JP5740242B2 - Multi-fusible link - Google Patents

Description

  The present invention relates to a multi-fusible link used for distributing and supplying battery current to a load of a vehicle body in an automobile or the like, and more particularly to a multi-fusible link that can be arranged even in a narrow arrangement space.

  In automobiles, fusible links are used to distribute and supply battery current to the load of the vehicle body. Patent Document 1 describes a fusible link unit.

The fusible link unit described in Patent Document 1 is formed by engaging and assembling a plurality of fusible links, and connecting from the load of the vehicle body to one fusible link connected to the battery terminal. Other fusible links connected to the electric wires are assembled so as to intersect at a predetermined intersection angle. In order to maintain the crossing state of one fusible link and another fusible link, a holding member that holds these at a predetermined crossing angle is used. Each of the plurality of fusible links and holding members of Patent Document 1 is formed by processing a conductive metal plate into a three-dimensional three-dimensional structure and assembling the three-dimensional structure between the battery and the connecting wire. The entire fusible link unit has a three-dimensional structure.

JP 2010-251176 A

  Since the conventional fusible link unit has a three-dimensional three-dimensional structure and is arranged around the battery, there is a problem that the fusible link unit cannot be arranged when the arrangement space around the battery is small. is there.

  Therefore, an object of the present invention is to provide a multi-fusible link that can be arranged even when the arrangement space is small.

The multi-fusible link according to the first aspect of the present invention is formed at a middle portion in the longitudinal direction of the long main conductor so as to have a cross-sectional area smaller than the cross-sectional area of the main strand portion of the main conductor by rolling. The first fusible link consisting of a main fusing part that can be blown by an electric current, and a cross-sectional area smaller than the cross-sectional area of the branch wire portion of the branch conductor by rolling in the longitudinal intermediate portion of the long branch conductor Second and third fusible links formed by branch fusing portions that are formed and can be melted by a current of a predetermined value, and the second and third fusible links at one end in the longitudinal direction of the first fusible link. One end of the link is connected, and the joint portion is formed by branching the branch conductor from the main conductor.

 The invention according to claim 2 is the multi-fusible link according to claim 1, wherein the main conductor is formed of a plurality of strands, the branch conductor is formed of a plurality of strands, and the main fusing The part and the branch fusing part are formed by rolling a plurality of strands.

 A third aspect of the present invention is the multi-fusible link according to the second aspect, wherein the branch conductor is formed of a strand obtained by branching a plurality of strands of the main conductor according to a branch capacitance. It is characterized by that.

 Invention of Claim 4 is the multi-fusible link of any one of Claims 1-3, Comprising: The said main fusing part and the said branch fusing part are the said main conductor and the said branch in the said joint part. It is formed by rolling after branching the conductor.

  According to the first aspect of the present invention, the main conductor is branched into a plurality of branch conductors by connecting the second and third fusible links to the first fusible link by the joint portion. Therefore, it is possible to distribute current from a power source or the like.

  In addition, since the main fusing part provided in the first fusible link and the branch fusing parts provided in the second and third fusible links have smaller cross-sectional areas than the respective wire parts, The resistance is large and the temperature rises efficiently with current.

  Accordingly, when a current of a predetermined value or more flows through each fusible link, the main fusing part and the branch fusing part are blown out in a short time, and thus the connection electric wires connected to the multi-fusible link can be protected.

  The above multi-fusible link is an electric wire type multi-fusible link because each of the first, second, and third fusible links is formed of a long conductor. It is not a three-dimensional structure. For this reason, it can be easily arranged even in a narrow arrangement space.

  According to the second aspect of the invention, the main conductor and the branch conductor are formed by a plurality of strands, and the main fusing part and the branch fusing portion are formed by rolling a plurality of strands. A part and a branch fusing part can be formed easily.

  According to the invention described in claim 3, since the branch conductor is formed by branching a plurality of strands of the main conductor according to the branch capacitance, the branch conductor can be easily branched.

