This application claims the benefit of German Patent Application No. DE 10 2012 025 053.3, filed Dec. 21, 2012, and German Patent Application No. DE 20 2013 002 811.4, filed Mar. 25, 2013, the disclosures of which are incorporated by reference herein in their entirety.
The invention relates to a motor vehicle lock and to a motor vehicle door arrangement.
The motor vehicle lock under discussion is assigned to a motor vehicle door arrangement with a motor vehicle door. In the present case, the term “motor vehicle door” should be understood in broad terms. It includes in particular side doors, rear doors, tailgates, rear lids or engine bonnets. Such a motor vehicle door can in principle also be designed in the manner of a sliding door.
Crash safety plays an important role in motor vehicle locks nowadays. The primary concern is that neither crash-induced accelerations nor crash-induced deformations should lead to an undesirable opening of the motor vehicle door to which the motor vehicle lock is assigned.
The known motor vehicle lock (DE 10 2011 015 675 A1), on which the invention is based, is equipped with crash protection means which prevents a crash-induced, i.e. an automatic and undesirable, opening of the motor vehicle door, in the event of a crash. For this purpose, a crash element which can be adjusted by a crash-induced deformation of the door outer skin into a crash position and thereby blocks an actuating lever of the motor vehicle lock is provided.
In the known motor vehicle lock, the crash element is of pivotable design. Such a pivotable mounting is generally preferred in the region of the motor vehicle locks since the operational reliability of such pivot bearings even in the event of disadvantageous environmental conditions, for example in the event of icing conditions, is considered to be high.
However, a disadvantage of the known motor vehicle lock with a crash element which is pivotable via a pivot bearing is the fact that the introduction of force for an adjustment of the crash element always has to take place in a plane which is oriented perpendicularly to the pivot axis of the crash element. If this is not observed, destruction of the pivot bearing has to be anticipated particularly with the high forces occurring in the event of a crash. Account can be taken of this circumstance, in order to ensure high operational reliability, only with a particularly robust and therefore cost-intensive design of the pivot bearing of the crash element.
The invention is based on the problem of designing and developing the known motor vehicle lock in such a manner that the operational reliability of the crash protection means is increased with simple structural means.
The above problem is solved in the case of a motor vehicle lock according to the following. The basic consideration is essentially to provide a crash element mounting which is designed as a linear guide and in which the crash element is displaceably guided.
According to the proposal, it has been recognized that such a linear guide, when suitably designed, is robust against an introduction of force into the crash element, the alignment of which introduction of force differs from the alignment of the linear guide. This applies specifically to the generally high crash forces which act on the crash element and lead to the crash element being “pressed” to a certain extent through the crash element mounting. In this case, even a certain deformation of the crash element mounting may occur without the actual function of the crash element mounting being impaired. A possible tilting of the crash element in the linear guide therefore plays only a subordinate role, if any at all, in the event of a crash.
In a an embodiment, the crash element has an engagement section for the engagement with the component of the motor vehicle door, which component has undergone crash-induced deformation, wherein the engagement section can be substantially plate-like design. The plate-like design is made in such a manner that the crash forces are essentially absorbed by the plate surface of the engagement section. The absorption of crash forces over a relatively large area which corresponds to the plate surface is thereby possible.
In an embodiment, the crash element blocks an actuating lever which can be pivotable. It has been shown in this context that the blocking of a pivotable actuating lever by a linearly displaceable crash element can be configured in a particularly compact and, above all, robust manner.
In an embodiment, during the blocking by the crash element, the blocking force can run via an in particular positionally fixed support and outside the crash element mounting. The wording “can” means here that not every blocking force, in particular a small blocking force, has to run via the support. For example, it is conceivable that, in the event of small blocking forces, a certain play remains between the crash element and the support, said play being eliminated only by increased blocking forces. In an embodiment, the crash element mounting can be designed in a weak and therefore cost-effective manner, since at any rate high blocking forces can be substantially absorbed by the support.
The abovementioned blocking of a pivotable actuating lever by means of a linearly displaceable crash element permits the crash element to be aligned substantially as desired with respect to the actuating lever axis.
In an embodiment, a motor vehicle lock in which a crash element mounting is provided, in which the crash element is guided, wherein the crash element, during the adjustment thereof into the crash position, is adjusted, in particular pushed, between the component to be blocked by the crash element and an in particular positionally fixed support such that at least some of the force flux of the blocking force can run via the support and outside the crash element mounting. The advantageous cost aspect of such an arrangement has already been discussed further above. The realization of the linear displaceability of the crash element can be dispensed with according to this further teaching. Otherwise, reference should be made to all of the explanations regarding the motor vehicle lock according to the proposal.
