KR100929822B1 - Surface-Mount Small Fuses - Google Patents

Abstract

The present invention relates to a surface-mounted small fuse, and an object of the present invention is to provide a surface-mounted small fuse that can improve the melt characteristics and productivity while reducing the failure rate.

To this end, the surface-mounted small fuse according to the present invention includes a base having a pair of through holes, a pair of lead wires installed in the base to penetrate the through holes, and one end of each of the lead wires. A fusing element is provided, and the lead wire and the fusing element are directly welded to each other in a state where at least a part of the end of the fusing element is accommodated in and in contact with the corresponding lead wire end.

Lead wire, fusing element, receiving groove, crimping part

Description

Surface Mount Small Fuses {A SURFACE-MOUNTED SMALL FUSE}

The present invention relates to a surface-mounted small fuse, and more particularly, is surface-mounted on a printed circuit board of an electrical appliance, and when the overcurrent is applied to the substrate, the internal fusing element is melted to prevent the components in the substrate from being burned out to flow the current. The present invention relates to a surface mount small fuse that prevents damage to a circuit in a substrate by blocking.

For example, a communication device connected to a telephone line or the like may be applied with a voltage much higher than usual due to a surge current caused by induction lightning or when the telephone line is in contact with a power line. For this reason, a fuse used for a communication device is required to have a high breaking capability characteristic that safely cuts off the current that causes the communication device to fail, and a strong time lag characteristic so that it is not blown by the surge current caused by induction lightning.

Recently, as devices are miniaturized, even in the case of small fuses of a surface mount type, such high breaking capability and strong time delay characteristics are required.

Conventionally, a conventional surface mount small fuse is installed in the base 1 having a pair of fastening holes 1a and a base 1 having a fastening hole 1a as shown in FIG. 1. Fusing bonded between the pair of lead wires 2, the fusing element 3 for connecting and connecting the ends of the respective lead wires 2 to the upper side of the base 1, and the lead wires 2, respectively. It is provided with a case 4 coupled to the base 1 to cover the device 3.

The fusing element 3 is usually wound on a support 5 made of glass fiber, and then cut in a predetermined length together with the support 5, and a ring-shaped fixing portion 2a formed on the upper end of the lead wire 2. After being inserted into the joint is bonded to the fixing part (2a) by soldering.

However, in the case of the conventional surface mount small fuse, as the support 5 is always used during the bonding operation of the fusing element 3, the overall configuration becomes complicated and the joining operation of the fusing element 3 becomes difficult. There was a problem that the productivity is lowered.

In the case of such a surface-mounted small fuse, it passes through a high temperature solder bath when mounted on a substrate. In this case, the solder 6 between the fusing element 3 and the lead wire 2 is dissolved to fuse the fusing element 3 with the fusing element 3. There is a fear of poor bonding of the lead wires 2.

In addition, some of the molten solder (6) during soldering between the fusing element (3) and the lead wire (2) flows along the support (5) to the fusing element (3) to short-circuit between the windings of the fusing element (3). There is a concern, but in this case, the overall length of the fusing element 3 is shortened, and the blown-out performance of the small fuse decreases.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide a surface-mounted compact fuse which can improve the melting characteristics and productivity while reducing the failure rate.

In order to achieve the above object, the surface-mounted small fuse according to the present invention includes a base having a pair of through holes, a pair of lead wires installed in the base so as to pass through the respective through holes, and each of the lead wires. And a fusing element connecting one end of the fusing element, wherein the lead wire and the fusing element are directly welded to each other in a state in which at least a part of the end of the fusing element is accommodated in and in contact with the corresponding lead wire end.

And an accommodation groove is provided at one end of the lead wire to accommodate at least a portion of the end of the fusing element.

In addition, the receiving groove is characterized in that it is provided to have a "V" shape.

In addition, the receiving groove is characterized in that it is provided to have a "U" shape.

In addition, before the fusing element and the lead wire is welded, the lead wire side receiving wire is deformed so as to be in close contact with the fusing element so that the accommodating groove surrounds at least half the outer surface of the fusing element.

In addition, the width of the receiving groove is larger than the diameter of the fusing element or the diameter size of the fusing element is characterized in that the depth of the receiving groove is formed larger than half the diameter of the fusing element.

In addition, the receiving groove is characterized in that the punched processing on the lead wire.

In addition, an end portion of the lead wire to which one end of the fusing element is coupled may form a crimp portion that is compressed to be flat, and the receiving groove is provided in the crimp portion.

