JP5903399B2 - Multipolar fusible link - Google Patents

Description

The present invention relates to a multipolar fusible link mainly used in an electric circuit for automobiles.

Conventionally, multipolar fusible links have been used to protect various electrical components when an overcurrent flows between a battery and various electrical components in an automobile or the like. As shown in FIG. 3A, a conventionally known multipolar fusible link 200 mainly includes an input terminal portion 210 and a substantially rectangular shape in plan view in which a current input from the input terminal portion 210 flows. And a plurality of terminal parts (240A to 240D) connected to the bus bar part 220 via fusible parts (230A to 230D).

A battery power source or the like is connected to the input terminal portion 210 of the multipolar fusible link 200, and various electrical components are connected to the terminal portions (240A to 240D). Thereby, it becomes the structure by which a fuse is provided in the electric circuit between battery power supplies etc. and various electrical components. When an unintended high current flows in the electric circuit, the fusible body portion 230 is melted by heat generated by the high current, and the various electrical components are protected from excessive current.

Further, in the multipolar fusible link 200 including the plurality of terminal portions 240, the fusible portion 230 having various ratings is connected between each terminal portion 240 and the bus bar portion 220. For example, the multipolar fusible link 200 shown in FIG. 3A has a fusible part 230A with a rating of 50A (ampere), a fusible part 230B with a rating of 40A, and a rating from the side close to the input terminal part 210. A 30A fusible part 230C and a 20A fusible part 230D are connected. In the drawing, the rating of each fusible part is displayed on the connected terminal part 240 for convenience.

By the way, generally these soluble body parts are made high in the full length, ie, height, of a soluble body part, in order to make resistance value of a soluble body part large, when a rating becomes small. For example, as shown in FIG. 3A, the height a1 of the fusible part 230A having a rating of 50A, the height a2 of the fusible part 230B having a rating of 40A, and the height a3 of the fusible part 230C having a rating of 30A. The height a4 of the fusible body portion 230D having a rating of 20A increases as the rating decreases (a1 <a2 <a3 <a4).

Various shapes and arrangements of the terminal portions 240 are conceivable. In the present specification, for convenience of explanation, the height of each terminal portion 240 is unchanged at d0, and the lower end of each terminal portion 240 is the same. Are all aligned in a horizontal row. In addition, the heights a1 to a4 of each soluble body part are also unchanged.

Therefore, as shown in FIG. 3A, the heights of the respective soluble body portions 230 arranged in a horizontal row gradually increase to heights a1, a2, a3, and a4 as the distance from the input terminal portion 210 increases. Yes.

And since the lower end part 222 of the bus bar part 220 having a substantially rectangular shape in plan view is linear, when the lower end part 222 is connected to the fusible part 230D having the highest height, the other fusible part 230A and fusible part 230B. And a gap is formed between the front end and the lower end portion 222 of each of the fusible body portions 230C, and they cannot be connected to each other. Therefore, a height adjusting unit 250A, a height adjusting unit 250B, and a height adjusting unit 250C are provided at the tip of each soluble body part so that each soluble body part and the lower end part 222 can be connected.

The height L0 of the multipolar fusible link 200 having the above configuration is L0 = (c0 + a4 + d0). Since the height a4 and the height d0 are unchanged, the height L0 depends on the width c0 of the bus bar portion 220. However, since the bus bar portion 220 has a substantially rectangular shape in plan view and the width c0 is uniform, there is a limit to further reducing the height L0 of the multipolar fusible link 200. . As described above, since the dimensional regulation of the height of the multipolar fusible link 200 is severe, there is a problem that, for example, the fuse box to which the multipolar fusible link 200 is attached cannot be made small.

On the other hand, the multipolar fusible link disclosed in Patent Document 1 is characterized in that the upper end portion of the bus bar portion is inclined in order to suppress variation in the fusing time of the fusible body portion. b) shows a multipolar fusible link 300 having this feature. However, as can be seen from FIG. 3B, even if the upper end 321 of the bus bar portion 320 is inclined, the height of the multipolar fusible link 300 is the same as the multipolar fusible link shown in FIG. The same problem as the height L0 of the link 200 cannot be solved.

JP 2012-230856 A

In view of the above problems, an object of the present invention is to provide a multipolar fusible link capable of reducing the overall height with a simple structure.

The multipolar fusible link of the present invention includes an input terminal portion, a bus bar portion through which a current input from the input terminal portion flows, and a plurality of terminal portions connected to the bus bar portion via a fusible portion. A width between a lower end portion of the bus bar portion to which the fusible body portion is connected and an upper end portion on the opposite side of the lower end portion is connected to the lower end portion. It changes according to the said soluble body part to be made, The change is made | formed by changing the shape of the said lower end part.

