1. Field of the Invention
The present invention relates to a crimping terminal with a conductor crimping portion.
2. Description of the Related Art
In general, the conductor crimping portion 512 of the crimping terminal includes a bottom plate 521 and a pair of conductor crimping tabs 522 and 522 extending upward from both edges of the bottom plate 521. The conductor crimping portion 512 is formed so as to have a substantially U-shaped cross-section. The pair of conductor crimping tabs 522 and 522 is curled inward so as to wrap the conductor W of the electric cable which is disposed on the inner surface of the bottom plate 521, so that the respective front ends thereof is crimped so as to bite the conductor W.
Since the crimping terminal with the above-described structure is installed in a vehicle in many cases, the crimping terminal needs to be designed to sufficiently withstand thermal shock. Thus, a sampling test is performed to evaluate thermal shock resistance performance of the crimping terminal. In this test, for example, an environmental temperature with respect to the conductor crimping portion 512 repeatedly alternates between a high temperature and a low temperature, so that stress as thermal shock is continuously applied thereto.
In
As shown in these figures, since the environmental temperature repeatedly alternates between the high temperature and the low temperature, the conductor crimping portion 512 repeatedly expands and contracts as illustrated in
This increase of the contact resistance is likely to be due to a decrease in the crimping performance caused by the repeated thermal expansion and thermal contraction. That is, a part of the terminal which covers the conductor W from the outside thereof (that is, the conductor crimping portion 512) may slightly move with respect to the conductor W due to the repeated thermal expansion and thermal contraction. According to the analysis of the movement of the conductor crimping portion 512 of which the crimping performance is degraded, the contact resistance between the conductor W and the terminal may be affected by the large bending deformation or the movement of the bottom plate 521 of the conductor crimping portion 512 or the portion from the bottom plate 521 to the conductor crimping tab 522. Furthermore, the bending deformation is generated from the center portion Q of the bottom plate 521 in its widthwise direction.
In a conventional crimping terminal, if the conductor crimping portion has no sufficient rigidity, a relative movement may be easily generated between the crimping terminal and the conductor of the electric cable when the crimping terminal receives the thermal shock as described above. For this reason, the contact resistance between the terminal and the connection portion of the electric cable may increase, and the electric connection performance may be degraded. Especially, in recent years, there has been a demand for a decrease in the size or the thickness of the terminal. With this current tendency, it is desirable to solve the above-described problem.
Further, the conductor crimping portion has an inner surface with serrations to obtain a satisfactory connection state between the terminal and the electric cable in the structure of the general crimping terminal. The serrations may easily tear an oxide coating which is formed on a contact surface between the terminal and the electric cable by using the edges thereof. As a result, the electric cable and the terminal may be electrically connected to each other satisfactorily.
However, when the serrations are formed in the conductor crimping portion, the thickness of the portion provided with the serrations is thinned, whereby the terminal may be easily stretched in its axial direction (longitudinal direction) during the crimping operation. When the stretching amount increases, the terminal may protrude from a connector housing, for example, in accommodating the terminal into the connector housing. No severe problem occurs when serrations are formed from an array of grooves, but some problem may easily occur when the serrations are formed from scattered square or circular recesses. Especially, when the latter serrations are provided in the inner surface of the conductor crimping portion, the above-described stretching may increase due to its wideness of the area in which the serrations are formed.
Further, when plural recesses that serve as the serrations are formed in the inner surface of the conductor crimping portion, the terminal has high rigidity in an initial state after being produced because of its work hardening. However, when thermal shock is applied to the terminal, the terminal is annealed and softened, so that the rigidity thereof is degraded compared to the initial processing time. As a result, the force for tightening the conductor of the portion provided with the serrations is weakened, and a gap is formed between the terminal and the electric cable. When the gap is formed, the oxide coating is more easily generated from the gap, and this may increase the contact resistance.
