| JPS6050665 | [Title of the Invention] A cap for fuel tanks |
| JPH06293223 | FUEL LID OPENING/CLOSING DEVICE |
BECK CHRISTIAN (DE)
| WO2008031814A1 | 2008-03-20 |
| EP0802345A2 | 1997-10-22 | |||
| DE3149635A1 | 1983-06-23 | |||
| DE19650594A1 | 1998-06-18 | |||
| EP2017112A1 | 2009-01-21 |
| Claims [Claim 1] A drive actuating a flap pivotably supported in or on an automobile, in particular actuating a fuel tank flap, comprising a push-push kinematics cooperating with one side of the flap, said push-push kinematics exhibiting the following features: • a housing (10) suitable for integration into an automobile, • a pushbar (20) which is supported in axially displaceable manner in the housing (10) and which in all its axial positions partly projects through a housing aperture (34) out of the housing (10) and comprises an external actuating end cooperating the flap, • a spring (22) in the housing (10) prestressing the pushbar (20) to project from the housing (10), • a rotatable ring (36) which encloses the pushbar (20) and which is supported in the housing (10) in axially fixed manner • at the outside of the pushbar (20), at least one groove (4) running parallel to its axis and at least one protrusion at the inner circumference of said ring to engage said groove over a wide adjustment range of the pushbar (20), as a result of which the ring (36) retains its rotational position in said range of the groove when the pushbar (20) is displaced axially, • a first deflection face (50) which runs obliquely to the axis of the pushbar (20) and is configured between the groove (40) and the actuation end and which cooperates with the protrusion (38) of the ring (36) and rotates this ring through a predetermined angle when the pushbar (20) is displaced by a predetermined first excursion into the housing (10), • a locking recess (46) pointing toward the actuation end and situated at the pushbar (20) at a circumferential spacing from the first deflection face (50) and receiving the protrusion (38) when the pushbar (20) is released following the first excursion, as a result of which the pushbar (20) following a return excursion is locked in a locked position in the housing (10), • a second deflection face (54) running obliquely to the pushrod axis between the locking recess (46) and the actuation end, cooperating with the protrusion (38) when the pushrod (20) is moved out of the locked position by means of a second excursion farther into the housing (10), whereby the ring (36) is rotated by a predetermined second angle and the protrusion (38) is aligned with the groove (40) and the pushbar (20) is displaceable into its maximally extended position. [Claim 2] Drive as claimed in claim 1, characterized in that the pushbar (20) is fitted with three circumferentially equidistant grooves (40) running parallel to the pushbar axis, further with first and second deflection faces (50, 54) and locking recesses (46) and in that the ring (36) is fitted at its inner circumference with three circumferentially equidistant protrusions (38). [Claim 3] Drive as claimed in either of claims 1 and 2 as claimed in either of claims 1 or 2, characterized in that the ring (36) is rotatably supported in the housing (10) and in decelerating/speed-controlling manner. [Claim 4] Drive as claimed in claim 3, characterized in the ring (36) is fitted at its outside with at least one tangential resilient tang (42) of which the end projects beyond the external periphery of the ring (36) when latter is in its unloaded state and which when loaded rests against a cylindrical wall of the housing (10). [Claim 5] Drive as claimed in claim 4, characterized in that the cylindrical wall is fitted with a serrate snap-in toothing (44) in a manner that the ring (36) is rotatably only in one direction of rotation opposite to that wherein the resilient tang (42) cooperates in blocking manner with the snap-in toothing (44). [Claim 6] Drive as claimed in claim 5, however characterized in that the housing aperture (34) is subtended in a cover (14) which may be deposited in engaging manner on the housing (10). [Claim 7] Drive as claimed in claim 6, characterized in that the ring (36) is received in an inner ring recess of the cover (14). [Claim 8] Drive as claimed in one of claims 1 through 6, characterized in that the pushbar (20) is fitted with at least one radial protrusion (28) acting as a rest for the spring (22) and in turn resting against the ring (36) when the pushbar (20) is situated in its most extended position. [Claim 9] Drive as claimed in one of claims 1 through 8, characterized in that the first and second deflection faces (50, 54) as well as the locking recess (46) are subtended at radial rises (48, 52) of the pushbar (20). [Claim 10] Drive