This application is a National Stage of International Application No. PCT/JP2015/067633, filed Jun. 18, 2015, claiming priorities based on Japanese Patent Application Nos. 2014-126411, filed Jun. 19, 2014 and 2014-239494, filed Nov. 27, 2014, the contents of all of which are incorporated herein by reference in their entirety.
The present invention relates to a crimp terminal.
It is known that the crimp terminal has a conductor crimp portion which includes a serration formed by cylindrical recesses on the inner surface and the conductor crimp portion is crimped to an end of a conductor of a wire so as to be connected to the conductor of the wire (for example, see Patent Document 1).
Patent Document 1: JP 2012-38453 A
Edge portions of the recesses forming the serration break an oxide film formed on the surface of the conductor of the wire, so that the connection between the conductor crimp portion and the conductor of the wire is achieved. In this regard, since the shape of the outer edge of the recess forming the serration is a circular shape in the above-mentioned crimp terminal, the outer edge of the serration is short with respect to an area which is occupied by the serration. In order to improve reliability in the connection between the conductor crimp portion and the conductor of the wire, it is necessary to increase the area of the recess by an increase in the diameter of the cylindrical recess in the above-mentioned crimp terminal. However, there is a problem that energy required for forming the serration is increased, if the area of the recess is increased by an increase in the diameter of the cylindrical recess.
An object of the invention is to provide a crimp terminal which can improve reliability in connection between the crimp terminal and a conductor portion of a wire while suppressing an increase in energy required for the forming of serrations.
[1] A crimp terminal according to the invention includes a barrel on which a recessed serration is formed, the barrel is to be bent and crimped to a conductor portion of a wire, and the shape of an outer edge of the serration is formed so that arcs each of which is convex outward continue to each other.
[2] In the invention, the shape of the outer edge may include a round shape which is formed at a connected portion between the adjacent arcs.
[3] In the invention, a smallest circle which is circumscribed about the shape of the outer edge may be a true circle.
[4] In the invention, the number of the arcs which form the shape of the outer edge may be 3, 4, or 6.
[5] A crimp terminal according to the invention includes a barrel on which a serration is formed, the barrel is to be bent and crimped to a conductor portion of a wire, and the serration includes: a recess which has a circular contour in a plan view; and a protrusion which is provided in the recess.
[6] In the invention, the protrusion may be connected to the contour of the recess in a plan view.
[7] In the invention, the protrusion may include a strip shape which linearly extends and passes through a center of the recess in a plan view.
[8] In the invention, the protrusion may include first and second strip shapes which linearly extend and are substantially orthogonal to each other at a center of the recess in a plan view, both end portions of the first strip shape in an extending direction of the first strip shape may be connected to the contour of the recess, and both end portions of the second strip shape in an extending direction of the second strip shape may be connected to the contour of the recess.
[9] In the invention, the following Equation (1) may be satisfied.
α=β=45° (1)
Here, in the Equation (1), α denotes an angle between an extending direction of the conductor portion and an extending direction of the first strip shape, and β denotes an angle between the extending direction of the conductor portion and the extending direction of the second strip shape.
[10] In the crimp terminal according to the invention, the crimp terminal includes the barrel on which serrations each of which is the serration are formed, the serrations may be disposed along the extending direction of the first strip shape or the extending direction of the second strip shape.
[11] In the invention, the protrusion may include a strip shape which linearly extends and passes through a center of the recess in a plan view, and both end portions of the strip shape in an extending direction of the strip shape may be connected to the contour of the recess.
[12] In the invention, the protrusion may include first to third strip shapes each of which linearly extends to a center of the recess from the contour of the recess in a plan view, the first to third strip shapes may be connected to each other at the center of the recess, and the following Equation (2) may be satisfied.
γ=δ=ε (2)
Here, in the Equation (2), γ denotes an angle between an extending direction of the first strip shape and an extending direction of the second strip shape, δ denotes an angle between the extending direction of the second strip shape and an extending direction of the third strip shape, and ε denotes an angle between the extending direction of the third strip shape and the extending direction of the first strip shape.
[13] In the invention, a round shape may be formed at an intersection between the protrusion and the contour of the recess.