In addition, the pressing unit is characterized in that the pressing deformation to be in close contact with the fusing element to wrap at least half the outer surface of the fusing element accommodated in the receiving groove before the fusing element and the lead wire is welded.

In addition, an end portion of the lead wire to which one end of the fusing element is coupled may form a crimping portion that is compressed to be flat, and the crimping portion is in close contact with the fusing element to wrap at least half of the fusing element end before being welded to the fusing element. Pressurized deformation is characterized in that to accommodate the end of the fusing element therein.

In addition, the receiving groove is characterized in that formed along the longitudinal direction of the lead wire at the end of the lead wire.

In addition, the lead wire and the fusing element is characterized in that the arc welding.

As described above in detail, the surface-mounted small fuse according to the present invention can be directly bonded to the lead wire through the fusing element, thereby improving the melting characteristics and productivity, and reducing the failure rate.

Further, in the present invention, the end of the fusing element is arc welded with the lead wire in a state where at least part thereof is supported to be received by the lead wire.

Therefore, the surface-mounted compact fuse according to the present invention not only makes it easy to determine the welding position of the fusing element prior to arc welding, but also stably without arcing at one end of the fusing element during the arc welding. It can be supported, so that the fusing element and the lead wire can be arc welded more stably and precisely, and spark generation is reduced even during arc welding, so that the welding strength between the fusing element and the lead wire can also be increased significantly. do.

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

As shown in FIG. 2 and FIG. 3, the surface-mounted small fuse according to the present embodiment includes a circular base 10 having a pair of through holes 10 a, and a through hole 10 a of the base 10. A pair of lead wires 20 which are installed to penetrate each other, the fusing element 30 which connects and connects between the upper ends of the lead wires 20 on the upper side of the base 10, and each of the lead wires 20. The case 40 includes a case 40 that is finally coupled to the base 10 so as to cover the fusing element 30 and the lead wire 20 on the upper side of the base 10 in the state in which the fusing element 30 is coupled. The base 10 and the case 40 are coupled so that the bottom of the case 40 is fitted inside the outer rim of the base 10. In contrast, the case 40 and the base 10 have a conventional coupling protrusion and a coupling groove. Each may be provided and coupled to each other.

In the present exemplary embodiment, the fusing element 30 and the lead wire 20 may have an end portion of the fusing element 30 in a state in which one end of the fusing element 30 is received and contacted by one end of the lead wire 20. After placing the two arc welding electrodes on the lead wire 20, the two arc welding electrodes are directly connected by mutual arc welding by applying power to the two arc welding electrodes.

The direct joining structure of the fusing element 30 and the lead wire 20 allows the fusing element 30 to be bonded to the lead wire 20 without using a support body that is conventionally used. While simplifying the bonding operation of the lead wire 20 and the fusing element 30 can be performed more quickly and easily to improve the overall productivity of the small fuse.

In addition, the surface-mounted small fuse provided in this way passes through a high temperature solder bath (not shown) in the process of being mounted on a substrate (not shown). Thus, the lead wire 20 and the fusing element 30 are directly welded to each other. In this state, since the junction between the lead wire 20 and the fusing element 30 does not have to be dissolved even in the process of passing the small fuse through the solder tank, the small fuse passes through the solder tank (not shown). In the process, the junction between the fusing element 30 and each of the lead wires 20 does not fall, thereby reducing the product failure rate of the small fuse.

When the fusing element 30 is arc welded to the lead wire 20, there is no fear that the fuse between the windings of the fusing element 30 is shorted by solder when the fusing element 30 and the lead wire 20 are bonded. Since the length of the fusing element 30 can be secured, it is possible to effectively prevent the blown-down performance of the small fuse.

On the other hand, the fusing element 30 is pulled out of the metallic support (not shown) in a winding state by a predetermined number of turns in accordance with the resistance value to the rod-shaped metallic support (not shown) so as to face both ends in the same direction After aligning and cutting using a cutter, both ends of the fusing device 30 thus manufactured are in contact with the upper side of the lead wire 20 of the upper side of the base 10, the fusing device 30 and the lead wire 20 ) Are bonded to each other by arc welding in such a manner as to apply power to the two arc welding electrodes in this state. Referring to FIG. 4, the lead wires 20 on the upper side of the base 10 in the present embodiment are connected to each other. The outer surface of one end of the upper side) is formed with a receiving groove 21 for supporting a portion of the outer surface of one end portion of the fusing element 30 bonded to the lead wire 20, the end of the fusing element 30 Is The outer side is arc welded to the lead wire 20 into close contact with the support is accommodated in the receiving groove (21) state.

