The present application is based on, and claims priority from Japanese Patent Application No. 2018-043944, filed Mar. 12, 2018, the disclosure of which is hereby incorporated by reference herein in its entirety.
The present application relates to a cable connection structure for connecting a round cable and a flat cable and a manufacturing method of the cable connection structure.
A conventional cable connection structure of this kind is illustrated in
The plurality of round cables W1 and the flat cable W2 held by the holder 50 overlap each other at the end portions thereof, and are pulled out in mutually opposite directions. Core wires (not illustrated) at end portions of the round cables W1 and conductors (not illustrated) at an end portion of the flat cable W2 are connected to each other by connecting portions 53 formed by ultrasonic welding or the like.
The mold resin portion 51 collectively covers the holder 50 and the round cables W1 and the flat cable W2 pulled out from the holder 50. Accordingly, the portion including the connecting portions 53 is waterproofed by the mold resin portion 51.
The core wires (not illustrated) of the round cables W1 and the conductors (not illustrated) of the flat cable W2 are connected by, for example, ultrasonic welding using an ultrasonic welding device 30, as illustrated in
Incidentally, when the holder 50 holding the round cables W1 and the flat cable W2 is set in the ultrasonic welding device 30, the round cables W1 may have to be set away from the ultrasonic welding device 30, and the flat cable W2 may have to be set in the space between the horn 33 and the device main body 31 in some cases. For example, in a case where the round cables W1 compose a long wire harness (not illustrated), the wire harness (not illustrated) may not be set in the space between the horn 33 and the device main body 31.
Although the flat cable W2 is excellent in flexibility in the direction of bending the flat surface, it can hardly be bent in the direction orthogonal to the flat surface (lateral direction). Therefore, there is a problem that it is difficult to perform ultrasonic welding in a case where the flat cable W2 is sufficiently longer than the distance between the horn 33 and the device main body 31. There is a similar problem with a connecting device other than the ultrasonic welding device 30.
The present application has been conceived to solve the problem described above, and an object of the present application is to provide a cable connection structure, as well as a manufacturing method of the cable connection structure, capable of being manufactured using a connecting device such as an ultrasonic welding device regardless of a length of a flat cable.
A cable connection structure according to a first aspect of the present application includes: a round cable having a round cross section and including a core wire and a round insulating sheath covering the outer circumference of the core wire; a flat cable having a cross section in a flat rectangular shape and including a tabular conductor and a flat insulating sheath covering the conductor; a holder holding the end portion of the round cable and the end portion of the flat cable and pulling out the round cable and the flat cable in the same direction in an overlapped state; a connecting portion in which the core wire exposed from an end portion of the round cable and the conductor exposed from an end portion of the flat cable held by the holder are connected to each other; and a waterproof exterior portion collectively covering the outer circumference of the holder and the outer circumference of the round cable and the flat cable pulled out from the holder.
A manufacturing method of a cable connection structure according to a second aspect of the present application includes: a cable setting step of holding, in a state in which a round cable and a flat cable are pulled out in a same direction in an overlapped state, the end portion of the round cable and the end portion of the flat cable in a holder; a connecting step of connecting a core wire exposed from the end portion of the round cable held by the holder and a conductor exposed from the end portion of the flat cable held by the holder; and an exterior forming step of forming a waterproof exterior portion covering, with an insulating resin, the holder, the round cable pulled out from the holder, and the flat cable pulled out from the holder.
According to the aspects of the present application, in the connecting step of connecting the core wire exposed from the end portion of the round cable and the conductor exposed from the end portion of the flat cable, the round cable and the flat cable are pulled out from the holder in the same direction, whereby it can be manufactured using a connecting device such as an ultrasonic welding device regardless of a length of the flat cable.
Hereinafter, embodiments will be described with reference to the drawings.
Each of the round cables W1 has a round cross section, and includes the core wire 1a and an insulating sheath 1b covering the outer circumference of the core wire 1a. The core wire 1a is exposed from the insulating sheath 1b at an end portion of each of the round cables W1.