The invention is made in view of the above-described circumstances, and it is an object of the invention to provide a crimping terminal capable of effectively improving rigidity of a portion from a bottom plate of a conductor crimping portion to a conductor crimping tab thereof, suppressing an increase in the contact resistance between the crimping terminal and an electric cable as much as possible even when receiving a thermal shock, and suppressing the conductor crimping portion from being excessively stretched in the axial direction.
An aspect of the present invention is a crimping terminal comprising: an electric connection portion; and a conductor crimping portion provided at a back side of the electric connection portion in a lengthwise direction thereof, the conductor crimping portion being connected to a conductor exposed at a front end of an electric cable so as to crimp the conductor. The conductor crimping portion includes: a bottom plate on which the conductor is placed, a pair of conductor crimping tabs configured to crimp the conductor on the bottom plate so as to wrap the conductor, the conductor crimping tabs being formed so as to extend from left and right sides of the bottom plate when seen from the lengthwise direction, serrations configured to retain the conductor inside the conductor crimping portion, the serrations being formed in at least a part of an inner surface of the conductor crimping portion, the part being curled so as to wrap the conductor when crimping the conductor, and at least one bead formed extending in a direction perpendicular to the lengthwise direction and being formed protruding from the inner surface of the conductor crimping portion toward the conductor on the bottom plate, the at least one bead being provided at the back side of the serrations in the lengthwise direction or the back and front sides of the serrations in the lengthwise direction in the inner surface of the conductor crimping portion.
The at least one bead may be formed by stamping a sheet forming the conductor crimping portion from an outer surface of the sheet.
Recesses as the serrations may be independently provided so as to be spaced from each other.
The recesses may be staggered.
The recesses may be formed in a circular shape.
The recesses may have the same shape.
When it is assumed that a grid includes a plurality of quadrilateral unit frames each of which is formed by the recesses serving as grid points, a first diagonal line of each unit frame may be positioned along the lengthwise direction of the crimping terminal, and a second diagonal line of each unit frame may be positioned so as to be perpendicular to the lengthwise direction of the crimping terminal.
The first and second diagonal lines may have the same length.
The first diagonal line may be longer than the second diagonal line. In this case, a recess on the second diagonal line of the recesses may partly overlap the other recess on the first diagonal line of the recesses when seen from the extension direction of the first diagonal line.
The second diagonal line may be longer than the first diagonal line. In this case, a recess on the first diagonal line of the recesses may partly overlap the other recess on the second diagonal line of the recesses when seen from the extension direction of the second diagonal line.
According to the crimping terminal, it is possible to improve the rigidity of the portion provided with the bead in the conductor crimping portion. Thus, the deformation (i.e. the movement causing expansion or contraction) in the event of thermal shock can be suppressed to be small, and it is possible to reduce the relative deviation of the terminal with respect to the electrical cable or vice versa in a boundary therebetween due to the repeated deformation by the thermal shock. Therefore, it is possible to stably suppress an increase in the contact resistance between the terminal and the electric cable.
Hereinafter, embodiments of the present invention will be described by referring to the drawings.
