1. Field of the Invention
The present invention relates to a crimp connection terminal that connects an electric wire and, for example, is housed in a connector housing, and mates with a connection terminal of an opposite side connector; and a production method for the same.
2. Description of Related Art
With the miniaturization and integration of electronic circuits in recent years, a demand has arisen for smaller connection terminals used in the connections of circuits. For example, a rod-shaped insertion portion into an opposite side connection terminal is used that has a smaller diameter than the electrical wire that will be connected and that has an outer diameter of about 0.5 mm×0.5 mm.
PTL 1: JP-A-2009-123597
With the miniaturization of connection terminals described above, the thickness of a conductive metal plate forming a connection terminal is decreased, the diameter of the electric wire is reduced, and the crimping force of a conductor crimping portion of the connection terminal securing a conductor portion of the electric wire is limited. Accordingly, trouble, that is, the conductor portion secured to the connection terminal falling out during use, is more likely to occur, and there is a concern about declines in electrical reliability.
As described in PTL 1, a countermeasure has been conceived in which a structure is formed in which two conductor crimping portions are stacked and grooves, holes, or the like are provided on an inner side of the conductor crimping portions to ensure the securing of the conductor portion.
However, this two-layer structure of conductor crimping portions also includes another plate-like member stacked at the bottom portion, which complicates the terminal production process and leads to an increase in the number of parts. Additionally, even when the grooves, holes, or the like are provided in the bottom portion, sufficient locking force cannot be obtained by forming the groove shapes, the holes, or the like.
An object of the present invention is to solve the problems described above, and provide a small crimp connection terminal whereby the conductor portion of the electric wire can be reliably crimped in the conductor crimping portion, and the reliability of the electrical connection can be ensured; and a production method for the same.
A crimp connection terminal according to the invention for achieving the object described above is a crimp connection terminal including a conductor crimping portion that includes a pair of crimping tabs erected in a U-shape, wherein the crimping tabs are formed by punching, stamping, and folding one conductive metal plate, and a conductor portion of an electric wire is crimped and secured by the pair of crimping tabs. The conductor crimping portion has a stacked structure in which at least a bottom layer plate and a top layer plate are stacked, the top layer plate includes a punched long hole, a recessed portion is formed in an upper portion of the punched long hole, and an edge, namely edge portions of the punched long hole and the recessed portion, is formed in two steps.
A production method for the crimp connection terminal according to the invention is a production method for the crimp connection terminal including a punching step of punching one conductive metal plate to form a pair of side portions protruding outward in a conductor crimping portion, and punching a punched long hole in a first side portion that becomes a top layer plate of a bottom portion of the conductor crimping portion; a stamping step of stamping from a back side of the first side portion to form a recessed portion along the punched long hole; and a folding step of folding such that the first side in which the punched long hole is formed is folded back on a second side portion so as to become the top layer plate, and so that the recessed portion formed in an upper portion of the punched long hole is positioned on a front surface side of the top layer plate.
According to the crimp connection terminal and the production method thereof of the invention, the crimping tabs of the conductor crimping portion have a two-layer structure obtained by folding a conductive metal plate. Furthermore, the elongated groove-like punched long hole is provided in the top layer plate of the conductor crimping portion and a step is provided in the edge of the punched long hole due to the recessed portion. Therefore, the crimping force on the conductor portion of the electric wire is strengthened, and the edges of the punched long hole and the recessed portion bite into the conductor portion in two steps, thereby increasing conductivity and locking. As a result, electrical reliability is improved.
The invention will be described in detail on the basis of the embodiments illustrated in the drawings.
First Embodiment
In the male connection portion 2, the conductive metal plate 1 is folded back to form a two-layer insertion end structure, but may also be a female connection portion or a male connection portion of a different form.
In the conductor crimping portion 3, a stacked structure is formed in which side portions 3a, 3b are folded back in part to form a bottom layer plate 3c and a top layer plate 3d, and a stacked pair of crimping tabs 3e, 3f facing diagonally upward are erected in a U-shape from both sides.
