The present invention relates to an openable/closable member locking device which, for example, locks an openable/closable lid with respect to a cavity portion in an instrument panel of a motor vehicle.
For example, a glove box is provided in an instrument panel of a motor vehicle, and a lid is mounted openably/closably to a cavity portion of this glove box. There is further provided a locking device which not only locks the lid in the closed state but also brings the lid into the opened state with respect to the cavity portion of the glove box.
For example, Patent Literature 1 describes a side locking device including a rotor, a pair of rods, a knob and a return spring. The rotor is pivoted rotatably on a back side of a lid. The rods are supported such that proximal end portions are in engagement point symmetrically with respect to an axis of the rotor, and such that distal end portions appear and disappear from both sides of the lid so as to be brought into engagement with and disengagement from a circumferential edge of the cavity portion. The knob is mounted on a front side of the lid, and causes the rotor to rotate by being pushed in or pulled out. The return spring normally rotationally urges the rotor in a direction in which the rods project from both the sides of the lid. When the knob is pushed in or pulled out, the rotor rotates against the return spring, and the rods draws into the lid. Each of the proximal end portions of the rods have a frame shape, and spherical engagement portions are provided on the rotor. The spherical engagement portions are brought into engagement with the corresponding frame-shaped proximal end portions, whereby the rods are connected to the rotor.
JP-2007-100343-A
In the side locking device of Patent Literature 1, the proximal end portions of the rods are in engagement point symmetrically with respect to the axis of the rotor. Thus, when the knob is operated and the rotor rotates, the proximal end portions of the rods move arcwise interlocking with the rotation of the rotor, and the rods slide while being inclined depending on the rotation angel of the rotor. As a result, the rods are brought into sliding contact strongly with guide holes provided in the lid or engagement holes provided in the circumferential edge of the cavity portion, thereby increasing the sliding resistance and/or generating abnormal noise.
An object of the invention is to provide an openable/closable member locking device which, when a rotor is rotated to cause sliding pins to slide, can prevent an increase in sliding resistance of the sliding pins to allow the sliding pins to slide smoothly while suppressing the generation of abnormal noise.
To attaining the object, the invention provides, a locking device for an openable/closable member to be mounted openably/closably to a cavity portion in a platform member, including:
a mounting base which is mounted on one of the platform member and the openable/closable member;
a pivot which projects from the mounting base;
a rotor which is mounted rotatably on the mounting base via the pivot;
a pair of arms which extend radially outwards from the rotor;
a pair of sliding pins which includes:
a return spring which rotationally urges the rotor in a direction in which the sliding pins are inserted into the engagement holes; and
a lock release unit which moves the rotor or the sliding pins against an urging force of the return spring so as to draw the sliding pins out of the engagement holes,
wherein the proximal end portions of the sliding pins are connected to the distal end portions of the arms so as to have no play in a lengthwise direction of the sliding pins but have a given play in a direction perpendicular to the lengthwise direction, and
wherein there is provided a guide portion which causes the sliding pins to slide straight along the lengthwise direction.
The invention may provide the locking device,
wherein the guide portion includes:
The invention may provide the locking device,
wherein the mounting base is mounted such that the pivot projecting surface thereof is faced towards the one of the platform member and the openable/closable member in a state in which the rotor and the sliding pins are held between the mounting base and the one of the platform member and the openable/closable member.
The invention may provide the locking device,
wherein a rotation restricting portion is provided on the mounting base and the rotor so as to restrict a rotational angle of the rotor in the urging direction of the return spring.
According to the invention, when the openable/closable member closes the cavity portion in the platform member, the sliding pins are pushed out by the urging force of the return spring so as to be inserted into the engagement holes, thereby locking the openable/closable member in the closed state.
When the lock release unit is manipulated, the rotor or the sliding pins are moved against the urging force of the return spring, and the sliding pins are drawn out of the engagement holes, thereby bringing the openable/closable member into the opened state.
