The present invention relates to a door handle unit for a lock in a vehicle with a door handle to open a door, hatch, or the like by a user, being supported in an articulate fashion in a bearing chamber. Further, the invention also relates to a method for securing a door handle unit for a lock in a vehicle with a door handle for opening a door, hatch, or the like by the user, which is supported in an articulate fashion in a bearing frame. The door handle of such a door handle unit comprises at least one resting position and one operating position. Further, a mechanic coupling unit is provided, by which a motion of the door handle from its resting position into its operating position can be transferred to a lock in order to allow opening the lock, thus allowing to also open the door, hatch, or the like. Furthermore, the crash block provides at least one normal position and one blocking position, with the crash block in its normal position allowing a motion of the door handle and/or the coupling unit to operate the lock and in the blocking position, which is given during or after the impact of an acceleration, particularly caused by an accident, blocks any motion of the door handle and/or the coupling unit such that an operation of the lock is prevented or hindered.
Various measures are implemented in such door handle units in order to, e.g., prevent in a lateral impact any unintentional motion of the door handle and thus an opening of the lock. For example, such door handle units may be equipped, on the one hand, with a counter-weight in order to compensate the weight of the door handle. Additionally, a crash block may be used preceding any potential motion of the door handle under the impact of an acceleration in order to block the motion of the door handle in advance. The publication DE199 29 022 C2 is named as prior art, for example. In this door handle unit, too, the crash block serves as a rapid safety means locking the door handle in a form-fitting fashion in its resting position and the weight block serves as an inert safety counteracting the force of acceleration at the door handle in general.
Furthermore, it is known from the publication DE10 2009 053 553 A1 that by the rapid crash block an additional force affects the door handle, by which it shall also be securely prevented that any unintentional motion of the door handle occurs. After its initial activation, this crash block can only be deactivated by a targeted engagement of the door handle unit so that the door handle can once more be used in its normal operation. Usually the adjustment of the crash block from the activated position to the deactivated position occurs by a trained specialist in a garage.
Thus, the invention provides a door handle unit and a safety method therefor, which securely keep the door, hatch, or the like closed even under differently impacting forces of acceleration, for example caused by a crash, using the provided crash block, with the door handle after activation of the crash block can be returned to normal operation by way of a common operation of the door handle.
Here, it shall already be mentioned that the features disclosed in the claims and the description as well as in the drawings may each be essential for the invention individually or in any combination. Features and details described in the context with the method according to the invention are here applicable with the door handle unit according to the invention and vice versa, of course.
The door handle unit according to the invention serves in a vehicle to open a door, rear hatch, glove compartment lid, or the like (in the following text only called door for simplification) by a user, in which the provided lock can be operated. Usually, a door handle is arranged in an articulate fashion at an exterior side of the door, with the door handle directly or indirectly being supported in an articulate fashion in a bearing frame, which is commonly arranged at an interior side of the door. The door handle itself may assume at least one resting position and one operating position, where the motion of the door handle from the resting position into the operating position can be transferred via a mechanical coupling unit to the lock at the door. The mechanical coupling unit can also be arranged in a pivotal or articulate fashion in a bearing frame of the door handle and be in a mechanically effective connection to the door handle. Generally, the motion of the mechanical coupling unit introduced by the door handle can be transferred directly or indirectly via a transfer element to the lock of the door. Within the scope of the invention, an operating unit shall comprise the door handle and/or the mechanical coupling unit. This transfer element may comprise, e.g., a rod, a Bowden-cable, or the like. Furthermore, the door handle unit comprises a crash block, which may show at least one normal position and one blocking position. In the normal position, the crash block allows a common motion of the door handle and/or the coupling unit (or the operating unit, respectively) in order to operate the lock. In the blocked position, which is given during or after the impact of an acceleration, particularly in case of a crash, any motion of the door handle and/or the coupling unit (or the operating unit, respectively) is blocked such that any operation of the lock is prevented. This case is also called the activation of the crash block. Consequently, the present crash block secures the door handle from any unintentional motion in case of a crash, in order to here prevent any opening of the lock and thus an opening of the door at the vehicle in case of a crash.
