1. Field of the Invention
The invention relates to a connector with a movable member, such as a lever.
2. Description of the Related Art
Japanese Unexamined Patent Publication No. 2001-326024 discloses a lever-type connector assembly with male and female housings that can be connected to one another. A lever is mounted rotatably on the female housing and is formed with cam grooves. Cam pins are formed on the male housing and can be received in the cam grooves of the lever. The cam pins move along cam grooves as the lever is rotated to pull the housings together. An operable portion of the lever is radially distanced from an axis of rotation. The operable portion is near a side of the female housing immediately before the two housings, are connected properly and is operated in a direction along a connecting direction of the female housing.
The side of the female housing that is near the operable portion of the lever immediately before the housings are connected properly is pushed along the connecting direction of the female housing as the lever is rotated. Thus, there are cases where a connected state of the side near the operable portion of the lever precedes the side of the housing opposite to the operable portion of the lever, resulting in an inclined posture.
The invention was developed in view of the above problem and an object thereof is to correct the posture of one housing in the process of connecting the two housings.
The invention relates to a connector with a housing and a movable member mounted movably on the housing. The movable member has a side plate and an operable portion on the side plate. The movable member has at least one cam engageable with at least one mating cam on a mating housing so that the mating cam can be guided along the cam as the movable member is operated to connect the housing with the mating housing. An engaging portion is formed on an end of the movable member substantially opposite the operable portion and is engageable with a locking projection on the mating housing immediately before the housing is connected properly with the mating housing. Thus, the engaging projection exerts a force on the locking projection along a connecting direction of the mating housing as the movable member is operated.
The side of the housing near the operable portion of the movable member may precede the side opposite to the operable portion of the operable member immediately before the housings are connected properly. However, the engaging portion at the side of the movable member opposite the operable portion exerts a force on the locking projection substantially along the connecting direction. Thus, the posture of the housing can be corrected so that the two housings can be connected in their substantially proper postures.
The movable member preferably is a lever mounted rotatably to the housing and the operable portion of the movable member is at a side of the housing radially distanced from an axis of rotation of the movable member.
The movable member preferably moves along a connecting direction of the housing immediately before the housings are connected properly.
The housing preferably is a harness-side housing to be connected with wires of a wiring harness, and the mating housing preferably is a waiting-side housing to be disposed on a fixed member.
At least one guiding wall preferably is formed near an end surface of the housing that is to be connected with the mating housing. The guiding wall is at a position substantially corresponding to the locking projection of the mating housing, and extends substantially in the connecting directions of the two housings. Thus, the guiding wall slides in contact with the locking projection during a connecting operation of the two housings, and the two housings can be connected and separated in substantially proper postures.
The movable member preferably is mountable to the housing in two substantially transversely symmetrical postures, and two locking projections are formed at two transversely symmetrical positions on the mating housing. Accordingly, operation efficiency is improved because the mounting posture of the movable member can be selected freely to avoid any restriction on an operating space of the movable member.
At least two supporting shafts are formed at substantially transversely symmetrical positions with respect to the housing. The movable member is mounted rotatably on one of the supporting shafts, and can be mounted in two substantially transversely symmetrical postures on the housing.
The operable portion of the movable member mounted on the first supporting shaft preferably is at a side of the first supporting shaft opposite to the second supporting shaft immediately before the housings are connected properly.
Two cam pins preferably are formed on the mating housing at positions corresponding to the cam groove of the movable member in the respective states where the movable member is mounted on the first supporting shaft. The cam pin that is not engaged with the cam groove functions as the locking projection. Thus, the construction of the mating housing can be simplified as compared to a case where the locking projection is separate.
The invention also relates to a connector assembly comprising the above-described connector and a mating connector with the mating housing. The locking projection is formed on the mating housing.
Two mating cams preferably are formed on the mating housing at positions corresponding to the cam of the movable member in the respective states of the movable member on one of the supporting shafts.