Moreover, the edges of the side portions 3a, 3b abut against each other in a rising portion of the top layer plate 3d, thereby forming a joint 3g. Additionally, for example, three elongated groove-like punched long holes 3i to 3k are formed, in an oblique direction with respect to a longitudinal direction of the crimp connection terminal, in a bottom portion 3h of the top layer plate 3d. The punched long hole 3i is subjected to further processing, but this will be described in detail later.
In the cover crimping portion 4, a pair of crimping tabs 4a, 4b facing diagonally upward are erected in a U-shape from both sides of a bottom portion 4c.
Actual crimp connection terminals may also include a stabilizer for stabilizing the posture of the crimp connection terminal within a connector housing, a locking portion for preventing pulling out of the crimp connection terminal in a forward-backward direction, and the like, but illustrations of these known mechanisms are omitted in the drawings.
Additionally, in the conductor crimping portion 3, the side portions 3a, 3b that become the bottom layer plate 3c and the top layer plate 3d each protrude outward from both sides with differing lengths and, for example, the three elongated groove-like punched long holes 3i to 3k are punched in the oblique direction in the longer side portion 3a. The punched long holes 3i to 3k provided in the side portion 3a are configured so as to be positioned on the bottom portion 3h on the top layer plate 3d side in a state in which when folded back and stacked on the other side portion 3b in a folding step. For example, the punched long hole 3i is formed long and the punched long holes 3j, 3k on both sides are formed shorter than the punched long hole 3i to allow for disposal in the oblique direction.
As a result of the forging by stamping, the conventional edge portion of the punched long hole 3i, namely an edge 3n, protrudes in an arc shape into the punched long hole 3i, and a total of six new arc-shaped edges 3n′ are formed on both sides of the inner edge at positions lower than the surface of the conductive metal plate 1. In reality, the original shapes of the edges 3n′ are not necessarily maintained, but the sharp shape of the corner portions of the edge 3n are substantially maintained as-is. Thus, the edges 3n′ of the punched long hole 3i and the edges 3m of the upper recessed portions 3l of the punched long hole 3i are formed in two steps as illustrated in
Note that, while there is no particular problem with the edges of the other short punched long holes 3j, 3k not being subjected to the stamping processing, the recessed portions 3l may be provided in the same manner as in the punched long hole 3i. Additionally, the number of the punched long holes 3i to 3k is not limited to three and, provided that there is at least one, any number may be used. However, there must be a punched long hole provided with the recessed portions 3l.
In an example of dimensional sizes of the punched long hole 3i and the like, a length of the punched long hole 3i is 1.8 mm, a width is 0.2 mm, a diameter of the round recessed portions 3l is 0.5 mm, a depth is 0.04 mm, and a width of the largest section of the portion where the edges 3n′ protrude into the punched long hole 3i is 0.05 mm.
In
The conductive metal plate 1 that has been punched and stamped as described above is, for example, chamfered and surface treated, as necessary and, thereafter, while being transported by the feed tab 5, is successively folded in various molding steps by a forming press and molded into the crimp connection terminal illustrated in
The electric wire 10 that is used is a so-called fiber electric wire in which core wires made from aramid fiber filaments having a diameter of about 20 μm are subjected to copper plating at a thickness of about 1 μm, and 130 of these core wires are twisted together. A diameter of the conductor portion 10b of this electric wire 10 is about 0.3 mm, and an outer diameter of the electric wire 10 including the insulation cover portion 10a is about 0.7 to 0.8 mm.