The receiving groove 21 is provided over a predetermined length along the longitudinal direction of the lead wire 20, and can be supported in a stable contact state without one side end of the fusing element 30 accommodated therein. It is formed so that it is dug into a roughly "U" or "V" shape.

Therefore, when one end portion of one side of the fusing element 30 is accommodated in the receiving groove 21 formed as described above and welded between the one end of the fusing element 30 and the lead wire 20, the lead before the welding operation is performed. Not only the welding position of the fusing element 30 with respect to the wire 20 can be easily determined, but also the flow of the fusing element 30 is suppressed during welding, thereby enabling a more stable and precise welding operation.

In addition, when one end of one side of the fusing element 30 is accommodated in the receiving groove 21, the contact area between the fusing element 30 and the lead wire 20 is increased, the fusing element 30 during arc welding Since one end of the c) can be pressed more closely to the lead wire 20, the sparking phenomenon is significantly reduced during arc welding, and the welding strength can also be significantly increased.

The accommodating groove 21 may be simply formed through a punching process of pressing an outer surface of the lead wire 20 with a punching tool (not shown), and may be formed on the outer surface of the lead wire 20 having a circular cross section. In the process of pressurizing the punching tool, the punching tool (not shown) slightly deflects the lead wire 20, so that the receiving groove 21 may not be formed at the center of the outer surface of the lead wire.

Therefore, as shown in FIG. 5 of the second embodiment of the present invention, one end of the lead wire 20 connected to the fusing terminal 30 is pressed by applying a predetermined pressure before forming the receiving groove 21. It is preferable to form a slightly flattened crimping portion 20a, and when the receiving groove 21 is formed by punching the surface of the crimping portion 20a, the accommodating groove 21 is more easily formed during punching processing. You can do it. In this case, the end of the fusing element 30 and the lead wire 20 are directly arc-welded in a state where the end of the fusing element 30 is accommodated in the receiving groove 21.

In the first and second embodiments, only one end of the fusing element 30 is provided to be accommodated in the lead wire 20 through the receiving groove 21. However, in the surface-mounted small fuse according to the present invention, The end of the fusing element 30 may be welded to the lead wire 20 in a state almost or completely accommodated in the lead wire 20. Next, the fusing element 30 according to the third and fourth embodiments of the present invention, in which the end of the fusing element 30 is welded to the lead wire 20 while the end wire is almost or completely accommodated in the lead wire 20. The coupling structure of the lead wire 20 is introduced.

That is, as in the third embodiment shown in FIG. 6, the receiving groove 21 formed at the end of the lead wire 20 has a width larger than the diameter of the fusing element 30 or at least the fusing element 30. ) And may be processed to have a depth greater than half of the diameter of the fusing element 30, and in the state in which the end of the fusing element 30 is accommodated in the accommodating groove 21. The lead wire 20 is pressed against the receiving element 21 so as to be in close contact with the fusing element 30 so as to cover the outer surface of the fusing element 30 by at least half, and then the end of the fusing element 30 When arc welding the lead wire 20, the end of the fusing element 30 can be more firmly fixed to the lead wire 20, as well as between the lead wire 20 and the fusing element 30 during arc welding It is possible to further reduce the electric shock generated.

Here, the end side of the lead wire 20 in which the accommodating groove 21 is formed has a larger width and depth of the accommodating groove 21, so that the outer diameter thereof is somewhat expanded when the accommodating groove 21 is processed. (21) When pressing the lead wire 20 to be in close contact with the fusing element 30 while covering the outer surface of the fusing element 30, both sides of the receiving groove 21 are retracted inward by using a pressing tool (not shown). It becomes. At this time, the lead wire 20 may be applied to a predetermined heat so that the pressure deformation is more easily performed.

7 shows a coupling structure of the lead wire 20 and the fusing element 30 according to the fourth embodiment of the present invention.

As shown in FIG. 7, in the present embodiment, an end portion of the lead wire 20 to which one end of the fusing element 30 is coupled is flatly compressed so as to facilitate pressure deformation surrounding the fusing element 30. And the lead wire 20 and the fusing element 30 are formed on the outer surface of the fusing element 30 such that the crimped portion 20a can cover at least half of the end of the fusing element 30. Arc welding is performed with the lead wire 20 in the pressure-deformed state to be in close contact.

