1. Field of the Invention
This invention relates to a terminal fitting and an electrical cable equipped with the same.
2. Description of the Related Art
Heretofore, a terminal fitting disclosed, for example, in JP HEI 10 (1998)-125362A has been known as a terminal fitting for a wire harness of a motor vehicle. This terminal fitting includes a connecting section to be coupled to a mating conductor and a crimp contact section located in a rearward position from the connecting section so that the crimp contact section is crimped on an end of a core wire in a covered electrical cable to surround the end. If an oxide layer is formed on a surface around the core wire when crimping, an electrical connection is carried out under a condition where the oxide layer is interposed between the core wire and the crimp contact section. Consequently, there is a problem that a contact resistance will become great. Accordingly, in the prior art, a plurality of laterally elongated depressions that intersect an axial direction of the core wire are arranged in a back-and-forth direction on a contact surface that surround the end of the core wire, so that opening edges around the depressions penetrate the oxide layer on the core wire upon crimping to contact with inner conductors.
However, in the above structure, only the laterally elongated edges contact with the inner conductors in the core wire. In order to increase a whole length of each opening edge that contributes to enhance a performance in electrical connection, there is an idea that a plurality of polygonal depressions are arranged on the contact surface in a back-and-forth direction and in a right and left direction and that not only the edges extending in the right and left direction but also the edges extending in the back-and-forth direction are brought into contact with the inner conductors. However, the polygonal depressions are inevitably provided with angled corner portions. The core wire will engages with most straight edges of the depressions upon crimping and will not be able to engage with the angled corner portions.
In view of the above problems, an object of the present invention is to provide a terminal fitting and an electrical cable equipped with the same in which a whole periphery of an opening edge around a depression (including an edge around an angled corner portion) penetrates an oxide layer on a core wire to contact with inner conductors.
A terminal fitting of the present invention comprises: a connecting section to be coupled to a mating conductor; a crimp contact section to be crimped on an end of a core wire in a covered electrical cable so as to surround the end; a plurality of depressions provided on a contact surface of the crimp contact section for surrounding the core wire. The crimp contact section is located in a rearward position from the connecting section. The core wire includes a plurality of metallic strands and is covered with a sheath to form the covered electrical cable. Each of the depressions is formed into a polygonal shaped recess with which the core wire engages upon crimping. At least one of corner portions of the each depression is rounded.
According to the above structure, the core wire engages with the depressions upon crimping and the opening edge around each of the depressions penetrates an oxide layer on a core wire to contact with the inner conductors. In this case, since at least one of the corner portions of each depression is rounded, the core wire will engage with the rounded corner to penetrate the oxide layer on the core wire, thereby contacting with the inner conductors. Accordingly, the whole periphery of an opening edge around each depression penetrates an oxide layer on a core wire to contact with the inner conductors.
The following constructions will be preferable as embodiments of the present invention.
Each of the depressions is formed into a quadrangular shape including a pair of orthogonal side portions that are disposed at a front position and a back position on the contact surface to extend in a direction substantially orthogonal to an axial direction of the core wire, and a pair of adjacent side portions that are disposed adjacent to the orthogonal side portions on the contact surface and are disposed on right and left positions of the orthogonal side portions. The depressions are juxtaposed in an extending direction of the orthogonal side portions and in an extending direction of the adjacent side portions.
According to the above structure, since the projections in a die that forms the depressions in a pressing process are juxtaposed in the extending directions of the orthogonal side portions and adjacent side portions, grooves between the projections can be formed by a cutting machine, thereby easily producing the die.
Each of the depressions is provided with an opening edge having a substantially parallelogram. A pair of acute diagonal corner portions of the opening edge may be rounded.
In the case where the corner portions are acute, it is difficult in fact to embed the core wire into the corner portions. On the contrary, according to the above structure, since a pair of acute diagonal corner portions of the opening edge are rounded, it is possible to embed the core wire even in the diagonal corner portions.
A pair of obtuse diagonal corner portions of the opening edge may be angled. If the corner portions are obtuse, it is easy to embed the core wire in the corner portions. Thus, according to this structure, the diagonal corner portions are angled and these angled diagonal corner portions catch the core wire, thereby effectively restraining the core wire from moving in the axial direction of the core wire and in the direction orthogonal to the axial direction of the core wire.
The depressions disposed adjacent to each other in a back-and-forth direction may be arranged in a staggered manner to be overlapped on one another in the extending direction of the orthogonal side portions. According to this structure, it is possible to eliminate the line on which the depressions are not arranged in the axial direction of the core wire. That is, since more depressions are arranged closely, it is possible to increase the whole lengths of the opening edges around the depressions.
Straight edges except the corner portions at any one of the pair of orthogonal side portions may be arranged to be overlapped on one another in the extending direction of the orthogonal side portions. According to this structure, it is possible to eliminate the line on which the straight edges of the depressions are not arranged in the axial direction of the core wire. Accordingly, since the core wire engages with the straight edges at a whole width in the extending direction of the orthogonal side portions, it is possible to enhance a fixing force on the crimp contact section, thereby positively restraining the core wire from moving in the axial direction of the core wire.
