JPWO2009054025A1 - Rotating connector - Google Patents

Abstract

An electrical connector for conducting a conductive connection, in which one connector component is rotatable relative to the other connector component, and provides a highly reliable and durable rotating connector. Objective. A rotary connector according to this embodiment includes a multipolar plug and a multipolar jack. A plurality of electrodes 11a to 11e are sequentially exposed in the axial direction in the core rod portion 14 of the multipolar plug 10 with the insulating collars 12a to 12d interposed therebetween. A bearing 17 is formed at the tip of the core rod portion 14 of the multipolar plug 10. The multipolar jack 20 has two sets of conductive terminals 23 a to 23 e and 24 a to 24 e that are in conductive contact with the electrode 11, and a rotary shaft 25 installed in the back of the plug housing space. When the multipolar plug 10 and the multipolar jack 20 are connected, the rotating shaft 25 is rotatably supported by the bearing 17. [Selection] Figure 5

Description

  The present invention relates to an electrical connector that performs electrical wiring connection, and more particularly to a rotary connector in which one connector component can rotate relative to the other connector component.

  Conventionally, when it is necessary to exchange electrical signals between the relatively moving first device and the second device, the two devices are electrically connected by cable wiring or a flexible printed circuit board. There were many cases to connect.

  However, if the first device and the second device rotate relatively 360 ° or more, the wiring breaks if it is a flexible substrate, and if it rotates many times, the cable wiring breaks, etc. End up. For this reason, for example, even in a folding mobile phone with a biaxial hinge, it has not been possible to adopt a configuration in which the main body side and the display side are relatively rotated by 360 ° or more.

On the other hand, as an electrical connector, a two-pole, three-pole, and four-pole single-head plug / jack that is conventionally determined by the standards of the Japan Electronics and Information Technology Industries Association, or five or more poles as disclosed in Patent Documents 1 and 2 below. Single-head plugs and jacks are provided.
JP 2002-134237 A JP 2002-42996 A

  These multipolar plugs and multipolar jacks have a ring-shaped electrode sequentially exposed in the axial direction across an insulating layer on the plug side shaft portion which is one connector part, and the other at a position facing each electrode. This is a configuration in which conductive contact terminals are arranged on the jack side which is a connector part. Therefore, it is possible to make many relative rotations around the axis while maintaining the conductive state.

  That is, if it is a conventional multipolar plug and multipolar jack, if the plug is attached to one device (including wiring from the device) and the jack is attached to the other device (including wiring from the device), It is possible to rotate both devices relatively many times.

  In this way, with the conventional multipolar plug and multipolar jack, it is possible to rotate relatively around the axis, but the above-described structure presses the conductive contact terminal on the jack side to the plug electrode. Thus, the shaft portion of the plug, which is the rotating shaft, is only supported and fixed by the conductive contact terminal.

  For this reason, the rotating shaft is unstable, and if it rotates at a high speed, the plug-side electrode and the conductive contact terminal on the jack side may be separated from each other, and the energized state may be interrupted. Lack.

  In addition, since the rotating shaft is unstable, an extra force is applied to the electrode and the conductive contact terminal during rotation, and these components may be damaged if the rotation is relatively 1,000 times. Also lacks durability.

  The present invention has been made to solve such a problem, is an electrical connector for conducting conductive connection, one connector component is rotatable relative to the other connector component, And it aims at providing a rotation connector with high reliability and durability.

  In order to solve the above-described problems, a rotary connector according to the present invention includes a multipolar plug having a core bar in which a plurality of electrodes insulated from each other are sequentially exposed on the surface, and a plug in which the core bar of the multipolar plug is accommodated A multi-pole jack having a housing space and having a plurality of conductive terminals placed facing the plug housing space so as to be in conductive contact with the electrodes when connected to the multi-pole plug, respectively. In the connector, a bearing provided at one of the tip of the core rod of the multipolar plug or the back of the plug housing space of the multipolar jack, and a rotating shaft provided at the other, the multipolar plug and And a rotating shaft supported by the bearing when the multipolar jack is connected.