  According to invention of Claim 4, since the main fusing part and the branch fusing part are formed by the rolling process after the branch of the main conductor and the branch conductor, the main fusing part and the branch fusing part can be formed simultaneously. And the manufacturing process can be simplified.

It is a perspective view which shows the multi-fusible link of 1st Embodiment of this invention. (A)-(c) is a perspective view which shows the process of manufacturing the multi-fusible link of 1st Embodiment. It is a perspective view which shows the state which connected the multi fusible link to the battery. It is a perspective view which shows the multi-fusible link of 2nd Embodiment of this invention.

  Hereinafter, the present invention will be described in detail with reference to the illustrated embodiments. In each embodiment, the same member is described with the same reference numeral.

[First Embodiment]
FIG. 1 shows a multi-fusible link 1 according to a first embodiment of the present invention, in which a first fusible link 2, a second fusible link 3 branched from the first fusible link 2, and a third fusible link. It has a bull link 4.

  The first fusible link 1 has a long main conductor 11, and the second and third fusible links 3 and 4 have long branch conductors 21 and 31. The main conductor 11 and the branch conductors 21 and 31 are formed by stranded wires obtained by twisting a plurality of strands made of a conductive metal. As the conductive metal, copper, silver, aluminum, or an alloy thereof can be used. Thus, the multi-fusible link 1 formed by the first, second, and third conductors 11, 21, and 31 is an electric wire type and does not have a three-dimensional three-dimensional structure.

  As shown in FIG. 2A, the first fusible link 2 is provided with a main fusing part 13 at an intermediate part in the longitudinal direction of the long main conductor 11. The main fusing part 13 is formed by rolling the longitudinal intermediate part of the main conductor 11, and has a smaller cross-sectional area than other parts of the main conductor 11. That is, the main fusing part 13 is formed to have a smaller cross-sectional area than the main strand part 12 indicated by the D region in FIG. Since the cross-sectional area is small, the heat capacity of the main fusing part 13 is smaller than the heat capacity of the main wire part 12. Further, the electrical resistance of the main fusing part 13 is larger than the electrical resistance of the main strand part 12, and the amount of heat generation is larger than that of the main strand part 12, and the temperature rises more than that of the main strand part 12.

  A low melting point metal body 14 is welded to the main fusing part 13. A metal having a lower melting point than that of the main conductor 11 is used for the low melting point metal body 14. As the low melting point metal, for example, tin, cadmium, lead, bismuth, indium, or an alloy thereof can be used. When the low melting point metal body 14 is welded to the main fusing part 13, the low melting point metal body 14 is alloyed with the main fusing part 13 and diffuses into the main fusing part 13. Since the melting point of the main fusing part 13 is lower than the melting point of the main wire part 12 of the main conductor 11 due to alloying and diffusion of the low melting point metal body 14, the main fusing part 13 has a lower temperature than the main wire part 12. Can be melted. The current supply is stopped by the fusing of the main fusing part 13. As a result, no overcurrent flows downstream of the first fusible link 2, and the second and third fusible links 3, 4 connected to the downstream side and these fusible links 3, 4 are connected. It is possible to protect the connecting wire from the load that is applied.

  The first fusible link 2 is connected to a power source such as an in-vehicle battery, and a terminal fitting 40 is attached to one end as shown in FIG. The terminal fitting 40 includes a terminal portion 41 connected to a battery terminal (battery post) of the battery, and a crimping portion 42 formed continuously on the terminal portion 41. The crimp part 42 is crimped to the main conductor 11, and the terminal fitting 40 is attached to the first fusible link 2 by this crimping.

  FIG. 2 (c) shows the second and third fusible links 3 and 4. The second and third fusible links 3 and 4 are connected to one end of the first fusible link 2 so as to branch from the first fusible link 2 by the joint portion 5. To distribute the current. A connecting wire from a load is connected to the downstream side of the second and third fusible links 3 and 4.

