1. Field of the Invention
The present invention relates to a door lock system for a vehicle.
2. Description of the Related Art
When a door-opening operation is performed on a door lock system in a locked position using an outside handle of a vehicle while an unlocking operation is simultaneously performed using an inside lock knob of the vehicle, the door-opening and the unlocking operations interfere each other. This may bring a state (hereinafter, “panic state”) in which neither the door-opening operation nor the unlocking operation is attained. For example, Japanese Patent Application Laid-open No. 2005-282221 discloses a conventional door lock system provided with anti-panic mechanism for avoiding such a panic state.
The conventional door lock system includes a ratchet lever, an opening lever, a sector gear, a link lever, an anti-panic lever, and a spring. The ratchet lever is interconnected with a ratchet and disengages the ratchet from a latch. The opening lever is rotatable in response to a door-opening operation performed on an outside handle. The sector gear, which is rotatably supported by a gear shaft, moves from a locked position to an unlocked position in response to an unlocking operation, and moves from the unlocked position to the locked position in response to a locking operation. The link lever, which is rotatably supported on an end of the opening lever, moves from a transmitting position, at which the ratchet lever is allowed to disengage the ratchet from the latch, and a non-transmitting position, at which the ratchet lever is not allowed to disengage the ratchet from the latch. One end of the anti-panic lever is rotatably supported by the gear shaft and the other end is coupled to the link lever. As the sector gear moves, the anti-panic lever causes the link lever to move to and from the transmitting position and the non-transmitting position. One end of the spring is engaged with the sector gear, and the other end of the spring is engaged with the anti-panic lever. Hence, the spring nests between the anti-panic lever and the sector gear and urges the anti-panic lever toward the sector gear.
In the conventional door lock system, when the outside handle is operated to open the door, the opening lever is moved from a non-operable position to an operable position, causing the link lever to move upward into contact with an abutting portion of the ratchet lever. This in turn moves the ratchet lever upward, and disengages the ratchet from the latch. Thus, the door can be opened with respect to a vehicle body.
When a locking operation is performed through a drive motor or the inside lock knob on the door in a closed position, the sector gear is moved from the unlocked position to the locked position, thereby pushing the anti-panic lever. Hence, the anti-panic lever is moved integrally with the sector gear, which in turn moves the link lever from a transmittable position to a non-transmittable position. Thus, the door lock system is locked.
When, in the locked state, the inside lock knob is operated in a direction to unlock the door, the sector gear is moved from the locked position to the unlocked position. This movement causes the anti-panic lever to be moved following the sector gear by a resilient force of the spring, and hence moves the link lever from the non-transmittable position to the transmittable position. Thus, the door lock system is unlocked.
When, in the locked state, the outside handle is operated to open the door while the inside lock knob is operated in the direction to unlock the door, the sector gear is moved from the locked position to the unlocked position, and the link lever comes into contact with a side face of the ratchet lever and stays at the non-transmittable position. When thereafter the outside handle is released to move the link lever downward, the resilient force of the spring moves the link lever to the transmittable position. Thus, the door lock system is unlocked. When the outside handle is operated to open the door again in this state, the door can be opened.
In the conventional door lock system having the anti-panic mechanism, the anti-panic lever is coupled between the sector gear and the link lever with the spring interposed between the sector gear and the anti-panic lever. Accordingly, the number of components is increased and the structure is complicated, which poses a problem of an increase in the man-hours required for assembly and in the manufacturing cost.
It is an object of the present invention to at least partially solve the problems in the conventional technology.
According to an aspect of the present invention, a door lock system includes a latch, a ratchet that engages with the latch, a ratchet lever that is interlocked with the ratchet and disengages the ratchet from the latch, an opening lever, a first link lever, a second link lever, and a spring. The opening lever moves from a non-operable position to an operable position in response a door-opening operation. The first link lever moves to a first position, in response to an unlocking operation, to allow the ratchet lever to disengage the ratchet from the latch, and moves to a second position, in response to a locking operation, to prevent the ratchet lever from disengaging the ratchet from the latch. The second link lever includes a cylindrical bushing that is connected to an end of the opening lever, and a ratchet driver that is formed integrally with the bushing and extends radially outward from the bushing. The ratchet driver is rotatable between a first rotational position and a second rotational position with respect to the first link lever. The ratchet driver allows, when in the first rotational position, the ratchet lever to disengage the ratchet from the latch in response to the door-opening operation that is performed on the opening lever while the first link lever is in the first position. The spring is interposed between the first link lever and the second link lever, and maintains the second link lever in the first rotational position with respect to the first link lever by a resilient force thereof when the first link lever moves from the second position to the first position.