The flat cable W2 has a cross section in a flat rectangular shape, and includes a plurality of tabular conductors 2a arranged in parallel at intervals, and an insulating sheath 2b collectively covering the plurality of tabular conductors 2a. Each of the conductors 2a is exposed from the insulating sheath 2b at an end portion of the flat cable W2.
The holder 10 includes a round cable holder 11 for holding the end portions of the round cables W1, and a flat cable holder 15 for holding the end portion of the flat cable W2.
The round cable holder 11 is formed of an insulating material. As illustrated in
The flat cable holder 15 is formed of an insulating material. As illustrated in
As illustrated in
The mold resin portion 21 is formed of an insulating resin. The mold resin portion 21 collectively covers, with no gap left, the outer exposed surface of the round cable holder 11, the outer exposed surface of the flat cable holder 15, the outer circumference of each of the round cables W1 pulled out from the round cable holder 11, and the outer circumference of the flat cable W2 pulled out from the flat cable holder 15.
In the cable connection structure 3A according to the first embodiment, the mold resin is firmly attached onto, with no gap left, the outer circumference surface of each of the round cables W1 and the outer circumference surface of the flat cable W2 at the positions of the round cables W1 pulled out from the mold resin portion 21 to the outside and the position of the flat cable W2 also pulled out from the mold resin portion 21 to the outside, thereby securing waterproof property of the connecting portion 20.
The holder 10 includes the round cable holder 11 and the flat cable holder 15, and the round cables W1 are held by the round cable holder 11 while the flat cable W2 is held by the flat cable holder 15, thereby achieving good workability of holding cables with the holder 10.
Next, a manufacturing method of the cable connection structure 3A according to the first embodiment will be described. The manufacturing method of the cable connection structure 3A is performed in the order of a cable setting step, a connecting step, and an insert resin molding step that is an exterior forming step. The cable setting step includes a cable holding step and a holder combining step. Hereinafter, the manufacturing method of the cable connection structure 3A will be described in order.
In the cable holding step, the round cables W1 are held in the round cable holder 11, and the flat cable W2 is held in the flat cable holder 15. Specifically, as illustrated in
In the holder combining step, the round cable holder 11 and the flat cable holder 15 are joined together. Specifically, as illustrated in
In the connecting step, the round cables W1 and the flat cable W2 are electrically connected by ultrasonic welding using the ultrasonic welding device 30. As illustrated in
Specifically, in the connecting step, the round cables W1 and the flat cable W2 pulled out from the combined round cable holder 11 and the flat cable holder 15 are not arranged in the space between the horn 33 and the device main body 31, but are arranged in the open space on the opposite side, in such a manner that the combined round cable holder 11 and the flat cable holder 15 are positioned on the anvil 34. Then, by the branched horn 33, ultrasonic vibration is applied (in the direction of the arrow in
In the insert resin molding step, insert resin molding is performed with the round cable holder 11, the flat cable holder 15, the round cables W1 pulled out from the round cable holder 11, and the flat cable W2 pulled out from the flat cable holder 15 serving as inserts, and the mold resin portion 21 is molded. In this manner, the cable connection structure 3A as illustrated in
As described above, the cable connection structure 3A according to the first embodiment includes the round cables W1 each having a round cross section and including the core wire 1a and the round insulating sheath 1b covering the outer circumference of the core wire 1a, the flat cable W2 having a cross section in a flat rectangular shape and including the tabular conductors 2a and the flat insulating sheath 2b covering the conductors 2a, the holder 10 holding the end portions of the round cables W1 and the end portion of the flat cable W2 and pulling out the round cables W1 and the flat cable W2 in the same direction in an overlapped state, the connecting portions 20 in which the core wires 1a exposed from the end portions of the round cables W1 and the conductors 2a exposed from the end portion of the flat cable W2 held by the holder 10 are connected, and the mold resin portion 21 as a waterproof exterior portion that collectively covers the outer circumference of the holder 10 and the outer circumference of the round cables W1 and the flat cable W2 pulled out from the holder 10. In the step of connecting the core wires 1a of the round cables W1 and the conductors 2a of the flat cable W2, the round cables W1 and the flat cable W2 are pulled out from the holder 10 in the same direction, whereby it can be manufactured using a connecting device such as the ultrasonic welding device 30 regardless of a length of the flat cable W2.