According to the invention, the shape of the outer edge of the serration is formed so that arcs each of which is convex outward continue to each other. Accordingly, the outer edge of the serration can be made long with respect to the area which is occupied by the serration. Accordingly, it is possible to improve reliability in the connection between the crimp terminal and the conductor portion of the wire while an increase in energy required for forming the serration is suppressed.
According to the invention, the protrusion is provided in the recess of the serration. Accordingly, the edge portion formed within the contour of the recess can be made long. For this reason, it is possible to improve reliability in the connection between the crimp terminal and the conductor portion of the wire while an increase in energy required for forming the serration is suppressed.
A first embodiment of the invention will be described below with reference to the drawings.
The crimp terminal 1 in the present embodiment is a terminal which is attached to an end portion of a wire 2 (see
As illustrated in
The connecting portion 11 of the crimp terminal 1 is provided at one end portion (an end portion corresponding to −Y side in
As illustrated in
The structure or the shape of the connecting portion 11 or a method of connecting the connecting portion 11 to the connecting-counterpart terminal is not particularly limited. For example, the connecting portion 11 of the crimp terminal 1 may be a plug, and the connecting-counterpart terminal may be a receptacle.
The first barrel 12 of the crimp terminal 1 is a portion which is in contact with and fixed to the cover portion 22 of the wire 2 when the wire 2 is attached to the crimp terminal 1, and is provided at the other end portion (an end portion corresponding to +Y side in
The second barrel 13 is a portion which fixes the conductor portion 21 of the wire 2 when the wire 2 is attached to the crimp terminal 1, and is formed between the connecting portion 11 and the first barrel 12 as illustrated in
As illustrated in
When the wire 2 is to be attached to the crimp terminal 1, first, the cover portion 22 of the wire 2 is placed on the bottom portion 121 of the first barrel 12, and the conductor portion 21 of the wire 2 is placed on the bottom portion 131 of the second barrel 13 (see an arrow of
Likewise, the side portions 132 are bent so that tip portions 133 of the two side portions 132 of the second barrel 13 press a substantially widthwise central portion of the conductor portion 21 toward the −Z direction in
As illustrated in
As illustrated in
As illustrated in
As shown in
As illustrated in
For example, an interval between the island-shaped portions 142 formed on one side of one linear portion 141 may be different from an interval between the island-shaped portions 142 formed on the other side of the linear portion 141. The island-shaped portions 142 which are disposed so as to be arranged in one row are formed between adjacent linear portions 141 in the present embodiment. However, the island-shaped portions 142 which are disposed so as to be arranged in a plurality of lines may be formed between adjacent linear portions 141. A plurality of linear portions 141 may be formed between a pair of lines each of which includes the island-shaped portions 142 arranged in one row.
The shape of an outer edge of the island-shaped portion 142 (the shape of an edge portion 144 (see
Specifically, the first arc A1 is formed in a convex shape protruding toward a +Y direction in
In the present embodiment, each of the first to fourth arcs A1 to A4 is formed in the shape of a true semicircle having a radius r/2. For this reason, a circumscribed circle 15 which is circumscribed about the shape of the outer edge of the island-shaped portion 142 is a true circle. In
The “circumscribed circle” in the present embodiment is the smallest virtual circle which is in point contact with all the arcs A1 to A4 forming the island-shaped portion 142. For example, in a case in which the radii of the arcs forming the island-shaped portion 142 are different from each other, the circumscribed circle is an ellipse. In the present embodiment, since each of the arcs A1 to A4 forming the island-shaped portion 142 is formed in the shape of a true semicircle as described above, the circumscribed circle 15 is a true circle. The circumscribed circle 15 in the present embodiment corresponds to an example of “a smallest circle which is circumscribed about the shape of an outer edge” in the invention.