The present invention is also directed to an electrical cable equipped with a terminal fitting. A core wire including a plurality of metallic strands is covered with a sheath to form an covered electrical cable. Any one of the above terminal fitting is crimped on an end of the core wire. The metallic strands may be made of aluminum or aluminum alloy.
According to the present invention, a whole periphery of an opening edge around each depression can penetrate an oxide layer on a core wire to contact with the inner conductors.
Referring now to
As shown in
The main body section 20 is provided in its interior with a elastic contact piece 21 that can be elastically deformable and is formed by bending a front side edge of a bottom surface 22 of the main body section 20 backward. A space between the elastic contact piece 21 and a surface (not shown) opposed to the piece 21 in the interior of the main body section 20 is adapted to receive a tab-like mating conductor (not shown).
A distance between the elastic contact piece 21 in a natural state and the opposed surface is set to be slightly smaller than a thickness of the mating conductor. Thus, when the mating conductor is inserted into the space between the piece 21 and the opposed surface while deflecting the elastic contact piece 21, the elastic contact piece 21 is brought into elastic and electrical contact with the mating conductor.
The crimp contact section 30 includes a substantially U-shaped wire barrel portion 31, and a substantially U-shaped insulation barrel portion 32 located on a backward position from the wire barrel portion 31. The wire barrel portion 31 and insulation barrel portion 32 include a base surface 33 that is continued to the bottom surface 22 of the main body section 20 and extends in a back-and-forth direction (in an axial direction of the core wire 42), and a pair of caulking pieces 31A and 32A (
As shown in
As shown in
Next, an arrangement of the serrations 34 will be explained below. The serrations 34 are aligned in a right and left direction and are spaced apart from one another by a given distance. The serrations 34 are also aligned in the extending direction of the adjacent side portions 34B and are spaced apart from one another by a given distance. The serrations 34 that are disposed adjacent to one another in a back-and-forth direction are arranged in a staggered manner so as to be overlapped on one another in the right and left direction.
The arrangement of the serrations 34 will be explained in more detail by referring to
Then, the first and second serrations 341 and 342 are overlapped on each other in the right and left direction on an area R1. The second and third serrations 342 and 343 are overlapped on each other in the right and left direction on an area R2. Thus, there is no line in which any serration does not exist in the back-and-forth direction. Accordingly, it is possible to closely arrange more serrations 34.
A clearance S1 between the serrations 341 and 343 in the right and left direction is set to be shorter than a length of each adjacent side portion 34B. Furthermore, a clearance S2 between the serrations 341 and 342 in the extending direction of the adjacent side portion 34B is set to be shorter than a length of each orthogonal side portion 34A. Accordingly, it is possible to increase a whole length of the opening edge of each serration 34 in comparison with a prior art structure in which only the orthogonal side portions 34A constitute the serrations mainly.
A distance P1 between the serrations 34 in the right and left direction is set to be equal to or greater than 0.1 mm (millimeters) and equal to or smaller than 0.8 mm (millimeters). In the first embodiment, the distance P1 is set to be 0.5 mm (millimeters). The distance P1 designates a distance between a midpoint on a diagonal line of one serration 34 and a midpoint on a diagonal line of the other serration 34 adjacent the one serration 34 in the right and left direction.
A distance P2 between the serrations 34 in the back-and-forth direction is set to be equal to or greater than 0.3 mm (millimeters) and equal to or smaller than 0.8 mm (millimeters). In the first embodiment, the distance P2 is set to be 0.5 mm (millimeters). The distance P2 designates a distance between a midpoint on a diagonal line of one serration 34 and a midpoint on a diagonal line of the other serration 34 adjacent to the one serration 34 in the slant direction (in the extending direction of the adjacent side portion 34B).
Next, an effect obtained by embedding the core wire 42 in the serrations 34 will be explained below. When the core wire 42 is crimped by the wire barrel portion 31, the core wire 42 is embedded in the serrations 34. Since the embedded portions of the core wire 42 are engaged with the orthogonal side portions 34A in the back-and-forth direction, this will contribute to enhance a fixing force that can restrain movement of the core wire 42 in the back-and-forth direction. At the same time, since the opening edges around the serrations 34 penetrate an oxide layer generated on the surface of the core wire 42 to contact with the inner conductors, this will contribute to enhance a performance in electrical connection.
In other words, to increase the whole lengths of the opening edges around the serrations 34 will contribute to enhance a performance in electrical connection. However, a method for embedding the core wire 42 in the serrations 34 by crimping is difficult in embedding the core wire 42 in corner portions on which the orthogonal side portions 34A and adjacent side portions 34B are coupled to one another. In particular, in the case where the corner portions are sharp or acute, this inclination will become remarkable.
Accordingly, in the first embodiment, a pair of acute diagonal corner portions at the parallelogram opening edge of each serration 34 are rounded, so that the core wire 42 can be embedded even at the diagonal corner portions 34C.