as claimed in one of claims 1 through 9, characterized in that the groove (40) running parallel to the pushrod axis is subtended between adjacent rises of said pushbar (20). [Claim 11] Drive as claimed in one of claims 1 through 10, characterized in that an axially collapsible cap (60) made of a flexible material covers the pushrod (20) outside the housing (10). [Claim 12] Drive as claimed in claim 11, characterized in that the cap (60) cooperates by means of an inner annular bead (62) with an annular groove (64) of the pushrod (20) by being affixed when required into said groove. [Claim 13] Drive as claimed in claim 12, characterized in that at its free end, the cap (60) is fitted with an inwardly directed flange engaging an external annular groove of the housing respectively the cover. [Claim 14] Drive as claimed in claim 13, characterized in that said annular groove is bounded by an externally pointing, radial flange engaging an inner annular groove of the cap (60). |
Title of Invention: ACTUATION MEANS FOR A ROTATABLY SUPPORTED FLAP IN AN AUTOMOBILE COMPRISING A
PUSH-PUSH KINEMATICS
[I] The present invention relates to a pivotable drive for an automotive flap, in particular for a fuel tank flap, fitted with a push-push kinematics, as defined in claim 1.
[2] It is known to combine a push-push kinematics with a fuel tank flap. The fuel tank flap is closed in said kinematics' locked position. When unlocking the fuel tank, and by unlocking the pushbar of said kinematics, said flap may be partly pivoted outward when a pressure is applied to it. The spring configured in the push-push kinematics acts on the pushbar and thereby on the fuel tank flap to rotate it outward by a given angle to allow manually seizing it and to fully pivot it
[3] The push-push kinematics of the known state of the art uses a so-called control wire operating in concert with a cardioid cam. Manufacturing the known push-push kinematics is comparative costly and such designs may offer only limited service lives. Again kinematics assembly is relatively elaborate.
[4] The objective of the present invention is to fit an automobile with a push-push kinematics allowing economical manufacture and undergoing little wear.
[5] This problem is solved by the features of claim 1.
[6] The present invention comprises the following features:
[7] • a housing appropriate for installation in an automobile,
[8] • a pushbar supported in the housing in axially displaceable manner and partly projecting in all axial positions through a housing aperture beyond said housing and fitted with an external drive end cooperating with the flap,
[9] • a spring inside the housing prestressing the pushbar out of the housing,
[10] - a ring enclosing the pushbar and being axially affixed in the housing while being rotatable,
[I I] - at least one groove running parallel to the pushbar axis on the pushbar's outer side, and at least one protrusion at the inside of the ring engaging the groove across another pushbar adjustment range, whereby the ring preserves its rotational position when the pushbar is axially displaced,
[12] - a first deflection face at the pushbar and oblique to its axis, situated between the groove and the drive end, cooperating with the ring's protrusion and rotating said ring by a predetermined angle when said pushbar has been moved by a first predetermined excursion into the housing,
[13] - a locking recess which points to the drive end and is situated in the pushbar while being circumferentially spaced from the first deflection face and which receives the protrusion when, after the first excursion, the pushbar has been released, as a result of which, following a return excursion, the pushbar is locked into a locking position,
[14] - a second deflection face oblique to the pushbar axis configured between the locking recess and the drive end and cooperating with the protrusion when said pushbar is forced out of the locking position and by means of a second excursion is forced deeper into the housing, whereby the ring is rotated by another angle and the protrusion is aligned with the groove and the pushbar is displaceable into its extended position.
[15] Using the drive respectively its push-push device of the present invention, a number of advantages are attained. The push-push kinematics of the invention contains a minimum of components and its manufacture is economical. Only plastic parts being used, service life is lengthened. Tolerances moreover can be tightened. The mechanical geometry of the push-push kinematics of the present invention is simple, and this kinematics may be installed in automated manner. The push-push kinematics of the present invention allows modular construction to meet different requirements. It is compact.
