This application is the United States National Phase of International Patent Application Number PCT/JP2012/076497 filed on 12 Oct. 2012 which claims priority to Japanese Patent Application No. 2011-227122 filed on 14 Oct. 2011, all of which said applications are herein incorporated by reference in their entirety.
The present invention relates to a terminal where an electrical wire or the like is pressed into a U-shaped insertion groove, to be connected in relay connection of a censor or the like.
There have hitherto been provided a variety of terminals to be pressure-welded with an electrical wire, for use in a connector to connect the electrical wire.
Examples of such terminals include a terminal 103 in which an electrical wire 6 is pressed into an insertion part 102 provided with a U-shaped insertion groove 101 shown in
As a terminal having the above configuration, a pressure-welding connector terminal, which is connected with an electrical wire via an insertion part provided with a U-shaped slit similarly to the above, is described in Japanese Unexamined Patent Publication No. H9-312106.
However, in the terminal described in this publication, the U-shaped slit is just provided in a platy insertion part and the insertion part is thus apt to be plastically deformed in the case of pressing an electrical wire into the U-shaped slit, thus leading to a decrease in force of holding the electrical wire. There has thus been a problem of poor repairability at the time of reinserting and using the electrical wire.
Further, when the strength of the insertion part is enhanced for ensuring predetermined force of holding the electrical wire, spring force of the insertion part needs increasing, thus causing a problem of making the U-shaped slit difficult for pressing-in of the electrical wire.
The present invention has been made in view of the above conventional problems, and provides a terminal which does not require a large amount of applied load at the time of pressing-in of an electrical wire and reduces plastic deformation that occurs by the pressing-in of the electrical wire, thus allowing improvement in repairability at the time when the electrical wire is pulled out of an insertion groove and reinserted thereinto to be used.
The invention provides a terminal, including an insertion groove for pressing a conductor thereinto disposed between a pair of conductive arm parts, where, when t represents a distance from a center of a contact part between the conductive arm part and the conductor to an end of the conductive arm part at a time of pressing-in of the conductor; h represents a width of the conductive arm part at the end thereof; and Y represents a width between an arbitrary position of the insertion groove and an outer edge of the conductive arm part, the following relation holds: at a point of (½)×t, Y=(h/√2)×(0.8 to 1.2.
The invention further provides a terminal, including an insertion groove for pressing a conductor thereinto disposed between a pair of conductive arm parts, where, when X represents a distance from a center of a contact part between the conductive arm part and the conductor to an inside at a time of pressing-in of the conductor; Y represents a width between the insertion groove at a point of the distance X and an outer edge of the conductive arm part; and b represents a thickness of the conductive arm part, b is proportional to X in the case of Y being substantially constant.
Hereinafter, embodiments of the terminal according to the present invention will be described in accordance with
In a First Embodiment, as shown in
Specifically, as shown in
Next, an operation of pressing the electrical wire 6 into the insertion groove 13 will be described with reference to
The electrical wire 6 has a twisted line 8 bundling a plurality of single lines 7, and a coated layer 9 made up of a resin coating a periphery of this twisted line 8. Upon pressing-in of the electrical wire 6 from the upper portion of the insertion part 12, first, the coated layer 9 is removed by the peeling part 15 and the twisted line 8 is exposed. When the electrical wire 6 is further pressed downward in the insertion groove 13, the twisted line 8 is guided downward from the opening 13a while slightly expanding the conductive arm part 14 outward (see FIG. 2(B)), and by reaction force thereof, the single line 7 begins to be deformed. Then, the twisted line 8 pressed into the insertion groove 13 is pressed with the single lines 7 in the state of being densely provided within the insertion groove 13 (see
As shown in
The insertion part 12 is a platy body having a uniform thickness b. As shown in
Hereinafter, it is designed in
Herein, as shown in
Z=(b×h2)/6
Next, balance of force in the cantilevered beam 22 shown in
The section modulus Z at the point of the distance X is expressed by the following formula by using the width Y and the thickness b at this point:
Z=(b×Y2)/6 Formula (1)
The relation between a bending moment M and stress at the point of the distance X is expressed by the following formula:
M=σ×Z Formula (2)
Further, the bending moment M at the point of the distance X is expressed by the following formula:
M=W×X Formula (3)
According to Formulas (2), (3), the following formula can be expressed:
Z=(W/σ)×X Formula (4)
At that time, Z may be made proportional to X in order to make σ constant.
