The present invention relates to a lever-fitting-type connector enabling a female connector and a male connector to be fitted to each other through rotating operation of a lever.
The female connector 110 has a female connector housing 112 housing terminals 111, and the female connector housing 112 is provided with rotation support shafts 113 on the left and right outside walls thereof so as to protrude. The rotation support shafts 113 are each rendered to be the rotation center of the lever 140.
The male connector 130, being a partner connector, has a male connector housing 131 to be fitted into the female connector housing 112. In the male connector housing 131, partner terminals 132 to be connected to the terminals 111 of the female connector housing 112 are housed. On the left and right outside walls of the male connector housing 131, bosses 133 are provided so as to protrude, and the bosses 133 are engaged to the lever 140.
A pair of left and right arm plates 141 and an operating portion 142 coupling the pair of left and right arm plates 141 on one side are integrally configured to form the lever 140. In the pair of left and right arm plates 141, there are formed cam grooves 143 into which the bosses 133 of the male connector 130 are inserted. Moreover, in the pair of left and right arm plates 141, there are formed support holes 144 into which the rotation support shafts 113 of the female connector 110 are inserted.
The lever-fitting-type connector 100 as described above causes the lever 140 to be mounted to the female connector 110 by inserting the rotation support shafts 113 of the female connector 110 into the support holes 144 of the lever 140. By inserting the bosses 133 into the cam grooves 143 of the lever 140 in this mounting state, the male connector 130 is joined to the lever 140, and the operating portion 142 is operated to cause the lever 140 to be rotated. Since the bosses 133 move along the cam grooves 143 due to rotation of the lever 140, it becomes possible to cause the male connector housing 131 to be fitted into the female connector housing 112.
However, in the related lever-fitting-type connector 100, the lever 140 is idle-rotated when the lever 140 is operated. When such an idle rotation occurs, a worthless operation force becomes necessary, because it is required to rotate the lever 140 further by the amount of being idle-rotated. In addition, since the range of operating the lever 140 is reduced due to the idle rotation of the lever 140, the operability of the lever 140 is reduced.
It is an object of the present invention to provide a lever-fitting-type connector that enables to reduce the force to be applied to a lever by preventing the lever from being idle-rotated, and thereby causes the operability of the lever to be enhanced.
A lever-fitting-type connector in accordance with some embodiments includes: a female connector including a female connector housing having a terminal of a wire end housed in the female connector housing; a male connector including a male connector housing configured to house a partner terminal of a wire end to be connected to the terminal housed in the female connector housing, the male connector housing fitted into the female connector being configured to connect the terminal of the wire end to the partner terminal of the wire end; a hood for the female connector to be mounted and for the male connector to be inserted; a lever rotatably assembled on the hood and configured to selectively apply a fitting force and a separation force between the male connector and the female connector by a rotating operation of the lever, wherein the male connector includes a lever drawing-in boss, the lever includes a boss drawing-in groove for the lever drawing-in boss to be drawn by a rotating operation of the lever, and the boss drawing-in groove includes a lever inversion groove portion configured to cause the lever drawing-in boss to rotate the lever in an opposite direction opposite to a fitting rotation direction for the male connector to be fitted into the female connector, in response to an insertion of the male connector into the hood with the lever being positioned at an initial rotation position, a drawing-in groove portion configured to guide the lever drawing-in boss by a rotating operation of the lever in the fitting rotation direction and cause the male connector to be fitted into the female connector, and a lever inertial rotation portion provided in between the lever inversion groove portion and the drawing-in groove portion and configured to rotate in the fitting rotation direction due to an inertial force of the lever after rotation of the lever in the opposite direction and cause the lever drawing-in boss to move to the drawing-in groove portion.
According to the aspect, by inserting the male connector into the hood, the lever drawing-in boss of the male connector is drawn into the boss drawing-in groove of the lever, and the lever rotates in the direction opposite to the fitting rotation direction. Accordingly, the idle rotations (lost rotation) of the lever at the occasion of operating the lever is reduced, and it becomes possible to draw the lever drawing-in boss into the boss drawing-in groove at an early stage. The force for inserting the male connector into the hood can thereby be reduced, and the force for operating the lever when causing the male connector to fit into the female connector can also be reduced.
In addition, the lever drawing-in boss and a lever inertial rotation portion of the boss drawing-in groove come into contact with each other due to the push of the male connector, and the lever rotates in the fitting rotation direction by the inertial force thereof. Since the region of operating the lever increases because of this rotation, the operability of the lever is enhanced.