Thus, the conductor portion 10b will be bitten into in two steps even though the core wires of the conductor portion 10b are extremely thin and the depths of the edges 3m of the recessed portions 3l formed in the vicinity of the punched long hole 3i provided in the top layer plate 3d of the conductor portion 10b and the protruding edges 3n′ of the punched long hole 3i are small. Moreover, along with the biting by the edges of the punched long holes 3j, 3i, strong locking force against the pulling out of the conductor portion 10b is obtained. Furthermore, creeping distance along the edges increases since the edges 3m of the recessed portions 3l are arc-shaped, and, as such, the place where the core wires of the conductor portion 10b are bitten is lengthened and the locking force increases.
At the same time, even if an insulating film such as an oxide or a sulfide has formed on the surface of the core wires of the conductor portion 10b, the insulating film will be destroyed by the biting of the edges 3m of the recessed portions 3l, the edges 3n′ of the punched long hole 3i and the edges of the punched long holes 3j and 3k, and the conductivity between the conductor crimping portion 3 and the conductor portion 10b will be good.
Note that the core wires of the conductor portion 10b are twisted in a helical direction and, as such, the punched long holes 3i to 3k are formed in an oblique direction so as to intersect the core wires, thereby increasing the effectiveness of the biting by the edges of the punched long holes 3i to 3k.
In the cover crimping portion 4, the outside of the insulation cover portion 10a of the electric wire 10 is crimped by the pair of crimping tabs 4a, 4b and, as such, the electric wire 10 is strongly secured, thereby enabling resistance against pulling out forces acting on the electric wire 10.
Note that, in this embodiment, the joint 3g between the side portions 3a, 3b of the conductor crimping portion 3 is provided on the top layer plate 3d side of the one crimping tab 3f, and it is preferable that the joint 3g is provided on the top layer plate 3d rather than being provided on the bottom layer plate 3c because this position will be in the direction in which the space of the joint 3g narrows when crimping.
Additionally, if the joint 3g is provided on the top layer plate 3d and a slight space is provided, edge portions of this joint 3g will also bite into the conductor portion 10b, thereby further promoting the locking force. Note that the joint 3g need not necessarily be oriented in the longitudinal direction and, by punching the edges of the side portions 3a, 3b in the oblique direction, the joint 3g may be formed so as to be inclined from the longitudinal direction.
Note that, as illustrative dimensions of the various components of the crimp connection terminal after the electric wire 10 is crimped, as illustrated in
In the first embodiment described above, the conductor crimping portion 3 is a two-layer structure, but, as necessary, an intermediate layer plate may be provided between the bottom layer plate 3c and the top layer plate 3d by folding back, or a separate intermediate layer plate may be disposed to form a three-layer structure and further increase the crimping force.
Second Embodiment
For example, when using, as the conductor portion of the electric wire, a fiber electric wire made by twisting together a plurality of conducting wires that have extremely small diameters or the like, the conductor portion may unravel when the insulation cover portion is pulled off and the conductor portion is exposed when crimping to the crimp connection terminal, thereby making the crimping by the conductor crimping portion 3 difficult.
Therefore, as illustrated in
The conductor portion 10b of the electric wire 10′ processed in this manner does not unravel and, as such, it is possible to perform normal crimping by the conductor crimping portion 3. Additionally, at this time, as illustrated in
Note that when the electric wire 10′ illustrated in
1 Conductive metal plate
2 Male connection portion
3 Conductor crimping portion
3
a, 3b Side portion
3
c Bottom layer plate
3
d Top layer plate
3
e, 3f Crimping tabs
3
g Joint
3
h Bottom portion
3
i to 3k Punched long hole
3
l recessed portion
3
m, 3n, 3n′ Edge
4 Cover crimping portion
8 Conductor end crimping portion
10, 10′ Electric wire
10
a Insulation cover portion
10
a′ Remaining portion
10
b Conductor portion
Number | Date | Country | Kind |
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2016-042638 | Mar 2016 | JP | national |
2016-211688 | Oct 2016 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2017/008198 | 3/1/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2017/150644 | 9/8/2017 | WO | A |
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1976067321 | May 1976 | JP |
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Number | Date | Country | |
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20190044253 A1 | Feb 2019 | US |