Other configurations in the second embodiment are the same as those in the first embodiment, and the same constituent elements are denoted by the same reference signs to omit redundant descriptions.
As illustrated in
Next, a manufacturing method of the cable connection structure 3B according to the second embodiment will be described. In the manufacturing method of the cable connection structure 3B according to the second embodiment, a cable setting step (cable holding step and holder combining step) and a connecting step are performed in a similar manner to those in the first embodiment, and thus descriptions thereof will be omitted. The manufacturing method of the cable connection structure 3B according to the second embodiment is different from the first embodiment only in an insert resin molding step. That is, as illustrated in
Each of the round cables W1 has a round cross section, and includes the core wire 1a and an insulating sheath 1b covering the outer circumference of the core wire 1a. The core wire 1a is exposed from the insulating sheath 1b at the end portion of each of the round cables W1.
The flat cable W2 has a cross section in a flat rectangular shape, and includes a plurality of tabular conductors 2a arranged in parallel at intervals, and an insulating sheath 2b collectively covering the plurality of tabular conductors 2a. Each of the conductors 2a is exposed from the insulating sheath 2b at the end portion of the flat cable W2.
The holder 10A is formed of an insulating material. As illustrated in
The upper side of each of the round cable arrangement grooves 26 is opened. The round cable arrangement grooves 26 are partitioned by dividing walls 25a in the crosswise direction. The distal end side of each of the round cable arrangement grooves 26 in the crosswise direction is partitioned by partition walls 25b. At the time of ultrasonic welding, the horn 33 of the ultrasonic welding device 30 is inserted from the opening portions above the partition walls 25b. Each of the round cables W1 is arranged in the corresponding round cable arrangement groove 26 in such a manner that the core wire 1a exposed at the end portion is positioned at the portion partitioned by the partition walls 25b.
The flat cable arrangement chamber 27 is formed to be surrounded by the base wall 25 and a surrounding wall 28 covering the lower part of the base wall 25. The partition walls 25b extend toward the distal end side of the flat cable arrangement chamber 27 in the crosswise direction. The distal end side of the flat cable arrangement chamber 27 is partitioned in the crosswise direction by the partition walls 25b. A plurality of through holes 28a opened to the flat cable arrangement chamber 27 is formed at the position on the surrounding wall 28 where the partition walls 25b are positioned. At the time of ultrasonic welding, the anvil 34 of the ultrasonic welding device 30 is inserted from the through holes 28a. The flat cable W2 is arranged in the flat cable arrangement chamber 27 in such a manner that the conductors 2a exposed at the end portion are positioned at the portions partitioned by the partition walls 25b.
On the base wall 25, a pair of hooking claws 29 is provided to protrude from the position on the side opposite to the direction in which the flat cable W2 is inserted into the flat cable arrangement chamber 27.
The round cables W1 and the flat cable W2 held by the holder 10A are pulled out from the holder 10A in the same direction. The end portion of each of the round cables W1 and the end portion of the flat cable W2 are arranged to overlap each other.
On the inner circumference surface of the heat shrinkable tube 24, the hot melt adhesive (insulating resin) 23, which is a thermoplastic adhesive, is attached over the entire region. The hot melt adhesive 23 is thermally melted by heating to the heat shrinkable tube 24 to collectively cover the outer exposed surface of the holder 10A and the outer circumference of the round cables W1 and the flat cable W2 pulled out from the holder 10A with no gap left, and is solidified. The heat shrinkable tube 24 is made in the shrunk state, and covers the outer circumference of the solidified hot melt adhesive 23 with no gap left.
In the cable connection structure 3C according to the third embodiment, the hot melt adhesive (insulating resin) 23 is firmly attached to, with no gap left, the outer circumference surface of each of the round cables W1 and the outer circumference surface of the flat cable W2 at the position of the round cables W1 pulled out from the hot melt adhesive 23 to the outside and the position of the flat cable W2 also pulled out from the hot melt adhesive 23 to the outside, thereby securing waterproof property of the connecting portion 20.