In the present embodiment, as illustrated in an enlarged view drawn to the right in
In the present embodiment, a round shape 18 is also formed at a connected portion 143b between the first arc A1 and the second arc A2 as in the case of the connected portion 143a. A round shape 18 is also formed at a connected portion 143c between the second arc A2 and the third arc A3 as in the case of the connected portion 143a. A round shape 18 is also formed at a connected portion 143d between the third arc A3 and the fourth arc A4 as in the case of the connected portion 143a. A ratio of the length of a portion of the edge portion 144 which is occupied by the round shapes 18 formed at the island-shaped portion 142 with respect to the entire length of the edge portion 144 in the shape of the outer edge of the island-shaped portion 142 is 5% or less. The connected portions 143a to 143d may be vertexes (intersections T) where the arcs A1 to A4 intersect each other. However, since the connected portions 143a to 143d are formed of the round shapes 18, it is possible to easily from the serration 14.
In the present embodiment, all the island-shaped portions 142 formed on the inner surface 130 of the second barrel 13 are disposed in the same direction as illustrated in
The disposition (direction) of the island-shaped portions 142 formed on the inner surface 130 of the second barrel 13 is not particularly limited to the above-mentioned disposition (direction). For example, the respective island-shaped portions 142 may be disposed (directed) so as to be rotated from the disposition (direction) illustrated in
The shape of the island-shaped portion 142 is also not particularly limited to the above-mentioned shape.
For example, as in an island-shaped portion 142B illustrated in
A circumscribed circle 15 which is circumscribed about the island-shaped portion 142B has the shape of an ellipse in the case of an example illustrated in
The number of arcs forming the island-shaped portion is also not particularly limited. For example, as in an island-shaped portion 142C illustrated in
The island-shaped portion has the shape of an axisymmetric outer edge in the above-mentioned examples. However, the island-shaped portion is not particularly limited thereto, and may have the shape of a non-axisymmetric outer edge.
Next, the function of the crimp terminal 1 in the present embodiment will be described.
In a case in which a wire which includes a conductor portion is made of aluminum or an aluminum alloy is connected to a crimp terminal, an oxide film having a high electric resistance value is generally formed on the surface of the conductor portion. For this reason, when crimping connection is performed, it is necessary to perform contact conduction between the crimp terminal and the conductor portion of the wire while the oxide film is broken.
In a case in which the crimp terminal includes the barrel on which the recessed serration are formed, the oxide film formed on the surface of the conductor portion is broken by edge portions of the serration when the barrel is crimped to the conductor portion of the wire. Accordingly, the crimp terminal and the conductor portion of the wire are electrically connected to each other. For this reason, in order to improve reliability in the connection between the crimp terminal and the conductor portion of the wire, it is preferable that the serration formed on the barrel is formed in a shape having a long outer edge.
In this regard, since the edge portion of the serration is short in a case in which the shape of the outer edge of the serration is a circular shape (a true-circular shape or an elliptical shape), it is necessary to increase the entire length of the edge portion by increasing an area which is occupied by the shape of the outer edge. However, if the area occupied by the shape of the outer edge is increased, energy required for forming the serration is increased. In this case, it is possible to suppress an increase in energy required for forming the serration by a structure in which the depth of the serration (the depth of the recessed shape) is reduced. However, since efficiency in which the edge portion of the serration breaks the oxide film of the conductor portion of the wire is reduced in this case, reliability in the connection between the crimp terminal and the conductor portion of the wire is reduced. For this reason, it is not possible to employ this structure.
On the other hand, in the present embodiment, the shape of the outer edge of the island-shaped portion 142 of the serration 14 formed on the inner surface 130 of the second barrel 13 is formed so that the plurality of arcs (the first to fourth arcs A1 to A4 in the present embodiment) continue to each other as illustrated in
Specifically, in
Accordingly, concerning the crimp terminal 1 in the present embodiment, it is possible to improve reliability in the connection between the crimp terminal 1 and the conductor portion 21 of the wire 2 while an increase in energy required for forming the serration 14 is suppressed. In a case in which the circumscribed circle 15 which is circumscribed about the shape of the outer edge of the island-shaped portion 142 is a true circle as illustrated in
Incidentally, when the crimp terminal is connected to the wire 2 in a case in which tinning is performed on the inner surface 130 of the second barrel 13, a newly formed surface made of tin fills a gap between the respective thin wires 211 while adhering to the thin wires 211 forming the conductor portion 21 of the wire 2. Accordingly, a gas-tight structure is obtained. For this reason, it is possible to further improve reliability in the connection between the crimp terminal 1 and the conductor portion 21 of the wire 2.