The above and other objects, features, advantages and technical and industrial significance of this invention will be better understood by reading the following detailed description of presently preferred embodiments of the invention, when considered in connection with the accompanying drawings.
Exemplary embodiments of the present invention are explained in detail below with reference to the accompanying drawings.
The housing 10 formed with the main casing 2 and sub casing 3 includes a latch-mechanism accommodating unit 11 and a lock-mechanism accommodating unit 12. The latch-mechanism accommodating unit 11 extends in a direction traversing the door D to and from the interior and the exterior of the vehicle (hereinafter, “widthwise direction”). The lock-mechanism accommodating unit 12 extends along the door D from an interior-side end of the latch-mechanism accommodating unit 11 in the front-and-rear direction (hereinafter, “longitudinal direction”) and is essentially L-shaped in its top view. As shown in
The latch-mechanism accommodating unit 11 has, at its substantially heightwise midpoint, a horizontal notched groove 13 that extends essentially horizontally from the interior side to the exterior side of the vehicle, and accommodates the latch mechanism 20 therein.
As in the conventional technology, the latch mechanism 20 is used for retaining a striker S on the vehicle body by latching, and includes a latch 21 and a ratchet 22 as shown in
The latch 21 is disposed at a position above the horizontal notched groove 13 of the latch-mechanism accommodating unit 11 to be rotatable about a latch shaft 23 that extends essentially horizontally in the longitudinal direction of the vehicle body. The latch 21 has an engaging groove 21a, a hook portion 21b, and a stopper portion 21c.
The engaging groove 21a is formed by grooving the latch 21 from its outer periphery radially inward toward the latch shaft 23. The engaging groove 21a has a width large enough to accommodate the striker S therein.
When the latch 21 is oriented such that the engaging groove 21a is open downward, the hook portion 21b of the latch 21 assumes a position closer to the interior of the vehicle than the engaging groove 21a. The hook portion 21b is formed such that, as shown in
When the latch 21 is oriented such that the engaging groove 21a is open downward, the stopper portion 21c of the latch 21 assumes a position closer to the exterior of the vehicle than the engaging groove 21a. The stopper portion 21c is formed such that, as shown in
The ratchet 22 is disposed at a position, which is below the horizontal notched groove 13 of the latch-mechanism accommodating unit 11 and closer to the interior of the vehicle than the latch shaft 23, to be rotatable about a ratchet shaft 24 that extends essentially horizontally in the longitudinal direction of the vehicle body. The ratchet 22 includes an engaging portion 22a and an actuating arm 22b.
The engaging portion 22a of the ratchet 22 extends radially outward with respect to the ratchet shaft 24 toward the exterior of the vehicle. When the ratchet 22 is rotated counterclockwise in
As shown in
A switch 27 for detecting a position of the latch 21 is disposed above the latch 21 in the latch mechanism 20. The switch 27 includes an armature that is in sliding contact with an outer periphery of the latch 21, and detects that the latch 21 is at the fully-latched position when the switch 27 is away from the outer periphery of the latch 21. When the latch 21 is out of the fully-latched position (e.g., at the open position or the half-latched position), the switch 27 turns on a courtesy lamp (not shown) or the like.
In the latch mechanism 20, when the door D is open with respect to the vehicle body, as shown in
The further the side door D is closed from this state, the further the striker S advances into the accommodating groove 6, causing the latch 21 to further rotate counterclockwise as shown in
When the door D is further closed from the half-latched position, as shown in
When, with the door D being fully latched, the actuating arm 22b of the ratchet 22 or the abutting portion 25a of the ratchet lever 25 is rotated clockwise in
As shown in
As shown in
The opening-actuating arm 30a of the opening lever 30 extends radially outward from the opening lever shaft 31 toward the exterior of the vehicle, and has an extended end that projects out of the housing 10. The opening-actuating arm 30a is connected via the projecting end to an outside handle link 32, such as a link, that is connected to the outside handle 1 on the door D. More specifically, the outside handle link 32 is connected to the outside handle link 32 such that when the outside handle 1 is operated to open the door, the opening lever 30 is rotated counterclockwise in
As shown in
The pressure-receiving portion 30c is a portion of the opening lever 30 positioned to be lower than the opening-action arm 30b and forwardly bent from a lower edge of the opening lever 30. An opening lever spring 33 that constantly urges the opening lever 30 clockwise in
The spring 40 is housed in the second link lever 60, described later.
