The present invention relates to a terminal connection structure for connecting a terminal to a wire and a method of manufacturing the terminal connection structure.
A terminal connection structure of a conventional example is shown in
The terminal 60 includes a wire crimping section 61 and an external connection section 62. The wire crimping section 61 includes a base section 61a and a pair of caulking sections 61b formed in extension from opposite edges of the base section 61a. By caulking the pair of caulking sections 61b, the conductor 50 is fixed to the wire crimping section 61 by a crimping force thereof.
A terminal connection structure of another conventional example (see Patent Literature 1) is shown in
Furthermore, the conductor 50 and the pair of caulking sections 71b have a friction-agitation connection section 73 formed by making these sections into a state of integrated plastic flow. The friction-agitation connection section 73 is formed by using a connection tool (not shown) having a pin at the tip of a shoulder and operating the connection tool from the side of the pair of caulking sections 71b.
However, in the terminal connection structure of the former conventional example, the conductor 50 and the wire crimping section 61 are fixed only by the crimping force. As the crimping force increases, electric contact resistance between the conductor 50 and the wire crimping section 61 is stabilized at lower values. However, when the crimping force increases, fixing strength (tensile strength) between the conductor 50 and the wire crimping section 61 decreases. It is because when the crimping force is large, the conductor 50 extends in an axial direction to decrease a sectional area thereof. Therefore, a decrease in the electric contact resistance and an increase in the fixing strength (tensile strength) cannot be ensured concurrently.
On the other hand, in the terminal connection structure of the latter conventional example, the conductor 50 and the wire crimping section 71 are fixed not only by the crimping force but also by a connection force of the friction-agitation connection section 73. Accordingly, the fixing strength (tensile strength) can be increased without increasing the crimping force of the wire crimping section 61. Therefore, while causing the electric contact resistance to be lower than in the terminal connection structure of the former conventional example, the fixing strength (tensile strength) can be increased. However, as shown in
As shown in
The present invention has been achieved to solve the above problems, and an object of the present invention is to provide a fixed terminal connection structure that can sufficiently and reliably ensure a decrease in the electric contact resistance and an increase in the fixing strength concurrently, and a method of manufacturing the terminal connection structure.
To achieve the above object, a first aspect of the present invention is to provide a terminal connection structure for connecting a terminal to a wire, comprising: a wire crimping section of the terminal, the wire crimping section having a base section upon which a conductor of the wire is arranged, and a caulking section formed in extension from the base section and caulked so as to crimp the conductor; and a friction-agitation connection section formed by making both of the base section and the caulking section together with the conductor into a state of integrated plastic flow.
In a second aspect of the present invention depending on the first aspect, in the terminal connection structure, the terminal has an external connection section as a separate body from the wire crimping section; and the friction-agitation connection section is formed by making also the external connection section together with the base section, the caulking section, and the conductor into the state of integrated plastic flow.
To achieve the above object, a third aspect of the present invention is to provide a method of manufacturing a terminal connection structure, comprising: a wire crimping step of mounting a conductor on an upper surface of a base section of a wire crimping section of a terminal, and caulking a caulking section formed in extension from the base section to cover the conductor, thereby crimping the conductor; and a friction-agitation connection-processing step of, after the wire crimping step, performing friction-agitation connection processing to the wire crimping section by using a connection tool, and making both of the base section and the caulking section together with the conductor into a state of integrated plastic flow, thereby forming a friction-agitation connection section.
In a fourth aspect of the present invention depending on the third aspect, in the method of manufacturing a terminal connection structure, the connection tool is operated from a side of the base section in the friction-agitation connection-processing step.
In a fifth aspect of the present invention depending on the third or fourth aspect, in the method of manufacturing a terminal connection structure, the terminal includes an external connection section as a separate body from the wire crimping section; and in the friction-agitation connection-processing step, the external connection section is closely attached to an external surface of the wire crimping section, the connection tool is operated from a side of the external connection section, and the external connection section is also made into the state of integrated plastic flow, thereby forming the friction-agitation connection section.
