JP2012009178A - Press-fit terminal and press-fit terminal manufacturing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a press-fit terminal and a press-fit terminal manufacturing method in which resistance material existing on the surface of an electrical conduction portion of a coated electric wire can be sufficiently broken when the electrical conduction portion is press-fitted by press-fitting means to achieve excellent connection.SOLUTION: The press-fit face 14 of press-fitting means 10 for press-fitting an electrical conduction portion 102 is provided with plural fitting portions 13 to which a part of the electrical conduction portion 102 is fitted. The fitting portions 13 are arranged so that the center points 13a of the fitting portions 13 are coincident with the intersecting points between reference arrangement lines 21L and inclined arrangement lines 22L. The reference arrangement lines 21L are along any one of the axial direction L coincident with the longitudinal direction L of a coated electrical wire 100 connected by the press-fitting means 10 and a width direction W, and are arranged at a predetermined interval P1 in the other direction. The inclined arrangement lines 22L are inclined to the reference arrangement lines 21L at a predetermined inclination angle θ and arranged at a predetermined interval P2 along the one direction. The inclination angle θ is set to satisfy θ=tan((n+1)P1/P2), when n represents any integer.

Description

  The present invention relates to, for example, a crimp terminal that is crimped to a conductor portion of a covered electric wire and attached to the tip of the covered electric wire, and a method of manufacturing the crimp terminal.

Conventionally, as a terminal fitting to be attached to the tip of a covered electric wire, a crimp terminal provided with a wire barrel as a crimping means for crimping a conductor portion from which the coating has been peeled is often used.
On the pressure-bonding surface of the pressure-bonding means, locking portions called serrations are formed at predetermined intervals in the longitudinal direction. For example, as a crimping means formed on a crimp terminal for a copper electric wire, one in which a lateral groove type locking portion whose groove extends in the width direction is often used.

  Such a locking part can increase the holding power of the core wire by the crimping means, and when the conductor part is crimped to the conductor part of the covered electric wire, the conductor part bites into the locking part, thereby existing on the surface of the conductor part. It plays a role of obtaining a good connection by destroying a resistance substance such as an oxide film.

In recent years, as the need for weight reduction has increased, the use of aluminum wires instead of copper wires has been studied.
However, for example, when crimping such an aluminum wire, the aluminum wire has a strong and low-conductivity oxide film. Therefore, in a crimp terminal for a copper wire with a lateral groove type serration, The resistance substance present on the surface of the portion cannot be sufficiently destroyed, and the problem that the electrical resistance in the electrical connection between the crimp terminal and the conductor portion increases has become prominent.

  In order to solve such a problem, a terminal fitting and a terminal-attached electric wire in which a discontinuous serration as in Patent Document 1 is formed on a wire barrel have been proposed.

  A plurality of serrations disclosed in Patent Document 1 are arranged on the inner surface of the wire barrel, and are formed as concave portions having the same shape each having a parallelogram shape in plan view.

  For example, the serrations described above are linearly arranged at predetermined intervals along a direction (width direction) perpendicular to the longitudinal direction (extending direction in which the core wire extends), and intersect the longitudinal direction at a predetermined angle. It arrange | positions at predetermined intervals along the 2nd direction.

  By arranging in this way, a region in which the edge formed on the edge of the recess as the serration bites into the core wire can be present in the longitudinal direction, and the holding force of the core wire by the wire barrel is enhanced.

  On the other hand, when the edge of the locking part (serration) is bent and rounded or the edge angle is loose, the conductor part when the conductor part of the covered wire is crimped by the crimping part is sheared by the locking part. Thus, there is a problem that the resistance substance existing on the surface of the conductor portion cannot be sufficiently destroyed and a good connection cannot be obtained.

  For this reason, it is important that the shape of the locking part is accurately formed, such as the edge of the edge of the locking part being formed, and it is necessary to regularly inspect the formation accuracy of the locking part.

  Specifically, for one locking part, the crimping surface of the wire barrel is cut so as to pass through the central part of the locking part from the two directions of the longitudinal direction and the width direction, and the shape of this cutting part For example, it is necessary to inspect various points such as depth, the horizontal and vertical dimensions of the bottom portion, and the angle of the edge.

  When a plurality of locking portions are arranged on the pressure-bonding surface as in a non-continuous locking portion, the cutting is performed along the longitudinal direction and the width direction for each of the locking portions, There is a problem that it takes a very long time to inspect the shape of the cut portion.

  It is efficient if a plurality of locking portions can be cut together by one cut and the cross-sections of the cut locking portions can be confirmed together, but as in Patent Document 1, the longitudinal direction and the width direction If the periodic arrangement is performed only along one of the directions, it takes time for the inspection.

  When the locking portions are not periodically arranged in the other direction orthogonal to the one direction, an attempt is made to cut a plurality of locking portions along the other direction so as to pass through the central portion of each locking portion. In this case, it is not possible to cut a plurality of locking portions together by one cutting, and it is necessary to cut the plurality of locking portions one by one, which requires time for inspection.

  Furthermore, since it becomes difficult to accurately inspect the locking portion, the quality check of the serration punch used as a pressing jig for pressing the pressure-bonding surface is used when forming the locking portion. There has also been a problem that it cannot be performed based on the shape.

  Therefore, a locking part is formed on the crimping surface with such a serration punch that is not well-controlled, and when the conductor part of the covered wire is crimped, the resistance substance present on the surface of the conductor part is removed. It was not possible to obtain a crimp terminal that could not be sufficiently broken and could obtain a good connection.

JP 2010-3584 A

  Therefore, the present invention provides a crimp terminal and a crimp that can sufficiently destroy the resistance substance existing on the surface of the conductor part when the conductor part of the covered electric wire is crimped by the crimping means and can obtain a good connection. It aims at providing the manufacturing method of a terminal.