In the present embodiment, the shape of the outer edge of the island-shaped portion 142 is formed so that the four arcs A1 to A4 continue to each other. Accordingly, since the island-shaped portions 142 can be most densely disposed on the inner surface 130 of the second barrel 13, it is possible to further improve reliability in the connection between the crimp terminal 1 and the conductor portion 21 of the wire 2, and it is possible to suppress an increase in an electric resistance value between the crimp terminal 1 and the wire 2. This effect can be obtained not only in the case of the island-shaped portion 142C (see
Since the crimp terminal in the second embodiment is the same as the crimp terminal in the above-mentioned first embodiment except that the structure of a serration 17 is different from that of the first embodiment, only portions different from the portions of the first embodiment will be described, the same portions as the portions of the first embodiment will be denoted by the same reference numerals as the reference numerals of the first embodiment, and the description thereof will be omitted.
As illustrated in
As long as a region where the serrations 17 are formed in the inner surface 130 of the second barrel 13 includes a portion which comes into contact with the conductor portion 21 of the wire 2 when the crimp terminal 1 is attached to the wire 2, it is not particularly limited to the above. For example, the serrations 17 may be formed on only the inner surface 130 of the bottom portion 131 of the second barrel 13.
As illustrated in
As illustrated in
The protrusion 172 in the present embodiment has a planar shape including a first strip shape 172a and a second strip shape 172b each of which extends linearly. A portion corresponding to the first strip shape 172a is formed on the bottom surface 171a of the recess 171 as illustrated in
A portion corresponding to the second strip shape 172b is also formed on the bottom surface 171a of the recess 171. The portion corresponding to the second strip shape 172b has the shape of a protrusion which has a constant width (a width between a side surface 177b and a side surface 178b) R2 in a plan view and which has a substantially rectangular cross-section. A height of the shape of the protrusion is substantially equal to the depth D1 of the recess 171. A width R2 of the second strip shape 172b is substantially equal to a width R1 of the first strip shape 172a (R2=R1) in the present embodiment, but these widths R1 and R2 may be different from each other. The first and second strip shapes 172a and 172b may not have a constant width.
In the present embodiment, a center line CL1 of the first strip shape 172a intersects a center line CL2 of the second strip shape 172b substantially at a right angle in a plan view. That is, an angle between an extending direction E1 of the first strip shape 172a and an extending direction E2 of the second strip shape 172b is 90°. An intersection between the two center lines CL1 and CL2 corresponds to a center C of the shape of the contour (true circle) of the serration 17. Accordingly, an overlapping portion 170 where the first strip shape 172a and the second strip shape 172b overlap each other is formed substantially at the center of the serration 17 in a plan view. The two center lines CL1 and CL2 may not intersect each other at a right angle, and the intersection between the two center lines CL1 and CL2 may not correspond to the center C.
Both end portions 173 and 174 of the first strip shape 172a in the extending direction E1 of the first strip shape 172a continue to the side surface 171b of the recess 171. Accordingly, both the end portions 173 and 174 are connected to the contour of the recess 171 in a plan view. Both end portions 175 and 176 of the second strip shape 172b in the extending direction E2 of the second strip shape 172b also continue to the side surface 171b of the recess 171, and are connected to the contour of the recess 171 in a plan view.
For this reason, the recess 171 in the present embodiment is partitioned into four recessed portions (a first recessed portion 1711, a second recessed portion 1712, a third recessed portion 1713, and a fourth recessed portion 1714) by the protrusion 172.
In plan view, the first recessed portion 1711 has a fan shape which is defined by the side surface 171b of the recess 171, the side surface 177 of the first strip shape 172a, and the side surface 177b of the second strip shape 172b. In plan view, the second recessed portion 1712 has a fan shape which is defined by the side surface 171b of the recess 171, the side surface 178 of the first strip shape 172a, and the side surface 177b of the second strip shape 172b.