  The rotary connector according to the present invention can provide a rotary connector with high reliability and durability. Then, if the multipolar plug is installed in the first device and the multipolar jack is installed in the second device, the first device and the second device are rotatably coupled by the rotary connector. Electrical connection is also possible.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The rotary connector according to the present embodiment is configured by a combination of a multipolar plug and a multipolar jack.

  First, based on FIG.1 and FIG.2, the structure of the multipolar plug which comprises the rotation connector which concerns on this embodiment is demonstrated. FIG. 1 is a perspective view of a multipolar plug according to the present embodiment, and FIG. 2 is a cross-sectional perspective view of the multipolar plug according to the present embodiment.

  As shown in FIGS. 1 and 2, the multipolar plug 10 includes first to fifth electrodes 11 a to 11 e made of a conductive metal and first to fourth electrodes made of an insulating resin for insulating the electrodes 11. The insulating collars 12a to 12d are configured. Further, the electrode 11 and the insulating collar 12 are used to form a rod-shaped core rod portion 14 which is a portion to be inserted into the jack side, a flange-shaped flange portion 15 located at the base of the core rod portion 14, and a set (device) ) Side and lead portion 16 to which wiring is connected is formed.

  The rod-shaped first electrode (chip) 11a is located at the axial center of the multipolar plug 10, and is exposed on the surface of the core rod portion 14 at the tip. Using this exposed portion as a contact portion, the conductive terminal on the jack side Conductive contact. Also, the lead portion 16 is exposed on the surface at the tip. Furthermore, a concave portion 17 is formed at the tip portion (first electrode 11a) of the core rod portion 14, and this concave portion 17 acts as a bearing. A jack-side rotating shaft, which will be described later, is fitted into and supported by the bearing 17.

  A cylindrical second electrode (ring) 11b is arranged outside the first electrode 11a with a first insulating collar 12a as an insulating layer interposed therebetween. Similarly, toward the outside of the plug, the cylindrical second insulating collar 12b, the third electrode (ring) 11c, the third insulating collar 12c, the fourth electrode (ring) 11d, the fourth insulating collar 12d, Five electrodes (rings) 11e are sequentially installed.

  In this way, the electrode 11 and the insulating collar 12 that are sequentially installed on the same axis are arranged so that the first electrode 11a, the first insulating collar 12a, and the second electrode 11b are directed from the distal end side of the core rod portion 14 toward the flange portion 15. The second insulating collar 12b, the third electrode 11c, the third insulating collar 12c, the fourth electrode 11d, the fourth insulating collar 12d, and the fifth electrode 11e are successively exposed on the surface in a ring shape.

  Moreover, in the flange part 15, a part of 5th electrode 11e protrudes in the shape of a ring zone, and forms the collar part. Also in the lead portion 16, the fifth electrode 11e, the fourth insulating collar 12d, the fourth electrode 11d, the third insulating collar 12c, the third electrode 11c, and the second insulating collar from the flange portion 15 side toward the tip of the lead portion 16. 12b, the second electrode 11b, the first insulating collar 12a, and the first electrode 11a are sequentially exposed on the surface. When the multipolar plug 10 is installed in one device (set) such as an electronic device, the core bar portion 14 is exposed to the outside of the device, and the lead portion 16 is fixed so as to be positioned in the set, The lead wire in the set is connected to the exposed portion of each electrode 11.

  Next, based on FIG.3 and FIG.4, the structure of the multipolar jack which comprises the rotation connector which concerns on this embodiment is demonstrated. FIG. 3 is a perspective view of the multipolar jack according to the present embodiment, and FIG. 4 is a perspective view partially showing the multipolar jack according to the present embodiment.

  As shown in FIG. 3 and FIG. 4, the multipolar jack 20 has a predetermined casing housing 21 so as to make conductive contact with the insulating casing 21 made of synthetic resin and each electrode 11 of the multipolar plug 10. A conductive terminal A23 installed at a location, a conductive terminal B24 that makes conductive contact with each electrode 11 and a rotary shaft 25 fixed to the housing 21 are provided.