According to the invention, it is provided in this door handle unit that the crash block in its blocked position can be transferred into its normal position by a motion of the door handle and/or the coupling unit. Due to the fact that the crash block is already in its blocking position, an impact of the force of acceleration has already occurred upon the door handle; thus the crash block has been activated into its blocking position. From this blocking position, the crash block can only be transferred into the normal position by an additional motion of the door handle and/or the coupling unit. Here, this additional motion of the door handle is initially blocked by the crash block so that an operation of the lock continues to be prevented. Consequently, the usual operation of the door handle from its resting position into the operating position of the door handle cannot be performed because the crash block prevents the operating position from being reached. Only when the door handle is moved back in the direction towards its resting position can the crash block move into its normal position. Accordingly, even after a single triggering of the crash block, it is necessary that a repeated operation of the door handle from its resting position in the direction of its operating position is required in order to deactivate the crash block, with the crash block here being transferred at least from a blocking position into the normal position. However, during the initial operation of the door handle, said door handle fails to reach its operating position, because this motion is still blocked by the crash block, which is at least in a blocking position. Only when the crash block has once more assumed its normal position can the door handle be transferred from its resting position into the operating position, whereby the lock can be opened at the door.
Here, the crash block can only be transferred in its blocked position by a (common or usual) motion of the door handle and/or the coupling unit into the normal position. Consequently it is not necessary after a crash to see a garage in order to deactivate the crash block in the door handle unit or to return it into its normal position. This measure is replaced by the additional (unlocking) motion of the door handle and/or the coupling unit. Here, as described above, the door handle cannot be moved to its operating position.
Here, it shall also be pointed out that the motion of the door handle and/or the coupling unit to deactivate the crash block is equivalent to the normal pulling motion to open the lock. This way it is ensured that after an accident helpers from the outside can open the door by a normal operation of the door handle. Intuitively, these helpers will pull the door handle at least twice in order to open the door. This way it is ensured that aid can quickly be provided to the passengers, without it being necessary for such persons to be particularly trained in the opening of doors after a crash has occurred.
Furthermore, it may be provided that the crash block comprises at least two blocking positions, with here the crash block comprising a first blocking position by the impact of a force of acceleration, which is, however, only provided during the impact of a force of acceleration. Consequently, this first blocking position may represent a temporarily unstable position of the crash block from which the crash block can be returned into its normal position. Furthermore, the crash block may also show a second blocking position, in which the crash block is held steady, in particular temporarily. The crash block may also be transferred from a first blocking position directly into a second blocking position, regardless if any motion of the door handle and/or the coupling unit has occurred by the impact of the force of acceleration. In this second blocking position, the crash block can only be transferred back into its normal position by the above-described (unlocking) motion of the door handle and/or the coupling unit. In the following, this motion is also called the unlocking motion of the door handle and/or the coupling unit. For the purpose of clarification, it shall once more be mentioned that in its second blocking position the crash block also blocks a motion of the door handle and/or the coupling unit up to the operating position in order to this way securely prevent the operation of the lock. Only by a subsequent, second motion of the door handle can the door handle be transferred from its resting position into its operating position, thus realizing an operation of the lock. Due to the fact that the crash block is then once more in its operating position, it is capable of reacting to additional impacts of a force of acceleration, in order to perhaps once more allow blocking a motion of the door handle and/or the coupling unit.
Furthermore, it may be provided that the crash block and/or the coupling unit are supported in an articulate fashion at the bearing frame. For this purpose, respective axes may be provided, which are arranged in or at the bearing frame and about which the crash block and/or the coupling unit is/are supported in a rotational or articulate fashion. Further, the crash block and/or the coupling unit may be connected to a solid weight in order to allow automatically performing the desired motion upon the impact of a force of acceleration. However, due to its lower weight, the crash block temporarily precedes the coupling unit and thus it is securely possible to block the coupling unit in its blocking position. The coupling unit is of higher inertia due to its greater weight and thus it cannot follow the motion of the crash block with the same speed in the event of an accident.