Further, Formula (1) may be substituted for Z of Formula (4), to make Y2 proportional to X.
At this time, when boundary conditions for the end 26: X=t and Y=h, are substituted, the constant stress a can be expressed by the following formula:
σ=(6×W×t)/(b×h2)
From the above, the width Y of the conductive arm part 14 is decided such that the section modulus Z is proportional to the distance X, namely the relation for making the width Y2 proportional to the distance X holds. Accordingly, even when the load W is applied at the time of pressing the electrical wire 6 into the insertion groove 13, the stress a generated throughout the conductive arm part 14 is constant, and hence the stress a is not biased to a specific place of the conductive arm part 14. Hence it is possible to reduce plastic deformation and plastic distortion that occur in the conductive arm part 14, while reducing a decrease in holding force due to exhaustion even when the electrical wire is once pulled out of the insertion groove 13 and reinserted thereinto, so as to improve the repairability. Further, the shape of the conductive arm part 14 is simplified, thereby facilitating production of the terminal 11 and allowing reduction in production cost thereof.
The present inventors conducted analysis of applying a load to each of the insertion part 12 according to the present invention and the conventional insertion part shown in
According to the present analysis results, the inclination of the elastic deformation region is small in the insertion part 12 of the present invention as compared with the conventional insertion part. Namely, it is found that the insertion part 12 of the present invention is apt to be elastically deformed and is not apt to be plastically deformed. Therefore, when the electrical wire 6 is pulled out in a state where the displacement of each insertion part has reached 13, the insertion part 12 of the present invention returns to the original shape along a straight line A.
On the other hand, the conventional insertion part returns to the original shape along a straight line B. Since the insertion part 12 of the present invention is apt to be elastically deformed and is reduced in plastic distortion, it was confirmed that, even when the electrical wire 6 is once pulled out of the insertion groove 13 and reinserted thereinto, the holding force does not decrease and the repairability is high.
Further, as apparent from
As described above, in order to make constant the stress to be applied to each cross section of the conductive arm part 14, the width Y of the conductive arm part 14 was decided so as to make the width Y2 proportional to the distance X. However, the beam 22 having uniform strength is not restrictive, and even one with a shape approximate to that of the beam 22 having uniform strength can efficiently disperse stress. At this time, the following relation holds:
when X=(½)×t,
at a point of X, Y=(h/√2)×(0.8 to 1.2) Formula (5)
The present inventors conducted analysis of applying a load to each of the conductive arm parts 14 formed by applying a variety of values to α.
According to the present analysis results, the displacement amount of the conductive arm part 14, applied with 0.8 to 1.2 as the value of a, namely plastic deformation, becomes small. On the other hand, it is found that, even when the value of a becomes smaller than 0.8 or the value of a becomes larger than 1.2, the displacement amount, namely the plastic deformation, becomes large. When α becomes smaller than 0.8, at the time of pressing the electrical wire 6 into the insertion groove 13, stress concentrates on the tip of the conductive arm part 14 and the tip is plastically deformed. When α becomes larger than 1.2, at the time of pressing the electrical wire 6 into the insertion groove 13, stress concentrates on the end 26 of the conductive arm part 14 and the end 26 is plastically deformed. From the above, α is preferably from 0.8 to 1.2.