A crimping terminal 10 of the embodiment is produced by pressing one metal sheet, for example. As illustrated in
Here, the relative direction which will be used in the following description will be defined. In the array of the crimping terminal 10 illustrated in
As described above, the crimping terminal 10 includes the electric connection portion 11 which is positioned at the front side (the front end side) thereof and the conductor crimping portion 12 and the sheath crimping portion 13 which are positioned at the back side (the back end side) thereof. The electric connection portion 11 is a portion that is electrically connected to a counter terminal when the counter terminal is inserted. The conductor crimping portion 12 is connected to the back portion of the electric connection portion 11 through a connecting portion 14, and crimps the conductor W which is exposed at the front end of the electric cable (for example, see
As illustrated in
As illustrated in
Further, the serrations 35 are formed in the inner surface of the conductor crimping portion 12. Each serration 35 has an uneven surface which comes into contact with the conductor W, and retains the conductor W inside the conductor crimping portion 12. Due to this retaining state, the serration 35 is provided in the region between the front and back beads 31 or the vicinities of the respective beads 31, and includes plural recesses. The plural recesses are independently provided so as to be spaced from each other. In this case, as illustrated in
After the crimping terminal 10 is flatly exploded by pressing, the electric connection portion 11, the conductor crimping portion 12, or the sheath crimping portion 13 is bent as the next pressing step. For example, the conductor crimping portion 12 is bent toward the direction M so as to have a U-shaped cross-section (see
The next operation is performed so as to crimp the conductor crimping portion 12 of the crimping terminal 10 at the conductor W of the front end of the electric cable. The crimping terminal 10 is placed on a placement table (an upper surface) of a lower die (an anvil) (not illustrated). Furthermore, the conductor W is placed on the upper surface (the inner surface) of the bottom plate 21 between the conductor crimping tabs 22 and 22. Then, an upper die (a clamper) (not illustrated) is moved down, so that the guiding surface of the upper die gradually rounds the conductor crimping tab 22 inward from the front end side thereof. Finally, the guiding surface of the upper die rounds the front ends of the conductor crimping tabs 22 so as to be folded toward the conductor W, whereby the front ends of the conductor crimping tabs 22 and 22 bite into the conductor W while coming into contact with each other. As a result, the conductor W is crimped so as to be wrapped by the conductor crimping tabs 22 (see
By the above-described operations, the conductor crimping portion 12 of the crimping terminal 10 can be connected to the conductor W of the electric cable by crimping. Furthermore, the same crimping operation is performed on the sheath crimping portion 13. As a result, the crimping terminal 10 can be electrically and mechanically connected to the electric cable.
According to the crimping terminal 10, the bead 31 is formed so as to be stretched in the left-right direction at the front and back ends of a portion from the bottom plate 21 of the conductor crimping portion 12 to the conductor crimping tab 22 thereof. The bead 31 can improve the rigidity of a portion where the bead is provided. Thus, the deformation (i.e. the movement causing expansion or contraction) in the event of thermal shock can be suppressed to be small, and it is possible to reduce the relative deviation of the terminal with respect to the electrical cable or vice versa in a boundary therebetween due to the repeated deformation by the thermal shock. Therefore, it is possible to stably suppress an increase in the contact resistance between the terminal and the electric cable can be stably suppressed for a long period of time.
The terminal with the serration has higher initial hardness than that of the terminal without the serration. This is because of work hardening with the formed serration. Further, the effect of work hardening with the formed serration becomes more apparent in the terminal with plural circle or parallelogram recesses as the serration than the terminal with three grooves as the serration. Incidentally, even in the terminal with the serration, if the terminal does not have the bead, the effect of work hardening with the formed serration disappears after the thermal shock. On the contrary, in the terminal with both the serration and the bead, the terminal is hardly affected by the thermal shock and has a value similar to the initial rigidity. Thus, when the bead 31 is provided, the effect of work hardening which is obtained by the formed serration can be maintained as much as possible even after the thermal shock. Further, the rigidity of the conductor crimping portion can be improved by providing the bead 31.
According to the crimping terminal 10 of the embodiment, when the bead 31 is provided at the front and back ends of the conductor crimping portion 12, both the conductor W of the electric cable and the conductor crimping portion 12 can be suppressed from being stretched.