Next, a manufacturing method of the cable connection structure 3C according to the third embodiment will be described. The manufacturing method of the cable connection structure 3C according to the third embodiment is performed in the order of a cable setting step, a connecting step, and a tube shrinking step that is an exterior forming step. Hereinafter, the manufacturing method of the cable connection structure 3C according to the third embodiment will be described in order.
In the cable setting step, as illustrated in
Next, the round cables W1 are inserted into the round cable arrangement grooves 26 from above the holder 10A. Then, as illustrated in
The core wires 1a exposed at the end portions of the round cables W1 and the conductors 2a exposed at the end portion of the flat cable W2 are arranged to overlap each other, and the overlapping portions are exposed from the holder 10A to the outside. The round cables W1 and the flat cable W2 are pulled out from the holder 10A to overlap each other in the same direction.
In the connecting step, the round cables W1 and the flat cable W2 are electrically connected by ultrasonic welding using the ultrasonic welding device 30. As illustrated in
As illustrated in
In the tube shrinking step, first, the flat cable W2 is bent in the direction indicated by the broken line arrow in
Next, the heat shrinkable tube 24 and the hot melt adhesive 23 are heated. Then, as illustrated in
As described above, the cable connection structure 3C according to the third embodiment includes the round cables W1 each having a round cross section and including the core wire 1a and the round insulating sheath 1b covering the outer circumference of the core wire 1a, the flat cable W2 having a cross section in a flat rectangular shape and including the tabular conductors 2a and the flat insulating sheath 2b covering the conductors 2a, the holder 10A holding the end portions of the round cables W1 and the end portion of the flat cable W2 and pulls out the round cables W1 and the flat cable W2 in the same direction in an overlapped state, the connecting portions 20 in which the core wires 1a exposed from the end portions of the round cables W1 and the conductors 2a exposed from the end portion of the flat cable W2 held by the holder 10A are connected, and the heat shrinkable tube 24 to which the hot melt adhesive 23 is attached as a waterproof exterior portion that collectively covers the outer circumference of the holder 10A and the outer circumference of the round cables W1 and the flat cable W2 pulled out from the holder 10A. In the step of connecting the core wires 1a of the round cables W1 and the conductors 2a of the flat cable W2, the round cables W1 and the flat cable W2 are pulled out from the holder 10 in the same direction, whereby it can be manufactured using a connecting device such as the ultrasonic welding device 30 regardless of a length of the flat cable W2.
In the cable connection structure 3A according to the first embodiment and the cable connection structure 3B according to the second embodiment, the holder 10 is divided into the round cable holder 11 and the flat cable holder 15. However, it may be one component.
In the cable connection structure 3C according to the third embodiment, the holder 10A is one component. However, the holder 10A may be two components as in the cable connection structure 3A according to the first embodiment and the cable connection structure 3B according to the second embodiment.
In the cable connection structure 3C according to the third embodiment, the tube shrinking step is performed in such a manner that the flat cable W2 is bent to be guided in the direction different from the pulled-out direction from the holder 10A and set. However, as in the first embodiment, the flat cable W2 may not be bent, and the tube shrinking step (heating with respect to heat shrinkable tube 24 and hot melt adhesive 23) may be performed while the flat cable W2 and the round cables W1 are pulled out from the holder 10A in the same direction.
In the cable connection structure 3C according to the third embodiment, the heat shrinkable tube 24 that changes its shape by thermal action is used. However, it may be a shrinkable tube that changes its shape by the action of light or the like.
In the first to third embodiments, the core wires 1a of the round cables W1 and the conductors 2a of the flat cable W2 are connected by ultrasonic welding using the ultrasonic welding device 30. However, it is only necessary to use a connecting device capable of electrically connecting the core wires 1a of the round cables W1 and the conductors 2a of the flat cable W2, which may be, for example, a resistance welding device.
Number | Date | Country | Kind |
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2018-043944 | Mar 2018 | JP | national |