As shown in
The attachment hole 50a in the first link lever 50 has a diameter greater than that of a bushing 61 of the second link lever 60, described later. The attachment hole 50a receives the opening-action arm 30b to pass through the attachment hole 50a with the bushing 61 of the second link lever 60 interposed therebetween.
The opening 50b is formed in the first link lever 50 at a portion higher than the attachment hole 50a, and has side walls 50f and 50g. The opening 50b is formed such that a projection 64a on a first-link-lever abutting portion 64 on the second link lever 60, described later, is inserted into the opening 50b to allow the projection 64a to move within the opening 50b.
The spring engaging portion 50c projects out of a side face of the first link lever 50 at a portion near the attachment hole 50a of the first link lever 50. The spring engaging portion 50c is used for engagement with a tip end of the leg portion 42 of the spring 40.
The locking-lever coupling portion 50d is positioned at a portion of the first link lever 50 higher than the opening 50b and extends upward with respect to the axis of the attachment hole 50a. A vertically-elongated coupling slot 50e is formed in the locking-lever coupling portion 50d. A locking lever 650, described later, is coupled to the coupling portion 50d. Hence as the locking lever 650 is moved, the first link lever 50 is moved between the transmitting position, at which a door-opening operation is transmitted to the ratchet, and the non-transmitting position, at which the door-opening operation is not transmitted to the ratchet.
As shown in
The bushing 61 of the second link lever 60 includes a cylindrical portion 61a and wall portions 61b and 61c. A hole through which the opening-action arm 30b of the opening lever 30 passes is formed in the cylindrical portion 61a. Although not clearly shown in the drawings, the widthwise length of the cylindrical portion 61a on the side extending toward the exterior of the vehicle is greater than that of the spring receptacle 62. This geometry allows the second link lever 60 to be rotatably supported via the cylindrical portion 61a by the first link lever 50 about its axis and inserted into the opening-action arm 30b. Each of the wall portions 61b and 61c is formed inside the hole in the cylindrical portion 61a and inclined to have a diameter that gradually increases radially outward. The wall portions 61b and 61c limit rotation ranges of the first link lever 50 and the second link lever 60 in relation to the opening-action arm 30b.
The spring receptacle 62 of the second link lever 60 is used for housing the spring 40 therein, and has a cylindrical shape to house the bushing 61 therein. The spring receptacle 62 includes a recess 62a, a groove 62b, and an engaging projection 62c between an inner wall of the spring receptacle 62 and the cylindrical portion 61a of the bushing 61. The ring portion 41 of the spring 40 is housed in the recess 62a. The leg portion 42 of the spring 40 is disposed in the groove 62b, and the tip end of the leg portion 42 is engaged with the spring engaging portion 50c of the first link lever 50. The leg portion 43 of the spring 40 is engaged with the engaging projection 62c.
The ratchet driver 63 of the second link lever 60 extends radially outward with respect to the axis of the bushing 61 toward the abutting portion 25a of the ratchet lever 25. The ratchet driver 63 is formed so that the ratchet lever 25 can press against the abutting portion 25a when the second link lever 60 is moved upward by the door-opening operation.
The first-link-lever abutting portion 64 of the second link lever 60 extends upward from the axis of the bushing 61 and nests adjacent to the ratchet driver 63. The projection 64a that projects toward the exterior of the vehicle is formed on a tip end of the first-link-lever abutting portion 64.
As shown in
The inner actuating arm 70a extends upward from the inner lever shaft 71, and has an extended end that projects out of the housing 10. Of the inner actuating arm 70a, the end portion projecting out of the housing 10 is connected to an inside handle link 72, such as a link or wire, that connects between the inner actuating arm 70a and the inside handle 5 on the interior side of the door D. More specifically, the inside handle link 72 is connected to the inner actuating arm 70a such that when the inside handle 5 is operated to open the door, the inner handle lever 70 is pivoted counterclockwise in
A single-motion lever coupling hole 70c is formed in a portion halfway of the inner actuating arm 70a in its elongated direction. A single-motion lever 73 is engaged with the single-motion lever coupling hole 70c. The single-motion lever 73 extends toward the front of the vehicle from the inner actuating arm 70a to assume an arc shape concentric with the inner lever shaft 71. The single-motion lever 73 has a shaft portion 73a and an abutting portion 73b on its base end. The shaft portion 73a is rotatably attached to the inner actuating arm 70a at the single-motion lever coupling hole 70c. The abutting portion 73b is to be brought into contact with a side face of the inner actuating arm 70a. A single-motion spring 74 that urges the abutting portion 73b of the single-motion lever 73 into contact with the side face of the inner actuating arm 70a is interposed between the single-motion lever 73 and the inner actuating arm 70a.