  A plug housing space for housing the core rod portion 14 of the multipolar plug 10 is formed in the housing 21, and an opening is opened on one side surface of the housing 21. The core rod portion 14 of the multipolar plug 10 is inserted into the housing 21. When the core rod portion 14 is inserted into the housing 21, the rotary shaft 25 is fitted to the bearing 17 at the tip thereof, and the electrode 11 exposed on the surface of the core rod portion 14 contacts the conductive terminals 23 and 24. Supported. Thereby, the multipolar plug 10 and the multipolar jack 20 are connected so as to be relatively rotatable about the axis.

  The multipolar jack 20 according to the present embodiment is provided with two sets of conductive terminals, that is, a conductive terminal A23 and a conductive terminal B24, as conductive terminals that are in conductive contact with the first to fifth electrodes 11a to 11e. The first set of conductive terminals A23a to 23e are arranged in a line in the axial direction so that the contact portion of each terminal faces the plug accommodating space. The second set of conductive terminals B24a to 24e are similarly arranged in a row on the opposite side of the conductive terminal A23 across the plug housing space.

  When the multipolar plug 10 is inserted into the multipolar jack 20, the first conductive terminal A23a and the first conductive terminal B24a are in contact with the first electrode 11a, and the second conductive terminal A23b and the second conductive terminal B24b are The third conductive terminal A23c and the third conductive terminal B24c are in contact with the third electrode 11c, the fourth conductive terminal A23d and the fourth conductive terminal B24d are in contact with the fourth electrode 11d, and the fifth electrode 11b is in contact with the second electrode 11b. The conductive terminals 23 and 24 are disposed so that the conductive terminal A23e and the fifth conductive terminal B24e are in contact with the fifth electrode 11e.

  The conductive terminal A23 and the conductive terminal B24 are arranged such that the corresponding conductive terminal 23 and the conductive terminal 24 that are in contact with the same electrode 11 are slightly shifted in the axial direction. In this embodiment, the conductive terminal A23 and the conductive terminal B24 are more than the conductive terminal A23. The conductive terminal B24 is disposed 0.3 mm away from the opening side (entrance side) of the housing 21.

  The conductive terminals 23 and 24 are made of a conductive metal. The conductive terminals 23 and 24 are formed and arranged so as to be in pressure contact with the electrodes 11 by elastic force when the plug and the jack are connected. Yes.

  Specifically, the contact portions of the respective conductive terminals 23 and 24 are positioned so as to slightly protrude into the plug housing space when the multipolar plug 10 is not inserted, and when the multipolar plug 10 is inserted, When the contact portions of the terminals 23 and 24 are pushed back by the electrodes 11a to 11e and deformed, an elastic force in a direction perpendicular to the axis is generated, and the contact portions are pressed against the electrodes 11a to 11e. Thus, if the contact portions of the conductive terminals 23 and 24 are in pressure contact with the electrode 11 on the plug side, the conductive contact can be satisfactorily maintained even if some external force is applied to the plug or jack.

  Here, in this embodiment, it is comprised so that the contact force which press-contacts to the electrode 11 of conductive terminal A23 and the contact force which press-contacts to the electrode 11 of conductive terminal B24 may differ. Specifically, the contact force of the conductive terminal A23 is 50 to 70 [N], the contact pressure of the conductive terminal B24 to the electrode 11 is 30 to 50 [N], and the contact force of the conductive terminal A23 is greater. It is configured to be high.

  If the contact force is high, a cleaning effect such as peeling off an oxide film or the like on the surface of the electrode 11 occurs due to the contact between the plug and the jack, and the initial conductive contact can be stabilized. If the contact force is low, even if the relative number of rotations of the plug and jack in the connected state increases, there is almost no deterioration due to the removal of the conductive metal, and stable conductive contact can be maintained for a long time. it can.