So long as the outer edge 14a of the conductive arm part 14 passes between E2 and E3 at the point of X=(½)×t, the shape is not particularly restricted. For example, points m and E1, as well points E1 and n, may be connected by a straight line, or may be connected by a curve. Further, there may be adopted a configuration where an arbitrary point p (see
Naturally, the insertion part of the present invention is not restricted to the above embodiment, and a variety of shapes can be adopted so long as the section modulus Z is proportional to the distance X.
A modified example of First Embodiment is a case where a discontinuous circular hole 27 is provided on the deeper side than the insertion groove 13 as shown in
Another modified example is a case where an arc-like notched part 30 with an angle over 180° is provided at the end 26 of the insertion groove 13, as shown in
Other components are the same as the insertion part 12 according to First Embodiment, and hence the same numeral is provided to the same portion and a description thereof is omitted.
A second Embodiment is a case where a reinforcing part 36 is provided between a conductive arm part 33 as the beam having uniform strength and the end of a peeling part 35 in an insertion part 31, as shown in
Further, a modified example of Second Embodiment is a case where an inclined surface 37 which is inclined parallel to the end surface of the peeling part 35 is formed on the peeling part 35 of the insertion part 31, as shown in
Third Embodiment is a case where a long slit 44 is provided in the vicinity of the insertion groove 34 of a conductive arm part 42 and a short slit 45 is provided on the outer side of this slit 44 along the outer shape of the conductive arm part 42, as shown in
A fourth Embodiment is a case where a U-shaped slit (first slit) 53, which extends along the insertion groove 34 and surrounds the end 26 of the insertion groove 34, is provided in a conductive arm part 52 of an insertion part 51, as shown in
On the other hand, in the conventional insertion part, it returns to the original shape along the straight line B. Since the insertion part 51 of the present embodiment is apt to be elastically deformed and is significantly reduced in plastic distortion, it was confirmed that, even when the electrical wire 6 is once pulled out of the insertion groove 34 and reinserted thereinto, the holding force does not decrease and the repairability becomes higher.
A modified example of the Fourth Embodiment is a case where a linear slit (second slit) 56, whose end is formed in a semicircular shape, is provided on the outer side of the U-shaped slit (first slit) 53 of an insertion part 55 along the outer shape of a conductive arm part 57, as shown in
A fifth Embodiment is a case where the arc-like notched part 30 is provided at the end 26 of the insertion groove 34, while the U-shaped slit 53 surrounding this arc-like notched part 30 and extending along the insertion groove 34 is provided, in the insertion part 31 according to Second Embodiment shown in
Stress at the point X of a conductive arm part 48 of an insertion part 47 shown in
σ=(6×W×X)/(Y2×b) Formula (6)
At this time, when the width Y is substantially uniform and the thickness b is proportional to the distance X as in
Further, a pair of pressing-in notches 90 may be formed in positions (contact parts 34a with the electrical wire 6) opposed to the insertion groove 34, as in a Seventh Embodiment shown in
The present inventors conducted analysis of reaction force from each of the conductors 6 distributed to points, F, F′, G, G′, H, H′, I, I′, J and J′ of the pressing-in notch 90.
Although the insertion part 12 has been applied to the terminal 11 for use in the connector 1 to connect the electrical wire 6 in the above embodiment, this is not restrictive.
For example, as in an Eighth Embodiment shown in
This insertion part 82 is provided with a substantially oval insertion groove 83 for inserting the extension card thereinto, and a pair of conductive arm parts 84 symmetrically formed with this insertion groove 83 provided therebetween. Since the conductive arm part 84 has a shape approximate to that of the beam with uniform strength, it is possible to obtain a similar effect.
Further, as a modified example of the Eighth Embodiment shown in
On the other hand, as in a Ninth Embodiment shown in
This insertion part 71 is provided with: an insertion groove 72 for inserting a flexible print substrate thereinto (not shown); a fixed piece 73 which extends below the insertion groove 72 and is fixed to a housing (not shown); and a conductive arm part 74 opposed to the fixed piece 73 with the insertion groove 72 provided therebetween. Since the conductive arm part 74 has a shape approximate to that of the beam with uniform strength, it is possible to obtain a similar effect.