That is, when the case without the bead 31 (
Further, the pressure Kb which is applied to the conductor W between the beads 31 can be increased without excessively compressing the conductor crimping portion 12. Furthermore, in the case without the bead, the pressure Ka which is applied to the conductor W is small. In this way, since the high pressure Kb which is applied to the conductor W is obtained, all recesses which serve as the serrations 35 provided between the beads 31 can sufficiently bite into the conductor W. For example, in the case without the bead 31, with regard to the serration 35 in the vicinity of the front end or the back end of the conductor crimping portion 12, the pressure applied to the conductor W becomes smaller, whereby the serration may not easily bite into the conductor W. However, as indicated by the arrow G of
Further, since there is no need to excessively compress the conductor crimping portion 12, a decrease in the cross-sectional area of the conductor during the crimping operation can be suppressed as small as possible. Thus, the strength of the conductor W in the tensile direction can be improved. Further, since both the electrical connection performance and the fixation performance between the crimping terminal and the electric cable can be improved without excessively compressing the crimping terminal and the electric cable, a wide range of compressibility of the conductor crimping portion 12 can be ensured during the crimping operation and the production management thereof becomes easier.
Further, according to the crimping terminal 10 of the embodiment, since plural circular recesses are provided as the serration 35, the following effect can be obtained.
That is, when the conductor crimping portion 12 is compressed against the conductor W of the electric cable by using the crimping terminal 10, the conductor W of the electric cable are plastically deformed so as to enter into the respective small circular recesses provided as the serration 35 in the inner surface of the conductor crimping portion 12. Thus, the bonded state between the crimping terminal 10 and the conductor W can be reinforced. At this time, due to the friction between the edges of the respective recesses and the surface of the conductor which moves by the pressure or the friction between the inner surface of the recess and the surface of the conductor which enters into the recess, the oxide coating of the surface of the conductor W is peeled off, so that a newly-formed surface is exposed and is electrically connected to the terminal. Furthermore, since plural small circular recesses are provided in the crimping terminal 10 so as to be scattered, the total length of the hole edge of the recess can be effectively used to scrape the oxide coating away regardless of the tensile direction of the conductor W. Thus, it is possible to improve the electrical connection effect due to the exposure of the newly-formed surface compared to the crimping terminal in which the linear serration is provided so as to intersect with the extension direction of the conductor W of the electric cable.
Further, plural serrations 35 which include circular recesses are formed between the front and back beads 31 and 31, and by the combination of the beads 31 and the serrations 35 including plural circular recesses, the pressure Kb of the conductor W with respect to the serration 35 can be further increased and the conductor W and the newly-formed surface of the conductor crimping portion 12 can be further rigidly bonded to each other. Furthermore, the shape of the recess (especially, the shape of the opening) as the serration 35 of the embodiment is not limited, but a circular shape is desirable. This is because the deformation of the circular recess does not occur or is relatively suppressed compared to the recess with a corner portion from the viewpoint of the deformation of the serration due to the press-inserting pressure of the conductor W. Since the deformation is suppressed, the relative sliding amount between the conductor W of the electric cable and the conductor crimping portion 12 of the crimping terminal 10 increases and the exposure area of the newly-formed surface increases. As a result, the newly-formed surfaces can be rigidly bonded to each other. Especially, when the fact in which the bead 31 further increases the press-inserting pressure (the pressure Kb) of the conductor W is taken into consideration, the circular recess may be more suitable as the serration compared to the recess with the corner portion which is easily deformable.
Further, if forming a serration including at least one linearly stretched groove by pressing, a linear projection needs to be formed in the pressing mold, and such projection needs to be formed by grinding. On the other hand, when plural circular projections are formed in the pressing mold so as to process the serration, it is easy to use a processing method other than the above-described grinding. For example, when a linear projection is formed in the pressing mold, if the projection needs to be formed by electro-discharge machining, there is a need to form a linear recess in a discharge electrode. In fact, since it is very difficult to form the linear recess in a metal block, the linear projection is not easily formed by the electro-discharge machining. However, when plural circular projections are formed in the pressing mold so as to process the serration, the projections of the mold can be easily formed by the electro-discharge machining. For example, when the circular projection is formed by the electro-discharge machining, the plural circular projections can be transferred to the mold just by drilling a base block as an electrode so as to form round holes as plural circular recesses. Thus, the processing can be easily performed.