According to the above feature, the width of the lower end portion and the upper end portion of the bus bar portion (hereinafter simply referred to as “the width of the bus bar portion”) is changed by changing the shape of the lower end portion. That is, if the width of the bus bar portion is narrowed by changing the shape of the lower end portion, a space in the height direction in which the fusible body portion can be arranged can be secured by the narrowed portion. That is, the lower end portion of the bus bar portion is shaved, and the fusible body portion can be arranged in the shaved portion, so that the entire bus bar portion can move to the fusible body portion side, and as a result, the multipolar fusible The overall link height is reduced.

Thus, if the height of the entire multipolar fusible link is lowered, the fuse box to which the multipolar fusible link is attached can be made smaller. In addition, since the multipolar fusible link is formed by punching a conductive metal sheet, the multipolar fusible link can be produced from a single metal plate if the height of the multipolar fusible link is reduced. The number of bulllinks will increase and the yield will improve.

Furthermore, in the multipolar fusible link of the present invention, the width between the lower end portion and the upper end portion of the bus bar portion is the end portion on the opposite side of the input terminal portion from the input terminal portion side. The shape of the lower end is changed so that the side is narrower.

In the multipolar fusible link, the current input from the input terminal portion flows through the bus bar portion and branches to the downstream terminal portion. Therefore, as the distance from the input terminal portion increases, the current branches to each terminal portion, so that the current flowing through the bus bar portion decreases. Therefore, according to the decrease of the flowing current, the width of the bus bar portion can be narrower on the end portion side opposite to the input terminal portion side than on the input terminal portion side. Therefore, it can be optimized according to the current flowing through the width of the bus bar portion.

Furthermore, in the multipolar fusible link of the present invention, the fusible part is arranged such that its rating is smaller on the end part side than on the input terminal part side.

In a multi-pole fusible link, a fusible part with a large rating generates more heat than a fusible part with a small rating, so a fusible part with a large rating is placed closer to the input terminal part. It is desirable to arrange a fusible part with a small rating farther away from the head. That is, when the fusible part is arranged so that the rating of the fusible part is smaller on the end part side than on the input terminal part side, the arrangement of the fusible part parts is optimal.

As described above, according to the multipolar fusible link of the present invention, the overall height can be reduced by a simple structure as compared with the conventional multipolar fusible link.

It is a top view of the multipolar fusible link which concerns on this invention. (A) is a top view of the multipolar fusible link of the present invention, and (b) is a plan view of an insulating housing attached to the multipolar fusible link of the present invention. (A) is a plan view of a conventional multipolar fusible link, and (b) is a plan view of another conventional multipolar fusible link.

  Embodiments of the present invention will be described below with reference to the drawings. 1 to 3, in order to facilitate comparison with the conventional multipolar fusible link, the rating and height of each fusible part, the height d0 of the terminal part, and the input terminal of the bus bar part The part-side width c0 is not changed. In addition, the shape of the bus-bar part in the embodiment demonstrated below, the rating, shape, etc. of a soluble body part show an example, and are not limited to these.

FIG. 1 shows a multipolar fusible link 100 according to the present invention. The multipolar fusible link 100 is connected to an input terminal portion 110, a bus bar portion 120, and a lower end portion 122 of the bus bar portion 120. The fusible part 130 and the terminal part 140 are connected via the fusible part 130.

Further, the fusible portion 130 is arranged in the same order as the conventional multipolar fusible link 200 from the side closer to the input terminal portion 110, the fusible portion 130A having a rating of 50A and a length of a1. A fusible body part 130B having a length of a2 at 40A, a rated part of 30A, a fusible part 130C having a length of a3, and a fusible part 130D having a rating of 20A and a length of a4 are connected.

As shown in FIG. 1, in the multipolar fusible link 100 of the present invention, the width of the bus bar portion 120 is not constant as in the prior art (see FIG. 3A) and becomes narrower toward the end portion 123. ing. Hereinafter, the reason why the width of the bus bar portion 120 is changed in this way will be briefly described.

The current flowing through the multipolar fusible link 100 is first input from the input terminal portion 110 and flows through the bus bar portion 120 toward the end portion 123. In the process, the current branches to each terminal part 140 via each fusible part 130. More specifically, first, a current of 140 A is input to the input terminal unit 110. And as it progresses from the input terminal part 110 to the terminal part 123, a current of 50A branches to the fusible part 130A. Then, the current flowing from the point A to the end portion 123 side is reduced by the branched 50A, and thus becomes 90A.

Therefore, the width of the bus bar portion 120 closer to the end portion 123 than the point A can be set to a width b1 narrower than the width c0 according to the current of 90A flowing therethrough. That is, the shape of the lower end portion 122 can be changed so that the width of the upper end portion 121 and the lower end portion 122 becomes narrow.

Similarly, at point B on the end portion 123 side from point A, the current flowing toward the end portion 123 side is reduced by the amount of 40A branched to the fusible body portion 130B, and thus becomes 50A. Therefore, the width of the bus bar portion 120 on the terminal end 123 side from the point B can be a width b2 narrower than the width b1 according to the current of 50A flowing therethrough.