The present invention is a crimp terminal provided with a crimping means for crimping a conductor portion of a covered electric wire, comprising a plurality of latching portions for latching a part of the conductor portion on a crimping surface of the crimping means, Along with any one of the axial direction coinciding with the longitudinal direction of the covered electric wire connected to the crimping means and the width direction orthogonal to the axial direction, and arranged at predetermined intervals P1 in the other direction. The center point of the locking portion is at the intersection of the reference arrangement line and the inclined arrangement line that is inclined with respect to the reference arrangement line at a predetermined inclination angle θ and arranged at predetermined intervals P2 along the one direction. Are arranged so that they coincide with each other, and when the tilt angle θ is n is an arbitrary integer,
θ = tan ⁻¹ ((n + 1) P1 / P2)
It is the crimp terminal set to (1).

  As an aspect of the present invention, the locking portions can be formed in the same plan view shape and size.

  As an aspect of the present invention, the arbitrary integer n can be set to zero.

As an aspect of the present invention, the locking portions are formed in a parallelogram shape in which the reference sides that are parallel to each other along the one direction and have a dimension of A2 are arranged in the other direction at a predetermined interval A1. And the predetermined interval P1 and the predetermined interval P2.
P1> A1, P2> A2
Can be set to

In addition, as an aspect of the present invention, an inclination angle α with respect to the reference side of the inclined side having both sides in the one direction of the locking portion formed in a parallelogram shape,
α ≧ tan ⁻¹ (A1 / A2)
Can be set to

  Further, as an aspect of the present invention, the inclination angle α and the inclination angle θ can be matched.

The present invention further includes a crimping means for crimping a conductor portion of the covered electric wire, and a plurality of latching portions to which a part of the conductor portion is latched are arranged at predetermined positions on the crimping surface of the crimping means. A crimp terminal manufacturing method is provided, wherein a reference arrangement line parallel to any one of an axial direction coinciding with a longitudinal direction of the covered electric wire and a width direction orthogonal to the axial direction is set, and a plurality of Are arranged at predetermined intervals P1 along another direction orthogonal to the one direction, and an inclined arrangement line inclined by a predetermined inclination angle θ with respect to the reference arrangement line is set. The inclined arrangement lines are arranged at predetermined intervals P2 along the one direction, and the predetermined arrangement positions coincide with the intersections between the reference arrangement lines and the inclined arrangement lines at the center points of the locking portions. Set the position to The predetermined inclination angle theta, when n is any integer,
θ = tan ⁻¹ ((n + 1) P1 / P2)
And a plurality of the locking portions are provided.

  According to this invention, when the conductor part of the covered electric wire is crimped by the crimping means, the resistance substance existing on the surface of the conductor part can be sufficiently destroyed, and a crimp terminal capable of obtaining a good connection and A method of manufacturing a crimp terminal can be provided.

Explanatory drawing by the perspective view of the crimp terminal of 1st Embodiment. Explanatory drawing of the crimp terminal of 1st Embodiment. Explanatory drawing of the latching | locking part of 1st Embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of 1st Embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of 1st Embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of 2nd Embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of 2nd Embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of 3rd Embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of 3rd Embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of other embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of other embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of other embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of other embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of other embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of other embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of other embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of other embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of other embodiment. Explanatory drawing regarding arrangement | positioning of the latching | locking part of the conventional crimp terminal.

An embodiment of the present invention will be described below with reference to the drawings.
(First embodiment)
FIGS. 1A and 1B are explanatory views of the crimp terminal 1A in perspective view, FIG. 2A is an explanatory view of the crimp terminal 1A in an unfolded state, and FIG. 2B is a crimp view represented by a plan view. The explanatory view of terminal 1A is shown. 3A and 3B are explanatory views of the serration 13A. Specifically, FIG. 3A is an enlarged view of a region a in FIG. 2A, and FIG. 3B is an A-A in FIG. FIG. 3C is a sectional view taken along line B-B in FIG. 4 shows an enlarged plan view of the wire barrel portion 10 in the crimp terminal 1A in an unfolded state, FIG. 5 (a) shows an enlarged view of a region b in FIG. 4, and FIG. 5 (b) shows FIG. The enlarged view of the area | region c part in a) is shown.

  In all the drawings other than FIGS. 1 and 3, the serration 13 </ b> A shown in the plan view is represented only by the outer peripheral edge.

  1 A of crimp terminals of 1st Embodiment are the crimp terminals provided with the wire barrel part 10 which crimps | bonds the core wire 102 of the covered electric wire 100, Comprising: A part of the said core wire 102 is attached to the crimping surface 14 in the said wire barrel part 10. A plurality of serrations 13A to be locked are provided. The crimp terminal 1 </ b> A is one of an axial direction L that coincides with the longitudinal direction L of the covered electric wire 100 connected to the wire barrel portion 10 and a width direction W that is orthogonal to the axial direction L. A reference arrangement line 21L that extends along the width direction W and is arranged at predetermined intervals P1 in the axial direction L, which is the other direction, and is inclined at a predetermined inclination angle θ with respect to the reference arrangement line 21L. The serration 13A is arranged so that the center point 13a of the serration 13A coincides with the intersection with the inclined arrangement line 22L arranged at every predetermined interval P2 along the direction W, and the inclination angle θ is arbitrarily set to n. Is an integer of

[Equation 1]
θ = tan ⁻¹ ((n + 1) P1 / P2)
It is the configuration set to.

  The configuration of the crimp terminal 1A described above will be described in detail. The crimp terminal 1A is configured as a female terminal, and as shown in FIG. 1, insertion of a male connector (not shown) from the front to the rear in the axial direction L is performed. , A wire barrel portion 10 disposed behind the box portion 2 via a first transition 18 having a predetermined length, and a second portion having a predetermined length behind the wire barrel portion 10. The insulation barrel portion 15 disposed via the two transitions 19 is integrally formed.

The wire barrel part 10 is crimped by crimping the core wire 102 of the covered electric wire 100 with the wire barrel piece 12, and the insulation barrel part 15 is fixed by caulking the insulating coating 101 of the covered electric wire 100 with the insulation barrel piece 16. Yes.
In addition, with the recent miniaturization and weight reduction of electronic devices, the covered electric wire 100 forms a core wire 102 by bundling light aluminum strands compared to conventional copper wires, and the entire outer peripheral portion of the core wire 102 excluding the tip portion. Are covered with an insulating coating 101.