  In the second and third fusible links 3, 4, branch fusing parts 23, 33 are provided in the middle part of the long branch conductors 21, 31 in the longitudinal direction. These branch fusing parts 23, 33 are formed by rolling the longitudinal intermediate part of the branch conductors 21, 31, and branch strand parts 22, 32 which are other parts of the branch conductors 21, 31. The cross-sectional area is smaller than that. Due to the small cross-sectional area, the branch fusing parts 23 and 33 have a smaller heat capacity than the branch strand parts 22 and 32 and a larger electrical resistance than the electrical resistance of the branch strand parts 22 and 32. . Thereby, the branch fusing parts 23 and 33 generate more heat than the branch wire parts 22 and 32, and the temperature rises more than the branch wire parts 22 and 32.

  The low melting point metal bodies 24 and 34 are welded to the branch fusing parts 23 and 33. For the low melting point metal bodies 24 and 34, a metal having a melting point lower than that of the branch conductors 21 and 31, for example, tin, cadmium, lead, bismuth, indium, or an alloy thereof is used. The low melting point metal bodies 24 and 34 are welded to the branch fusing parts 23 and 33, whereby the low melting point metal bodies 24 and 34 are alloyed with the branch fusing parts 23 and 33 and diffuse into the branch fusing parts 23 and 33. Since the melting point of the branch fusing parts 23 and 33 is lower than the melting point of the branch wire parts 22 and 32 of the branch conductors 21 and 31 due to the alloying and diffusion of the low melting point metal bodies 24 and 34, the branch fusing parts 23 and 33 Can be melted at a temperature lower than that of the branch wire portions 22 and 32. The current supply is stopped by blowing the branch fusing parts 23 and 33. Thereby, an overcurrent does not flow to the downstream side of the second and third fusible links 3 and 4, and the connection electric wire from the load connected to the downstream side can be protected.

  As shown in FIG. 1, the joint portion 5 connects the second and third fusible links 3 and 4 at one end in the longitudinal direction of the first fusible link 2. When the second and third fusible links 3 and 4 are connected, the branch conductors 21 and 31 of the fusible links 3 and 4 made of a plurality of strands are connected to the first fuse made of the plurality of strands. It can be performed by welding such as soldering to the main conductor 11 of the bull link 2. In this case, the number of wires corresponding to the branch capacity from the main conductor 11 of the first fusible link 2 is connected to the strands of the branch conductors 21 and 31 of the second and third fusible links 3 and 4. The joint portion 5 covers the connecting portions of the fusible links 2, 3, and 4, thereby protecting the wires at the connecting portions.

  FIG. 3 shows a state in which the multi-fusible link 1 of this embodiment is attached to an in-vehicle battery 45. The attachment to the battery 45 can be performed by passing the battery terminal 47 of the battery 45 through the terminal fitting 40 attached to the first fusible link 2 and tightening the connection bolt 49. On the other hand, a connecting wire from the load of the vehicle body is connected to the downstream side of the second and third fusible links 3 and 4 branched from the first fusible link 2. As a result, the current of the battery 45 can be distributed and supplied from the second and third fusible links 3 and 4 to the connecting wires.

  The multi-fusible link 1 of this embodiment is an electric wire type and does not have a three-dimensional three-dimensional structure. For this reason, it can arrange | position easily also with respect to a narrow arrangement | positioning space.

  The main fusing part 13 of the first fusible link 2 and the branch fusing parts 23 and 33 of the second and third fusible links 3 and 4 have a small cross-sectional area, and the temperature rises efficiently and the low melting point metal body. Since 14, 24, and 34 are welded and can be melted at a low temperature, when an overcurrent exceeding a predetermined value flows, they melt in a short time. Thereby, the connection electric wire connected to the multi-fusible link 1 can be protected.

[Second Embodiment]
FIG. 4 shows a multi-fusible link 1A according to the second embodiment of the present invention.