The action arm 70b of the inner handle lever 70 extends from the inner lever shaft 71 in a downwardly inclined manner toward the rear of the vehicle. A single-motion link 76 is attached through a rivet 75 to the action arm 70b to be movable upward. A portion of the action arm 70b is bent toward the exterior of the vehicle as a pressing portion 70d. When the inner handle lever 70 is pivoted counterclockwise in
When the inner handle lever 70 is pivoted counterclockwise in
A coupling slot (not shown) elongated in the longitudinal direction is formed in the base end of the single-motion link 76. The rivet 75 is engaged with the coupling slot with play left for allowing sliding. As shown by alternate long and two short dashes lines in
The lock mechanism 600 is switched between an unlocked state, under which rotation of the opening lever 30 resulting from the door-opening operation performed using the outside handle 1 is transmitted to the latch mechanism 20, and a locked state, under which rotation of the opening lever 30 resulting from the door-opening operation performed using the outside handle 1 is not transmitted to the latch mechanism 20. As shown in
The key lever 610 is rotatably disposed at a position below the housing 10. As shown in
The input shaft portion 611 of the key lever 610 receives an input of a rotary driving force applied when the key cylinder KC in the door D is turned using a key. The input shaft portion 611 is connected to a key cylinder link 615 (see
The rotation support recess 612 of the key lever 610 is formed in the input shaft portion 611. The rotation support recess 612 receives a projection 302 formed on the sub casing 3 in a fitting manner, thereby rotatably supporting the key lever 610.
The lever portion 613 of the key lever 610 extends radially outward with respect to the input shaft portion 611. A key-link coupling hole 614 is formed in an extended end of the lever portion 613.
As shown in
The projection 201 on the main casing 2 extending into the housing 10 (the interior side of the vehicle body) is inserted through the rotation support hole 621 in the key sub lever 620. Hence, the rotation support hole 621 receives the key sub lever 620 rotatably about the projection 201 in
The key-link coupling unit 622 of the key sub lever 620 extends radially outward with respect to the axis of the rotation support hole 621 (the projection 201). A key-link coupling hole 622a (see
Each of the locking switch lug 623 and the unlocking switch lug 624 on the key sub lever 620 extends radially outward with respect to the axis of the rotation support hole 621. The locking switch lug 623 switches the lock mechanism 600 from the unlocked state to the locked state in response to rotation of the key sub lever 620. On the other hand, the unlocking switch lug 624 switches the lock mechanism 600 from the locked state to the unlocked state in response to rotation of the key sub lever 620.
Each of the locking-operation detecting lug 625 and the unlocking-operation detecting lug 626 on the key sub lever 620 extends radially outward with respect to the axis of the rotation support hole 621. When the key sub lever 620 is moved from the unlocked position to the locked position, the locking-operation detecting lug 625 toggles a detecting piece 628a of a switch 628 counterclockwise. On the other hand, when the key sub lever 620 is moved from the locked position to the unlocked position, the unlocking-operation detecting lug 626 toggles the detecting piece 628a of the switch 628 clockwise. Thus, the locking-operation detecting lug 625 and the unlocking-operation detecting lug 626 actuate the detecting piece 628a of the switch 628 for discrimination among operations performed using the key via the key cylinder KC, i.e., discrimination between the locking operation and the unlocking operation.
As shown in
The switching lug 631 is used for moving the connecting lever 630 from an unlocked position to a locked position, and vise versa. The switching lug 631 is formed on the face of the connecting lever 630 facing the key sub lever 620. More specifically, the switching lug 631 can be brought into contact with the locking switch lug 623 and the unlocking switch lug 624 on the key sub lever 620. When the switching lug 631 comes into contact with the locking switch lug 623 to thus be pressed by the same, the connecting lever 630 is moved from the unlocked position to the locked position. On the other hand, when the switching lug 631 comes into contact with the unlocking switch lug 624 to thus be pressed by the same, the connecting lever 630 is moved from the locked position to the unlocked position.