In order to embed the crash block according to the invention in a particularly stable fashion in the door handle unit, an accept may be embodied, for example, in the form of a box-shaped frame with at least three sides, particularly comprising a bearing frame, in which the crash block is supported at its axis. This box-shaped accept prevents, on the one hand, objects from being able to penetrate the motion area of the crash block and, on the other hand, it counteracts the deformations that develop in a crash.
Optionally, it is therefore possible that the crash block is supported rotational about an axis and axially displaceable in reference to said axis in order to reach at least the normal position and one blocking position. By a rotation of the crash block about its axis, it can reach its first blocking position. Therefore, it is not necessary for the crash block to also be axially displaced longitudinally in order to reach the first blocking position, which is also possible, though. The second blocking position is reached by the crash block after it has been rotated out of its first blocking position opposite in reference to the first rotary direction and axially displaced longitudinally. In this second blocking position the crash block remains stable temporarily. The first blocking position of the crash block is embodied unstable, however, so that the crash block remains here only for a brief period of time and then moves into the normal position or perhaps the second blocking position. Regardless into which position the crash block is transferred then, it remains fully functional, though, so that upon another impact of a force of acceleration it is once more activated when it is taken out of its normal position or remains activated if it is still arranged in the second blocking position. This way it is ensured that, even in case of the door handle flapping, an operation of the lock is securely prevented.
In order to transfer the crash block from at least one blocking position into the normal position, the crash block can be mechanically stressed by a spring. This spring may particularly be embodied as a pressure and/or torsion spring and arranged between the bearing frame and the crash block. In order to save space, the spring may be embodied as a flat spring and arranged about the axis of the crash block. Further, the spring may also serve to transfer the crash block from the first blocking position into a second blocking position, with the spring being able to ensure a longitudinal displacement of the crash block on the axis. Consequently the spring may not only serve to return the crash block from the first blocking position in the direction towards the normal position, but simultaneously the spring may also serve to displace the crash block longitudinally on its axis, in order to reach the second blocking position.
In order to achieve that the crash block in every case blocks a motion of the door handle and/or the coupling unit under the impact of a force of acceleration, said crash block may block at least in one, preferably in all blocking positions the motion of the door handle and/or the coupling unit in a form-fitting fashion. In order to maintain the above-mentioned form-fitting connection, a projection may be provided at the door handle and/or the coupling unit mechanically cooperating with a stop at the crash block in a form-fitting fashion. This way, the crash block can be overcome in its blocked position only by destroying the door handle unit in order to transfer the door handle and/or the coupling unit directly into its operating position. Of course, a cinematic inversion is possible between the projection at the door handle and/or the coupling unit and the respective stop at the crash block in order to achieve the desired form-fitting connection in a blocking position of the crash block.
Furthermore, it may be provided that the crash block rotates in the first blocking position only about the axis and the crash block particularly comprises a first stop for the bearing frame. This stop may serve as a rotary stop or as a lateral guiding stop for the longitudinal displacement of the crash block. Furthermore, the crash block may comprise a second stop for the bearing frame which also serves as a rotary stop, particularly for the first blocking position. This second rotary stop may be arranged at a disc-shaped segment of the crash block, with this second stop being arranged projecting perpendicular in reference to the planar alignment of the disc-shaped segment. The disc-shaped segment of the crash block may further show a recess or a clear space serving, in the normal case, to allow that the projection can be guided past the crash block unhindered by the coupling unit so that an unhindered motion of the door handle or the coupling unit is possible between the resting position and the operating position. Furthermore, a third stop may be provided at the crash block, particularly arranged at the disc-shaped segment of the crash block and projecting from the planar surface of the disc-shaped segment, with this third stop, too, being able to cooperate with a counter-stop at the bearing frame. The third stop may be embodied arched. By this third stop the crash block can be held steady in the second blocking position. Consequently, the third stop prevents the crash block from being able to be easily turned back from the second blocking position in order to reach the normal position. In the second blocking position the crash block is rotated about its axis and displaced axially into its normal position.
The first and/or the second and/or the third stop cooperate in a form-fitting fashion with respective counter-stops at the bearing frame. These counter stops may also be fastened directly at the bearing frame.