Moreover, as a modified example of the Ninth Embodiment shown in
As discussed above, the invention provides a terminal in which an insertion groove for pressing a conductor thereinto is provided between a pair of conductive arm parts, wherein, when t represents a distance from the center of a contact part between the conductive arm part and the conductor to the end of the conductive arm part at the time of pressing-in of the conductor, h represents a width of the conductive arm part at the end thereof, and Y represents a width between an arbitrary position of the insertion groove and the outer edge of the conductive arm part, the following relation holds:
at a point of (½)×t, Y=(h/√2)×(0.8 to 1.2).
With the above configurations, since stress that is applied to the conductive arm parts becomes constant, plastic deformation is not apt to occur, and holding force does not decrease even when the electrical wire is once pulled out of the insertion groove and reinserted thereinto, thus leading to improvement in repairability.
As for the width Y, the outer edge of the conductive arm part may have a curved shape outwardly projecting from the end of the insertion groove toward the center of the contact part.
When X represents a distance from the center of the contact part toward the end and Z represents a section modulus of the conductive arm part at a point of the distance X, Z may be proportional to X.
Therefore, stress that is acted on the cross section at the point of the distance X becomes constant even when a load is applied to an opening of the insertion groove. This can prevent the stress from concentrating on a specific place of the terminal, so as to reduce the plastic deformation. Accordingly, the holding force does not decrease even when the electrical wire is once pulled out of the insertion groove and reinserted thereinto, thus leading to improvement in repairability.
As for the distance X, the width Y and the thickness b of the conductive arm part, Y2 may be proportional to the distance X in the case of b being constant.
Therefore, the conductive arm part is elastically deformed by a small load as compared with the conventional terminal. Hence a load required at the time of pressing the electrical wire into the insertion groove is small, thus enhancing pressing-in of the electrical wire. Further, the shape of the terminal is simplified, thereby facilitating production and allowing reduction in production cost.
In a terminal in which an insertion groove for pressing a conductor thereinto is provided between a pair of conductive arm parts, when X represents a distance from the center of a contact part between the conductive arm part and the conductor to the inside at the time of pressing-in of the conductor; Y represents a width between the insertion groove at a point of the distance X and the outer edge of the conductive arm part; and b represents a thickness of the conductive arm part, b is proportional to X in the case of Y being substantially constant.
Therefore, stress that is acted on the cross section at the point of the distance X becomes constant even when a load is applied to an opening of the insertion groove. This can prevent the stress from concentrating on a specific place of the terminal, so as to reduce the plastic deformation. Accordingly, the holding force does not decrease even when the electrical wire is once pulled out of the insertion groove and reinserted thereinto, thus leading to improvement in repairability. Further, the shape of the terminal is simplified, thereby facilitating production and allowing reduction in production cost.
A plurality of slits may be provided in the conductive arm part, and the plurality of slits may be disposed such that the slit provided in a position closest to the insertion groove has the maximal length and the slits sequentially have smaller lengths as being more distant from the insertion groove.
A slit may be provided in a portion located on the deeper side than the end of the insertion groove.
Therefore, the conductive arm part becomes apt to be elastically deformed at the time of applying a load for expanding the opening of the insertion groove, to disperse stress that concentrates on the end of the insertion groove, so as to prevent stress concentration.
A notched part with a width larger than a width of the insertion groove may be provided at the end of the insertion groove.
Therefore, by application of a load, force of a vertical component and vertical force generated by the load cancel each other, out of a horizontal component and the vertical component of force generated at each end of the arc-like notched part, and hence it is possible to disperse stress that concentrates on the end of the insertion groove, so as to prevent stress concentration.
A reinforcing part may be provided between the conductive arm part and the end of the peeling part configured to remove a coated material of the conductor.