In plan view, the third recessed portion 1713 has a fan shape which is defined by the side surface 171b of the recess 171, the side surface 178 of the first strip shape 172a, and the side surface 178b of the second strip shape 172b. In plan view, the fourth recessed portion 1714 has a fan shape which is defined by the side surface 171b of the recess 171, the side surface 177 of the first strip shape 172a, and the side surface 178b of the second strip shape 172b.
In the present embodiment, these first to fourth recessed portions 1711 to 1714 have the fan shapes which are substantially equal to each other in a plan view, and all the central angles of these fan shapes are 90°. The total length of linear portions of the fan shapes of the first to fourth recessed portions 1711 to 1714 (linear portions formed by the side surfaces 177 and 178 of the first strip shape 172a or the side surfaces 177b and 178b of the second strip shape 172b) is longer than the total length of the end portions 173 to 176 of the first and second strip shapes 172a and 172b in a plan view.
The shape of the serration 17 is not particularly limited to the above-mentioned shape. For example, round shapes 18 may be formed on the peripheries of the first to fourth recessed portions 1711 to 1714 as illustrated in
Likewise, concerning the second to fourth recessed portions 1712 to 1714, the round shape 18 is formed between the side surface 171b of the recess 171 and the side surface 177 or 178 of the first strip shape 172a, the round shape 18 is formed between the side surface 171b of the recess 171 and the side surface 177b or 178b of the second strip shape 172b, and the round shape 18 is formed between the side surface 177 or 178 of the first strip shape 172a and the side surface 177b or 178b of the second strip shape 172b. It is preferable that a ratio of the length of all portions in which the round shapes 18 are formed with respect to the entire length of the outer edges of the first to fourth recessed portions 1711 to 1714 in a plan view is 5% or less. In a case in which such round shapes 18 are formed, it is possible to improve the workability of the serrations 17.
The following Equation (3) is satisfied in the present embodiment.
α=45° (3)
Here, in the Equation (3), a denotes an angle between an extending direction E3 of the conductor portion 21 of the wire 2 which is to be connected to the crimp terminal 1 and the extending direction E1 of the first strip shape 172a, and β denotes an angle between the extending direction E3 of the conductor portion 21 and the extending direction E2 of the second strip shape 172b (see
In the present embodiment, as illustrated in
As described above, the serration 17 in the present embodiment includes the recess 171, and the protrusion 172 is formed in the recess 171. For this reason, in comparison with a serration including a recessed portion having the same contour as the contour of the serration 17 (a true circle in the present embodiment), the edge portion formed within the contour can be made long. Accordingly, in the crimp terminal 1 of the present embodiment, it is possible to improve reliability in the connection between the crimp terminal 1 and the conductor portion 21 of the wire 2 while an increase in energy required for forming the serration 17 is suppressed. In the present embodiment, the first and second strip shapes 172a and 172b pass through the center C of the contour of the recess 171B, and the edge portion formed within the contour can be effectively made long. Accordingly, it is possible to further improve the above-mentioned effect.
The protrusion 172 formed in the recess 171 of the serration 17 in the present embodiment is connected to the side surface 171b of the recess 171. That is, the end portions 173 and 174 of the first strip shape 172a and the end portions 175 and 176 of the second strip shape 172b are connected to the side surface 171b of the recess 171. For this reason, it is possible to suppress the occurrence of the bending or folding of the protrusion 172 which is caused by crimping when the crimp terminal 1 is connected to the conductor portion 21 of the wire 2, and it is possible to more reliably connect the crimp terminal 1 to the conductor portion 21 of the wire 2. Since the first and second strip shapes 172a and 172b are orthogonal to each other at the center C in the present embodiment, this effect can be further improved.
In the present embodiment, the serrations 17 formed on the main surface 130 of the second barrel 13 are linearly disposed along the extending direction E1 of the first strip shape 172a. For example, first strip shapes 172a of serrations 17A, 17B, and 17C illustrated in
Likewise, the serrations 17 of the crimp terminal 1 in the present embodiment are linearly disposed along the extending direction E2 of the second strip shape 172b. For example, second strip shapes 17b of serrations 17D, 17E, and 17F illustrated in
The Equation (3) is satisfied in the present embodiment. For this reason, when the crimp terminal 1 is crimped, the oxide film formed on the surface of the conductor portion 21 of the wire 2 is easily broken by the serrations 17. Accordingly, it is possible to further improve reliability in the connection between the crimp terminal 1 and the conductor portion 21 of the wire 2.