In this way, as the distance from the input terminal portion 110 increases, the flowing current diminishes to each fusible body portion, so that the width b3 of the bus bar portion 120 is the smallest at the end portion 123 farthest from the input terminal portion 110. It becomes. As described above, the width of the bus bar portion 120 can be optimized by gradually narrowing according to the flowing current.

And as shown in FIG. 1, each soluble body part (130B to 130D) can be arrange | positioned in the lower end part 122 of the bus-bar part 120 by the part which the width | variety of the bus-bar part 120 became narrow gradually with b1, b2, b3. Space S is secured. Therefore, the bus bar portion 120 can be brought closer to each fusible body portion 130 by the space S. As a result, the overall height of the multipolar fusible link 100 is reduced.

Specifically, the height L1 = (b3 + a4 + d0) of the multipolar fusible link 100 is lower than the height L0 = (c0 + a4 + d0) of the conventional multipolar fusible link 200 because of the relationship of width b3 <c0. I can see that

Moreover, as shown in FIG. 1, each soluble body part (130A to 130D) is arranged side by side so that a rating may become small gradually as it leaves | separates from the input terminal part 110 side. This is because a fusible part with a large rating generates more heat than a fusible part with a small rating, and therefore, a fusible part with a large rating is arranged closer to the input terminal part 210 and is far from the input terminal part 210. This is because it is desirable to arrange a fusible part having a small rating in the case, and this is the optimum arrangement.

And since the soluble body part with a smaller rating increases in height, the disposition of each soluble body part shown in FIG. 1 gradually increases as the distance from the input terminal part 110 side increases. It will be.

On the other hand, the width of the bus bar portion 120 is reduced as the distance from the input terminal portion 110 side increases. Therefore, a space in the height direction in which the fusible part can be arranged is secured at the lower end part 122 of the bus bar part 120 as the distance from the input terminal part 110 side increases.

That is, as the distance from the input terminal portion 110 side increases, the height of each fusible body portion gradually increases, but on the other hand, the width of the bus bar portion 120 also gradually decreases, thereby increasing the height. A space where each soluble body portion can be arranged is secured.

Therefore, the shape of the bus bar portion 120 whose width becomes narrower as it goes away from the input terminal portion 210 side is best suited to the arrangement of each fusible body portion whose rating becomes smaller as it goes away from the input terminal portion 110 side. It will be optimal.

In the present embodiment, the width of the bus bar portion is narrowed by inclining the lower end portion of the bus bar portion linearly, but is not limited thereto, and the width is gradually reduced. It can be changed arbitrarily.

Next, FIG. 2 shows an aspect in which an insulating housing is attached to the multipolar fusible link of the present invention.

The multipolar fusible link 100 is formed by punching a metal plate having a uniform thickness into a shape as shown in FIG. 2A, and integrally forming the bus bar portion 120, the fusible portion 130, and the terminal portion 140. Yes. As the material of the metal plate, a conductive metal such as copper can be used. In addition, the bus bar part 120, the fusible body part 130, and the terminal part 140 may be formed by individually preparing each member and welding them, instead of punching out a single plate and integrally forming it. .

Next, as shown in FIG. 2B, an insulating housing H made of an insulating synthetic resin or the like is mounted so as to be sandwiched from above and below the multipolar fusible link 100. However, the input terminal portion 110 and the terminal portion 140 of the multipolar fusible link 100 are exposed to be connected to a fuse box or the like. Moreover, since the soluble body part 130 is covered with the transparent window W of the insulation housing H, the soluble body part 130 can be visually recognized from the outside. The multipolar fusible link 100 with the insulating housing H attached is used by being attached to a fuse box or the like.

  In addition, the multipolar fusible link of the present invention is not limited to the above-described examples, and various modifications and combinations are possible within the scope described in the claims and the scope of the embodiments. Such modifications and combinations are also included in the scope of the right.

The application of the multipolar fusible link of the present invention is not limited to an automobile electric circuit, and can be used as a fuse in an electric circuit for various applications, and of course these are also included in the scope of the present invention.

DESCRIPTION OF SYMBOLS 100 Multipolar fusible link 110 Input side terminal part 120 Bus bar part 121 Upper end part 122 Lower end part 123 Terminal part 130 Fusible part 140 Terminal part

Claims (1)

A multipolar fusible link comprising an input terminal part, a bus bar part through which current input from the input terminal part flows, and a plurality of terminal parts connected to the bus bar part via a fusible part. And
The width between the lower end portion of the bus bar portion to which the fusible body portion is connected and the upper end portion on the opposite side of the lower end portion is changed according to the fusible body portion connected to the lower end portion,
The change is made by changing the shape of the lower end,
The width between the lower end portion and the upper end portion of the bus bar portion is:
The shape of the lower end portion is changed so that the end portion side opposite to the input terminal portion is narrower than the input terminal portion side,
The fusible link is characterized in that the fusible part is arranged so that its rating is smaller on the end part side than on the input terminal part side .

Images