An inner wall of the hood may include a lever temporary engagement arm being flexible and enabling the lever to be engaged at the initial rotation position, the lever may include a lever temporary engagement holding portion configured to temporarily engage with the lever temporary engagement arm and hold the lever at the initial pivot position, the male connector may include a lever temporary engagement release lug configured to warp the lever temporary engagement arm in response to insertion of the male connector into the hood with the lever being positioned at the initial rotation position and release a temporary engagement between the lever temporary engagement arm and the lever temporary engagement holding portion, and the lever drawing-in boss may be positioned at the lever inertial rotation portion upon release of the temporary engagement between the lever temporary engagement arm and the lever temporary engagement holding portion in response to the insertion of the male connector into the hood with the lever being positioned at the initial rotation position.
According to the configuration described above, since the state of temporary engagement between the lever temporary engagement arm and the lever temporary engagement holding portions is released due to the insertion of the male connector into the hood at the state in which the lever is at the initial rotation position and, due to the release, the lever drawing-in boss is positioned at the lever inertial rotation portion, the rotation of the lever in the fitting rotation direction due to inertia can be reliably carried out.
The lever may include a pair of arm plates each having a pivot support axis provided to protrude from an outer peripheral surface of the arm plate, and an operating portion coupling the pair of arm plates and for performing the rotating operation with the operating portion being rotatably supported by the hood, each of the pair of arm plates may include the boss drawing-in groove on toward the inner wall, and the lever inversion groove portion may include a drawing-in inlet for the lever drawing-in boss of the male connector to be inserted, and an inclined wall inclined downward along a direction for the male connector to be fitted into the female connector and configured to be in contact with the lever drawing-in boss inserted from the drawing-in inlet.
According to the configuration described above, since the lever inversion groove portion is provided with the drawing-in inlet to which the lever drawing-in boss of the male connector is inserted, and the inclined wall with which the lever drawing-in boss inserted from the drawing-in inlet is in contact and which inclines downward along the direction in which the male connector is fitted into the female connector, it is possible to reliably rotate the lever in the direction opposite to the fitting rotation direction.
The hood may include a lever lock engagement portion, and the operating portion of the lever may include a lever lock configured to engage with the lever lock engagement portion upon completion of a fit between the male connector and the female connector.
According to the configuration described above, since the lever lock engagement portion is provided in the hood and the lever lock, which is engaged to the lever lock engagement portion, is provided in the lever, the state of fitting of the male connector with the female connector can be reliably locked.
In the following, the present invention will be specifically described according to the embodiment shown in
The lever-fitting-type connector 1 is provided with a female connector 2, a male connector 3, a hood 5 and a lever 7.
AS shown in
The male connector 3 has a plurality (two) of male connector housings 31, 31a and spacers 32 provided in correspondence to the respective male connector housings 31, 31a as shown in
The plurality of male connector housings 31, 31a are used after having been assembled along the height direction. In the male connector 3 in which the plurality of male connector housings 31, 31a are assembled, there are formed lever drawing-in bosses 35, lever temporary engagement release lugs 36 and rib guide grooves 37 (refer to
The lever drawing-in bosses 35 draw the male connector 3 in, by being engaged with the lever 7, into the hood 5 through rotating operation of the lever 7, and cause the male connector 3 to be fitted into the female connector 2. The lever drawing-in bosses 35 are formed on the outside of the male connector housing 31 on the other side (the lower side in
The lever temporary engagement release lugs 36 are provided on the outside of the male connector housing 31a on one side (the upper side in
The rib guide grooves 37 are formed in the male connector housing 31a on the one side (the upper side in
Incidentally, there is formed a guide projection portion 38 on the top wall portion of the male connector housing 31a on the one side (refer to
The male connector 3 is inserted to and the female connector 2 is mounted in the hood 5, and the hood 5 has a collar-like plate portion 51, a pair of support wall portions 52 and a coupling cover portion 53.
The collar-like plate portion 51 is formed to be like a plate in an oval shape, and is positioned on the opposite side with respect to the side on which the male connector 3 is fitted. To the collar-like plate portion 51, the female connector 2 is mounted. For this reason, a mounting opening portion 51a (refer to
The pair of support wall portions 52 is provided so as to protrude toward the male connector 3 from one face side (the face on the side of the male connector 3) of the collar-like plate portion 51. The pair of support wall portions 52 have the lever 7 rotatably attached and support the rotation of the lever 7.
The coupling cover portion 53 couples the pair of support wall portions 52. In the present embodiment, the coupling cover portion 53 couples the end portions on one side of the pair of support wall portions 52 (the end portion on the upper side in
There are formed lever-falling prevention walls 54 on the collar-like plate portion 51. The lever-falling prevention walls 54 are provided so as to protrude in the same direction as the pair of support wall portions 52 as shown in
The pair of support wall portions 52 is provided with lever temporary engagement arms 55, lever lock engagement portions 56 and rotation support shaft support holes 57.