Next, an example of the serration of the embodiment will be described by referring to
As illustrated in
The grid 50 includes plural quadrilateral unit frames (unit grids) 50c each of which is formed by four adjacent recesses serving as grid points. The unit frame 50c includes two diagonal lines 50a and 50b. The diagonal line (the first diagonal line) 50a is positioned along the lengthwise direction of the crimping terminal 10 (or the lengthwise direction of the conductor W), and the diagonal line (the second diagonal line) 50b is positioned so as to be perpendicular to the lengthwise direction of the crimping terminal 10 (or the lengthwise direction of the conductor W). Further, the grid 50 is positioned along the circumferential direction of the conductor W.
As illustrated in
When the crimping terminal 10 crimps the conductor W, the conductor W is press-inserted into the serration (that is, the recess) 35. At this time, the edge of the serration 35 tears the oxide coating of the surface of the conductor W, so that the newly-formed surface therebelow is exposed. As a result, the newly-formed surface and the serration 35 come into close contact with each other, so that the electrical resistance between the crimping terminal 10 and the conductor W can be decreased. Further, when the conductor W is press-inserted into the serration (the recess) 35, the conductor W is caught by the edge of the serration 35, so that the mechanical connection strength can be improved.
Further, since the serration 35 is formed in almost the entire inner surface of the conductor crimping portion 12, damage which is applied to each wire Wa of the conductor W during the crimping operation (in other words, the compressibility) can be dispersed. The dispersion of the damage is particularly effective for the conductor W which is formed by twisting and binding the wires Wa. Further, since the mechanical connection strength can be stably improved and the edge length of the serration 35 can be sufficiently ensured, the newly-formed surface can be formed in the wide range of the surface of the conductor W. Thus, the low electrical connection resistance can be stably maintained.
As described above, the serration (the recess) 35 is disposed at each grid point of the grid 50, and the grid 50 is formed by plural unit frames 50c. The first diagonal line 50a of the unit frame 50c is positioned along the lengthwise direction of the crimping terminal 10, and the second diagonal line 50b is positioned so as to be perpendicular to the first diagonal line 50a. In other words, the first diagonal line 50a is positioned along the lengthwise direction of the conductor W, and the second diagonal line 50b is positioned along the circumferential direction of the conductor W. The lengths of the diagonal lines 50a and 50b are equal to each other, and the unit frame 50c forms a square shape. Thus, the low electrical connection resistance and the mechanical connection strength between the conductor W and the crimping terminal 10 can be obtained with a good balance in space and be reinforced, and can be stably maintained.
As in the above-described conductor crimping portion 12, plural circular recesses which serve as the serrations 35 are arrayed even in the conductor crimping portion 12′. Each recess is positioned at each grid point (the intersection point) of a grid 51. The grid 51 includes plural unit frames (unit grids) 51c, and each unit frame 51c includes a first diagonal line 51a and a second diagonal line 51b. The first diagonal line 51a is positioned along the lengthwise direction of the crimping terminal 10, and the second diagonal line 51b is positioned so as to be perpendicular to the first diagonal line 51a. In other words, the first diagonal line 51a is positioned along the lengthwise direction of the conductor W, and the second diagonal line 51b is positioned so as to be perpendicular to the lengthwise direction of the conductor W. As illustrated in
As described above, the first diagonal line 51a of the grid 51 is positioned along the lengthwise direction of the crimping terminal 10, and the second diagonal line 51b is positioned so as to be perpendicular to the lengthwise direction of the crimping terminal 10. Furthermore, the first diagonal line 51a is longer than the second diagonal line 51b. The serration (the recess) 35 is arrayed in the grid point (the intersection point) of the grid 51. Thus, since the interval between the recesses serving as the serrations 35 in the circumferential direction of the conductor W is narrower than the interval between the recesses in the lengthwise direction of the conductor W, a newly-formed surface in which the edge of the serration 35 is wide is formed. As a result, the electrical connection resistance between the conductor W and the crimping terminal 10 decreases and the connection resistance can be stably maintained.