The mating cam that is not engaged with the cam preferably functions as the locking projection.
These and other objects, features and advantages of the present invention will become more apparent upon reading of the following detailed description of preferred embodiments and accompanying drawings. It should be understood that even though embodiments are separately described, single features thereof may be combined to additional embodiments.
A connector according to a first embodiment of the invention is described with reference to
The male housing 11 is made e.g. of a synthetic resin and is a waiting-side housing arranged on an unillustrated fixed member, as shown in
Mounting locks 16 are formed on the outer left and right side surfaces of the terminal accommodating portion 15 in
As shown in
The female housing 10 is made e.g. of a synthetic resin and has an outer tube 31 and an inner tube 32 within the outer tube 31. Cavities 17 are formed substantially side by side along a width direction in the inner tube 32 and extend in forward and backward directions FBD at plural stages, as shown in
The receptacle 13 of the male housing 11 is insertable into a clearance between the inner and out tubes 31 and 32. A tubular seal ring 35, made of resilient material such as rubber, is mounted on the outer peripheral surface of the inner tube 32 at a substantially middle part of the inner tube 32 with respect to forward and backward directions FBD. Sealing is provided between the female and male housings 10 and 11 by the close resilient contact between lips 36 formed around the outer peripheral surface of the seal ring 35 and the inner peripheral surface of the receptacle 13 of the male housing 11.
A lever accommodating space 37 is formed at an upper side of the outer tube 31 for accommodating the lever 12. A substantially cylindrical supporting shaft 38 extends down from the ceiling wall of the lever accommodating space 37. The lever accommodating space 37 is substantially transversely symmetrical with respect to the axis of symmetry 39 passing the center axis of the supporting shaft 38. As shown in
As shown in
A shaft hole or recess 44 is formed to vertically penetrate the center of the side plate 42, and the aforementioned supporting shaft 38 is or can be at least partly inserted into this shaft hole 44. The cam groove 26 oblique to both circumferential direction and radial directions (or having a spiral-like shape) substantially centered on the shaft hole 44 is formed before the shaft hole 44 in the side plate 42. The cam-pin receiving portion 64 for receiving the larger-diameter portion 27 of the cam pin 25 is formed at the upper edge of the cam groove 26 over the entire length of the cam groove 26. The locking piece 41 for holding or positioning the lever 12 at the standby position SP is formed at a position of the side plate 42 at the lateral (right) side of the shaft hole 44. The locking piece 41 preferably is substantially in the form of a plate narrow and long in forward and backward directions FBD, and has the front end thereof supported on the side plate 42 while projecting backward. This resilient locking piece 41 is resiliently deformable upward and downward or inwardly and outwardly or towards and away from the housing 10 with the base end (front end) as a supporting point. The rear end of the locking piece 41 is engaged with the aforementioned receiving portion 29 when the lever 12 is at the standby position SP. Further, when the lever 12 is at the standby position SP (first position), the entrance of the cam groove 26 preferably is located substantially on the axis of symmetry 39 passing the supporting shaft 38 of the lever 12.
A resilient lock piece 45 is formed at the left rear of the side plate 42 and is a long narrow plate that extends substantially in forward and backward directions FBD. This resilient lock piece 45 is cantilevered back from its front end, and is resiliently deformable up and down towards and away from the housing 10. Outwardly projecting locks 46 are formed in the vicinity of a substantial center of the resilient lock piece 45 with respect to forward and backward directions FBD. Two return preventing portions 47 are formed at transversely symmetrical positions in the lever accommodating space 37. The lock projection 46 of the resilient lock piece 45 engages the lock projections 46 to hold the lever 12 at the connected position CP.
Holding steps 48 extend into both upper and lower surfaces of the side plate 42 near the resilient lock piece 45. The holding steps 48 engage the return preventing portion 47 to hold the lever 12 is at the standby position SP.