  As shown in FIG. 2A, the crimp terminal 1A has an assembled three-dimensional configuration as shown in FIG. 2B by bending from a plate state before assembly. The box portion 2 is formed of an inverted hollow square column body, and includes a contact piece 2a that is bent rearward in the axial direction L and contacts a male connector to be inserted.

  As shown in FIG. 1 (a), the wire barrel portion 10 before crimping is composed of a barrel bottom portion 11 and wire barrel pieces 12 extending obliquely outward and upward from both sides in the width direction W, and the rear view is omitted. It is formed in a U shape.

  Similarly, the insulation barrel portion 15 before crimping is also composed of a barrel bottom portion 17 and an insulation barrel piece 16 extending obliquely outward and upward from both sides in the width direction W, and is formed in a substantially U shape in rear view. Yes.

  The wire barrel portion 10 is formed as a crimping surface 14 on both sides thereof, the surface on the side to be crimped with the core wire 102 held, that is, the surface shown in FIG.

As shown in FIG. 4, a plurality of serrations 13 </ b> A are arranged on the crimping surface 14 of the wire barrel portion 10.
As shown in FIG. 2 (a), the serration 13A is formed by punching a metal plate into a shape in which the crimp terminal 1A is expanded as described above, and then pressing the pressing plate (not shown) onto the crimping surface 14 by pressing. 3 is formed in a concave shape.

  The pressing jig has a plurality of serration punches arranged in a convex shape so as to correspond to the arrangement of the plurality of serrations 13 </ b> A arranged on the crimping surface 14.

  In addition, when the crimping terminal 1A is punched into the developed shape of the crimping terminal 1A, the crimping surface 14 is pressed simultaneously with or before the punching to form a plurality of serrations 13A on the crimping surface 14. May be.

  As shown in FIG. 4, the serrations 13A on the crimping surface 14 are arranged such that the center point 13a of the serration 13A coincides with the intersection of the reference arrangement line 21L (21L to 21L7) and the inclined arrangement line 22L. Is arranged in a serration arrangement region z in which is arranged.

  The reference arrangement lines 21L are virtual straight lines extending in the width direction, and a plurality of reference arrangement lines 21L are arranged along the axial direction L at a predetermined interval P1 every 0.4 mm. Specifically, the reference arrangement line 21L has a total of seven lines from the first reference arrangement line 21L1 to the seventh reference arrangement line 21L7 from the rear in the axial direction L (downward in FIG. 4) to the front (upward in FIG. 4). Consists of straight lines.

  On the other hand, the inclined arrangement line 22L is an imaginary straight line that is inclined at a predetermined inclination angle θa with respect to the reference arrangement line 21L and arranged in plural along the width direction W every 0.5 mm.

  Here, since the arbitrary integer n is set to 2 in the “Equation 1”, the tilt angle θ can be set to θa = 67.38 °.

  With such a setting, the predetermined intervals P1 and P2 and the predetermined inclination angle θa have a relationship as shown in FIGS. 4 and 5A, and therefore the serration 13A extends along the width direction W. It is arranged on the crimping surface 14 at every predetermined interval P2, and is arranged so that its center part 13a coincides in the width direction W periodically every two (every two) along the axial direction L. Will be.

  Therefore, for example, as shown by the alternate long and short dash line extending in the left-right direction in FIG. 4, when the wire barrel portion 10 is cut along the cutting line CLw that coincides with the predetermined reference arrangement line 21L, all the lines arranged in the reference arrangement line 21L It can cut | disconnect with the cutting line CLw which crosses the center part 13a of the serration 13A.

  Furthermore, when the wire barrel portion 10 is cut along the axial direction L, for example, in the intermediate portion in the width direction W, the first reference arrangement line 21L1 and the fourth reference line 21L1, as shown by the one-dot chain line extending in the vertical direction in FIG. It can cut | disconnect with the cutting line CL which crosses the center part 13a of serration 13A distribute | arranged in the middle of the reference | standard arrangement | positioning line 21L4 and the 7th reference | standard arrangement | positioning line 21L7.

Further, the plurality of serrations 13A are formed in a parallelogram shape having the same size.
Specifically, as shown in FIG. 5B, the serrations 13 </ b> A are parallel to each other along the width direction W and have a reference side 24 having a dimension A <b> 2 with a predetermined interval A <b> 1 in the axial direction L. Formed in a parallelogram shape, and the predetermined interval P1 and the predetermined interval P2

[Equation 2]
P1> A1, P2> A2
It is set to satisfy.

  Furthermore, the inclination angle α with respect to the reference side 24 of the inclined side 25 having both sides of the serration 13A formed in a parallelogram shape in the width direction W is:

[Equation 3]
α ≧ tan ⁻¹ (A1 / A2)
It is set to satisfy.

  Specifically, in the serration 13A of the first embodiment, the inclination angle α is set to 67.38 °, which is an angle that coincides with the inclination angle θa, so that “Equation 3” is satisfied.

  In the state before crimping of the crimp terminal 1A configured as described above, the wire barrel portion 10 and the covered electric wire 100 are arranged as shown in FIG. 1A and crimped by a crimp applicator (not shown). As shown in (b), the core wire 102 is crimped by the wire barrel portion 10, and the crimp terminal 1 </ b> A can be attached to the covered electric wire 100.

Specifically, the covered electric wire 100 is crimped so that the core wire 102 of the covered electric wire 100 is inside the wire barrel portion 10 bent into a substantially U shape when viewed from the rear, and the vicinity of the front end of the insulating coating 101 is inside the insulation barrel portion 15. Mounted from above the terminal 1A.
In this state, the wire barrel portion 10 is sandwiched by a crimping applicator (not shown) to curl the wire barrel piece 12, and an insulation barrel crimper (not shown) is omitted from the top of the insulation barrel portion 15. The insulation barrel piece 15 is clamped between the anvil for the insulation barrel and the crimper for the insulation barrel to curl the insulation barrel piece 16.

  Thereby, the core wire 102 is pressed against the barrel bottom 11 by the wire barrel piece 12, and further, the insulation coating 101 is pressed toward the barrel bottom 17 by the insulation barrel piece 16, and the two-cylinder pressure bonding is arranged in parallel in the width direction W. The state can be configured.