Further, in the conductor W which is formed by twisting and binding the wires Wa, the edges of the serrations 35 crimp the respective wires Wa without a speck therein due to the dense array of the serrations 35 along the circumferential direction of the conductor W. Furthermore, since the interval between the serrations 35 in the lengthwise direction of the conductor W becomes wider, damage which is applied to each wire Wa during the crimping operation can be dispersed. Thus, it is possible to suppress the damage which is caused by the thin wire diameter of the wire Wa forming the conductor W. Further, sufficient mechanical connection strength can be obtained between the conductor W and the crimping terminal 10, and low electrical connection resistance between the conductor W and the crimping terminal 10 can be stably maintained.
As in the above-described conductor crimping portion 12, plural circular recesses which serve as the serrations 35 are arrayed even in the conductor crimping portion 12″. Each recess is positioned at each grid point (the intersection point) of a grid 52. The grid 52 includes plural unit frames (unit grids) 52c, and each unit frame 52c includes a first diagonal line 52a and a second diagonal line 52b. The first diagonal line 52a is positioned along the lengthwise direction of the crimping terminal 10, and the second diagonal line 52b is positioned so as to be perpendicular to the first diagonal line 52a. In other words, the first diagonal line 52a is positioned along the lengthwise direction of the conductor W, and the second diagonal line 52b is positioned so as to be perpendicular to the lengthwise direction of the conductor W. As illustrated in
As described above, the first diagonal line 52a of the grid 52 is positioned along the lengthwise direction of the crimping terminal 10, and the second diagonal line 52b is positioned so as to be perpendicular to the lengthwise direction of the crimping terminal 10. Furthermore, the first diagonal line 52a is shorter than the second diagonal line 52b. The serration (the recess) 35 is arrayed at the grid point (the intersection point) of the grid 52. Thus, since the interval between the recesses which serve as the serrations 35 in the lengthwise direction of the conductor W is narrow, a newly-formed surface in which the edge of the serration 35 is wide is formed. As a result, the electrical connection resistance between the conductor W and the crimping terminal 10 decreases and the connection resistance can be stably maintained.
Further, since the serrations 35 are densely arrayed along the lengthwise direction of the crimping terminal 10, the number of contact points between the conductor W and the serrations 35 increases along the lengthwise direction during the crimping operation. Thus, even when a load is applied in the direction where the conductor W is extracted from the crimping terminal 10, sufficient mechanical connection strength between the conductor W and the crimping terminal 10 can be obtained and be stably maintained.
Further, the conductor W may be formed by a single conductive wire or twisting plural wires Wa with a comparatively large diameter. In this way, when the number of the wires Wa forming the conductor W is small, the conductor W is comparatively strong against mechanical damage. Even in the conductor W, the array of the serrations 35 illustrated in
In a crimping terminal 110 of the second embodiment, the bead 31 is provided only at the back end of a part of the conductor crimping portion 12 from the bottom plate 21 of the conductor crimping portion 12 to the conductor crimping tab 22 thereof, wherein the part is curled so as to wrap the conductor W of the electric cable when crimping the conductor W. In other words, the bead 31 is provided only at the back side of the serration 35 in the lengthwise direction of the crimping terminal 110 in the inner surface of the conductor crimping portion 12. Further, the same serrations 35 as those of the first embodiment (see
Even in the crimping terminal 110 of the embodiment, the same effect as that of the crimping terminal 10 of the first embodiment is obtained. That is, the bead 31 is provided at the back end of a portion from the bottom plate 21 of the conductor crimping portion 12 to the conductor crimping tab 22 so as to be stretched in the left-right direction. The bead 31 can improve the rigidity of the portion where the bead is provided. Thus, the deformation (i.e. the movement causing expansion or contraction) in the event of thermal shock can be suppressed to be small, and it is possible to reduce the relative deviation of the crimping terminal 110 with respect to the electrical cable or vice versa in the boundary therebetween due to the repeated deformation with the thermal shock. Therefore, it is possible to stably suppress an increase in the contact resistance between the terminal and the electric cable.