According to the present invention described in the first to fifth aspects, the conductor and the wire crimping section are fixed by the crimping force and the connection force of the friction-agitation connection section. Because the conductor is fixed to the caulking section and to the base section by the friction-agitation connection section, the conductor is rigidly fixed between the caulking section and the base section. Accordingly, no gap is formed between the conductor and the caulking section and between the conductor and the base section because of terminal deformation due to an external force or slight terminal deformation due to a temperature change of the external environment or energization heat generation. With this configuration, a decrease in the electric contact resistance and an increase in the fixing strength can be ensured sufficiently and reliably.
a) is an enlarged cross-sectional view along a line IV-IV in
a), 6(b) and 6(c) show a first embodiment of the present invention,
a), 7(b) and 7(c) are cross-sectional views showing a manufacturing procedure of the terminal connection structure according to the first embodiment.
Embodiments of the present invention are explained below with reference to the drawings.
a) to 6(c) show a terminal connection structure according to a first embodiment of the present invention. In
The terminal 10 is formed by bending one sheet metal having a predetermined shape. The terminal 10 includes a wire crimping section 11, and an external connection section 12 integrally formed with the wire crimping section 11. The wire crimping section 11 includes a base section 13 and a pair of caulking sections 14 formed in extension from opposite edges of the base section 13. The conductor 1 is mounted on an upper surface of the base section 13, and the pair of caulking sections 14 is caulked so as to crimp the conductor 1 from above.
A friction-agitation connection section 20 is provided to the conductor 1, the pair of caulking sections 14, and the base section 13, which is formed by making these sections into a state of integrated plastic flow.
The external connection section 12 has a circular shape and has a mounting hole 12a at the center thereof. Another wire or the like is connected by using the mounting hole 12a.
A manufacturing procedure of the terminal connection structure described above is explained next.
First, the insulating coating 2 at the end of the wire W is peeled to expose the conductor 1.
As shown in
Friction agitation connection is then performed by using a connection tool 30 (a friction-agitation connecting process). As shown in
The wire crimping section 11 is placed to cause the bottom surface of the base section 13 to face the connection tool 30 having the configuration mentioned above. The shoulder section 31 and the pin section 32 are rotatingly driven to dig the rotating pin section 32 into the wire crimping section 11 from the base section 13, and then the pin section 32 is pulled out after a certain period of time. When the rotating pin section 32 is dug into the wire crimping section 11, the wire crimping section 11 and the conductor 1 at that portion are softened by frictional heat due to a friction-rotation agitating action of the pin section 32 to cause plastic flow. The wire crimping section 11 and conductor 1 in the state of plastic flow are rapidly cooled and solidified by heat conduction after the pin section 32 is pulled out, thereby forming the friction-agitation connection section 20 shown in
As explained above, the wire crimping section 11 of the terminal 10 includes the base section 13 upon which the conductor 1 of the wire W is arranged, and a pair of caulking sections 14 that is formed in extension from the base section 13 and is caulked so as to crimp the conductor 1 from above. The friction-agitation connection section 20, which is formed by making the conductor 1, the base section 13, and the pair of caulking sections 14 into the state of integrated plastic flow, is provided on the wire crimping section 11. Accordingly, the conductor 1 and the wire crimping section 11 are fixed by the crimping force and the connection force by the friction-agitation connection section 20. Because the conductor 1 is fixed by the pair of caulking sections 14 and also fixed to the base section 13 by the friction-agitation connection section 20, the conductor 1 is rigidly fixed between the pair of caulking sections 14 and the base section 13. Therefore, no gap is generated between the conductor 1 and the pair of caulking sections 14 and also between the conductor 1 and the base section 13 because of terminal deformation due to an external force or slight terminal deformation due to a temperature change of the external environment or energization heat generation. Consequently, a decrease in the electric contact resistance and an increase in the fixing strength (tensile strength) can be ensured sufficiently and reliably.