Furthermore, it is possible that also the second stop of the crash block prevents an unlocking motion of the door handle and/or blocks the coupling unit in a form-fitting fashion, if the crash block was previously arranged in the second blocking position. This way, the second stop can accept several functions, in that it, on the one hand, limits the rotary motion of crash block in the first blocking position and, on the other hand, blocks the door handle and/or the coupling unit in the blocking position in a form-fitting fashion.
In the first blocking position of the crash block, the projection at the coupling unit can cooperate with the disc-shaped segment of the crash block, particularly in a form-fitting fashion. In this first blocking position, the crash block with the disc-shaped segment prevents the motion of the projection of the coupling unit such that it cannot be rotated further in the direction of the operating position. Here, the crash block may laterally contact with its first stop a counter stop at the bearing frame in order to counteract a longitudinal motion of the crash block by the pressure of the projection of the coupling unit.
In the second blocking position, the crash block may be rotated on the one hand and be longitudinally displaced on the other hand, with the third stop of the crash block cooperating in a form-fitting fashion with the respective counter-stop at the bearing frame. This form-fitting connection may only be released by a longitudinal displacement of the crash block in the direction towards the normal position. When now an (unlocking) motion of the door handle and/or the coupling unit is performed, the projection of the coupling unit presses onto the disc-segment at the crash block, whereby said crash block first has to be longitudinally displaced in order to allow any further motion of the door handle or the coupling unit in the direction towards the operating position. By this longitudinal displacement of the crash block, the form-fitting connection of the third stop with the respective counter frame at the bearing stop is released so that the crash block now can rotate freely in the direction of its normal position. Additionally, now the door handle and/or the coupling unit can be moved slightly further, with the projection of the coupling unit now, however, contacting in a form-fitting fashion the second stop, which is arranged perpendicularly at the disc-segment of the crash block, and in this position also being blocked in a form-fitting fashion. This way, any (unlocking) motion at the door handle and/or the coupling unit leads to the deactivation of the crash block, in that said crash block is laterally displaced from its second blocking position, with, however, the blockage between the coupling unit and the crash block not yet being released. Only after the door handle and/or the coupling unit has been moved back into the resting position can the operating position be reached, because in the meantime the crash block has once more assumed its normal position.
Within the scope of the invention, it may therefore be provided that the crash block releases the stable, second blocking position by an additional (unlocking) motion of the door handle and/or the coupling unit. Here, the additional motion of the door handle and/or the coupling unit may lead to an axial displacement of the crash block so that the third stop is without effect upon the bearing frame. Additionally, the second rotary stop of the crash block can prevent the additional motion of the door handle and/or the coupling unit in a form-fitting fashion.
Additionally, the present disclosure also relates to a method for securing a door handle unit for a lock in a vehicle, particularly showing the features of the characterizing part. Here, it is provided according to the disclosure that in its blocking position the crash block is transferred into the normal position by a motion of the door handle and/or the coupling unit. This motion relates to an unlocking motion of the door handle, which, however, cannot lead to an operation of the lock because the crash block still reliably blocks any motion of the door handle and/or the coupling unit.
The method according to the invention may be performed with a door handle unit according to the invention.
It is also possible that, upon the influence of a force of acceleration, the crash block is transferred into a first blocking position, particularly automatically, by way of a rotation, and an existing motion of the door handle and/or the coupling unit is blocked such that an operation of the lock is securely prevented. By this blocked motion of the door handle and/or the coupling unit, it can be achieved that the crash block subsequently returns to its normal position, because here no longitudinal displacement has occurred in order to transfer the crash block into the second blocking position. The return motion and the longitudinal displacement of the crash block may also occur automatically by the above-mentioned spring.
Within the scope of the invention it is also possible that the crash block is transferred from the stable second blocking position into its normal position exclusively by an additional (unlocking) motion of the door handle and/or the coupling unit. Here, the additional motion can initially be blocked by the crash block in a form-fitting fashion. Additionally, the crash block can only assume its normal position when the door handle itself is in its resting position.
Additional advantageous embodiments of the invention are discernible from the following description, the claims, as well as the figures. In the figures, the invention is shown in a fundamental exemplary embodiment. In the figures:
In the following figures, identical technical features are marked with the same reference characters.