By providing the reinforcing part, it is possible to improve supporting strength of the peeling part.
A first slit extending along the insertion groove and surrounding the end of the insertion groove may be provided in the conductive arm part.
This facilitates elastic deformation of the conductive arm part to reduce the plastic deformation that occurs at the time of applying a load to the opening of the insertion groove, while allowing dispersion of stress that concentrates on the end of the insertion groove.
A second slit may be provided between the outer edge of the conductive arm part and the first slit.
This can lead to further reduction in plastic deformation.
A pressing-in notch for pressing and fixing the conductor thereinto may be formed on at least one side of the contact parts.
Therefore, reaction force by the pressed/fixed conductor is uniformly distributed to the pressing-in notch.
A pair of pressing-in notches for pressing and fixing the conductor thereinto may be formed in opposed positions of the contact parts.
Therefore, reaction force by the conductor is uniformly distributed to the pressing-in notch.
The pressing-in notch may be an arc curved outward.
Therefore, reaction force by the pressed/fixed conductor is uniformly distributed to the pressing-in notch in a more reliable manner.
Although the invention has been described in detail for the purpose of illustration based on what is currently considered to be the most practical and preferred embodiments, it is to be understood that such detail is solely for that purpose and that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover modifications and equivalent arrangements that are within the spirit and scope of the appended claims. For example, it is to be understood that the present invention contemplates that, to the extent possible, one or more features of any embodiment can be combined with one or more features of any other embodiment.
Number | Date | Country | Kind |
---|---|---|---|
2011-227122 | Oct 2011 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2012/076497 | 10/12/2012 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2013/054908 | 4/18/2013 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4317608 | Dechelette | Mar 1982 | A |
4826449 | Debortoli et al. | May 1989 | A |
5088934 | Chow et al. | Feb 1992 | A |
5290176 | Soes et al. | Mar 1994 | A |
5685733 | Janczak | Nov 1997 | A |
5827087 | Yamasaki | Oct 1998 | A |
6290531 | Onizuka et al. | Sep 2001 | B1 |
7118096 | Petrozziello | Oct 2006 | B2 |
8105105 | Taniguchi et al. | Jan 2012 | B2 |
20030045158 | Suzuki et al. | Mar 2003 | A1 |
20140213097 | Hemmi et al. | Jul 2014 | A1 |
20140315449 | Hemmi et al. | Oct 2014 | A1 |
Number | Date | Country |
---|---|---|
1229670 | Nov 1987 | CA |
9101351 | Apr 1991 | DE |
0549158 | Jun 1993 | EP |
S53-156080 | Dec 1978 | JP |
S56-007364 | Jan 1981 | JP |
H01-154471 | Jun 1989 | JP |
4179072 | Jun 1992 | JP |
7226236 | Aug 1995 | JP |
09232010 | Sep 1997 | JP |
9312106 | Dec 1997 | JP |
2000-077109 | Mar 2000 | JP |
5251115 | Mar 2003 | JP |
200377552 | Mar 2003 | JP |
3098197 | Sep 2003 | JP |
2005209540 | Aug 2005 | JP |
2011096628 | May 2011 | JP |
9411922 | May 1994 | WO |
Entry |
---|
International Search Report for corresponding application PCT/JP2012/076499 filed Oct. 12, 2012; Mail date Jan. 8, 2013. |
International Search Report for corresponding application PCT/JP2012/076497 filed Oct. 12, 2012; Mail date Jan. 8, 2013. |
International Search Report for corresponding application PCT/JP2012/076498 filed Oct. 12, 2012; Mail date Jan. 15, 2013. |
European Search Report from the corresponding European Patent Application No. 12839999.5 issued on May 4, 2015. |
Office Action from the corresponding Japanese Patent Application No. 2013-538598 issued on Jun. 30, 2015. |
Number | Date | Country | |
---|---|---|---|
20140213125 A1 | Jul 2014 | US |