The locking-lever coupling portion 632 of the connecting lever 630 extends radially outward with respect to a rotation center of the connecting lever 630. The locking-lever coupling portion 632 includes, at its extended end, a coupling projection 636. The coupling projection 636 extends from an exterior-side face of the tip end of the locking-lever coupling portion 632 essentially horizontally in the widthwise direction of the vehicle body.
The switching lever 633 is used for detecting a position of the connecting lever 630. The switching lever 633 toggles off a switch 637 when the connecting lever 630 is in the unlocked position (see
The single-motion lug 634 comes into contact with single-motion lever 73 to thereby switch the lock mechanism 600 in the locked state to the unlocked state. The single-motion lug 634 extends radially from the rotation center of the connecting lever 630 such that when the lock mechanism 600 is in the locked state, the single-motion lug 634 is at a position where the single-motion lug 634 can be brought into contact with the single-motion lever 73, whereas when the lock mechanism 600 is in the locked state, the single-motion lug 634 is at a position where the lug 634 cannot be brought into contact with the single-motion lever 73.
The rotary shaft portion 635 of the connecting lever 630 supports the connecting lever 630 rotatably with respect to the sub casing 3. The rotary shaft portion 635 extends from the connecting lever 630 integrally therewith, and has an end that projects out of the housing 10 through the sub casing 3. As shown in
An external-force transmitting lever 640 is fixedly attached to the projecting end of the rotary shaft portion 635. The external-force transmitting lever 640 rotates integrally with the connecting lever 630 as a unit. More specifically, when the connecting lever 630 is moved from the locked position to the unlocked position, the external-force transmitting lever 640 is moved from the locked position to the unlocked position, whereas when the connecting lever 630 is moved from the unlocked position to the locked position, the external-force transmitting lever 640 is moved from the unlocked position to the locked position. Meanwhile, when the external-force transmitting lever 640 is moved from the unlocked position to the locked position, the connecting lever 630 is moved from the unlocked position to the locked position, whereas when the external-force transmitting lever 640 is moved from the locked position to the unlocked position, the connecting lever 630 is moved from the locked position to the unlocked position.
The external-force transmitting lever 640 includes a lock-knob coupling portion 641. The lock-knob coupling portion 641 corresponds to the tip end of the external-force transmitting lever 640 that extends radially outward from the rotary shaft portion 635 of the connecting lever 630. A lock knob link 642, such as a link or wire, that connects between the lock-knob coupling portion 641 and an inside lock knob 6, which is provided on the interior side of the door D, is connected to the lock-knob coupling portion 641. More specifically, when the inside lock knob 6 is operated in the direction to lock the door, the driving force of the operation is transmitted to the external-force transmitting lever 640 via the lock-knob coupling link 642, causing the external-force transmitting lever 640 to rotate counterclockwise in
As shown in
The connecting-lever coupling portion 652 of the locking lever 650 extends radially outward with respect to the gear shaft 651. A coupling slot 656 is formed in the connecting-lever coupling portion 652. The coupling slot 656 allows the coupling projection 636 to pass therethrough. More specifically, counterclockwise pivoting in
The state-maintaining protrusion 653 is used for maintaining the locking lever 650 at a rotational position. The state-maintaining protrusion 653 protrudes from a face of the locking lever 650 facing the main casing 2 essentially horizontally in the widthwise direction of the vehicle body. The state-maintaining protrusion 653 is clamped by a spring 657 attached to the main casing 2, thereby maintaining either the unlocked state (
As shown in
The link-lever coupling projection 655 projects essentially horizontally in the widthwise direction of the vehicle body from an interior-side face of the tip end of the locking lever 650. The link-lever coupling projection 655 is engaged with the elongated coupling slot 50e in the first link lever 50.
As shown in
The intermittent gear 662 of the worm wheel 660 includes a base tooth 662a, a pair of first driving teeth 662b, and a pair of second driving teeth 662c. The intermittent gear 662 forms a unidirectional gearing between the intermittent gear 662 and the first and second driven tooth 654c and 654d and the pair of outer teeth 654a and 654b on the driven gear 654 of the locking lever 650. More specifically, as in the case of the outer teeth 654a and 654b, the first driven tooth 654c, and the second driven tooth 654d of the driven gear 654, the base tooth 662a, the first driving teeth 662b, and the second driving teeth 662c of the intermittent gear 662 are arranged along an extending direction of the worm shaft 661 at three levels which differ from each other in terms of height. In addition, these teeth are arranged such that the base tooth 662a meshes only with the outer tooth 654a or 654b, the first driving tooth 662b meshes only with the first driven tooth 654c, and the second driving tooth 662c meshes only with the second driven tooth 654d. Although not clearly shown, a return-to-neutral spring is disposed between the worm wheel 660 and the main casing 2. The return-to-neutral spring maintains the worm wheel 660 in a position (hereinafter, “neutral position”) in which the base tooth 662a of the intermittent gear 662 of the worm wheel 660 is oriented toward the axis of the gear shaft 651.