For example, the adjustability of the crash element at any rate also originates from a deformability of the crash element itself. A displaceability of the crash element within the above meaning then does not necessarily need to be provided.
The deformable design of the crash element gives rise to new possibilities for designing the crash element mounting. In an embodiment, the crash element mounting furthermore fixes the crash element on the motor vehicle lock. The guiding of the crash element by the crash element mounting is then simply restricted to holding the crash element in the region of the crash element mounting.
In an embodiment, the crash element is designed as a bow which is suspended via the crash element mounting at any rate at two suspension points. In the event that the crash element, as indicated above, is of deformable design, a particularly robust and at the same time cost-effective arrangement can thereby be achieved.
In an embodiment, a motor vehicle door arrangement with a motor vehicle door and a motor vehicle lock according to the proposal and assigned to the motor vehicle door. In this case, the motor vehicle lock can be arranged in the motor vehicle door. The motor vehicle lock then interacts with a striker or the like arranged on the motor vehicle body. Reference should be made to all of the explanations regarding the motor vehicle lock according to the proposal.
In an embodiment, the engagement section of the crash element is arranged in the immediate vicinity of the door outer skin of the motor vehicle door. In particular for the case in which the engagement section is of substantially plate-like design, crash-induced deformations of the door outer skin can be introduced into the crash element over a broad surface region.
In an embodiment, the invention provides a motor vehicle lock for a motor vehicle door arrangement, wherein a lock latch and a detent pawl assigned to the lock latch are provided, wherein the lock latch can be brought into an open position and into a closed position, wherein the lock latch in the closed position is in or can be brought into engagement with a striker or the like, wherein the detent pawl can be brought into an engaged position in which said detent pawl fixes the lock latch in the closed position, and wherein the detent pawl can be lifted into a release position in which said detent pawl releases the lock latch, wherein the detent pawl can be brought into the release position by means of an actuating arrangement, wherein a crash element is provided, said crash element, in order to avoid a crash-induced lifting of the detent pawl with a component of the motor vehicle door arrangement, such as a door outer skin, can be adjusted by the crash-induced deformation of said component into a crash position, and in that, for this purpose, the crash element in the crash position or an element coupled thereto blocks the detent pawl and/or the actuating arrangement or decouples the actuating arrangement from the detent pawl, wherein a crash element mounting is provided, said crash element mounting being configured as a linear guide and in which the crash element is displaceably guided.
In an embodiment, the crash element mounting is furthermore fitted onto the motor vehicle lock.
In an embodiment, the crash element has a guide section which is in guiding engagement with the crash element mounting, such that the guide section in cross section is of elongate design perpendicularly to the geometrical bearing axis of the crash element mounting, and/or in that the guide section in cross section is of substantially rectangular design perpendicularly to the geometrical bearing axis of the crash element mounting.
In an embodiment, the crash element has an engagement section for the engagement with the component of the motor vehicle door, which component has undergone crash-induced deformation, such that that the engagement section has an engagement surface which furthermore protrudes laterally over the crash element, such that the engagement section is of substantially plate-like design, such that the plate-like engagement section extends substantially perpendicularly to the geometrical bearing axis of the crash element mounting.
In an embodiment, the crash element is prestressed, such as by means of a spring arrangement, into an inoperative position from which the crash element can be adjusted into the crash position.
In an embodiment, the crash element has a supporting section which furthermore supports the spring arrangement in relation to the motor vehicle lock, such that the supporting section is arranged to the side of the guide section.
In an embodiment, the crash element is clipped into the crash element mounting.
In an embodiment, the actuating arrangement has a actuating lever such as a pivotable actuating lever, such as an outer actuating lever, the actuation of which brings about lifting of the detent pawl, and in that the crash element in the crash position blocks the actuating lever in the actuating direction.
In an embodiment, the crash element, during the adjustment thereof into the crash position, is adjusted, such as pushed, between the detent pawl and actuating arrangement and can be positionally fixed support such that at least some of the force flux of the blocking force blocking the detent pawl and the actuating arrangement can run via the support and outside the crash element mounting.
In an embodiment, the support is arranged immovably on the motor vehicle lock, such that the support is arranged on a housing plate, such as a back plate, of the motor vehicle lock.