As shown in
As shown in
An engaging portion 53 projects out from the lateral edge of the side plate 42 at an end (right end in
The locking piece 41 engages the right receiving portion 29 and the holding step 48 engages the left return preventing portion 47 when the housings 10, 11 are in the state shown in
The two housings 10, 11 are moved to the state shown in
The lever 12 then is rotated to the state shown in
The two housings 10, 11 are connected properly when the lever 12 is rotated to the connected position CP shown in
The lever 12 is held substantially in the orientation of the standby position SP and is inserted into the lever accommodating space 37 from behind. The ceiling wall of the lever accommodating space 37 deforms during this process so that the lever 12 can be mounted into the female housing 10. At this time, the left return preventing portion 47 in
The supporting shaft 38 moves onto the slanted surface 30 at the rear edge of the supporting shaft escaping groove 49 as the lever 12 is inserted farther to the back of the lever accommodating space 37 and then fits into the shaft hole 44. At this time, the left return preventing portion 47 in
The receptacle 13 of the male housing 11 can be fit lightly into the female housing 10 in this state. As a result, the cam pin 25 enters the entrance of the cam groove 26, as shown in
The operable portion 43 can be pushed to rotate the lever 12 counterclockwise about the supporting shaft 38 and to the position shown in
The operable portion 43 of the lever 12 is at the left rear side of the female housing 10, as shown in
The engaging portion 53 engages the right locking projection 52, as shown in
The resilient lock piece 45 can be pushed up by finger, jig or the like and deformed resiliently to separate the two locked housings 10, 11. As a result, the lock projection 46 disengages from the left return preventing portion 47 and permits the lever 12 to be rotated from the connected position CP towards the standby position SP. The lever 12 is rotated in the clockwise direction of
The lever 12 is mounted in the female housing 10 for movement in an operation direction OD from the standby position SP towards the connected position CP. Additionally, the operable portion 43 is at the left end of the female housing 10 when the lever 12 is at the connected position CP. Thus, the lever 12 also can be mounted in the female housing 10 in a posture transversely reversed from the posture described above. More particularly, the lever 12 has a substantially vertically symmetrical shape. The entrance of the cam groove 26 is substantially on the axis of symmetry 39 passing the supporting shaft 38 of the lever 12 when the lever 12 is at the standby position SP. The return preventing portions 47 are arranged at two substantially transversely symmetrical positions with respect to the axis of symmetry 39. Furthermore, the locking projections 52 are arranged at two substantially transversely symmetrical positions with respect to the axis of symmetry 39. The escaping holes 54 are at two substantially transversely symmetrical positions with respect to the axis of symmetry 39 and the guiding ribs 28 are at two substantially transversely symmetrical positions with respect to the axis of symmetry 39; and/or the receiving portions 29 project inward substantially transversely symmetrically with respect to the axis of symmetry 39.
The lever 12 can be mounted in a posture transversely reversed from the posture described above. Thus, the lever 12 is mounted in the female housing 10 for clockwise rotation and in an opposite operating direction OOD to the operating direction described above from the standby position SP to the connected position CP. Accordingly, the operable portion 43 is at the opposite or right end when the lever 12 is at the connected position CP. The procedure of connecting the two housings 10, 11 by rotating the lever 12 from the standby position SP to the connected position CP is transversely symmetrical with the procedure described above, and hence the functions are not described.
As described above, the lateral side of the female housing 10 near the operable portion 43 of the lever 12 may precede the lateral side opposite to the operable portion 43 of the lever 12 immediately before the two housings 10, 11 are connected properly. However, the engaging portion 53 at the side of the lever 12 opposite the operable portion 43 engages the locking projection 52 and exerts a force along the connecting direction CD of the male housing 11. Therefore, the posture of the female housing 10 is corrected, and the housings 10, 11 can be connected in their substantially proper postures.
Further, the locking projections 52 of the female housing 10 slide in contact with the guiding walls 55 in the male housing 11 to guide the connecting and separating operations of the two housings 10, 11. Thus, the two housings 10, 11 can be connected, in their substantially proper postures.