  In the multi-fusible link 1A, the branch conductors 21 and 31 of the second and third fusible links 3A and 4A are formed by branching the main conductor 11 of the first fusible link 2. That is, the main conductor 11 of the first fusible link 2 is composed of a plurality of strands of strands, and the branch conductors 21 and 31 of the second and third fusible links 3A and 4A are twisted of the main conductor 11. The multi-fusible link 1A is formed by using a single electric wire.

  The multi-fusible link 1A of this embodiment is manufactured by rolling the intermediate part in the longitudinal direction of the main conductor 11 of the first fusible link 2 to form the main fusing part 13 having a small cross-sectional area, and then the main fusing part. The joint portion 5A is formed by rolling an intermediate portion of the main conductor 11 on the downstream side of 13 to harden the strands. Then, the strand on the downstream side of the joint portion 5A is branched into two to form the branch conductors 21 and 31, and a branch fusing portion having a small cross-sectional area by rolling the intermediate portion in the longitudinal direction of the branch conductors 21 and 31. 23 and 33 are formed. Thereafter, the low melting point metal bodies 14, 24 and 34 are welded to the main fusing part 13 of the main conductor 11 and the branch fusing parts 23 and 33 of the branch conductors 21 and 31 to form the multi-fusible link 1A.

  The multi-fusible link 1A of such an embodiment is an electric wire type similarly to the multi-fusible link 1 of the first embodiment and does not have a three-dimensional three-dimensional structure. Easy to place. In addition, the main fusing part 13 and the branch fusing parts 23 and 33 having a small cross-sectional area in the first fusible link 2, the second and third fusible links 3 </ b> A and 4 </ b> A efficiently rise in temperature, and the low melting point metal body 14. 24, 34 are welded and can be melted at a low temperature. Therefore, when an overcurrent exceeding a predetermined value flows, they melt in a short time. Thereby, the connection electric wire connected to the multi-fusible link 1A can be protected.

  Furthermore, in this embodiment, the low melting point metal bodies 14, 24, and 34 can be simultaneously welded to the main fusing part 13 and the branch fusing parts 23 and 33. For this reason, the welding process of the low melting-point metal bodies 14, 24, and 34 can be decreased, and a manufacturing process can be simplified.

DESCRIPTION OF SYMBOLS 1, 1A Multi-fusible link 2 1st fusible link 3, 3A 2nd fusible link 4, 4A 3rd fusible link 5, 5A Joint part 11 Main conductor 12 Main strand part 13 Main fusing part 21 , 31 Branch conductor 22, 32 Branch strand
23, 33 Branch fusing part 14, 24, 34 Low melting point metal body

Claims (4)

A first fusing portion formed in a middle portion in the longitudinal direction of the long main conductor by a rolling process so as to have a cross-sectional area smaller than the cross-sectional area of the main strand portion of the main conductor and capable of fusing with a predetermined current. The fusible link of
A second fusing part formed by rolling at a middle portion in the longitudinal direction of the long branch conductor to have a cross-sectional area smaller than the cross-sectional area of the branch wire part of the branch conductor and capable of fusing with a predetermined current. A third fusible link;
One end of the second fusible link is connected to one end in the longitudinal direction of the first fusible link, and a multi-junction portion branches the branch conductor from the main conductor. Fusible link. The multi-fusible link according to claim 1,
The main conductor is formed of a plurality of strands, the branch conductor is formed of a plurality of strands, and the main fusing part and the branch fusing part are formed by rolling a plurality of strands. Multi-fusible link featuring A multi-fusible link according to claim 2,
The multi-fusible link according to claim 1, wherein the branch conductor is formed of a strand obtained by branching a plurality of strands of the main conductor according to a branch capacitance. The multi-fusible link according to any one of claims 1 to 3,
The main fusing part and the branch fusing part are formed by rolling after the main conductor and the branch conductor are branched at the joint part.

Images