In an embodiment, the actuating lever can be pivoted about an actuating lever axis, and in that the geometrical bearing axis of the crash element mounting is positioned in relation to the actuating lever axis, such that the geometrical bearing axis of the crash element mounting is positioned in relation to the actuating lever axis by an angle which lies within a range of between approximately 30° and approximately 60°, such as at approximately 45°.
In an embodiment, the crash element, during a crash-induced adjustment into the crash position, is destroyed in such a manner that the blocking of the detent pawl and of the actuating arrangement is ceased after the crash accelerations have occurred.
In an embodiment, the invention provides a motor vehicle lock for a motor vehicle door arrangement, wherein a lock latch and a detent pawl assigned to the lock latch are provided, wherein the lock latch can be brought into an open position and into a closed position, wherein the lock latch in the closed position is in or can be brought into engagement with a striker or the like, wherein the detent pawl can be brought into an engaged position in which said detent pawl fixes the lock latch in the closed position, and wherein the detent pawl can be lifted into a release position in which said detent pawl releases the lock latch, wherein the detent pawl can be brought into the release position by means of an actuating arrangement, wherein a crash element is provided, said crash element, in order to avoid a crash-induced lifting of the detent pawl with a component of the motor vehicle door arrangement, such a door outer skin, can be adjusted by the crash-induced deformation of said component into a crash position, and in that, for this purpose, the crash element in the crash position blocks the detent pawl and/or the actuating arrangement, wherein a crash element mounting is provided for the crash element, and in that the crash element, during the adjustment thereof into the crash position, is adjusted, such as pushed, between the component to be blocked by the crash element and such as positionally fixed support, such that at least some of the force flux of the blocking force can run via the support and outside the crash element mounting.
In an embodiment, the support is arranged immovably on the motor vehicle lock, such that the support is arranged on a housing part of the motor vehicle lock, such that the support is arranged on a plastics housing part, such as on a plastics cover, of the motor vehicle lock, or in that the support is arranged on a housing plate, such a back plate, of the motor vehicle lock.
In an embodiment, the adjustability of the crash element at any rate also originates, such as exclusively, from a deformability of the crash element, such that the deformability of the crash element is at least partially an elastic deformability.
In an embodiment, the deformability of the crash element originates from at least a local structural weakening of the crash element, such that the crash element is at least partially composed of bending elements, such as elastic wall elements.
In an embodiment, the crash element is of flexible design at least in a region of the crash mounting.
In an embodiment, the crash element mounting furthermore fixes the crash element on the motor vehicle lock.
In an embodiment, the crash element mounting has at least one pivot bearing.
In an embodiment, the crash element is designed as a lever which can be pivoted via the crash element mounting.
In an embodiment, the crash element is designed as a bow which is at any rate suspended via the crash element mounting at two suspension points.
In an embodiment, the crash-induced deformation of a component of the motor vehicle door arrangement, such as a door outer skin, causes a force from the component to act on the crash element, the line of dynamic effect of which force runs past at least one of the two suspension points of the crash element.
In an embodiment, the crash element has a blocking lug which, when the crash element is in the crash position, blocks the detent pawl and/or the actuating arrangement, such that, during a crash-induced adjustment of the crash element, the blocking lug executes a substantially linear movement.
In an embodiment, a delimitation is provided for the blocking lug, said delimitation delimiting the movability of the blocking lug in the event of a crash.
In an embodiment, a motor vehicle door arrangement comprises a motor vehicle door and a motor vehicle lock assigned to the motor vehicle door.
In an embodiment, the motor vehicle door has a door outer skin, and in that the crash element is arranged with an engagement section in the direct vicinity of the door outer skin, such that a gap which is smaller than approximately 20 mm, or such that the gap is smaller than approximately 10 mm, is provided between the crash element and the door outer skin.
The invention is explained in more detail below with reference to a drawing illustrating just one exemplary embodiment. In the drawing
The motor vehicle lock 1 illustrated in the drawing is assigned to a motor vehicle door arrangement 2 which, in addition to the motor vehicle lock 1, comprises a motor vehicle door 2a. With regard to the broad understanding of the term “motor vehicle door”, reference should be made to the introductory part of the description. The motor vehicle door 2a can be a side door of a motor vehicle.