The conductor 1 is arranged in the wire crimping section 11 without any gap. Therefore, the element wires of the conductor do not become loose due to an external force or the like, and thus an increase in the electric contact resistance and a decrease in the fixing strength (tensile strength) resulting from the loosened element wires can be prevented.
In the friction-agitation connecting process, the connection tool 30 is operated from the side of the base section 13. Because an external surface of the base section 13 is flat, workability is high.
The external connection section 12 has a round shape with the mounting hole 12a. However, needless to mention, other shapes can be also employed.
Other configurations are the same as those in the first embodiment and thus explanations thereof will be omitted to avoid redundancy. Like constituent parts in the drawings are denoted by like references for clarification.
A manufacturing procedure of the terminal connection structure described above is explained next.
The insulating coating 2 at an end of the wire W is first peeled to expose the conductor 1.
The conductor 1 with the wire W being exposed is then mounted on an upper surface of the base section 13 of the wire crimping section 11A, and the pair of caulking sections 14 is caulked to cover the upper part of the conductor 1 (the wire crimping process), thereby crimping the conductor 1 in the wire crimping section 11.
As shown in
Friction agitation connection is then performed by using a connection tool (not shown) (the friction-agitation connecting process). Because the configuration of the connection tool is the same as that in the first embodiment, explanations thereof will be omitted.
The bottom surface side of the external connection section 12A is arranged to face the connection tool. That is, the connection tool is operated from the side of the external connection section 12A. Friction agitation connection is then performed as explained in the first embodiment to form the friction-agitation connection section 20A shown in
As described above, the same operation and effect as those in the first embodiment are achieved also in the second embodiment.
Furthermore, the terminal 10A includes the wire crimping section 11A and the external connection section 12A which is a separate body from the wire crimping section 11A, and the friction-agitation connection section 20A is formed by making also the external connection section 12A into the state of integrated plastic flow. Accordingly, when the wire crimping section 11 and the external connection section 12 are an integrated component (in the case of the first embodiment), and when the number of forms of the wire crimping section 11 is N and the number of forms of the external connection section 12 is M, (N×M) components (terminals 10) need to be manufactured. On the other hand, in the second embodiment, it suffices to manufacture only (N+M) components, thereby enabling to reduce the number of components of the terminal 10A. For example, when the number of forms of the wire crimping section 11A (not shown) is two and the number of forms of the external connection sections 12A to 12C is three (shown in
In the friction-agitation connecting process, the connection tool (not shown) is operated from the side of the external connection section 12A. Because the external surface of the external connection section 12A is flat, workability is high.
In the first and second embodiments, the pin section 32 of the connection tool 30 is dug into a predetermined position of the wire crimping section 11, and is pulled out directly after the predetermined period of time, thereby forming the friction-agitation connection section 20 with spot connection. However, when the wire crimping section 11 of the terminal 10 is larger than the pin section 32 of the connection tool 30, the pin section 32 dug into the wire crimping section 11 can be moved to form the friction-agitation connection section 20 in a wide range.
The entire contents of Japanese Patent Application No. 2010-164761 (filed on Jul. 22, 2010) are incorporated by reference in the specification of the present application.
The present invention is not limited to the embodiment explained above and can be embodied in various manners by being properly modified.
Number | Date | Country | Kind |
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2010-164761 | Jul 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/065466 | 7/6/2011 | WO | 00 | 1/18/2013 |
Publishing Document | Publishing Date | Country | Kind |
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WO2012/011388 | 1/26/2012 | WO | A |
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20090315419 | Mita et al. | Dec 2009 | A1 |
20110058307 | Lee et al. | Mar 2011 | A1 |
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6-302341 | Oct 1994 | JP |
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Entry |
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Communication dated Jun. 17, 2014 from the Japanese Patent Office in counterpart Japanese application No. 2010164761. |
Number | Date | Country | |
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20130112476 A1 | May 2013 | US |