  Thus, the crimp terminal 1 </ b> A can be connected to the covered electric wire 100 in a state where the core wire 102 is crimped by the wire barrel portion 10.

The crimp terminal 1A can be configured with the above-described configuration, and the crimp terminal 1A having such a configuration can obtain various functions and effects as follows.
Since the crimp terminal 1A has a configuration in which a plurality of serrations 13A are arranged on the crimping surface 14 in the above-described arrangement, the serrations 13A arranged on the reference arrangement line 21L are overlaid in the axial direction L for each reference arrangement line 21L. The core wire 102 can be firmly bited into the serration 13A regardless of the location of the crimping surface 14.

  Therefore, the resistance substance present on the surface of the core wire 102 can be sufficiently destroyed, and a good connection can be obtained.

Specifically, for example, a conventional crimp terminal 200 will be described as a comparative example of the crimp terminal 1A of the first embodiment.
As shown in FIG. 19A, the conventional crimp terminal 200 has a reference arrangement line extending along the width direction W in which a plurality of serrations 201 are arranged in the axial direction L at a predetermined interval P1 every 0.4 mm. 21L and the reference arrangement line 21L with a predetermined inclination angle φ, and at the intersection of the serration 201 of the serration 201 at a plurality of arrangement lines 22L arranged every 0.5 mm as the predetermined interval P2 along the width direction W. In this configuration, the center point 201a is arranged on the pressure-bonding surface 14 so as to coincide with each other.

  The inclination angle φ is set to 60 °, which is an angle different from the inclination angle θa of the crimp terminal 1A of the first embodiment.

  In the case of such a configuration, the predetermined intervals P1 and P2 and the inclination angle φ do not satisfy the relationship of “Equation 1” when n is set to any integer, and as shown in FIG. The serrations 201 are periodically arranged at predetermined intervals P2 in the width direction W of the crimping surface 14, but are not periodically arranged in the axial direction L.

  For this reason, when the crimping surface 14 is cut along the axial direction L, it cannot be cut so that a cut portion passing through the central portion 201a of the serration 201 appears periodically.

  For example, in the case of a cutting line CL in which the wire barrel portion 10 is cut in the axial direction L at the intermediate portion in the width direction W, the cutting line CL includes a central portion 201a of the serration 201 arranged in the middle of the first reference arrangement line 21L1. Although it passes, it does not pass through the center part 201a of the serration 201 arranged in the middle of the other reference arrangement line 21L (see FIG. 19A).

  As described above, when the dimension of the serration 201 in the axial direction L is confirmed, it is necessary to cut the serration 201 for each serration 201 with the cutting line CL, and the number of the crimp surfaces is equal to the number of the plurality of serrations 201 arranged on the crimp surface 14. 14 has to be cut, and much labor is required to confirm the dimensions.

  Further, as shown with hatching in FIG. 19A, the serrations 201 arranged along the axial direction L at both ends in the width direction W of the serration arrangement region z are all parallelograms. On the other hand, a part of the shape is missing, and each part has a different shape.

  For this reason, it is necessary to form serration punches for forming serrations 201 each having a different shape and a part lacking, and some serration punches formed for normal parallelogram serrations 201 have some Something lacking in shape will occur.

  In this case, problems such as inferior durability of the serration punch, and labor and cost for performing additional machining occur.

  In addition, when performing additional machining, among other serration punches, other serration punches that do not need to be deleted are accidentally damaged, and forgetting to perform additional machining on serration punches that should be additionally machined There is also a problem that the quality control of the serration punch cannot be easily performed.

  On the other hand, as described above, the crimp terminal 1A of the first embodiment, as shown in FIG. 4 and FIG. 5 (a), has a plurality of serrations 13A on the crimp surface 14 and the reference arrangement line 21L. In this configuration, the center point of the serration 13A coincides with the intersection with the arrangement line 22L.

  The reference arrangement line 21L is an imaginary straight line extending along the width direction W arranged in the axial direction L at intervals of 0.4 mm, and the inclined arrangement line 22L is relative to the reference arrangement line 21L. These are imaginary straight lines that are inclined at a predetermined inclination angle θa and are arranged at intervals of 0.5 mm along the width direction W.

  Here, the predetermined inclination angle θa is set to 67.38 ° based on the above “Equation 1” by setting an arbitrary integer n to 2.

  With the above-described configuration, the predetermined intervals P1, P2, and the inclination angle θa satisfy the above-described “Equation 1”, and the serration 13A has a relationship as shown in FIG. 4 and FIG. In the width direction W, the serrations 13A can be periodically arranged at intervals of 0.5 mm at intervals of 0.5 mm, and the serrations 13A are periodically arranged at intervals of 1.2 mm with two reference arrangement lines 21L in the axial direction L. It can be arranged on the crimping surface 14 so as to coincide with the direction W.

  As described above, the crimp terminal 1A can have a configuration in which the plurality of serrations 13A are arranged on the crimping surface 14 in the arrangement shown in FIGS. 4 and 5A. Can be overlapped with each other in the axial direction L, and the plurality of serrations 13A can firmly mesh the surface of the core wire 102 with the serrations 13A regardless of the location of the crimping surface 14.

  Therefore, the resistance substance present on the surface of the core wire 102 can be sufficiently destroyed, and a good connection can be obtained.

  Further, as one of means for confirming the finishing condition of the plurality of serrations 13A formed on the crimping surface 14, for example, the crimping surface 14 is linearly cut so as to pass through the center point 13a of the serration 13A, and the cut portion is passed through. When confirming various dimensional accuracy of the serrations 13A formed on the pressure-bonding surface 14, even when the pressure-bonding surface 14 is cut along any of the axial direction L and the width direction W, a plurality of cuts can be made by a single cutting. The serrations 13A can be cut together.

  Thereby, the shape confirmation including the dimensions of the plurality of serrations 13A can be performed efficiently and accurately through the cut portion.

  Further, since the serration 13A is formed by pressing the pressing jig against the crimping surface 14, the quality of the serration punch as the pressing jig can be easily confirmed based on the result of the shape confirmation of the serration 13A. The serrations 13A can be formed on the crimping surface 14 with a high quality serration punch.