The motor vehicle lock 1 is equipped with the customary locking elements—lock latch 3 and detent pawl 4. The lock latch 3 can be brought into an open position and into a closed position shown in
The detent pawl 4 can be brought into the engaged position which is illustrated in
It should be emphasized that the illustration of the motor vehicle lock 1 in
In principle, in the event of a crash, as explained further above, the detent pawl 4 may be undesirably lifted. A cause thereof may be the crash accelerations which occur in the event of a crash and act, for example, on an actuating lever 6a or on a door handle, in particular outside door handle, assigned to the actuating lever 6a. A further cause thereof may be the deformations, which occur in the event of a crash, of components which, in the event of a crash, possibly come into engagement with such an actuating lever 6a or the like.
The motor vehicle lock 1 is equipped with a crash element 8 which, in order to avoid a crash-induced lifting of the detent pawl 4 with a component 9 of the motor vehicle door 2a, such as a door outer skin 2b, can be adjusted by the crash-induced deformation of said component into a crash position. In the illustration shown in
In the case of a side impact S, a crash-induced deformation of the door outer skin 2b occurs, as a result of which the crash element 8 is adjusted into a crash position. The position of the crash element 8 during normal operation is shown in
In order to avoid a crash-induced lifting of the detent pawl 4 occurring, the crash element 8 in the crash position can block the actuating arrangement 6.
Alternatively or in addition, it can be provided that the detent pawl 4 is blocked by the crash element 8.
However, instead of the blocking of the components mentioned, provision may also be made for an adjustment of the crash element 8 into the crash position to bring about a decoupling of the actuating arrangement 6 from the detent pawl 4.
In principle, the blocking or decoupling can take place directly by means of the crash element 8. In an embodiment, the relevant effect originates from an element coupled to the crash element 8.
It is essential that a crash element mounting 11 is provided, said crash element mounting being designed as a linear guide and in which the crash element 8 is displaceably guided. The crash element mounting 11 is aligned along a geometrical bearing axis 12, as can best be gathered from the illustration according to
An overall view of
In the exemplary embodiment illustrated in
The engagement section 14 can show an engagement surface 15 which furthermore protrudes laterally over the crash element 8. “Laterally” means a direction perpendicularly to the geometrical bearing axis 12.
In order to be able to ensure an optimum absorption of force, in particular over a relatively large planar region, the engagement section 14 can be of substantially plate-like design. As discussed above, the plate-like engagement section 14 furthermore protrudes laterally over the crash element 8 such that the plate-like engagement section 14 extends substantially perpendicularly to the geometrical bearing axis 12. The plate-like engagement section 14 here is aligned substantially concentrically with respect to the geometrical bearing axis 12.
The crash element 8 can be a single-piece element which, in an embodiment, is produced from a plastics material, in particular by a plastics injection moulding process. In principle, however, it is also conceivable for the crash element 8 to be of multi-part design.
During normal operation, the crash element 8 is in the inoperative position which is shown in
In order to support the spring arrangement 16 in relation to the motor vehicle lock 1, the crash element 8 is furthermore equipped with a supporting section 17 which can be arranged to the side of the guide section 13. In an embodiment, the supporting section 17 is arranged on both sides of the guide section 13, and therefore the spring arrangement 16 is supported symmetrically with respect to the geometrical bearing axis 12. A tilting of the crash element 8 in the crash element mounting 11 can therefore be countered.
In an embodiment, the spring arrangement 16 has two helical compression springs 16a, 16b which are supported via the supporting section 17 arranged on both sides of the guide section 13.
A spring receptacle 18, which in each case has a centering spike 19a, 19b for the helical compression springs 16a, 16b, is provided on the crash element mounting 11.
In the context of particularly simple installation, the crash element 8 is clipped into the crash element mounting 11. For this purpose, resilient latching elements 20 are provided, said latching elements latching into rigid counterlatching elements 21 during the installation of the crash element 8. In the exemplary embodiment illustrated, the resilient latching elements 20 are arranged on the crash element mounting 11 and the rigid counterlatching elements 21 are arranged on the guide section 13. This can also be provided the other way around.
In the fitted state, the spring arrangement 16 is supported at one end on the crash element guide 11 and at the other end on the supporting section 17 of the crash element 8. The crash element 8 conducts away the prestressing via the latching elements 20 and the counterlatching elements 21 in turn to the crash element guide 11.
In the exemplary embodiment illustrated, the installation of the crash element 8 originates from pushing the guide section 13 into the crash element guide 11. Said pushing-in takes place counter to the prestressing of the spring arrangement 16 until the latching elements 20 latch into the counterlatching elements 21. Tools are advantageously not required for this installation operation of the crash element 8.