Next, a structure of a die for pressing the crimp section 30 will be briefly explained below. Although the die is not shown in the drawings, projections in the die for forming the serrations are aligned in the back-and-forth direction and spaced apart from one another by a given distance. The projections are also aligned in the extending direction of the adjacent side portions 34B and spaced apart from one another by a given distance. That is, grooves between the adjacent projections are aligned in the back-and-forth direction and in the extending direction of the adjacent side portions 34B. These grooves can be formed by a cutting machine. Accordingly, only curved surfaces of the projections corresponding to the diagonal corner portions 34C can be formed by an electric discharge machine. This can make it easy to produce the die.
The terminal fitting in the first embodiment is constructed above. Next, a method for producing an electrical cable equipped with the terminal fitting will be described below. Firstly, the sheath 43 is stripped at an end of the covered electrical cable 40 to expose the core wire 42. Secondly, the core wire 42 is disposed on the contact surface of the wire barrel portion 31, and the sheath 43 is disposed on the contact surface of the insulation barrel portion 32. Thirdly, the caulking pieces 31A of the wire barrel portion 31 and the caulking pieces 32A of the insulation barrel portion 32 are caulked onto the core wire 42 and the sheath 43, so that the core wire 42 is secured to the wire barrel 31 and the sheath 43 and core wire 42 are secured to the insulation barrel portion 32. Then, the electrical cable equipped with the terminal fitting is completed.
As described above, since the both diagonal corner portions 34C at the opening edges around the serrations 34 are rounded in the first embodiment, a substantially whole peripheries of the opening edges around the serrations 34 penetrate the oxide layer on the core wire 42, so that the wire barrel 31 can contact with the inner conductors. Since the serrations 34 are aligned in the right and left direction and in the slant direction, it is possible to easily cut the grooves between the projections that constitute the serrations in the die for pressing the crimp contact section 30. Furthermore, the serrations 34 are arranged in the staggered manner so that the serrations 34 are overlapped on one another in the right and left direction, it is possible to eliminate lines on which no serration exists in the back-and-forth direction, it is possible to closely arrange more serrations, and it is possible to increase the whole lengths of the opening edges around the serrations 34.
Next, referring now to
Each serration 35 in the second embodiment includes a pair of front and back orthogonal side portions 35A that extend in a right and left direction, and a pair of adjacent side portions 35B that are disposed adjacent to and on both sides of the orthogonal side portions 35A, as is the case with the first embodiment. The side portions 35A and 35B define a substantially parallelogram. A pair of angled diagonal corner portions 35C at the opening edge around the parallelogram of each serration 35 are rounded, so that the core wire 42 can be embedded even in the diagonal corner portions 35C, as is the case with the first embodiment.
Next, an arrangement of the serrations 35 will be explained below. The serrations 35 are aligned in a right and left direction and are spaced apart from one another by a given distance. The serrations 35 are aligned in the extending direction of the adjacent side portions 35B and are spaced apart from one another by a given distance. Straight edges of one of orthogonal side portions 35A except the diagonal corner portions 35C are arranged to be overlapped on one another in the right and left direction. In order to avoid a redundant explanation of the orthogonal side portions 35A in the back-and-forth direction, a front orthogonal side portion 35A will be described below as a representative example.
An arrangement of the serrations 35 will be explained below in detail by referring to
Then, the respective straight edges are overlapped on one another in an area R1 between the first and second serrations 351 and 352, are overlapped on each other in the right and left direction in an area R2 between the second and third serrations 352 and 353, are overlapped on each other in the right and left direction in an area R3 between the third and fourth serrations 353 and 354, and are overlapped on each other in the right and left direction in an area R4 between the fourth and fifth serrations 354 and 355. Thus, it is possible to eliminate any line in which any straight edge does not exist in the back-and-forth direction. Accordingly, since the core wire 42 engages the straight edges over the whole widths in the right and left direction, it is possible to enhance a fixing force of the wire barrel portion 31 and to surely prevent the core wire 42 from moving in the back-and-forth direction.
It should be noted that the present invention is not limited to the above embodiments described above and illustrated in the drawings. For example, the following embodiments will be fallen within a technical scope of the present invention.
(1) Although the respective serrations are aligned in the right and left direction and are spaced apart from one another by the given distance in the above embodiments, the serrations may be spaced apart from one another in the right and left direction by different distances in the present invention. Similarly, the respective serrations may be spaced apart from one another in the extending directions of the adjacent side portions by different distances.
(2) Although each serration has the substantially parallelogram opening edges in the above embodiments, the serration may has opening edges in a triangular shape or a square shape in the present invention. In this case, all of the corner portions of the serration may be rounded.
(3) Although one serration is provided with a pair of adjacent side portions in the above embodiments, the one serration may be provided with plural pairs of adjacent side portions in the present invention.
(4) Although the straight edges are overlapped on one another between the fourth and fifth serrations 354 and 355 in the above second embodiment, the straight edges may be overlapped on one another between the second and fifth serrations 352 and 355 in the present invention. That is, the straight edges may be arranged in the staggered manner so that the straight edges are overlapped on one another in the right and left direction.
(5) Only one of corner portions of each serration may be rounded.
Number | Date | Country | Kind |
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2008-189033 | Jul 2008 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2009/060470 | 6/8/2009 | WO | 00 | 1/4/2011 |