[16] Advantageous embodiment modes of the present invention are defined in the dependent claims.
[17] In one embodiment mode of the present invention, the pushbar is fitted with three circumferentially equidistant grooves running parallel to its axis, further with a first and second deflection face and three locking recesses. At its internal surface, the ring comprises three circumferentially equidistant protrusions. In this design, the ring will rotate by 120° when the pushbar is moved out of the locked position and then back into the unlocked one. This feature is easily implemented using appropriate control faces.
[18] The reliability of operation of the push-push kinematics of the present invention is increased when the ring is supported in rotating manner with deceleration/speed control applied as needed. Accordingly, in one embodiment mode of this invention, the ring may be fitted at its outside with at least one tangential, resilient tang of which the end — in the relaxed state — projects beyond the ring's outer circumference. In the installed condition, the resilient tang is stressed against a cylindrical wall of said housing. Consequently the ring may be rotated only when a predetermined rotational force has been applied. In this respect another embodiment of the invention fits the cylindrical wall with a serrate snap-in surface in a manner that the ring can rotate only in one direction whereas, for the opposite direction, the resilient tang cooperates with the snap-in toothing. Ring rotation in the other direction would make the kinematics uncontrollable.
[19] To allow simple installation, in one embodiment mode of the invention, a housing aperture if fitted into a cover which can be snapped onto the housing. In this em- bodiment, the ring preferably is received in an inner annular recess in the pushbar.
[20] In another embodiment mode of the present invention, the first and second deflection faces and the locking recess are constituted on radial pushbar rises.
[21] To prevent contaminants from entering the push-push kinematics, a further embodiment mode of the present invention provides an axially collapsing cap covering the pushbar outside the housing and being configured outside this housing. This cap is connected preferably in geometrically interlocking manner with the pushbar respectively the housing respectively the cover.
[22] An illustrative embodiment mode of the present invention is elucidated below in relation to the appended drawings.
[23] Fig. 1 is a cross-section of a push-push kinematics of the invention in its open state,
[24] Fig. 2 shows the push-push kinematics of Fig. 1 in its locked state,
[25] Fig. 3 shows the unlocked state of the push-push kinematics of either Fig. 1 or Fig. 2,
[26] Fig. 4 is a cross-section relating to Fig. 1 along line 4-4,
[27] Fig. 5 is a perspective of the pushbar kinematics of Fig. 1,
[28] Fig. 6 is a perspective of the pushbar kinematics of Fig. 2, and
[29] Fig. 7 is a perspective of the pushbar of the push-push kinematics of Fig. 3.
[30] Figs. 1 through 3 show a drive system comprising a housing 10 fitted with a lower housing segment 12 that is open at its top and with a cover 14. The cover 14 is linked by a snap-in or weld connection to said lower housing segment. Said link however is not discussed in detail herein.
[31] The lower housing segment 12 subtends an approximately cylindrical and axial cavity 18 receiving a pushbar 20. The cavity 18 also receives a helical spring 22 resting by its lower end on a support 24. At its upper end said spring encloses a shank 26 of the lower end of said pushbar. Above said bolt 26 the pushbar is fitted with a radial flange 28 serving as a rest for the spring 22. Said flange moreover is fitted with radial protrusions 30 engaging axially parallel grooves within said cavity 18, as a result of which the pushbar during an up and down motion can be displaced only linearly.