It has furthermore already been explained above that the crash element 8 can obtain both a decoupling function and a blocking function. In an embodiment, the crash element 8 obtains a blocking function. Specifically, the actuating arrangement 6 is equipped with an actuating lever 6a which can be pivotable and the actuation of which brings about a lifting of the detent pawl 4. The actuating lever 6a here is an outer actuating lever which is coupled via the Bowden cable 7 to an outside door handle (not illustrated). In principle, the actuating lever 6a can be any actuating lever 6a, for example an inner actuating lever 6a. It is merely essential here that the actuation of the actuating lever 6a brings about a lifting of the detent pawl 4 and that the crash element 8 in the crash position (
A particularly interesting aspect in the case of the illustrated motor vehicle lock, which obtains independent importance within the context of further teaching, is the fact that at least some of the force flux of the blocking force occurring during the blocking by the crash element 8 runs substantially outside the crash element mounting 11. This is realized in an embodiment by the crash element 8, during the adjustment thereof into the crash position, being adjusted, such as pushed, between the actuating arrangement 6 and an in particular positionally fixed support 25. A crash case of this type is shown at the top left in the detailed illustration of the design shown in
In an embodiment, essentially the entire force flux of the above blocking force runs via the support 25 and outside the crash element mounting 11, and therefore the crash element mounting 11 can be of weak design, as discussed above.
It is also conceivable for a certain play to be present between the crash element 8 in the crash position and the support 25 if crash forces are not acting on the actuating lever 6a. Only when crash forces act on the actuating lever 6a is the play eliminated, possibly by deformation of part of the crash element mounting 11, such that the force flux can run via the support 25.
It does not matter in the case of the profile according to the proposal of the force flux of the blocking force outside the crash element mounting 11 whether the detent pawl 4 or the actuating arrangement 6, in particular the actuating lever 6a, is blocked by the crash element 8.
The support 25 can be an immovable surface on the motor vehicle lock 1, which the surface can be arranged on a housing plate, here on the back plate 26, of the motor vehicle lock 1. Other variants for realizing the rigid support 25 are conceivable.
As already discussed, the actuating lever 6a can be designed to be pivotable about an actuating lever axis 6b, wherein the geometrical bearing axis 12 of the crash element mounting 11 is positioned in relation to the actuating lever axis 6b. The geometrical bearing axis 12 of the crash element mounting 11 can be positioned in relation to the actuating lever axis 6b by an angle which lies within a range of between approximately 30° and approximately 60°, such as at approximately 45°. This positioning of the geometrical bearing axis 12 by an above angle in relation to the actuating lever axis 6b has proven particularly advantageous for the region of use of the side doors.
In an embodiment, it is provided that the crash element 8, during a crash-induced adjustment into the crash position, is destroyed in such a manner that the blocking of the detent pawl 4 and of the actuating arrangement 6 is ceased after the crash accelerations have occurred. This can be provided, for example, by the fact that, although the crash element 8 is broken open during a single adjustment of the crash element 8 into the crash position, a certain interlocking connection initially keeping the crash element stable remains. Only after the loading situation changes does the crash element 8 “disintegrate” into its individual parts such that the blocking of the blocking arrangement 6 is ceased.
A further teaching, which likewise obtains independent importance, claims a motor vehicle lock 1, in which a crash element mounting 11 is provided, in which the crash element 8 is guided, wherein at least some of the force flux of the blocking force can run in the above manner via the support 25 and outside the crash element mounting 11. Reference should be made to all of the explanations in this regard concerning the motor vehicle lock 1 according to the proposal.
The motor vehicle lock 1 shown in
The detent pawl 4 can be brought into the engaged position which is illustrated and in which said detent pawl fixes the lock latch 3 in the closed position, which is likewise illustrated in
The detent pawl 4 can also be brought here into the release position by means of an actuating arrangement 6, wherein the actuating arrangement 6 is equipped with an actuating lever 6a which is illustrated in
An overall view of
It is also essential in the case of the motor vehicle lock 1 illustrated in
Of particular interest in the case of the exemplary embodiment illustrated in
Specifically, the support 25, as likewise shown in
It is interesting in the exemplary embodiment which is illustrated in
In principle, it is conceivable for the crash-induced deformation of the crash element 8 to be a permanent deformation, in particular a plastic deformation. It is also conceivable that, as discussed above, the crash element 8 at least partially breaks and is destroyed by the crash-induced deformation. However, in an embodiment, the deformability of the crash element 8 is at least partially an elastic deformability. As a result, the behaviour of the crash element 8, in particular the deformation distance thereof, can best be foreseen.