  Further, as shown in FIG. 4A with hatching, the serration 13A is part of the serration arrangement region z on the crimping surface 14 that is arranged along both ends in the width direction W. However, the shape can be made uniform periodically.

  Therefore, the variation of the shape of the serration 13A lacking a part arranged along the end of the serration arrangement region z can be suppressed, and the serration punch can be formed to form the serration 13A lacking such a part. Therefore, it is possible to reduce the labor of additional work.

  In addition, since the plurality of serrations 13A are formed on the pressure-bonding surface 14 with the same shape and size in plan view, it becomes easy to compare the shape and size of the cut portion for each of the plurality of serrations 13A. Quality control such as 13A shape confirmation becomes easy.

  As shown in FIG. 5A, the serrations 13A are arranged with reference sides 24 that are parallel to each other along the width direction W and that have a dimension A2, with a predetermined interval A1 in the axial direction L. It is formed in a parallelogram shape, and the predetermined interval P1 and the predetermined interval P2 are set so as to satisfy the above-described “Equation 2” relationship.

  With the above configuration, a plurality of serrations 13A arranged along the axial direction L and the width direction W do not overlap each other, and a gap where no serrations 13A are formed is secured between adjacent serrations 13A. In this state, the plurality of serrations 13A can be independently arranged.

  Therefore, the crimping surface 14 can be formed in a concavo-convex shape in cross section, and the covered electric wire 100 can be firmly locked.

  Further, as shown in FIG. 19B, the inclination angle α of the inclined side 25 provided on both sides in the width direction W of the serration 202 formed in a parallelogram shape with respect to the reference side 24 is expressed by the above-described “Expression 3”. When the crimping surface 14 is cut by the cutting line CL that passes through the center points 202a of the serrations 202 arranged along the axial direction L, the cutting line CL It will cross the inclined side 25 of 202.

  In this case, the size of A1 cannot be measured by the cut portion of the serration 202, and the quality control of the serration 202 cannot be performed sufficiently.

  On the other hand, as shown in FIG. 5B, the serration 13A of the first embodiment has the reference side 24 of the inclined side 25 that is provided on both sides in the width direction W of the serration 13A formed in a parallelogram shape. Is a shape in which the inclination angle α with respect to is set so as to satisfy the relationship of “Equation 3” described above.

  Thereby, when the crimping surface 14 is cut by the cutting line CL that passes through the center points 13a of the serrations 13A arranged along the axial direction L, the cutting line CL is shown in FIGS. 5 (a) and 5 (b). As shown in FIG. 5, the cutting line CL crosses the reference side 24 instead of the inclined side 25 of each serration 13A.

  Therefore, the shape and dimensions of the cut portion including the dimension A2 in the axial direction L of the serration 13A can be easily and accurately measured, and quality control of the serration 13A can be easily and accurately performed. Can do.

  Further, the serration 13A of the first embodiment has a shape in which the inclination angle α and the inclination angle θa coincide.

  Accordingly, the inclined side 25 for each of the plurality of serrations 13A arranged along the inclined arrangement line 22L has a shape that is linearly connected along the inclined arrangement line 22L, as shown in FIGS. Therefore, it is possible to confirm at a glance the shift of the inclined side 25 for each serration 13A.

Below, the crimp terminal in other embodiment is demonstrated.
However, in the configuration of the crimp terminal described below, the same configuration as the crimp terminal 1A in the first embodiment described above is denoted by the same reference numeral, and the description thereof is omitted.

(Second Embodiment)
6 shows an enlarged plan view of the wire barrel portion 10 in the crimp terminal 1B in a developed state, FIG. 7 (a) shows an enlarged view of the region b in FIG. 6, and FIG. 7 (b) shows FIG. The enlarged view of the area | region c part in a) is shown.

  The crimp terminal 1B of the second embodiment has a configuration in which a plurality of serrations 13B are provided on the crimp surface 14 in a different arrangement from the serrations 13A in the crimp terminal 1A of the first embodiment.

  Specifically, the plurality of serrations 13B are arranged in the serration arrangement region z of the crimping surface 14 so that the center point 13a of the serration 13B coincides with the intersection of the reference arrangement line 21L and the inclined arrangement line 22L.

  The reference arrangement line 21L is an imaginary straight line extending in the width direction W arranged at a predetermined interval P1 every 0.4 mm along the axial direction L. The reference arrangement line 21L is a first line from the rear to the front in the axial direction L. It consists of a total of seven straight lines from the reference arrangement line 21L1 to the seventh reference arrangement line 21L7.

  On the other hand, the inclined arrangement line 22L is an imaginary straight line that is inclined at a predetermined inclination angle θb with respect to the reference arrangement line 21L and arranged in plural along the width direction W every 0.5 mm.

  Here, in the crimp terminal 1B of the second embodiment, the inclination angle θ is set to θb = 57.9 ° by setting an arbitrary integer n to 1 in the “Equation 1”.

  By arranging in the serration arrangement region z of the crimping surface 14 so that the center point 13a of the serration 13B coincides with the intersection of the reference arrangement line 21L and the inclined arrangement line 22L, FIG. 6 and FIG. As shown to (a), while the serration 13B arrange | positioned on the crimping | compression-bonding surface 14 can be arrange | positioned for every said predetermined space | interval P2 in the width direction W, the serration 13B is width | variety every other in the axial direction L. They can be arranged periodically to coincide with the direction W.

  Therefore, a plurality of serrations 13B can be periodically arranged on the crimping surface 14 at predetermined intervals in any of the axial direction L and the width direction W of the crimping terminal 1B. When confirming various dimensional accuracy of the serrations 13B formed on the crimping surface 14 through the portions, the plurality of serrations 13B can be cut together by one-time cutting.

  For example, as one of the means for confirming the finish of the plurality of serrations 13B formed on the crimping surface 14, for example, when the wire barrel portion 10 is cut in the axial direction L at the intermediate portion in the width direction W, the cutting line CL And the center portion 13a of the serration 13B coincides with the intersections of the first reference arrangement line 21L1, the third reference arrangement line 21L3, the fifth reference arrangement line 21L5, and the seventh reference arrangement line 21L7 (see FIG. 6) The cutting shape of these four serrations 13B can be confirmed by one cutting line CL.