  Therefore, as in this embodiment, if two pairs of conductive terminals 23 and 24 having different contact forces are used as the conductive terminals of the multipolar jack 20 and the contact positions are different from each other, the conductive terminal A23 having a high contact pressure is used. The initial conductive contact is stabilized, and the subsequent stable contact state can be maintained by the conductive terminal B24 having a low contact pressure, and the conductive contact is always stable over a long period of time compared to the case where only one set of conductive terminals is used. Can be realized.

  The rotating shaft 25 is formed of a hard metal such as stainless steel, and both ends of the cylindrical shaft are formed in a hemispherical shape, and a sheath portion protruding in a ring shape is formed near the center in the axial direction. The rotating shaft 25 is located in the back part of the plug accommodating space of the housing 21, and is fixed to the side surface opposite to the entrance of the housing 21 in this sheath portion.

  Further, the shaft portion on the opposite side to the one shaft portion that fits with the multipolar plug 10 of the rotating shaft 25 protrudes to the outside from a hole formed in the side surface of the housing 21. When the multipolar jack 20 is fixed to the set (device), the rotating shaft 25 can be further stabilized by directly fixing the protruding shaft portion of the rotating shaft 25 to the set side.

  The configuration of the multipolar plug 10 and the multipolar jack 20 has been described above. Next, a state in which the multipolar plug 10 and the multipolar jack 20 are connected will be described. FIG. 5 is a cross-sectional perspective view showing the rotary connector in a state where the multipolar plug and the multipolar jack according to the present embodiment are connected. Thus, the function of the rotary connector 1 is exhibited with the multipolar plug 10 and the multipolar jack 20 connected.

  As shown in FIG. 5, in a state where the multipolar plug 10 and the multipolar jack 20 are connected, one shaft portion of the rotary shaft 25 is inserted into the bearing 17 at the tip of the multipolar plug 10 inserted into the jack 20. Has been supported. Therefore, the connected multipolar plug 10 and multipolar jack 20 can be rotated relatively stably by the rotation shaft 25 being supported by the bearing 17. It is desirable to apply grease to the contact portion between the rotating shaft 25 and the bearing 17.

  As described above, in the present embodiment, the bearing 17 is provided at the tip of the multipolar plug 10, and the rotary shaft 25 fitted to the bearing 17 is provided in the multipolar jack 20, and the multipolar pole is formed by the rotary shaft 25 and the bearing 17. Since the relative rotation of the plug 10 and the multipolar jack 20 is realized, stable rotation can be secured. Therefore, according to this embodiment, a conductive state can be maintained over a long period of time, and a rotary connector with high reliability and durability can be provided.

  In this embodiment, since the bearing 17 is provided on the multipolar plug 10 side and the rotary shaft is provided on the multipolar jack 20 side, the axial dimension of the rotary connector 1 can be kept small. That is, the bearing 17 is provided inside the first electrode 11a located at the tip of the multipolar plug 10, and the exposed surface of the core rod portion 14 of the first electrode 11a and the bearing 17 are arranged so as to overlap in the axial direction. Therefore, the axial dimension of the rotary connector 1 can be reduced.

  Further, if a concave bearing 17 is provided at the tip of the multipolar plug 10, scraps and grease generated by sliding between the rotating shaft and the bearings accumulate in the bearing, so that the scraps and the like are removed from the electrode 11 and the conductive terminals 23 and 24. It is possible to prevent the conductive contact from being disturbed by moving to the contact portion.

  Next, a modification of the present embodiment will be described with reference to FIG. FIG. 6 is a cross-sectional perspective view of a rotary connector according to this modification. In addition, compared with the said embodiment, rotary connector 1 'which concerns on this modification comprises the point which provided the rotating shaft 18 in the multipolar plug 10' side, and provided the bearing 27 in the multipolar jack 20 'side. The other configurations are the same as those in the above embodiment. Therefore, the same configurations as those in the above embodiment are denoted by the same reference numerals, and description thereof is omitted.