With the above-discussed deformability of the crash element 8, it can basically be provided that the crash element mounting 11 furthermore fixes the crash element 8 on the motor vehicle lock 1. A degree of freedom of movement for the crash element 8 then arises exclusively from the deformability of the crash element 8.
However, the crash element mounting 11 can have at least one pivot bearing 32, 33, such as two pivot bearings 32, 33. Since pivoting movements occur here only in an exceptional situation, namely in the event of a crash, it suffices to design the pivot bearing or pivot bearings 32, 33 as frictional bearings.
It is conceivable in this connection for the crash element 8 to be designed as a lever which is pivotable via the crash element mounting 11. The advantage according to the proposal continues to remain here that, by the crash element 8 being supported via the support 25, an only small loading of the pivot bearing occurs in the event of a crash.
The bow-like crash element 8 is of arcuate design at least in a region between the two suspension points 34, 35 such that said crash element permits engagement with the relevant component 9 of the motor vehicle door arrangement 2 from different directions 36a, b, c.
The arrangement can be made in such a manner that, by means of the crash-induced deformation of the relevant component 9 of the motor vehicle door arrangement 2, such as a door outer skin 2b, a force from the component 9 acts on the crash element 8, the line of dynamic effect of which force runs past at least one of the two suspension points 34, 35 of the crash element 8.
The crash element 8 then can have a blocking lug 37 which, with the crash element 8 in the crash position (
It is also possible in principle, as discussed above, for the detent pawl 4 to be blocked. As likewise discussed above, the blocking takes place counter to the support 25, and therefore at least some of the force flux of the blocking force can run via the support 25 and outside the crash element mounting 11.
Of particular interest in the exemplary embodiment which is illustrated is the fact that the deformability of the crash element 8 is designed in such a manner that, in the event of a crash, the blocking lug 37 executes a substantially linear movement. The adjustment of the crash element 8, here of the blocking lug 37 of the crash element 8, can therefore be adjusted in a particularly space-saving manner between the component 4, 6 to be blocked by the crash element 8 and a support 25 which can be positionally fixed.
It should be emphasized that, in the present case, the term “blocking lug” should be understood in broad terms and comprises any component which can be adjusted between two components in order to produce a force flux between said two components.
In the exemplary embodiment illustrated in
In an embodiment, the blocking lug 37 is already in engagement with the delimitation 38 during normal operation, in particular projects into the slot-like formation 38, and therefore, in the event of a crash, the blocking lug 37 is already “inserted” into the slot-like formation 38.
Finally, the manner of operation of the motor vehicle lock illustrated in
In order to avoid a crash-induced lifting of the detent pawl 4 occurring, it is specifically provided that the crash element 8 in the crash position blocks the actuating arrangement 6. For the blocking, the actuating lever 6a is equipped, as in
As likewise discussed in conjunction with
It should also be emphasized that, for the explained principle of blocking against a support 25, it does not matter whether, as here, the actuating arrangement 6 or the detent pawl 4 is blocked by the crash element 8.
Finally, in an embodiment, the crash element 8 can be designed as a wire or strip which is bendable in a spring-elastic manner. An above-discussed deformability can therefore be realized in a particularly cost-effective manner. As likewise discussed above, the wire or strip can also be bent to form a bow or the like.
A further teaching, which likewise obtains independent importance, claims a motor vehicle door arrangement with a motor vehicle door 2a and a motor vehicle lock 1 assigned to the motor vehicle door 2a. The motor vehicle lock 1 is an above-described motor vehicle lock 1 according to the proposal, and therefore to this extent reference should be made to the explanations above.
In an embodiment, the motor vehicle door 2a has a door outer skin 2b, wherein the crash element 8, as illustrated in
In an embodiment, the motor vehicle door arrangement is equipped with an outside door handle which can be coupled to the actuating lever 6a via the Bowden cable 7. The arrangement here is made in such a manner that, in the event of a side impact, the outside door handle basically tends to lift automatically because of the prevailing crash accelerations and the deformation of the door outer skin 2b leads to an adjustment of the crash element 8 into the crash position. Given a suitable design, the crash element 8 can be adjusted into the crash position before the actuating lever 6a is actuated by the tendency of the outside door handle to automatically lift. A crash-induced opening of the associated motor vehicle door can therefore be effectively avoided.
Number | Date | Country | Kind |
---|---|---|---|
10 2012 025 053.3 | Dec 2012 | DE | national |
20 2013 002 811.4 | Mar 2013 | DE | national |