[32] Depending on its positions shown in Figs. 1 and 3, the pushbar 20 runs upward by a different length through an aperture 34 in the cover 14. The aperture 34 flares upward like a bugle. A ring 36 is received in a recess of the cover 14. Fig. 4 shows the ring geometry. It comprises three equidistant protrusions 38 situated at its inner periphery; said protrusions engage axially parallel grooves 40 of the pushbar 20. Tangential resilient tangs 42 are constituted externally between each of the protrusions 38 and, when in their relaxed state, project beyond the outer periphery of the ring 36. They cooperate with the cylindrical inner wall of the cavity 18 and in the process decelerate/ control the speed of rotation of the ring 36, said rotation, as elucidated further below, being counter-clockwise. Moreover a sawtooth arc 44 is constituted in the wall of the cavity 18. This sawtooth arc makes sure that the ring cannot rotate clockwise, as otherwise each tang jointly with a tooth of the sawtooth arc 44 would be jamming.
[33] The grooves 40 are subtended by corresponding rises at the outside of the pushbar
20. At their upper edge, the rises subtend an upwardly open locking notch 46 of triangular contour. Beveled faces are indicated on each side of the locking notch 46. A further rise 48 is constituted on the pushbar 20 above each groove 40 running parallel to the pushbar's axis and subtends a first deflection face 50 running obliquely downward. A further rise 52 is constituted between the rises 48 and at the outside of the pushbar 20, subtending a lower, second deflection face 54.
[34] In the embodiment mode shown in Fig. 1, the pushbar 20 is maximally extended and its flange 28 rests against the underside of the ring 36. When the pushbar is depressed from the top toward the bottom as indicated by the arrow 56, the spring 22 shall be compressed and the protrusions 38 will move along the axially parallel grooves. As the compression increases, the protrusions 38 make contact with the deflection faces 50. As a result the ring is rotated anti-clockwise by a given angle. When the force 56 is no longer applied, the spring 22 forces the pushbar upward again, as a result of which the protrusions 38 are received in the locking recesses 46. This state is shown in Fig. 2. The protrusions and the locking recesses are not visible in Fig. 2. In the configuration of Fig. 2, the push-push kinematics is locked in the shown position.
[35] If such locking is to be disengaged, then, as indicated in Fig. 3, the pushbar 20 is moved farther relative to the position of Fig. 2 into the cavity 18. As a result the locking recess 46 is disengaged from the protrusion 38. When the force is no longer applied to the pushbar 20, the spring 22 moves it upward again. In this manner the deflection face 54 makes contact with the bevel to the left of the locking recess 46. As a result, the ring 36 is rotated through another angle until the protrusions 38 are again aligned with the grooves 40. When the pushbar then is released, it moves back into the position of Fig. 1.
[36] In this manner, an illustrative fuel tank flap being loaded by the pushbar 20, may be moved against the force of the spring 18, 22 into a locked position wherein it is flush with the outside of the automobile's body sheetmetal. When, after having been disengaged, the flap is pressed inward, the locked position of the push-push kinematics is released and thereupon the pushbar is able, as indicated in Fig. 1, to pivot the flap through a given angle. This feature is not shown. However the principle is well known.
[37] As further shown in Figs. 1 and 3, a flexible cap 60 is mounted on the cover 14. The cap comprises at its inside an annular bead at 62 cooperating with an annular groove 64 in the pushbar 20. An inner annular groove 64' at the lower end of the cap 60 receives an annular flange 66 of the cover 14. In this manner the cap 60 geometrically interlocks with the cover 14. When pressure is applied to the cap 60 and hence to the pushbar 20 as shown in Fig. 1 (reference 56), the cap 60 collapses into folds, a main fold 68 being received in the cover 14 by the bugle-shaped widening of the aperture 34.
[38] Figs. 5 through 7 separately show a cutaway enlargement of the pushbar 20 and the ring 36, namely as shown in the positions of Figs. 1 through 3.
[39] Consequently, the rises 48, 52 are each fitted with a bevel at their tops. These bevels simplify assembly. During assembly, first the housing 10 is opened and next the spring 22 is inserted. The pushbar 20 is made to pass through the ring 36, whereupon this sub- assembly is inserted into the cover 14. Then the cap 60 is affixed to the cover 14. Then this pre-assembled unit is linked by means of the snap-in or weld joint 16 to the lower housing segment 12. Such assembly also may be wholly automated.