Since the crimp terminal in the third embodiment is the same as the crimp terminal in the above-mentioned second embodiment except that the structure of a serration is different from that of the second embodiment, only portions different from the portions of the second embodiment will be described, the same portions as the portions of the second embodiment will be denoted by the same reference numerals as the reference numerals of the second embodiment, and the description thereof will be omitted.
As illustrated in
The recess 171B has the same shape as the shape of the recess 171 described in the second embodiment. The protrusion 172B has a planar shape including only a linear first strip shape 172a of which a center line CL1 passes through a center C of the contour of the recess 171B. The protrusion 172B has the same cross-sectional shape as the cross-sectional shape of a portion which corresponds to the first strip shape 172a of the protrusion 172 described in the second embodiment. The protrusion 172B is provided on a bottom surface 171a of the recess 171B.
Both end portions 173 and 174 of the first strip shape 172a in an extending direction (an X-axis direction in
The structure of the serration 17B is not particularly limited to the above-mentioned structure. For example, as illustrated in
As in the second embodiment, in comparison with a serration including a recessed portion having the same contour as the contour of the serration 17B, the edge portion formed within the contour can be made long in the present embodiment. Accordingly, it is possible to improve reliability in the connection between the crimp terminal 1 and the conductor portion 21 of the wire 2 while an increase in energy required for forming the serration 17B is suppressed. In the present embodiment, the first strip shape 172a passes through the center C of the contour of the recess 171B, and the edge portion formed within the contour can be effectively made long. Accordingly, it is possible to further improve the above-mentioned effect.
As in the second embodiment, the protrusion 172B is connected to the side surface 171b of the recess 171B in the present embodiment. For this reason, it is possible to suppress the occurrence of the bending or folding of the protrusion 172B which is caused by crimping when the crimp terminal 1 is connected to the conductor portion 21 of the wire 2, and it is possible to more reliably connect the crimp terminal 1 to the conductor portion 21 of the wire 2.
As in the second embodiment, since the serrations 17B are disposed along the extending direction of the first strip shape 172a on the main surface 130 of the second barrel 13 in the present embodiment, it is possible to improve the workability of the serrations 17B.
Since the crimp terminal in the fourth embodiment is the same as the crimp terminal in the above-mentioned second embodiment except that the structure of a serration is different from that of the second embodiment, only portions different from the portions of the second embodiment will be described, the same portions as the portions of the second embodiment will be denoted by the same reference numerals as the reference numerals of the second embodiment, and the description thereof will be omitted.
As illustrated in
The recess 171C has the same shape as the shape of the recess 171 described in the second embodiment. The protrusion 172C has a planar shape including a first strip shape 172a, a second strip shape 172b, and a third strip shape 172c each of which linearly extends to a center C from the contour of the recess 171C.
Each of the first to third strip shapes 172a to 172c has the same cross-sectional shape as the cross-sectional shape of a portion which corresponds to the first strip shape 172a of the protrusion 172 described in the second embodiment. The first to third strip shapes 172a to 172c are provided on a bottom surface 171a of the recess 171C. As illustrated in
The following Equation (4) is satisfied in the present embodiment.
γ=δ=ε=120° (4)
Here, in the Equation (4), γ denotes an angle between an extending direction E1 of the first strip shape 172a and an extending direction E2 of the second strip shape 172b (an angle on the side where the third strip shape 172c is not provided), δ denotes an angle between the extending direction E2 of the second strip shape 172b and an extending direction E3 of the third strip shape 172c (an angle on the side where the first strip shape 172a is not provided), and ε denotes an angle between the extending direction E3 of the third strip shape 172c and the extending direction E1 of the first strip shape 172a (an angle on the side where the second strip shape 172b is not provided).
