliminating the welding when connecting the resistor and the fuse.

FIG. 1 is a partially broken perspective view showing a fuse-integrated resistor 1000 according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view illustrating the internal structure of the fuse-integrated resistor 1000 illustrated in FIG. 1 and according to an embodiment of the present invention.
3 is a cross-sectional view of a recessed portion showing a portion associated with the connection unit 300 of FIG.

Hereinafter, a resistor integrated with a fuse according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present specification, the same or similar reference numerals are given to different embodiments in the same or similar configurations.

FIG. 1 is a partially broken perspective view showing a fuse-integrated resistor 1000 according to an embodiment of the present invention.

Referring to the drawings, the resistance fuse assembly 1000 may include a resistor 100, a fuse 200, a connection unit 300, and a cover unit 400.

The resistor 100 is a device for exhibiting a function of a resistor and limiting an inrush current. The resistor 100 may be a wire 130 wound on a resistance rod 110 (see FIG. 2). In the cap 130 formed at one end of the resistor 100, the first lead 101 may extend.

The fuse 200 is an element for short-circuiting the circuit connection by overcurrent or heat. In the fuse cap 230 formed at one end of the fuse 200, the second lead 201 extends in correspondence with the first lead 101.

The connection unit 300 has a structure in which the resistor 100 and the fuse 200 are respectively fitted. Thereby, the connection unit 300 connects the resistor 100 and the fuse 200 together. At this time, the connection unit 300 is located between the resistor 100 and the fuse 200 and may be arranged so as to form a single line with them.

The cover unit 400 covers the resistor 100, the fuse 200, and the connection unit 300. The cover unit 400 allows the resistor 100, the fuse 200, and the connection unit 300 to be integrally formed, that is, a piece.

According to this configuration, the connection between the resistor 100 and the fuse 200 can be made more rigid.

Also, the resistor 100 and the fuse 200 may be connected to each other to form a single piece.

Next, the specific structure of the resistor 1000 will be described with reference to Fig.

FIG. 2 is a cross-sectional view illustrating the internal structure of the fuse-integrated resistor 1000 illustrated in FIG. 1 and according to an embodiment of the present invention.

Referring to the drawing, first, the resistor 100 includes a first lead 101, a resistance rod 110, a resistance cap 130, a resistance wire 150, and a protection portion 170 have.

The first lead wire 101 extends from the resistance cap 130. The first lead wire 101 is to be fitted and welded to the circuit board.

The resistance rod 110 is extended to have a generally cylindrical shape. The resistance rod 110 may be formed of a ceramic material.

The resistance cap 130 is coupled to one end of the resistance rod 110. The resistance cap 130 has a larger diameter than the resistance rod 110 and is formed of a metal material.

The resistance wire 150 may preferably be formed of an alloy of copper (Cu) and nickel (Ni) so as to withstand a high current without being melted. The resistance wire (150) is wound in a spiral shape on the resistance rod (110). One end of the resistance wire 150 is connected to the resistance cap 130 and the other end is connected to the connection unit 300.

The protector 170 is coated on the resistance rod 110 so as to surround the resistance wire 150. The protective portion 170 may be formed of a silicon material, specifically, liquid silicon. Thereby, the protective portion 170 can prevent the debris from being diverted when the resistance wire 150 is broken by the overcurrent.

The fuse 200 may have a second lead 201, a fuse rod 210, a fuse cap 230, a short circuit part 250, and a triggering part 270.

The second lead 201 extends from the fuse cap 230. And the second lead 201 corresponds to the first lead 101. Like the first lead wire 101, the second lead wire 201 may be in the form of a copper wire plated with tin. If the content of tin is less than 30 wt%, the weldability is not excellent. If the content of tin is more than 40 wt%, the electrical conductivity is not excellent.

The fuse rod 210 may be a cylindrical extension. The fuse rod 210 may be formed of a ceramic material containing alumina. At this time, the ceramic may contain 55% by weight to 85% by weight of alumina.

When the content of alumina is less than 55% by weight, the content of other components except for alumina increases, resulting in a problem that the economical efficiency is rapidly lowered. When the content of alumina is more than 80% by weight, there is a problem that the electrical conductivity is drastically lowered. The inventors have found that the content of such alumina is more preferably 55 wt% to 70 wt%.

The fuse cap 230 is disposed at one end along the longitudinal direction of the fuse rod 210. The fuse cap 230 is also formed of a conductive material.

Specifically, the fuse cap 230 may include a copper plate and a plating layer formed by plating 30% by weight to 40% by weight of tin with respect to 100% by weight of the plate on the surface of the plate. Here, copper is economical and has an advantage of low electrical resistance. Also, the tin improves the weldability between the second lead 201 and the fuse cap 230.

The shorting part 250 is a part for connecting the fuse cap 230 and the connection unit 300. The shorting portion 250 may specifically include a tin layer applied to the outer circumferential surface of the fuse rod 210. [

The tin layer is composed of a silver nitrate silver film 251 plated with silver nitrate on the outer circumferential surface of the fuse rod 210 washed with hydrochloric acid and a tin film 253 plated with tin alloy on the silver nitrate silver film 251 .

The tin layer may be formed on the outer circumferential surface of the fuse rod 210 to a thickness of 2 mu m to 10 mu m. If the thickness of the tin layer is less than 2 mu m, plating difficulty is large and shorting of the short circuit part 250 is not properly performed. If the thickness of the tin layer is more than 10 mu m, there is a problem that the short circuit of the short circuit part 250 becomes too fast (too sensitive).

