DE102021102591A1 - AUTOMOTIVE LOCK AND METHOD OF OPERATING SUCH AUTOMOTIVE LOCK - Google Patents

Abstract

The invention relates to a motor vehicle lock and a method for its operation, in particular a motor vehicle door lock. This is equipped with a locking mechanism (1) consisting essentially of a rotary latch and pawl and an actuating lever chain (2, 3, 4, 5, 11) for the locking mechanism, which has at least one actuating lever (2, 5), a coupling element (3) and a Has locking lever (4). In addition, at least one mass inertia element (6, 7) is implemented, which, at least in the event of a crash, transfers the clutch element (3) from its engaged to the disengaged state. According to the invention, in the event of a crash, the locking lever (4) is also unlocked as required.

Description

The invention relates to a motor vehicle lock, in particular a motor vehicle door lock, with a locking mechanism consisting essentially of a rotary latch and a pawl, also with an actuating lever chain for the locking mechanism, which has at least one actuating lever, a coupling element and a locking lever, and with at least one mass inertia element which at least in the event of a crash, the clutch element is transferred from its engaged state to its disengaged state.

The actuating lever chain for the locking mechanism usually ensures that after an outside door handle or inside door handle has been acted upon, the pawl is lifted from its latching engagement with the rotary latch. As a result, a locking bolt previously caught by the rotary latch is released. Since the motor vehicle lock is usually arranged inside a motor vehicle door, while the locking bolt is on the body side, this process leads directly to the associated motor vehicle door being able to be opened. This presupposes that the coupling element assumes its engaged state, so that as a result the actuating lever chain is mechanically closed.

In contrast, the disengaged state of the coupling element corresponds to the actuating lever chain being open. The mechanical connection from the previously mentioned outside door handle or inside door handle to the pawl is interrupted, so that when the clutch element is disengaged, operations of the inside door handle or outside door handle are ineffective.

With the help of the locking lever or locking element, the actuating lever chain can be transferred into a locked and unlocked state. The unlocked state of the locking lever corresponds to the actuating lever chain being mechanically closed. For this purpose, the locking lever usually works on the coupling element and ensures that this assumes its engaged position. In contrast, the locked state of the locking lever is part of the fact that the actuating lever chain is interrupted. In this case, the locking lever acts on the coupling element in such a way that it assumes its disengaged state.

In addition to the locking lever, the mass inertia element usually also works on the coupling element. At least in the event of a crash, the mass inertia element ensures that the clutch element is transferred from its engaged state to its disengaged state. As a result of this, the actuating lever chain is automatically and mechanically interrupted in the event of a crash. Any stresses caused by acceleration, in particular of the outside door handle, cannot therefore lead to an unintentional opening of the motor vehicle door. As a result, occupants in the associated motor vehicle are optimally protected. Because the mandatory safety devices in the motor vehicle door can only develop their full effect when they are closed.

In a motor vehicle lock and in particular motor vehicle door lock of the type described above according to the DE 10 2017 102 549 A1 the procedure is such that the coupling element is acted upon by a control lever, which in turn interacts with the mass inertia element. The control lever is guided in a control contour of the mass inertia element. In this way, the coupling element is forcibly guided overall. As a result, a defined control of the clutch behavior can be achieved and is made available.

The known procedure has proven itself in principle, but is increasingly reaching its limits in practice. This can be attributed to the fact that motor vehicles are typically locked nowadays during operation. If a crash then occurs, this is often associated with a failure of the energy supply, so that the respective motor vehicle lock retains its locked state. As a result, for example, the associated vehicle door can often not be opened by arriving rescue personnel and when operating the outside door handle, because after the end of the crash, the coupling element has indeed been transferred from its disengaged to the engaged state. However, the locking lever, which is still in the locked state, ensures that the actuating lever chain is still interrupted and the locking mechanism cannot be opened as a result.