  A rotary connector 1 ′ according to this modification includes a multipolar plug 10 ′ and a multipolar jack 20 ′. The re-tip of the first electrode 11 a ′ located at the tip of the core rod portion of the multipolar plug 10 ′ constitutes the rotating shaft 18. The rotating shaft 18 is on the tip side of the contact portion that is in conductive contact with the conductive terminals 23 and 24 of the first electrode 11a '. On the other hand, a bearing 27, which is a stainless steel ring, is installed in the back of the plug housing space of the multipolar jack 20 '.

  As shown in FIG. 6, in a state where the multipolar plug 10 ′ and the multipolar jack 20 ′ are connected, the rotary shaft 18 is fitted to the bearing 27 and is rotatably supported. Therefore, the multipolar plug 10 ′ and the multipolar jack 20 ′ can rotate relatively stably around the axis while maintaining a conductive state.

  As mentioned above, according to the rotary connector which concerns on this modification, while being able to show the effect similar to the said embodiment, since the bearing 27 is ring shape, compared with the case of a recessed part, the thermal radiation effect of friction heat Is expensive. Further, if a bearing is used as the ring-shaped bearing 27, the rotating shaft can be further stabilized and no shaving or the like occurs.

  Next, usage examples of the rotary connector according to this embodiment will be described with reference to the drawings. 7 and 8 are schematic views partially showing the usage of the rotary connector according to this embodiment.

  FIG. 7 shows a configuration in which the rotary connector 1 is applied to a hinge portion of a foldable mobile phone. As shown in the figure, a liquid crystal display unit 51 (second device) illustrated by a two-dot chain line can be rotated to a mobile phone body 50 (first device) illustrated by a dotted line via a rotary connector 1. It is supported by. The conductive connection between the mobile phone body 50 and the liquid crystal display unit 51 is realized by the rotary connector 1 including the multipolar plug 10 and the multipolar jack 20 that are in conductive contact.

  Specifically, the multipolar jack 20 is installed on the hinge portion of the mobile phone body 50 on the same axis at two locations, and the multipolar plug 10 is installed on the liquid crystal display portion 51 at two locations. Then, by connecting the multipolar jack 20 and the multipolar plug 10 that face each other, two rotary connectors 1 arranged on the same axis are formed, and the mobile phone body 50 and the liquid crystal display unit 51 are formed by the two rotary connectors 1. Are connected to be rotatable about the axis of the rotary connector 1.

  As described above, the rotary connector 1 according to the present embodiment functions as a support member that rotatably couples the main body 50 and the display unit 51 of the foldable mobile phone, and as an electrical connector that electrically connects the two. Is also functioning. Therefore, unlike the conventional case, it is not necessary to separately prepare a flexible substrate for electrical connection in addition to the support member for rotation, and the structure can be simplified and the cost can be reduced.

  FIG. 8 shows a configuration in which the rotary connector 1 is applied to a portable AV player. As shown in the figure, a liquid crystal display unit 61 (second device) illustrated by a two-dot chain line rotates via a rotary connector 1 to a portable AV player main body 60 (first device) illustrated by a dotted line. It is supported freely. The portable AV player main body 60 and the liquid crystal display unit 61 are conductively connected by the rotary connector 1 including the multipolar plug 10 and the multipolar jack 20 that are in conductive contact.

  Specifically, the multipolar jack 20 is installed in two locations on the portable AV player main body 60 on the same axis, and the multipolar plug 10 is installed in two locations on the liquid crystal display unit 61. Then, by connecting the multi-pole jack 20 and the multi-pole plug 10 facing each other, two rotary connectors 11 are formed, and the two rotary connectors 1 allow the portable AV player main body 60 and the liquid crystal display unit 61 to be connected to each other. The conductive connection is relatively made to be rotatable around the axis.

  As described above, the rotary connector 1 according to the present embodiment functions as a support member that rotatably connects the main body 60 and the display unit 61 of the portable AV player, and also serves as an electrical connector that electrically connects the two. It is functioning. Therefore, unlike the conventional case, it is not necessary to separately prepare a flexible substrate or the like for electrical connection, and the structure can be simplified and the cost can be reduced.