When the locking lever 650 is rotated clockwise about the gear shaft 651 from the position (hereinafter, “unlocked position”) shown in
Similarly, rotating the locking lever 650 counterclockwise about the gear shaft 651 from the locked position shown in
As shown in
When the drive motor 663 is actuated to rotate the worm wheel 660 from the position shown in
After the first link lever 50 and the second link lever 60 having been moved from the unlocked position shown in
Similarly, when the worm wheel 660 is rotated from the position shown in
After the first and the second link levers 50 and 60 having been moved from the locked position shown in
When the lock mechanism 600 is in the unlocked state, as shown in
When, in this unlocked state, the outside handle 1 is operated to open the door and the opening lever 30 is rotated counterclockwise in
When, in the unlocked state, the inside handle 5 is operated to open the door and the inner handle lever 70 is rotated counterclockwise in
When, with the door D in the closed position, the inside lock knob 6 in the unlocked position shown in
Even when, in this locked state, an attempt to open the door using the outside handle 1 is made and thereby the opening lever 30 is rotated clockwise in
Shifting from the unlocked state shown in
When, in the locked state, the inside lock knob 6 is operated in the direction to unlock the door, the external-force transmitting lever 640 is rotated as shown in
Performing the door-opening operation in the locked state shown in
When the outside handle 1 is released in the state shown in
Shifting from the locked state shown in
In the door lock system, when the inside handle 5 is operated to open the door, the single-motion lever 73 that rotates integrally with the inner handle lever 70 causes the connecting lever 630 to rotate, and the connecting lever 630 in turn rotates the locking lever 650. As a result, the first and the second link levers 50 and 60 are moved from the locked position to the unlocked position while the single-motion link 76 attached to the inner handle lever 70 simultaneously transmits the door-opening operation performed using the inside handle 5 to the ratchet, lever 25. Thus, a single-motion mechanism is provided. Meanwhile, the door-opening operation performed using the inside handle 5 is transmitted to the ratchet lever 25 via the single-motion link 76 without by way of the first and the second link levers 50 and 60. This allows to set a timing at which the first and the second link levers 50 and 60 are to be moved from the locked position to the unlocked position and a timing at which the single-motion link 76 transmits the door-opening operation performed using the inside handle 5 to the ratchet lever 25 as required. Thus, even for a door lock system with the single-motion mechanism, an unlocking timing and a door-opening timing can be set with consideration given to the operation feeling.
In the door lock system, the bushing 61 inserted into one end of the opening lever 30 and supported thereon rotatably about its axis, and the ratchet driver 63 that transmits the door-opening operation to the ratchet lever 25 are formed integrally as a unit. This allows to reduce the number of components as compared with a door lock system having a conventional anti-panic mechanism, and hence to attain cost reduction.
As set forth hereinabove, according to an embodiment of the present invention, a door lock system requires a less number of components as compared with the one having a conventional anti-panic mechanism, which enables cost reduction. Moreover, assembly work is facilitated as compared with a structure that requires assembling a link lever and a spring independently into a housing.
Although the invention has been described with respect to a specific embodiment for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.
This application claims priority from Japanese Patent Application 2006-271107, filed Oct. 2, 2006, which is incorporated herein by reference in its entirety.
Number | Date | Country | Kind |
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2006-271107 | Oct 2006 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
5054827 | Konchan et al. | Oct 1991 | A |
5277461 | Dzurko et al. | Jan 1994 | A |
5918917 | Elton et al. | Jul 1999 | A |
6010165 | Santarelli et al. | Jan 2000 | A |
6045168 | Johnson et al. | Apr 2000 | A |
6050620 | Rogers et al. | Apr 2000 | A |
20051218662 | Umino | Oct 2005 |
Number | Date | Country |
---|---|---|
1 136 641 | Sep 2001 | EP |
2 409 496 | Jun 2005 | GB |
3574990 | Jul 2004 | JP |
2005-282221 | Oct 2005 | JP |
WO 2006099730 | Sep 2006 | WO |
Number | Date | Country | |
---|---|---|---|
20080078215 A1 | Apr 2008 | US |