Furthermore, the lever 12 can be mounted into the female housing 10 in either of two postures transversely symmetrical with respect to the axis of symmetry 39. Thus, the rotating efficiency of the lever 12 can be improved by selecting the mounted posture of the lever 12 depending on a situation where the connector is arranged.
A second embodiment of the invention is described with reference to
The second housing 57 projects out from a wall of a fixed member 63 and is a waiting-side housing. Two substantially cylindrical cam pins 25 are formed on an outer surface of the upper wall of the second housing 57 near the front end. The cam pins 25 are at positions substantially transversely symmetrical with respect to an axis of symmetry 39 passing the widthwise or transverse center of the second housing 57 and substantially in parallel with connecting directions of the two housings 56, 57. A large-diameter portion 27 is formed at the distal end of each cam pin 25.
The first housing 56 is to be connected with wires 19 of a wiring harness and hence is a harness-side housing. Two substantially cylindrical supporting shafts 38 are formed at positions of the outer surface of the upper wall of the first housing 56 near the rear end. The supporting shafts 38 are at positions substantially transversely symmetrical with respect to the axis of symmetry 39 passing the widthwise or transverse center of the first housing 56 and are substantially parallel with the connecting directions of the housings 56, 57. Two protrusions 58 project laterally to the left and right from the distal end of each supporting shaft 38.
A substantially rectangular notch 40 is formed near the transverse center of a front side of the upper wall of the first housing 56. The notch 40 extends back from the front edge and is substantially transversely symmetrical with respect to the axis of symmetry 39. Left and right plate-like pressing portions 59 are provided at the opposite left and right sides of the notch 40. Both pressing portions 59 are substantially rectangular and are narrow and long along the transverse direction. The pressing portions 59 are substantially parallel with the upper wall of the first housing 56. A notch is formed at a rear-left corner of the right pressing portion 59 to prevent the interference with the lever 12, and an eave 60 is formed for pressing a bulge 62 of the lever 12 from above, as described later. Similarly, a notch is formed at a rear-right corner of the left pressing portion 59 to prevent the interference with the lever 12, and another eave 60 is formed for pressing the bulge 62 of the lever 12 from above.
As shown in
A shaft hole 44 vertically penetrates the center of the side plate 42, and has a shape conforming to the shape of the supporting shafts 38. Thus, one of the supporting shafts 38 may be inserted into the shaft hole 44. A round hole (not shown) is formed outside the: shaft hole 44 to let the protrusions 58 of the supporting shaft 38 escape when the lever 12 is rotated. A cam groove 26 is formed in the side plate 42 near the shaft hole 44 and extends oblique to both circumferential and radial directions substantially centered on the shaft hole 44. A cam-pin receiving portion 64 for receiving the large-diameter portion 27 of the cam pin 25 is formed at the upper edge of the cam groove 26 over substantially the entire length of the cam groove 26. A locking piece 41 is formed in the side plate 42 at the left side of the shaft hole 44 and holds the lever 12 at the standby position SP. The locking piece 41 is a plate that is long and narrow in forward and backward directions FBD and is cantilevered rearwardly. The locking piece 41 is resiliently deformable up and down towards and away from the housing 10 with the front end as a support. The rear end of the locking piece 41 is engaged with the rear edge of the notch 40 when the lever 12 is at the standby position SP. An arcuate bulge 62 bulges radially out at the front edge of the side plate 42 and is substantially concentric with the side plate 42. The upper surface of the bulge 62 is lowered with respect to the upper surface of the side plate 42 to form a step.