  As described above, the present embodiment including the modification has been described in detail. However, according to the present embodiment, the rotary connector includes a multipolar plug and a multipolar jack and performs conductive connection, and is reliable and durable. High rotational connector can be provided. Then, if the multipolar plug is installed in the first device and the multipolar jack is installed in the second device, the first device and the second device are rotatably coupled by the rotary connector. Electrical connection is also possible.

  As mentioned above, although embodiment of this invention was described in detail, embodiment of this invention is not limited to the said embodiment, A various deformation | transformation is possible within the range which does not deviate from the main point of this invention. Needless to say. For example, in the present embodiment, the rotary connector is composed of a 5-pole plug and a 5-pole jack, but it goes without saying that the number of poles of the plug and jack can be changed as appropriate. Moreover, the housing of the jack and the like may be formed integrally with the set (device) side.

FIG. 1 is a perspective view of a multipolar plug according to the present embodiment. FIG. 2 is a cross-sectional perspective view of the multipolar plug according to the present embodiment. FIG. 3 is a perspective view of the multipolar jack according to the present embodiment. FIG. 4 is a partially transparent perspective view of the multipolar jack according to the present embodiment. FIG. 5 is a cross-sectional view showing the rotary connector according to the present embodiment. FIG. 6 is a cross-sectional view showing a rotary connector according to a modification of the present embodiment. FIG. 7 is a schematic view partially showing a usage mode of the rotary connector according to the present embodiment. FIG. 8 is a schematic view showing a part of the usage of the rotary connector according to this embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Rotation connector 10 Multipolar plug 11 Electrode 12 Insulation collar 14 Core rod part 15 Flange part 16 Lead part 17 Bearing (recessed part)
20 Multi-pole jack 21 Housing 23 Conductive terminal A
24 Conductive terminal B
25 Rotating shaft

In order to solve the above-described problems, a rotary connector according to the present invention includes a multipolar plug having a core bar in which a plurality of electrodes insulated from each other are sequentially exposed on the surface, and a plug in which the core bar of the multipolar plug is accommodated A multi-pole jack having a housing space and having a plurality of conductive terminals placed facing the plug housing space so as to be in conductive contact with the electrodes when connected to the multi-pole plug, respectively. In the connector, a bearing formed of a recess formed at a tip portion of a core rod of the multipolar plug, and a rotary shaft provided in a back portion of a plug housing space of the multipolar jack, the multipolar plug and the And a rotating shaft supported by the bearing when connected to a multipolar jack.

Claims (4)

A multipolar plug having a core bar in which a plurality of electrodes insulated from each other are sequentially exposed on the surface;
A plurality of conductive conductors disposed so as to face the plug housing space so as to be in conductive contact with the electrodes when connected to the multipolar plug; In a rotary connector comprising a multi-pole jack having terminals,
A bearing provided at one of the tip of the core of the multipolar plug or the back of the plug housing space of the multipolar jack;
A rotating shaft provided on the other, the rotating shaft supported by the bearing when the multipolar plug and the multipolar jack are connected;
A rotary connector comprising:   The said bearing is a recessed part formed in the core rod tip of the said multipolar plug, and the said rotating shaft is provided in the back | inner part of the plug accommodation space of the said multipolar jack. Rotating connector.   The multipolar jack has two sets of conductive terminals that are in conductive contact with the respective electrodes of the multipolar plug, and the first set of conductive terminals and the second set of conductive terminals are connected to the same electrode. The rotary connector according to claim 1 or 2, wherein the conductive terminals that are in conductive contact are disposed so as to be in conductive contact at positions shifted from each other in the axial direction.   When the multipolar plug and the multipolar jack are connected, the contact force of the first set of conductive terminals to the electrode of the plug is greater than the contact force of the second set of conductive terminals. The rotary connector according to claim 3, wherein the rotary connector is configured as described above.

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