The lever temporary engagement arms 55 are temporarily engaged by lever temporary engagement holding portions 74 (refer to
The lever lock engagement portions 56 are provided below the respective support wall portions 52 (refer to
The rotation support shaft support holes 57 support the rotation of the lever 7 by that rotation support shafts 73 of the lever 7 (refer to
In the coupling cover portion 53 of the hood 5, there are formed guide ribs 58 corresponding to the rib guide grooves 37 formed in the male connector 3. As shown in
The lever 7 is subjected to rotating operation in order to cause the male connector 3 to be fitted into the female connector 2. The lever 7 is rotatably assembled on the hood 5, and causes a fitting force and a separation force (selectively) to be applied between the male connector 3 and the female connector 2 by the rotating operation of the lever 7. As shown in
The pair of arm plates 71 is rotatably supported at the pair of support wall portions 52 of the hood 5, and the rotation support shafts 73 are provided on the outer faces of the arm plates 71 so as to protrude, respectively. By inserting the rotation support shafts 73 into the rotation support shaft support holes 57 of the pair of support wall portions 52, the pair of arm plates 71 (that is, the lever 7) are rotatably supported at the pair of support wall portions 52.
In the pair of arm plates 71, there are further provided the lever temporary engagement holding portions 74 and the boss drawing-in grooves 80.
The lever temporary engagement holding portions 74 are engaged with the lever temporary engagement arms 55 formed on the support wall portions 52 of the hood 5, and the lever 7 is held at the initial rotation position by that the lever temporary engagement arms 55 are temporarily engaged. This will be described later according to
The boss drawing-in grooves 80 are cam-like grooves into which the lever drawing-in bosses 35 protruding from the outer face of the male connector (refer to
The lever inversion groove portion 82 has a drawing-in inlet 81, which opens such that the lever drawing-in boss 35 (refer to
The drawing-in groove portion 83 continues after the lever inversion groove portion 82 in the state of bending upward. By conducting rotating operation of the lever 7 in the fitting rotation direction, the lever drawing-in bosses 35 are drawn in the drawing-in groove portions 83. The drawing-in groove portions 83 thereby cause the male connector 3 to be fitted into the female connector 2 by guiding the lever drawing-in bosses 35. The rotating operation of the lever 7 in the fitting rotation direction is conducted after having rotated in the direction opposite to the fitting rotation direction by means of the lever inversion groove portions 82.
A lever inertial rotation portion 84 is formed in between the lever inversion groove portion 82 and the drawing-in groove portion 83. The lever inertial rotation portion 84 is the portion at which the lever 7 rotates in the fitting rotation direction by the inertial force of the lever itself, which is conducted after the lever 7 has rotated in the direction opposite to the fitting rotation direction, and the lever drawing-in bosses 35 are guided to the drawing-in groove portions 83. At such an occasion in which the lever drawing-in bosses 35 are positioned at the lever inertial rotation portions 84, the temporary engagement between the lever temporary engagement arms 55 of the hood 5 and the lever temporary engagement holding portions 74 of the lever 7 is in a state of being disengaged. Incidentally, the disengagement of the temporary engagement is conducted by inserting the male connector 3 into the hood 5.
Lever locks 75 are provided in the operating portion 72 of the lever 7 (refer to
Next, the action of fitting the male connector 3 to the female connector 2 will be described according to
Upon insertion of the male connector 3 into the hood 5, the lever drawing-in bosses 35 of the male connector 3 are drawn into the boss drawing-in grooves 80 of the lever 7 as shown in
By further continuing the insertion of the male connector 3, the lever drawing-in bosses 35 move to the ends of the lever inversion groove portions 82 as shown in
At this time, the lever drawing-in bosses 35 of the male connector 3 have reached the lever inertial rotation portions 84 in the boss drawing-in groove 80 (the position of reference numeral 35B in
In
In the structure as described above, since the lever 7 rotates in the direction opposite to the fitting rotation direction by inserting the male connector into the hood 5, idle rotations (lost rotations) of the lever 7 when the lever 7 is operated is reduced, and the lever drawing-in bosses 35 can be drawn into the boss drawing-in grooves 80 in an early stage. Accordingly, the force of inserting the male connector 3 into the hood 5 for fitting to the female connector 2 can be reduced and the operation force applied to the lever 7 can be also reduced.
Moreover, due to pressing of the male connector 3, the lever drawing-in bosses 35 and the lever inertial rotation portions 84 of the boss drawing-in grooves 80 come into contact with each other, and the lever 7 rotates in the fitting rotation direction due to an inertial force. Accordingly, the operation region for the lever 7 is increased and the operation ability of the lever 7 is improved.
In addition, in the beginning of insertion of the male connector 3, if the lever 7 is operated to rotate, it is possible to push out the male connector 3, because the lever drawing-in bosses 35 are not drawn into the boss drawing-in grooves 80. An abnormal event can thereby be visually confirmed.