Also in the second embodiment, before the lead wire 20 and the fusing element 30 are welded to each other, the pressing portion 20a can be pressed against the end of the fusing element 30 as in the fourth embodiment. In this state, the lead wire 20 and the fusing element 30 may be arc welded. In this case, the fusing element 30 is caught by the receiving groove 21 when the pressure deformation of the crimping portion 20a is performed. While not flowing, it is possible to more easily wrap the fusing element 30 by using the pressing portion (20a).

1 is a perspective view of a conventional surface mount small fuse.

Figure 2 is a perspective view of a surface-mounted small fuse according to a first embodiment of the present invention, showing a case in which the case is separated.

3 is a cross-sectional view of a surface-mounted compact fuse according to a first preferred embodiment of the present invention.

FIG. 4 is a view illustrating an end-side structure of the lead wire and the fusing element in the surface-mounted small fuse according to the first embodiment of the present invention. FIG. 4A shows that the end of the fusing element accommodates the lead wire. It is a perspective view of a state before being accommodated in the groove, and b of FIG. 4 is a plan view of a state in which one end of the fusing element is accommodated in the receiving groove of the lead wire.

5 is a view illustrating an end side structure of the lead wire and the fusing element according to the second embodiment of the present invention. FIG. 5A is a perspective view of a state before the end of the fusing element is accommodated in the receiving groove of the lead wire. 5B is a plan view of a state where one end of the fusing element is accommodated so as to be supported by the receiving groove of the lead wire.

6 is a view illustrating an end side structure of the lead wire and the fusing element according to the third embodiment of the present invention. FIG. 6A is a perspective view of a state before the end of the fusing element is accommodated in the receiving groove of the lead wire. 6B is a plan view of a state in which one end of the fusing element is accommodated in the accommodating groove of the lead wire. Is a plan view showing a state in which pressure is deformed.

7 is a view illustrating an end side structure of the lead wire and the fusing element according to the fourth embodiment of the present invention. FIG. 7A illustrates a state before the end of the fusing element and the end of the lead wire are in contact with each other. 7 is a plan view illustrating a state in which an end portion of the fusing element is in contact with the compression portion of the lead wire, and FIG. 7 c is a state in which the pressing portion is deformed so as to surround the end portion of the fusing element in close contact. It is a top view which shows.

* Description of the symbols for the main functions of the drawings *

10: base 20: lead wire

21: receiving groove 30: fusing element

Claims (12)

In a small surface-mount fuse having a base having a pair of through holes, a pair of lead wires provided in the base to penetrate the through holes, and a fusing element connecting one end of each of the lead wires. , The lead wire and the fusing element are directly welded to each other through arc welding in a state where at least a part of the end of the fusing element is accommodated in and in contact with the corresponding lead wire end, An accommodating groove is provided along one of the ends of the lead wire so as to accommodate at least a portion of the end of the fusing element along a length direction of the lead wire. The width of the receiving groove is larger than the diameter of the fusing element or the diameter size of the fusing element and the depth of the receiving groove is formed larger than half of the diameter of the fusing element, Before the fusing element and the lead wire is welded, the lead wire side receiving wire is deformed to be pressed against the fusing element so that the accommodating groove wraps at least half of the outer surface of the fusing element. . delete The method of claim 1, The receiving groove is a surface-mounted small fuse, characterized in that it is provided to have a "V" shape. The method of claim 1, The receiving groove is a surface-mounted small fuse, characterized in that it is provided to have a "U" shape. delete delete The method of claim 1, The receiving groove is a surface-mounted small fuse, characterized in that the lead wire punched. delete In a small surface-mount fuse having a base having a pair of through holes, a pair of lead wires provided in the base to penetrate the through holes, and a fusing element connecting one end of each of the lead wires. , The lead wire and the fusing element are directly welded to each other through arc welding in a state where at least a part of the end of the fusing element is accommodated in and in contact with the corresponding lead wire end, An accommodating groove is provided along one of the ends of the lead wire so as to accommodate at least a portion of the end of the fusing element along a length direction of the lead wire. An end portion of the lead wire to which one end of the fusing element is coupled forms a crimp portion that is compressed to be flat, and the receiving groove is provided in the crimp portion. And the crimping portion is pressurized and deformed to be in close contact with the fusing element so as to cover at least half the outer surface of the fusing element accommodated in the receiving groove before the fusing element and the lead wire are welded. delete delete delete

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