In
It is shown in
In
As soon as the crash block 14 has returned into its normal position IIa the door handle 11 and/or the coupling unit 13 can once more freely move back and forth between the resting position Ia and the operating position Ib in order to operate the lock 52. This position is shown in
Phase A: Based on the first impact of a force of acceleration (see reference character 101) now the crash block 14 is rotated counter-clockwise towards the first blocking position IIb1 (see reference character III). Further, by this impacting force of acceleration 60 the coupling unit 13 is also rotated from the resting position Ia towards the operating position Ib, indicated by the reference character 121. Based on the reference character 121 now the coupling unit 13 can be rotated back into its resting position (see reference character 123).
Phase B: It is indicated by the reference character 112 that from the first blocking position IIb1 the crash block 14 is rotated counter-clockwise by the spring 15. This way the crash block 14 can be returned into its normal position IIa (see reference character 114), if no longitudinal displacement of the crash block 14 has occurred. However, if any longitudinal displacement has occurred by the spring 15 at the crash block 14, the crash block 14 stops in the second blocking position IIb2, indicated by the reference character 113.
Phase C: From this second blocking position IIb2 (see reference character 113) the crash block 14 can be transferred either by a second impacting force of acceleration (see reference character 102) or by a manual operation of the door handle 11 (see reference character 130) back into the normal position IIa. If in the second case a manual unlocking operation of the door handle 30 occurs (see reference character 130) the crash block 14 is displaced longitudinally against the force of the spring 15 and subsequently rotated out of the second blocking position IIb2 towards the normal position IIa. However, here the crash block 14 blocks the coupling unit 13, which first must be returned into its resting position in order to allow that the crash block 14 can be rotated completely into the normal position IIa. In the first case, in which in the second blocking position IIb2 another force of acceleration 60 acts upon the crash block 14 (see reference character 102) the coupling unit 13 is also blocked by the crash block 14 (see reference character 122) so that it now can be rotated in the direction of the resting position Ia. The rotation of the coupling unit 13 is shown with the reference character 123 in
Finally it shall be mentioned that the present invention is not limited to the exemplary embodiment shown; for example, as already mentioned, the stops of the crash block or the bearing frame may also be embodied at least partially as diagonal control surfaces in order to this way generate the longitudinal displacement of the crash block 14. Furthermore, mechanically complementary embodiments of the invention are also possible, which shall also be covered by patent protection.
Number | Date | Country | Kind |
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10 2011 051 617 | Jul 2011 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
3719248 | Breitschwerdt et al. | Mar 1973 | A |
5669642 | Kang | Sep 1997 | A |
6042159 | Spitzley et al. | Mar 2000 | A |
6460904 | Stapf | Oct 2002 | B1 |
6471262 | Schwab | Oct 2002 | B1 |
6648382 | Monig et al. | Nov 2003 | B1 |
7029042 | Belchine, III | Apr 2006 | B2 |
7059641 | Chanya | Jun 2006 | B2 |
7635151 | Rodawold et al. | Dec 2009 | B2 |
8038185 | Wood | Oct 2011 | B2 |
8152209 | Lee | Apr 2012 | B2 |
8167342 | Bertolotti | May 2012 | B2 |
20100207404 | Corwin et al. | Aug 2010 | A1 |
20110115240 | Muller et al. | May 2011 | A1 |
20110181052 | Brose et al. | Jul 2011 | A1 |
20110181058 | Bland | Jul 2011 | A1 |
20120061162 | Savant et al. | Mar 2012 | A1 |
Number | Date | Country |
---|---|---|
19929022 | Jan 2001 | DE |
102009053553 | May 2011 | DE |
202009017667 | Jun 2011 | DE |
WO 2013053346 | Apr 2013 | DE |
1593802 | Nov 2005 | EP |
2325419 | May 2011 | EP |
2876135 | Apr 2006 | FR |
2940813 | Jul 2010 | FR |
2006003197 | Jan 2006 | WO |
2012028325 | Mar 2012 | WO |
Number | Date | Country | |
---|---|---|---|
20130056999 A1 | Mar 2013 | US |