Other and independent solutions are also presented in the prior art, which make it possible to unlock an associated actuating lever chain, particularly in the event of a crash. So busy WO 2019/210905 A1 with a motor vehicle lock in which the motor vehicle lock is unlocked and unlocked with the aid of a rotary movement of a driven pulley. The driven pulley is a part of a drive unit with a motor and the driven pulley driven by the motor.

This solution has basically proven itself because a blocking lever is additionally provided with which unlocking of the locking mechanism can be prevented. The blocking lever can be fixed in a blocking position with the help of a mass inertia element. This state of the art has also proven its worth in principle, but then and again it reaches its limits when the power supply fails in the event of a crash. Because then the blocking lever can no longer be acted upon with the help of the driven pulley, so that it is not possible to open the locking mechanism. This is where the invention aims to remedy the situation overall.

The invention is based on the technical problem of further developing such a motor vehicle lock in such a way that, in addition to perfect crash protection, the motor vehicle lock can also be opened in the locked state and if the power supply fails in the event of a crash.

In order to solve this technical problem, the invention proposes, in the case of a generic motor vehicle lock, that in the event of a crash the locking lever is additionally unlocked as required. In this way, the invention first of all ensures that in the event of a crash, the mass inertia element still and unchanged ensures that the clutch element is transferred from its engaged to the disengaged state. In addition and according to the invention and if required, the locking lever is unlocked in the event of a crash. As a result of this, it is ensured after the end of the crash that on the one hand the clutch element is again transferred from its disengaged state assumed in the event of a crash to the engaged state. On the other hand, taking the unlocked position of the locking lever ensures that the actuating lever chain is unlocked after the end of the crash, so the locking mechanism can be opened, for example, via an outside door handle.

All of this works even if, in the event of a crash, the power supply for any locking drive or, in general, an electric motor drive has failed. In this context, the electric motor drive can nevertheless ensure the unlocking of the locking lever during the crash event and transfer the locking lever from its previously typically assumed “locked” position to the “unlocked” position. For this purpose, for example, an emergency energy source that is independent of the electrical energy supply in the motor vehicle may be provided, with the aid of which the electromotive drive is operated in the event of a crash in order to ensure the described unlocking of the locking lever. In principle, this can also be carried out and implemented using the electrical power supply of the motor vehicle, in that the locking lever is unlocked immediately at the start of the crash. The invention is based on the further knowledge that typically the start of the crash is detected with the aid of an acceleration sensor on the motor vehicle.

If the locking lever is then immediately unlocked using the electric motor drive, this is usually also possible using the vehicle's energy source, because the failure of the vehicle's energy source is only observed a certain time after the triggering of the crash. In any case, the locking lever can assume its unlocked position with the aid of the electric motor drive or locking drive if this is provided by an additional and conceivable emergency energy source independent of the motor vehicle energy source.

However, another and particularly inexpensive solution provides that the mass inertia element working on the coupling element or a further second mass inertia element ensures the unlocking of the locking lever. In other words, there is the possibility that in the event of a crash, the clutch element is transferred from its engaged state to its disengaged state by the first mass inertia element. With the help of the second mass inertia element, the locking lever is transferred from its "locked" position to the "unlocked" position in the event of a crash. This happens at least as needed, namely when the locking lever has previously assumed its “locked” position. If, on the other hand, the locking lever is in its “unlocked” position from the outset, such a procedure is generally not necessary.

In addition to the possibility of applying a first and a second mass inertia element to the coupling element and the locking lever independently of one another, the invention also provides the option of combining both processes using one and the same mass inertia element. Ultimately, this depends on whether the two processes should be correlated in time or whether a time interval is desired.