The fitting guide portion 9 is provided for the fitting of the male connector 3 to the female connector 2 described above in the present embodiment (refer to
The pair of guide ribs 58 are formed in the inner wall of the coupling cover portion 53 of the hood 5 as shown in
Further, these guide ribs 58 and rib guide grooves 37 extend along the fitting direction of the male connector 3, and the hood guide ribs 58 are inserted into the rib guide grooves 37 at the occasion of fitting the male connector 3 into the female connector 2. Then, the male connector 3 moves in the fitting direction under the state in which the guide ribs 58 have been inserted into the rib guide grooves 37, and the guide ribs 58 slide relative to the rib guide grooves 37. The guide ribs 58 and the rib guide grooves 37 thereby guide the male connector 3 in the normal fitting direction with respect to the female connector 2.
The rib guide groove 37 is formed to have the cross-section of a dovetail groove as shown in
When the hood 5 is operated so as to rotate in the direction of arrow B shown in
In addition, since the guide ribs 58 of the hood 5 have been inserted into the rib guide grooves 37 of the male connector 3 and are engaged with each other, the state in which the hood 5 is supported by the male connector 3 develops, and the male connector 3 can be inserted smoothly into the hood 5 without causing the hood 5 to be opened when the lever 7 is operated.
Moreover, since the male connector 3 moves in the fitting direction under the state in which the guide ribs 58 have been inserted into the rib guide grooves 37, the hitting at the time of fitting can be prevented.
Incidentally, although the rib guide grooves 37 are formed in the male connector 3 and the guide ribs 58 are formed in the hood 5 in the present embodiment, the rib guide grooves 37 may be formed in the hood 5 and the guide ribs 58 may be formed in the male connector 3.
Next, the lever-falling prevention walls 54 are described. As described above, the lever-falling prevention walls 54 are formed in the collar-like plate portion 51 of the hood 5 so as to extend in the same direction as the pair of support wall portions 52 of the hood 5.
On the other hand, on the side of the coupling cover portion 53 of the hood 5, the lever-falling prevention walls 54 are formed stepwise in the top end portions of the support wall portions 52 extending from the collar-like plate portion 51 and further extend from the top end portions of the support wall portions 52 toward the wall portions 52 as shown in
As described above, the lever-falling prevention walls 54 are configured so as to support the arm plates 71 from the inner side thereof at plural places on the pair of arm plates 71 of the lever 7. The pair of arm plates 71 can be prevented from falling to the inner side by that the lever-falling prevention walls 54 support the pair of arm plates 71 from the inner side thereof as described above. Accordingly, the arm plates 71 do not fall to the inner side when the lever 7 is operated to rotate, and it is possible to insert the male connector 3 into the hood 5 with a small force. Moreover, since the state in which the pair of arm plates 71 are supported by the lever-falling prevention walls 54 develops and the male connector 3 moves in the fitting direction due to rotation of the lever 7 under this state, the hitting at the time of fitting can be prevented.
In
In
Since it is possible to prevent the reverse rotation of the lever 7 by providing the reverse rotation prevention portions 11 as described above, the lever 7 does not conflict and interfere with the male connector 3 when the male connector 3 is fitted through rotating operation of the lever 7, by which the workability of fitting the male connector 3 is improved.
The present invention has been described based on an embodiment, but the present invention is not limited to such an embodiment and the component of each unit can be replaced by a unit of any configuration having a similar function.
The entire content of Japanese Patent Application No. 2011-147440 (filing date: Jul. 1, 2011) is incorporated herein by reference.
Number | Date | Country | Kind |
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2011-147440 | Jul 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/066511 | 6/28/2012 | WO | 00 | 12/27/2013 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2013/005627 | 1/10/2013 | WO | A |
Number | Name | Date | Kind |
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5971779 | Okabe | Oct 1999 | A |
6065982 | Okabe | May 2000 | A |
6183277 | Okabe et al. | Feb 2001 | B1 |
6783388 | Matsushita | Aug 2004 | B2 |
Number | Date | Country |
---|---|---|
H10-214635 | Aug 1998 | JP |
H10-214653 | Aug 1998 | JP |
2000-091026 | Mar 2000 | JP |
2002-359037 | Dec 2002 | JP |
2003-324824 | Nov 2003 | JP |
2004-311190 | Nov 2004 | JP |
2006-344473 | Dec 2006 | JP |
2009-099469 | May 2009 | JP |
2010-097954 | Apr 2010 | JP |
Entry |
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A copy of Korean office action letter issued on Mar. 19, 2015 in the counterpart Korean patent application. |
A copy of Japanese office action letter issued on Feb. 3, 2015 in the counterpart Japanese patent application. |
Number | Date | Country | |
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20140113476 A1 | Apr 2014 | US |