For this reason, the recess 171C is partitioned into first to third recessed portions 1711 to 1713 by the protrusion 172C, and the first to third recessed portions 1711 to 1713 are formed in the fan shapes which are substantially equal to each other in a plan view. The total length of linear portions of the fan shapes of the first to third recessed portions 1711 to 1713 (linear portions formed by side surfaces 177 and 178 of the first strip shape 172a, side surfaces 177b and 178b of the second strip shape 172b, or side surfaces 177c and 178c the third strip shape 172c) is longer than the total length of end portion 173, 175, and 179 of the first to third strip shapes 172a to 172c in a plan view.
As in the second embodiment, in comparison with a serration including a recessed portion having the same contour as the contour of the serration 17C, the edge portion formed within the contour can be made long in the present embodiment. Accordingly, it is possible to improve reliability in the connection between the crimp terminal 1 and the conductor portion 21 of the wire 2 while an increase in energy required for forming the serration 17C is suppressed.
As in the second embodiment, the protrusion 172C is connected to a side surface 171b of the recess 171C in the present embodiment. For this reason, it is possible to suppress the occurrence of the bending or folding of the protrusion 172C which is caused by crimping when the crimp terminal 1 is connected to the conductor portion 21 of the wire 2, and it is possible to more reliably connect the crimp terminal 1 to the conductor portion 21 of the wire 2. Since the first to third strip shapes 172a to 172c are connected to each other at the center C of the contour of the recess 171C and the Equation (4) is satisfied in the present embodiment, it is possible to further improve this effect.
Since the crimp terminal in the fifth embodiment is the same as the crimp terminal in the above-mentioned second embodiment except that the structure of a serration is different from that of the second embodiment, only portions different from the portions of the second embodiment will be described, the same portions as the portions of the second embodiment will be denoted by the same reference numerals as the reference numerals of the second embodiment, and the description thereof will be omitted.
As illustrated in
The recess 171D has the same shape as the shape of the recess 171 described in the second embodiment. The protrusion 172D has a true-circular planar shape. In the present embodiment, a center C of the contour of the recess 171D and a center C′ of the protrusion 172D correspond to each other. The center C of the contour of the recess 171D and the center C′ of the protrusion 172D may not correspond to each other. The shape of the protrusion 172D in a plan view is not limited to the above-mentioned shape. For example, the shape of the protrusion 172D in a plan view may be an elliptical shape and may be a polygonal shape, such as a rectangular shape.
As illustrated in
As in the second embodiment, in comparison with a serration including a recessed portion having the same contour as the contour of the serration 17D, the edge portion formed within the contour can be made long in the present embodiment. Accordingly, it is possible to improve reliability in the connection between the crimp terminal 1 and the conductor portion 21 of the wire 2 while an increase in energy required for forming the serration 17D is suppressed.
The embodiments described herein above are presented in order to facilitate understanding of the present invention and are not presented to limit the present invention. Thus, the respective elements disclosed in the above embodiments are intended to cover all design alterations belonging to the technical scope of the present invention and equivalents thereof.
For example, in a plan view, the round shapes 18 (see
1: crimp terminal
11: connecting portion
12: first barrel
13: second barrel
130: inner surface (crimp surface)
131: bottom portion
132: side portion
14: serration
141: linear portion
142: island-shaped portion
143
a to 143d: connected portions
144: edge portion
15: circumscribed circle
17, 17B to 17D: serrations
171, 171B to 171D: recesses
1711 to 1714: first to fourth recessed portions
171
a: bottom surface
171
b: side surface
172, 172B to 172D: protrusions
172
a: first strip shape
172
b: second strip shape
18: round shape
2: wire
21: conductor portion
22: cover portion
A1 to A6: arcs
E1 to E3: extending directions of first to third strip shapes
Number | Date | Country | Kind |
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2014-126411 | Jun 2014 | JP | national |
2014-239494 | Nov 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/067633 | 6/18/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/194640 | 12/23/2015 | WO | A |
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51-067321 | May 1976 | JP |
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11-515137 | Dec 1999 | JP |
2009-193890 | Aug 2009 | JP |
2010-198789 | Sep 2010 | JP |
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Entry |
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Number | Date | Country | |
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20170141488 A1 | May 2017 | US |