The sliding pins are connected to the distal end portions of the arms of the rotor so as to have no play in the lengthwise direction of the sliding pins but have the given play in the direction perpendicular to the lengthwise direction. Therefore, when the rotor is rotated by the urging force of the return spring or by the lock release unit, even though the arms of the rotor move arcwise, the sliding pins are allowed to move straight in the lengthwise direction by the guide portion.
Thus, it is possible to prevent the increase in sliding resistance or the generation of abnormal noise which would otherwise be caused due to the inclination of the sliding pins which causes sliding contact with the engagement holes or other holes such as the guide holes.
Hereinafter, referring to
As shown in
As shown in
The mounting base 20 is formed into a rectangular plate with a partial cutout, and the pivot 21 integrally erects from a given position thereon. A distal end portion 21 a of the pivot 21 is narrowed diametrically relative to a proximal portion thereof via a step portion 21b, and projections 22 are provided on opposite positions of an outer circumferential surface of the distal end portion 21a. A pair of wall portions 23, 23 erect from an outer circumference of the pivot 21 of the mounting base 20 so as to face each other diametrically obliquely. One 62 of leg portions of the torsion coil spring 60 is locked on one of the wall portions 23, 23.
Guide walls 25, 26 erect from the mounting base 20 so as to face the arc-shaped wall portions 40, 40 on the outer circumferences of the arms 35 with spaces defined therebetween. These defined spaces allow the siding pins 51, 52 to be inserted therein. As shown in
The rotor 30, which is supported rotatably on the pivot 21, has a circular rotating portion 31. A shaft hole 32 is formed in the center of the circular rotating portion 31, and the arms 35, 35 extend radially outwards from opposite positions of an outer circumferential surface of the rotating portion 31. A pair of stopper projections 33, 33 project from opposite positions of an inner circumference of the shaft hole 32 along an axial direction of the shaft hole 32. As shown in
As shown in
The arms 35, 35 have base portions 36, 36 and distal end portions 37, 37. The base portions 36, 36 are suspended along the axial direction of the shaft hole 32 from opposite positions of the outer circumferential surface of the rotating portion 31 so as to define a space therebetween. The defined space is larger than outside diameter of the torsion coil spring 60. The distal end portions 37, 37 extend radially outwards from end portions of the corresponding base portions 36. Connecting members 38 for connection with the sliding pins 51, 52 are provided respectively at extending ends of the distal end portions 37. Distal end portions 38a of the connecting members 38 expand into a spherical shape.
As shown in
The arc-shaped wall portion 40 is formed on an outer circumference of the base portion 36 of each arm 35, and has an arc shape of a given radius about a center S2 (refer to
The sliding pins 51, 52, which are connected to the arms 35, 35 via the corresponding connecting members 38, are formed into an angular rod-like shape which extends generally straight. As shown in
A width W1 of the connecting recess portion 54 which is defined along the lengthwise direction of the sliding pin 51, 52 is set so as to match the outside diameter of the distal end portion 38a of the connecting member 38. A width W2 of the connecting recess portion 54 which is defined along the direction perpendicular to the lengthwise direction of the sliding pin 51, 52 is set so as to be slightly larger than the outside diameter of the distal end portion 38a (refer to
An axial distal region of the sliding pin 51 is bent correspondingly with the shape of the glove box main body 1, and has a rod-shaped lock release receiving portion 56 and a distal end portion 55. The lock release receiving portion 56 extends coaxially with an axial proximal region of the sliding pin 51, and the distal end portion 55 extends parallel to the lock release receiving portion 56 via a wall portion 57 (refer to
As shown in
The torsion coil spring 60 is placed over the pivot 21, and has a cylindrical coil portion 61 and the leg portions 62, 63. The coil portion 61 is disposed in an inner circumferential space defined by the arms 35, 35. The leg portion 62 extending from one end of the coil portion 61 is locked on the wall portion 23 of the mounting base 20, while the leg portion 63 extending from the other end of the coil portion 61 is locked on the outer circumference of the base portion 36 of the arm 35. The rotor 30 is rotationally urged in a given direction by this torsion coil spring 60 (refer to an arrow A in
The torsion coil spring 60 makes up a “return spring” of the invention. There is no specific limitation on the type of a return spring used, provided that a return spring used rotationally urges the rotor directly or indirectly in the directions in which the sliding pins are inserted into the corresponding engagement holes. For example, a coiled tensile spring may be used as a return spring. In this case, one end of the coiled tensile spring may be hooked on a pin provided on the mounting base 20, and the other end thereof may be hooked on the rotor 30 so as to rotationally urge the rotor 30 directly. Alternatively, the one end of the tensile spring may be hooked on the pin on the mounting base 20, and the other end thereof may be hooked on either of the sliding pins 51, 52 so as to rotationally urge the rotor 30 indirectly.