  Therefore, the dimensional accuracy of the serration 13B formed on the crimping surface 14 through the cut portion of the serration 13B can be confirmed efficiently and accurately. As a pressing jig used for forming the serration 13B on the crimping surface 14 The serration punch can be easily quality controlled, and the serration 13B can always be formed on the crimping surface 14 with a high quality serration punch.

  Furthermore, the serrations 13B arranged along the both ends in the width direction W in the serration arrangement region z on the crimping surface 14 have the same shape with substantially half of the parallelogram shape along the axial direction L. In detail, it appears on the first reference arrangement line 21L1, the third reference arrangement line 21L3, the fifth reference arrangement line 21L5, and the seventh reference arrangement line 21L7 (a hatched portion in FIG. 6). reference).

  Accordingly, variations in the shape of the serration 13B that is partially cut off along the end of the serration arrangement region z can be suppressed, and the shape of the serration 13B is corresponding to the crimp terminal 1A of the first embodiment. It becomes possible to suppress the labor of the additional work to be applied, and to suppress the occurrence of a serration punch defect.

(Third embodiment)
FIG. 8 shows an enlarged plan view of the wire barrel portion 10 in the crimp terminal 1C in an unfolded state, FIG. 9 (a) shows an enlarged view of a region b in FIG. 8, and FIG. 9 (b) shows FIG. The enlarged view of the area | region c part in a) is shown.

  The crimp terminal 1C of the third embodiment has a configuration in which a plurality of serrations 13C are provided on the crimp surface 14 in an arrangement different from the arrangement of the serrations 13A and 13B in the crimp terminals 1A and 1B of the first and second embodiments.

  Specifically, a plurality of serrations 13C are arranged in the serration arrangement region z of the crimping surface 14 so that the center point 13a of the serration 13C coincides with the intersection of the reference arrangement line 21L and the inclined arrangement line 22L.

  The reference arrangement line 21L is an imaginary straight line extending along the width direction W arranged in a plurality of 0.4 mm as the predetermined interval P1 in the axial direction L. The reference arrangement line 21L is the first from the rear to the front in the axial direction L. It consists of a total of seven straight lines from the reference arrangement line 21L1 to the seventh reference arrangement line 21L7.

  On the other hand, the inclined arrangement line 22L is an imaginary straight line that is inclined at a predetermined inclination angle θc with respect to the reference arrangement line 21L and arranged in plural along the width direction W every 0.5 mm as the predetermined interval P2.

  Here, in the crimp terminal 1 </ b> C of the third embodiment, the inclination angle θ is set to θc = 38.66 ° by setting an arbitrary integer n to 0 in the “Equation 1”.

  By arranging in the serration arrangement region z of the crimping surface 14 such that the center point 13a of the serration 13C coincides with the intersection of the reference arrangement line 21L and the inclined arrangement line 22L, FIGS. ), The serrations 13C can be arranged at the predetermined intervals P2 in the width direction W, and can be arranged at the predetermined intervals P1 in the axial direction L.

  Therefore, a plurality of serrations 13C can be periodically disposed on the crimping surface 14 at predetermined intervals in both the axial direction L and the width direction W of the crimping terminal 1C, and the serrations 13C can be cut. When confirming various dimensional accuracy of the serrations 13C formed on the pressure-bonding surface 14 through the portion, the plurality of serrations 13C can be cut together by one-time cutting.

  For example, as shown in FIG. 8, as one means for confirming the finish of the plurality of serrations 13 </ b> C formed on the crimping surface 14, for example, the wire barrel portion 10 is cut in the axial direction L at the intermediate portion in the width direction W. In this case, since the central portion 13a of the serration 13C coincides with the intersection of this cutting line CL and each of the first reference arrangement line 21L1 to the seventh reference arrangement line 21L7, by one cutting line CL, The cut shapes of these seven serrations 13C can be confirmed.

  Therefore, the dimensional accuracy of the serration 13C formed on the crimping surface 14 through the cut portion of the serration 13C can be confirmed efficiently and accurately. As a pressing jig used to form the serration 13C on the crimping surface 14 The serration punch can be easily quality controlled, and the serration 13C can always be formed on the crimping surface 14 with a high quality serration punch.

  Furthermore, the serrations 13C arranged along both ends in the width direction W in the serration arrangement region z on the crimping surface 14 are substantially half of the parallelogram shape as shown by hatching in FIG. The thing of the same shape which lacks appears along the axial direction L for every said predetermined space | interval P1.

  Therefore, the irregular shape of the serration 13C arranged along the end portion in the width direction W of the serration arrangement region z can be suppressed, and the serration punch for forming the serration 13C by pressing the crimping surface 14 is It is possible to minimize processing such as scraping corresponding to such irregularly shaped serrations 13C, and it is possible to suppress the occurrence of punch defects.

  Further, as shown in FIG. 8, the length in the width direction W of the serration arrangement region z is shortened by approximately half the length A2 of the width direction W of the serration 13C from both ends in the width direction W. If it is set as zw and the serration 13C is arranged in the serration arrangement region z ′, the serration 13C having a partially missing shape can be excluded, and all the serrations 13C are unified into a parallelogram shape. Can do.

  Therefore, the shape of the serration punch can be unified, no additional machining of the serration punch is required, and the occurrence of punch defects can be suppressed.

In the correspondence between the configuration of the present invention and the above-described embodiment,
The conductor portion corresponds to the core wire 102, and so on.
The crimping means corresponds to the wire barrel part 10,
The locking portion corresponds to serration 13 (13A, 13B, 13C).

  The present invention is not limited to the above-described embodiments, and can be configured in various embodiments.

For example, as shown in FIGS. 10 to 12, the serration 13D can be formed as a hexagon instead of a parallelogram.
Specifically, the six outer peripheral edges constituting the hexagonal shapes of the serrations 13D, 13E, and 13F include three sets of opposing edges 26 that are opposed to each other with the central portion 13a of the serrations 13D, 13E, and 13F. The opposing sides 26A of the set are arranged so as to coincide with the width direction W.

  As shown in FIGS. 10A and 10B, the serration 13D is arranged on the crimping surface 14 in the same arrangement as the serration 13A in the case of the crimp terminal 1A of the first embodiment.