In fact, in the event of a crash, the unlocking of the locking lever and the disengagement of the coupling element can coincide in time or be different. In general, the procedure is such that the coupling element is disengaged first, followed by the unlocking of the locking lever. In any case, this ensures that in the event of a crash, any acceleration-related deflections, for example of the outside door handle, which may accompany them, do not result in an opening of the locking mechanism and thus of the motor vehicle door, which must be avoided at all costs. In contrast, the unlocking of the locking lever can take place without any problems in terms of time. Such a procedure is particularly recommended in the event that the locking lever works on the coupling element in order to avoid any mutual mechanical interference at this point.

In any case, the chronological sequence described above can be implemented and realized in a particularly simple and functional manner in that the coupling element is disengaged first and then the locking lever is unlocked, in that two different mass inertia elements are responsible for this. In general, one can of course also work in such a case with a single inertia element, in which case the unlocking of the locking lever has to be delayed, for example by a mechanical delay element interposed between the single inertia element and the locking lever. Since the mass inertia element, on the other hand, works directly and without such a mechanical delay element on the clutch element and transfers it from the engaged to the disengaged state in the event of a crash, the time sequence described above is still guaranteed.

As a rule, the locking lever is spring-biased in the direction of its unlocked state. A spring provided at this point thus ensures that the locking lever—without being acted upon, for example by the electric motor drive or by the mass inertia element—consistently assumes its unlocked state. In a comparable manner, the coupling element is usually also spring-biased in the direction of its engaged position. That is to say, a spring implemented at this point typically ensures that the coupling element—without being acted upon by the mass inertia element or the locking lever—continuously assumes its engaged position. That is, the mass inertia element or the locking lever work against the force of the spring acting on the coupling element in order to convert the latter from its engaged position into the disengaged position.

In detail, the design can then be made such that the mass inertia element follows any movements of the actuating lever during normal operation. Consequently, when the actuating lever is acted upon to act on the locking mechanism, the movement of the actuating lever is so slow that the mass inertia element can follow the movement of the actuating lever. In contrast, in the event of a crash, the mass inertia element cannot (any longer) follow the movements of the actuating lever. As a result, the mass inertia element ensures, either directly or indirectly via, for example, an additionally provided control element or a control lever, that the clutch element is transferred from its engaged state to the disengaged state. After the accelerations associated with a crash have ceased, the mass inertia element returns to its original position (“engaged”) associated with normal operation, so that the loading of the clutch element against the force of the spring then also ceases. The coupling element is accordingly returned towards its engaged position with the aid of the spring. As a result, the actuating lever chain is closed and the pawl can be lifted from its latching engagement with the rotary latch with the help of the outside door handle, so that the rotary latch then opens with spring support and releases a previously caught locking bolt. The same applies to a motor vehicle door.

Since in the event of a crash the locking lever has been unlocked at the same time, if it had previously assumed its locked state, the coupling element in the example described is not (or no longer) acted upon by the locking lever when it returns to the engaged state and may still be in the disengaged state detained. Rather, the locking lever that assumes the unlocked state ensures that the coupling element assumes the engaged state after the end of the crash, so that the actuating lever chain unlocked in this way can be actuated by arriving rescue personnel, for example with the help of the outside door handle, and the motor vehicle door can be opened. This is where the main advantages can be seen.

The invention is explained in more detail below with reference to a drawing that merely shows an exemplary embodiment. The only 1 shows the motor vehicle lock according to the invention in a general functional overview, reduced to the elements essential to the invention.

In the 1 a motor vehicle lock is shown, which is a motor vehicle door lock. For this purpose, the motor vehicle door lock is arranged in a motor vehicle door, not shown in detail, and interacts with one on the body, also not shown locking bolt. For this purpose, a ratchet mechanism 1 consisting essentially of a rotary latch and a pawl with the usual functionality is implemented.

An actuating lever chain 2, 3, 4, 5, 11 can also be seen. In fact, the actuating lever chain 2, 3, 4, 5, 11 is equipped with at least one actuating lever 2, 5. According to the exemplary embodiment, the operating lever 2 is an external operating lever 2 , while the operating lever 5 is designed as an internal operating lever 5 . As a result, the outside operating lever 2 can be acted upon with the aid of an outside door handle, which is not explicitly shown. In a comparable way, an inside door handle, which is also not explicitly shown, acts on the inside operating lever 5. The operating lever chain 2, 3, 4, 5, 11 also includes a coupling element 3 and a locking lever 4.