In this embodiment, as shown in
Next, the function and advantage of the above-described openable/closable member locking device will be described.
As shown in
As this occurs, although the rotor 30 is rotationally urged in the direction indicated by the arrow A in
As described above, the rotor 30 is mounted on the mounting base 20 via the pivot 21, and the respective proximal end portions 53 of the sliding pins 51, 52 are inserted between the respective arc-shaped wall portions 40, 40 of the arms 35 and the guide walls 25, 26 erected from the mounting base 20. Then, the respective connecting members 38 of the arms 35 are fitted into the corresponding connecting recess portions 54, whereby the respective proximal end portions 53 of the sliding pins 51, 52 are connected respectively to the corresponding distal end portions 37 of the arms 35. Thus, the sliding pins 51, 52 are disposed point symmetrically with respect to the shaft hole 32 in the rotor 30 (refer to
In that state, the mounting base 20 is disposed while orienting the pivot 21 projecting surface thereof towards the back side of the upper wall of the glove box main body 1, so as to hold the rotor 30 and the sliding pins 51, 52 between the mounting base 20 and the back side of the upper wall of the glove box main body 1, and the respective distal end portions 55 of the sliding pins 51, 52 are inserted into the corresponding through holes 3a in the glove box main body 1. The guide ribs 4 on the glove box main body 1 are respectively inserted into the elastic pieces 59a, 59a of the frame-shaped guides 59 of the sliding pins 51, 52 (refer to
In the locking device 10, in a state in which the sliding pins 51, 52 are connected to the arms 35, 35 extending from the rotor, the rotor 30 and the sliding pins 51, 52 are held between the mounting base 20 and the glove box main body 1. Thus, the dislocation of the sliding pins 51, 52 from the corresponding arms 35 can be prevented.
In this locking device 10, since the arms 35, 35 and the sliding pins 51, 52 can be fitted together as an assembly by connecting the proximal end portions 53 of the sliding pins 51, 52 to the distal end portions 37 of the arms 35, 35 in advance, the mountability of the locking device 10 on the platform member can be enhanced.
When the locking device 10 is mounted on the glove box main body (platform member) 1, the sliding pins 51, 52 are rotationally urged in the direction indicated by the arrow A in
When the lid 5 is pushed in so as to close the cavity portion 2 in the glove box main body 1, the projecting portions 6 of the lid 5 are inserted into the recess portions 3 in the glove box main body 1, whereby the tapered surface 55a of the respective distal end portions 55 of the sliding pins 51, 52 are pressed against by the projecting portions 6, and the respective distal end portions 55 thereof slide inwards against the urging force of the torsion coil spring 60. Then, when the distal end portions 55 reach the corresponding engagement holes 6a, the rotor 30 is rotationally urged by the urging force of the torsion coil spring 60, and the sliding pins 51, 52 slide outwards as the rotor 30 so that the distal end portions 55 are brought into engagement with the corresponding engagement holes 6a, 6a in the lid 5, whereby the lid 5 can be locked in a state in which the cavity portion 2 in the glove box main body 1 is closed by the lid 5 (refer to
In this locked state, when the push button 72 of the lock release unit is pushed in, the lock release rod 73 projects from the side surface of the case 71 to press the lock release receiving portion 56 of the sliding pin 51, whereby the sliding pin 51 slides inwards against the urging force of the torsion coil spring 60, and in synchronism with this, the rotor 30 rotates against the urging force applied thereto to thereby cause the sliding pin 52 to slide inwards. Thus, the respective distal end portions 55 of the sliding pins 51, 52 are dislocated from the corresponding engagement holes 6a in the lid 5, whereby the cavity portion 2 in the glove box main body 1 is opened.