  As shown in FIGS. 11A and 11B, the serration 13E is arranged on the crimping surface 14 in the same arrangement as that of the serration 13B in the case of the crimp terminal 1B of the second embodiment.

  As shown in FIGS. 12A and 12B, the serration 13F is arranged on the crimping surface 14 in the same arrangement as that of the serration 13C in the case of the crimp terminal 1C of the third embodiment.

  10 (a), 11 (a), and 12 (a) are enlarged plan views of the wire barrel portion 10 in the crimp terminals 1D, 1E, and 1F in the unfolded state, respectively, and FIG. 10 (b). 11 (b) and FIG. 12 (b) show enlarged views of the region b in FIG. 10 (a), FIG. 11 (a), and FIG. 12 (a), respectively.

  Specifically, FIG. 10 shows a crimp terminal 1D having a configuration in which serrations 13D are arranged in the same arrangement as the arrangement of serrations 13A arranged on the crimp surface 14 in the crimp terminal 1A of the first embodiment. Is set to 0.4 mm, the predetermined interval P2 is set to 0.5 mm, an arbitrary integer n is set to 2, and the predetermined angle θa is set to 67.38 ° based on the “Equation 1”, the reference arrangement line 21L A configuration is shown in which serrations 13D are arranged at the intersections between and the inclined arrangement line 22L.

  FIG. 11 shows a crimp terminal 1E having a configuration in which serrations 13E are arranged in the same arrangement as the serrations 13B arranged on the crimp surface 14 in the crimp terminal 1B of the second embodiment. Reference arrangement line 21L and inclined arrangement when 4 mm, predetermined interval P2 is set to 0.5 mm, arbitrary integer n is set to 1, and predetermined angle θb is set to 59.99 ° based on the above “Equation 1” The structure which has arrange | positioned the serration 13E to the intersection with the line 22L is shown.

  FIG. 12 shows a crimp terminal 1F having a configuration in which serrations 13F are arranged in the same arrangement as that of the serrations 13C arranged on the crimp surface 14 in the crimp terminal 1C of the third embodiment, and a predetermined interval P1 is set to 0.4 mm. The reference arrangement line 21L and the inclined arrangement line 22L when the interval P2 is set to 0.5 mm, the arbitrary integer n is set to 0, and the predetermined angle θc is set to 38.66 ° based on the “Equation 1” A configuration is shown in which serrations 13C are arranged at the intersections.

As another embodiment, the serrations 13G and 13H can be formed in a diamond shape as shown in FIG.
FIGS. 13A and 13B show enlarged plan views of the wire barrel portion 10 in the crimp terminals 1G and 1H, respectively.

  Specifically, FIG. 13A shows the configuration of the crimp terminal 1G in which the serration 13G is arranged in the same arrangement as the arrangement of the serration 13C arranged on the crimp surface 14 in the crimp terminal 1C of the third embodiment. When the interval P1 is set to 0.4 mm, the predetermined interval P2 is set to 0.5 mm, an arbitrary integer n is set to 0, and the predetermined angle θc is set to 38.66 ° based on the “Equation 1”. The structure which has arrange | positioned the serration 13G in the intersection of the arrangement line 21L and the inclination arrangement line 22L is shown.

  FIG. 13B shows a configuration of the crimp terminal 1H in which the serration 13H is arranged in the same arrangement as the serration 13B arranged on the crimp surface 14 in the crimp terminal 1B of the second embodiment, and in detail, the predetermined interval P1. Is set to 0.4 mm, a predetermined interval P2 is set to 0.5 mm, an arbitrary integer n is set to 1, and a predetermined arrangement angle θb is set to 57.9 ° based on the “Equation 1”, the reference arrangement line 21L And a configuration in which serrations 13H are arranged at the intersections of the inclined arrangement line 22L.

  In addition, although illustration is abbreviate | omitted, you may comprise the crimp terminal of the structure which has arrange | positioned the serration formed in the rhombus by the same arrangement | positioning of the serration 13A arrange | positioned in the crimp surface 14 in the crimp terminal 1A of 1st Embodiment. .

  As described above, the serration 13 is not limited to a parallelogram, a hexagon, or a rhombus, but can be formed in a polygon such as a square, rectangle, pentagon, or star, a circle, an ellipse, or the like.

  Further, as another embodiment, the crimp terminal is a so-called discontinuous serration (discontinuous formed in the width direction W and the axial direction L) like the parallelogram, hexagon, or rhombus serration 13 described above. Hereinafter, it is not limited to a configuration in which only a plurality of “non-continuous serrations” are arranged on the crimping surface 14, and as shown in FIGS. 14 to 18, as these non-continuous serrations 13, for example, parallelogram serrations Both 13C and a so-called continuous serration 13L formed continuously along the width direction W of the serration arrangement region z can be arranged on the crimping surface 14.

  FIG. 14A shows the discontinuous serrations 13 </ b> C arranged on the reference arrangement line 21 </ b> L on both outer sides in the width direction W on the crimp surface 14 of the crimp terminal 1 </ b> C of the third embodiment (see FIG. 8). Instead of arranging four discontinuous serrations 13C arranged along the width direction W on both outer sides in the width direction W, instead of arranging the continuous serrations 13L on each reference arrangement line 21L. The front view of the crimping surface 14 of the crimp terminal 1S is shown.

  FIG. 14B shows a configuration in which the discontinuous serration 13C is arranged on the first reference arrangement line 21L1 on the crimping surface 14 of the crimp terminal 1C of the third embodiment, but not on the first reference arrangement line 21L1. The front view of the crimping surface 14 of the crimp terminal 1J of the structure which has arrange | positioned the serration 13L is shown.

  FIG. 15 (a) shows a configuration in which four discontinuous serrations 13C are not arranged along the width direction W on both outer sides in the width direction W on the crimp surface 14 shown in FIG. 14 (b). The front view of the crimp terminal 1K of the surface 14 is shown.

  In FIG. 15B, the discontinuous serration 13C is not arranged on the first reference arrangement line 21L1 and the continuous serration 13L is arranged on the first reference arrangement line 21L1 in the crimping surface 14 shown in FIG. 14A. The front view of the crimp terminal 1L of the crimping surface 14 of the structure which has arrange | positioned is shown.