Further, since the bead 31 is provided at the back end of the conductor crimping portion 12, the conductor W of the electric cable can be suppressed from being stretched to the back side of the crimping terminal 110. That is, since the compressing force with respect to the conductor W locally increases in the portion provided with the bead 31, the conductor W may not easily escape to the outside of the bead 31. As a result, the conductor W can be suppressed from being stretched backward and the crimping terminal 110 can be suppressed from being stretched backward.
Further, the pressure with respect to the conductor W can be increased without excessively compressing the conductor crimping portion 12. Thus, all recesses which serve as the serrations 35 formed on the front side of the bead 31 can sufficiently bite into the conductor W. For example, in the case without the bead 31, since the pressure with respect to the conductor W decreases in the serrations 35 near the back end of the conductor crimping portion 12, the serrations may not easily enter into the conductor W. Especially, when a bell mouth 12a which is inclined outward and widened so as to escape from the surface of the conductor W (see
Further, since the bead 31 increases the pressure with respect to the conductor W, the contact pressure between the conductor W and the crimping terminal 110 can be increased and the newly-formed surface can be more easily generated. Thus, the electrical connection performance between the conductor W and the crimping terminal 110 can be improved.
Further, since there is no need to excessively compress the conductor crimping portion 12, it is possible to suppress a decrease in the cross-sectional area of the conductor during the crimping operation. Thus, the strength of the conductor W in the tensile direction can be improved. Since both the electrical connection performance and the fixation performance between the crimping terminal and the electric cable can be improved without excessively compressing the crimping terminal and the electric cable, a wide range of compressibility of the conductor crimping portion 12 can be ensured during the crimping operation and the production management thereof becomes easier.
Furthermore, in the above-described respective embodiments, an example has been described in which the bead 31 is formed by pressing while the conductor crimping portion 12 is flatly exploded, but the bead may be formed at the same time of bending when the conductor crimping portion 12 is bent by a bending mold so as to have a U-shaped cross-section. In this case, a projection can be formed in the lower die so as to process the recess of the lower surface of the bead, and a recess may be formed in the upper die so as to process the projection of the upper surface of the bead.
Further, in the above-described respective embodiments, plural circular recesses are used as the serrations 35. However, the shape of the recess which serves as the serration 35 according to the present invention is not limited to the circular shape. For example, as described above, the shape of the recess may be a parallelogram shape. Further, the recess may have a groove shape which linearly extends toward a direction intersecting with the axial direction of the conductor.
Further, in the above-described first embodiment, each bead 31 is formed at the front and back ends of the conductor crimping portion 12. However, one bead may be further provided between the beads 31 of the front and back ends.
Number | Date | Country | Kind |
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2011-049778 | Mar 2011 | JP | national |
This application is a continuation application of International Application No. PCT/JP2012/000673, filed on Feb. 1, 2012, which claims priority to Japanese Patent Application No. 2011-049778, filed on Mar. 8, 2011, the entire contents of which are incorporated by references herein.
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Entry |
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International Search Report for PCT/JP2012/000673 dated Jun. 13, 2012. |
Communication dated Dec. 16, 2014, issued by the Japan Patent Office in corresponding Japanese Application No. 2011-049778. |
Communication dated Dec. 17, 2014, issued by the Korean Intellectual Property Office in counterpart Korean application No. 10-2013-7026623. |
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Number | Date | Country | |
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20140004758 A1 | Jan 2014 | US |
Number | Date | Country | |
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Parent | PCT/JP2012/000673 | Feb 2012 | US |
Child | 14018601 | US |