A substantially hook-shaped engaging portion 53 is formed at the left side of the entrance of the cam groove 26 of the side plate 42 and projects radially out from the lateral edge of the side plate 42. The rear edge of the engaging portion 53 is engageable with the left cam pin 25 of
The lever 12 is aligned so that the shaft hole 44 can receive the protrusions 58 of the supporting shaft 38 and then the supporting shaft 38 is inserted into the shaft hole 44. The lever 12 then is rotated to the standby position SP (see
In this state, the second housing 57 is fit lightly into the first housing 56 so that the right cam pin 25 in
The operable portion 43 is pushed in this state to rotate the lever 12 clockwise in the operating direction OD about the right supporting shaft 38. Thus, the right cam pin 25 is guided substantially along the cam groove 26, and the two housings 56, 57 are pulled towards each other along the connecting directions CD thereof. As the connecting operation progresses farther, the engaging portion 53 engages the left cam pin 25, as shown in
In the above description, the lever 12 is mounted in the first housing 56 so that the lever 12 is on the right supporting shaft 38 in
The lever 12 can be mounted in the posture transversely reversed from the posture described above. Thus, the lever 12 is rotated counterclockwise and opposite to the above-described operating direction OD from the standby position towards the connected position. Additionally, the operable portion 43 is at the opposite left end when the lever 12 is at the connected position. A procedure of connecting the two housings 56, 57 by rotating the lever 12 from the standby position to the connected position after the lever 12 is mounted into the first housing 56 is transversely symmetrical with the above-described procedure, the functions are not described.
The lever 12 engages the cam pin 25 not engaged with the cam groove 26 when the lever 12 is at the connected position CP. Thus, the construction of the second housing 57 is simpler as compared to a case where the locking projections 52 are provided separately.
The invention is not limited to the above described and illustrated embodiments. For example, the following embodiments are also embraced by the technical scope of the present invention as defined by the claims. Beside the following embodiments, various changes can be made without departing from the scope and spirit of the present invention as defined by the claims.
The lever 12 is plate-like in the first embodiment. However, the lever 12 may be substantially U-shaped by connecting ends of a pair of side plates 42 by an operable portion 43 or may be L- or V-shaped. In such a case, the posture of the female housing 10 can be corrected at both the upper side and the lower sides. Thus, the postures of the two housings 10, 11 being connected can be stabilized better.
The lever 12 is mountable in two transversely reversed postures with respect to the axis of symmetry 39 in the first embodiment. However, the lever 12 can be mountable only in one transverse posture. In some cases, only one locking projection 52 is formed.
The escaping holes 54 and the guiding walls 55 for letting the locking projections 52 escape and guiding the locking projections 52 are formed in the end of the female housing 10 that is connected with the male housing 11 in the first embodiment. However, material of the female housing 10 may be removed at positions corresponding to the locking projections 52 to let the locking grooves 52 escape.
The first housing is the female housing 10 and the second housing is the male housing 11 in the first embodiment. However, the first housing may be the male housing 11 and the second housing may be the female housing 10.
The male housing 11 is fixed to the fixed member by means of the mounting lock portions 16 in the first embodiment. However, the male housing 11 may project from a wall surface of the fixed member.
The operable member was described as a lever rotatably provided on the first housing. However, the invention is equally applicable to movable members having different operation paths, such as a slider with a substantially linear displacement path or to any other movable member having different moving paths, such as bent, elliptic or the like paths or combined paths.
Number | Date | Country | Kind |
---|---|---|---|
2005-175262 | Jun 2005 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
6551118 | Langolf et al. | Apr 2003 | B2 |
6623286 | Tachi | Sep 2003 | B2 |
6733313 | Shinozaki et al. | May 2004 | B2 |
6755674 | Fujii et al. | Jun 2004 | B2 |
20020004326 | Mochizuki | Jan 2002 | A1 |
20020019156 | Fukamachi et al. | Feb 2002 | A1 |
20030162427 | Shinozaki et al. | Aug 2003 | A1 |
20030199185 | Fujii et al. | Oct 2003 | A1 |
Number | Date | Country |
---|---|---|
2 322 242 | Aug 1998 | GB |
2001-326024 | Nov 2001 | JP |
Number | Date | Country | |
---|---|---|---|
20060286834 A1 | Dec 2006 | US |