As described above, when the sliding pins 51, 52 slide in connection with opening/closing of the lid 5, the arms 35, 35 move arcwise as the rotor 30 rotates. In the conventional construction, the proximal end portions 53 of the sliding pins 51, 52 also move arcwise, whereby the sliding pins 51, 52 are inclined.
However, in the invention, the respective proximal end portions 53 of the sliding pins 51, 52 are connected to the corresponding distal end portions 37 of the arms 35, 35 so as to have no play in the lengthwise direction of the sliding pins 51, 52 but have the given play in the direction perpendicular to the lengthwise direction (refer to
Even though the rotor 30 rotates, the arc-shaped wall portions 40 on the outer circumference of the arms 35 do not interfere with the sliding pins 51, 52 but can guide the sliding pins 51, 52 while maintaining the distance with the guide walls 25, 26 constant, whereby the sliding operation of the sliding pins 51, 52 can be performed more smoothly.
In this embodiment, the frame-shaped guides 59 are provided on axial intermediate regions of the sliding pins 51, 52, and the guide ribs 4 provided on the glove box main body 1 are elastically held by the elastic pieces 59a, 59a provided in the frame-shaped guides 59. Therefore, the sliding operation of the sliding pins 51, 52 is also guided by these elastic pieces 59a, 59a, whereby the sliding pins 51, 52 are allowed to slide straight in a more ensured fashion.
An openable/closable member locking device (locking device) 10a of this embodiment differs from the above-described embodiment in the construction of a guide portion which allows a pair guide pins 51, 52 to slide straight along a lengthwise direction thereof.
Namely, cylindrical guide projections 28 erect from a mounting base 20 of this locking device 10a so as to be aligned with portions of the sliding pins 51, 52 which lie slightly further distal towards than proximal end portions 53 thereof (refer to
As shown in
An openable/closable member locking device (locking device) 10b of this embodiment differs from the above-described embodiment in the construction of a guide portion which allow a pair guide pins 51, 52 to slide straight along a lengthwise direction thereof.
Namely, pairs of guide walls 29, 29 erect from a mounting base 20 of the locking device 10b at positions spaced a given distance away from distal end portions 37 of a pair of arms 35, 35. Each pair of guide walls 29, 29 define a space therebetween so as to allow the sliding pin 51, 52 to be inserted therein.
As shown in
In the above-described embodiments, the locking device is mounted on the glove box main body 1 as the platform member. However, the locking device can also be mounted on the lid 5 as the openable/closable member. There is imposed no specific limitation on the locking device mounting construction. In the constructions of the above-described embodiments, the lid 5 is mounted openably/closably to the cavity portion in the box-shaped glove box main body 1. However, the invention may be applied to a construction in which a box-shaped glove box is mounted openably/closably to a cavity portion in an instrument panel, or a construction in which a lid is mounted openably/closably to a cavity portion in an instrument panel (in this case, the instrument panel makes up the “platform member” of the invention, and the glove box or the lid makes up the “openable/closable member” of the invention). The invention can widely be applied to any platform member having a cavity portion. Although the push-button-type lock release unit in which the siding pin 51 is pushed in is adopted as the lock release unit, there is imposed no specific limitation on the type of the lock release unit. It is possible to use a lever-type unit which causes either of sliding pins 51, 52 to slide, a knob-rotating-type unit which directly causes a rotor 30 to rotate, or an knob-manipulating-type unit which causes a rotor 30 to rotate through pushing in or pulling out manipulation.
Number | Date | Country | Kind |
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2011-077872 | Mar 2011 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2012/052469 | 2/3/2012 | WO | 00 | 9/19/2013 |