The triggering portion 270 is disposed to surround the shorting portion 250 and is formed to facilitate shorting of the shorting portion 250. [ Specifically, the triggering portion 270 may be an epoxy film formed of epoxy disposed along the circumferential direction of the fuse rod 210 and promoting the temperature rise of the shorting portion 250 due to the heat applied to the shorting portion 250.

The connection unit 300 is configured such that the resistance rod 110 and the fuse rod 210 are respectively fitted. And is also a portion to which one end of each of the resistance wire 150 and the shorting portion 250 is connected. The connection unit 300 is formed as an electrical conductor. The specific structure of the connection unit 300 will be described later with reference to Fig.

Referring again to FIG. 2, the cover unit 400 is configured to surround the resistor rod 110, the fuse 200, and the connection unit 300 to form an appearance of the resistor 1000. Thereby, the resistor 1000 can be a single piece.

The cover unit 400 may be formed of a silicon material. At this time, the silicon of the cover unit 400 may have a higher hardness than that of the silicon of the protective portion 170. Thereby, the cover unit 400 protects the entire resistor 1000 more strongly.

According to such a configuration, the short circuit part 250 can be fused by the heat above the setting reference applied to the fuse 200. At this time, the shorting part 250 can be fused in a shorter time than the conventional one by providing the tin layer.

The melting point of tin of the tin film 253 is 231.93 占 폚, and the melting point of the silver nitrate silver film 251 is 212 占 폚. The melting point of nickel is 1,455 占 폚 and the melting point of copper is 1084.5 占 폚. ℃. In other words, since the melting point of the shorting part 250 is only 1/5 to 1/7 that of the conventional material, the shorting part 250 can be fused more quickly.

The tin, which is the main component of the tin layer, is not directly plated on the fuse rod 210. In order to solve this problem, in this embodiment, a silver nitrate silver film 251 plated with silver nitrate is first formed on the outer circumferential surface of the fused rod 210 washed with hydrochloric acid, and then a tin alloy- And a film 253 are formed. With such a configuration, the short-circuit part 250 can be quickly short-circuited in response to heat above a reference applied through the resistor 100. [

Further, the fusing of the short-circuit part 250 is further accelerated by the triggering part 270. [ On the other hand, the fuse 200 employing the epoxy film as the triggering unit 270 will be described in detail with reference to the experimental results of Table 1.

1st round Second round Three times Four times 5 times Average (s) Epoxy film
apply 36.4 42.3 39.2 37.5 43.3 39.74 Epoxy film
Unapplied 45.6 50.4 52.1 50.7 46.5 49.04

Referring to the above experimental result, when the epoxy film is applied as the triggering unit 270, the fuse 200 is short-circuited in 39.74 seconds on average. However, when the above epoxy film was not applied, short-circuiting of the resistor type fuse was performed in 49.04 seconds on average.

Therefore, it can be seen that the shorting time of the epoxy film as the triggering unit 270 is shortened by an average of 9.7 seconds. This provides about 20% shortening time shortening effect.

The configuration related to the connection unit 300 described above will be described with reference to Fig.

3 is a cross-sectional view of a recessed portion showing a portion associated with the connection unit 300 of FIG.

Referring to this figure, the connecting unit 300 is a conductor formed as a single piece.

Specifically, the connection unit 300 may be a holder having a first fixing groove 310 and a second fixing groove 330. Here, the first fixing groove 310 and the second fixing groove 330 may be arranged to be opened toward opposite directions.

The holder may further have a partition 350 separating the first fixing groove 310 and the second fixing groove 330 from each other.

According to this configuration, the resistance rod 110 is fitted in the first fixing groove 310, and the fuse rod 210 can be fitted in the second fixing groove 330. Thereby, the connection between the resistance rod 110 and the fuse rod 210 can be made simple through the holder.

The provision of the barrier ribs 350 allows the resistive load 110 and the fuse rod 210 to be held at a constant depth when they are fitted into the first and second fixing grooves 310 and 330, .

The resistor integrated with the fuse as described above is not limited to the configuration and operation of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

100: Resistor 110: Resistor rod
130: Resistance cap 150: Wire
170: Protection part 200: Fuse
210: Fuse rod 230: Fuse cap
250: short circuit part 270: triggering part
300: connecting unit 310: first fixing groove
330: second fixing groove 350: partition wall
400: Cover unit

Claims (10)

A resistor having a resistive rod, a conductive resistive cap surrounding one end of the resistive rod, and a conductive resistive wire having one end connected to the resistive cap;
A fuse having a fuse rod, a conductive fuse cap surrounding one end of the fuse rod, and a conductive shorting portion having one end connected to the fuse cap;
A first fixing groove for receiving the other end of the resistor rod and a second fixing groove for receiving the other end of the fuse rod and connected to the other end of the resistance wire and the other end of the shorting portion, Conductive holder; And
And a cover unit formed to surround the resistor, the fuse, and the conductive holder, the cover unit being integrated with the resistor, the fuse, and the conductive holder.
delete delete The method according to claim 1,
The conductive holder includes:
Further comprising a partition wall separating the first fixing groove and the second fixing groove.
The method according to claim 1,
The resistor
Further comprising a protective portion formed to cover the resistance wire and formed of a silicon material.
6. The method of claim 5,
The fuse,
Further comprising a triggering portion disposed to surround the shorting portion and configured to facilitate shorting of the shorting portion.
The method according to claim 6,
The triggering unit,
And an epoxy film disposed along a circumferential direction of the fuse rod to promote a temperature rise of the short circuit portion.
8. The method of claim 7,
The short-
A silver nitrate silver film plated with silver nitrate on the outer circumferential surface of said fuse rod; and a tin film plated with tin alloy on said silver nitrate film.
The method according to claim 6,
Wherein the cover unit is formed of silicon having a hardness higher than that of the protection unit. delete

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