  In FIG. 16A, in the crimping surface 14 shown in FIG. 14B, the discontinuous serration 13C is not arranged on the second reference arrangement line 21L2, and the continuous serration 13L is arranged on the second reference arrangement line 21L2. The front view of the crimping surface 14 of the crimp terminal 1M of the structure which has arrange | positioned is shown.

  In FIG. 16B, in the crimping surface 14 shown in FIG. 15A, the discontinuous serration 13C is not arranged on the second reference arrangement line 21L2, and the continuous serration 13L is arranged on the second reference arrangement line 21L2. The front view of the crimp surface 14 of the crimp terminal 1N of the structure which has arrange | positioned is shown.

  In FIG. 17A, in the crimping surface 14 shown in FIG. 15B, the discontinuous serration 13C is not arranged on the second reference arrangement line 21L2, and the continuous serration 13L is arranged on the second reference arrangement line 21L2. The front view of the crimping surface 14 of the crimp terminal 1T of the structure which has arrange | positioned is shown.

  FIG. 17B shows that the discontinuous serration 13C is not arranged on the fourth reference arrangement line 21L4 and the seventh reference arrangement line 21L7 on the crimping surface 14 shown in FIG. The front view of the crimping surface 14 of the crimp terminal 1P of the structure which has arrange | positioned the continuous serration 13 on the arrangement | positioning line 21L4 and the 7th reference | standard arrangement | positioning line 21L7 is shown.

  FIG. 18A shows that the fourth reference arrangement line 21L4 and the seventh reference arrangement line 21L7 are not arranged on the crimping surface 14 shown in FIG. The front view of the crimping surface 14 of the crimp terminal 1Q of the structure which has arrange | positioned the continuous serration 13L on the arrangement line 21L4 and the 7th reference arrangement line 21L7 is shown.

  FIG. 18B shows that the fourth reference arrangement line 21L4 and the seventh reference arrangement line 21L7 are not arranged on the crimping surface 14 shown in FIG. The front view of the crimping surface 14 of the crimp terminal 1R of the structure which has arrange | positioned the continuous serration 13L on the arrangement line 21L4 and the 7th reference arrangement line 21L7 is shown.

  The above-described first to third implementations of the crimp terminals 1D, 1E, 1F, 1G, 1H, 1S, 1J, 1K, 1L, 1M, 1N, 1T, 1P, 1Q, and 1R shown in FIGS. The above-described functions and effects produced by the crimp terminals 1A, 1B, and 1C can be exhibited.

  In FIG. 14A to FIG. 18B, the discontinuous serration 13C is arranged when the arbitrary integer n is set to “0” in “Equation 1”, but the arbitrary integer n is other than 0. Further, the discontinuous serrations 13 are not limited to parallelograms, and may have other shapes.

1A, 1B, 1C, 1D, 1E, 1F, 1G, 1H, 1S, 1J, 1K, 1L, 1M, 1N, 1T, 1P, 1Q, 1R ... Crimp terminal 10 ... Wire barrel part 13A, 13B, 13C, 13D , 13E, 13F, 13G, 13H ... serration 14 ... crimping surface 21L ... reference arrangement line 22L ... inclined arrangement line 24 ... reference side 25 ... inclined side W ... width direction L ... axial direction P1 ... predetermined interval P2 ... predetermined interval θa, θb, θc, ... Predetermined tilt angles

Claims (7)

A crimp terminal provided with a crimping means for crimping a conductor portion of a covered electric wire,
The crimping surface of the crimping means includes a plurality of latching portions that latch a part of the conductor portion,
Along with any one of the axial direction coinciding with the longitudinal direction of the covered electric wire connected to the crimping means and the width direction orthogonal to the axial direction, and arranged in the other direction at predetermined intervals P1 The reference placement line
The center point of the locking portion is aligned with the intersections with the inclined arrangement lines that are inclined at a predetermined inclination angle θ with respect to the reference arrangement line and arranged at predetermined intervals P2 along the one direction. Arranging the locking part,
The tilt angle θ is
When n is an arbitrary integer,
θ = tan ⁻¹ ((n + 1) P1 / P2)
Crimp terminal set to. The crimp terminal according to claim 1, wherein the locking portions are each formed in the same plan view shape and size. The crimp terminal according to claim 1 or 2, wherein the arbitrary integer n is set to 0. The locking portion,
The reference sides parallel to each other along the one direction and having a dimension of A2 are formed in a parallelogram shape arranged at a predetermined interval A1 in the other direction,
The predetermined interval P1 and the predetermined interval P2 are
P1> A1, P2> A2
The crimp terminal according to any one of claims 1 to 3, wherein An inclination angle α with respect to the reference side of the inclined side having both sides in the one direction of the locking portion formed in a parallelogram shape,
α ≧ tan ⁻¹ (A1 / A2)
The crimp terminal according to claim 4, which is set as described above. The crimp terminal according to claim 5, wherein the inclination angle α and the inclination angle θ coincide with each other. Manufacture of a crimp terminal comprising a crimping means for crimping a conductor portion of a covered electric wire, and a plurality of latching portions to which a part of the conductor portion is latched arranged at a predetermined arrangement position on a crimping surface of the crimping means. A method,
A reference arrangement line parallel to any one of the axial direction coinciding with the longitudinal direction of the covered electric wire and the width direction orthogonal to the axial direction is set,
A plurality of the reference arrangement lines are arranged at predetermined intervals P1 along another direction orthogonal to the one direction,
Set an inclined arrangement line inclined by a predetermined inclination angle θ with respect to the reference arrangement line,
A plurality of the inclined arrangement lines are arranged at predetermined intervals P2 along the one direction,
The predetermined arrangement position is set to an arrangement position where a center point of the locking portion coincides with an intersection portion of the reference arrangement line and the inclined arrangement line,
The predetermined inclination angle θ is
When n is an arbitrary integer,
θ = tan ⁻¹ ((n + 1) P1 / P2)
The manufacturing method of the crimp terminal which arrange | positions and arrange | positions the said several latching | locking part.

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