Finally, the basic structure includes at least one inertia element 6, 7 and an additional electric motor drive 8. The inertia element 6,7 ensures that, at least in the event of a crash, the coupling element 3 is transferred from its engaged to the disengaged state. According to the invention, with the help of the mass inertia element 6, 7, the function is additionally mapped that in the said crash situation the locking lever 4 is unlocked additionally and as required.

The electric motor drive 8 also works on the locking lever 4. In fact, the electric motor drive 8 is a central locking drive 8, with the help of which the locking lever 4 can be acted upon. It can be seen that according to the representation in the 1 the electric motor drive or central locking drive 8 can act on the locking lever 4 in two directions indicated by a double arrow, namely in its “unlocked” E or “locked” V position. A bistable spring or toggle spring, which is additionally provided at this point and is not expressly shown, supports this process.

The coupling element 3 is also equipped with a spring 9 . The spring 9 ensures that the coupling element 3 is spring-biased in the direction of its engaged position. The engaged position of the coupling element 3 corresponds to the unlocked position or E.

Finally, the locking lever 4 also has a spring 10. The spring 10 ensures that the locking lever 4 is spring-loaded in the direction of its unlocked state E. This is indicated by corresponding arrows in the 1 implied. The locking mechanism 1 can be acted upon overall with the aid of an additionally provided release lever 11, which in principle is also unnecessary. According to the exemplary embodiment, the release lever 11 belongs to the actuating lever chain 2, 3, 4, 5, 11.

It can be seen that in the illustrated embodiment, the inside actuating lever 5 can work directly on the release lever 11 in order to use it to lift the pawl that is in locking engagement with the rotary latch from the rotary latch when the locking mechanism 1 is in the closed state. As a result, the rotary latch moves directly into its open position and releases the previously caught locking bolt and the motor vehicle door can be opened. This applies both in normal operation and in the event of a crash.

In contrast, the conditions for the external operating lever 2 are different. Of course, this only applies as an example. That is to say, the inside operating lever 5 can also work and be designed in a manner comparable to the outside operating lever 2, which is not shown, however.

However, if the crash described above occurs, the first mass inertia element 6 according to the exemplary embodiment ensures that the clutch element 3 is transferred from its engaged to the disengaged state against the force of the spring 9 . This corresponds to the arrow representation in the 1 from position E or "unlocked" or engaged in direction V or "locked" and disengaged. According to the invention, the event of a crash now also corresponds, if necessary, to the locking lever 4 being unlocked if it is not already in the unlocked state. For this purpose, the further second mass inertia element 7 is implemented in the exemplary embodiment. Both mass inertia elements 6, 7 can in principle interact with a control lever, as is already outlined and discussed in the prior art according to FIG DE 10 2017 102 549 A1 is explained in detail.

The second inertia element 7 now ensures that, in the event of a crash, the locking lever 4 is transferred from its previously assumed “locked” position V to the “unlocked” position E. This is indicated by the associated arrow in the 1 which is oriented from the position "locked" V towards "unlocked" E. The spring 10 acting on the locking lever 4 may support this process, but is generally not necessary.

How it works is as follows. In normal operation, the locking lever 4 is in its "locked" position V. Since the locking lever 4 interacts with the coupling element 3, the coupling element 3 also takes its position V or is disengaged. For this purpose, the locking lever 4 works against the force of the spring 9, which spring-biases the coupling element 3 in the direction of its engaged position.

If a crash then occurs, the first mass inertia element 6 initially ensures that the clutch element 3 is disengaged. This can be done in such a way that the first mass inertia element 6 follows and can also follow the movements of the relevant actuating lever or external actuating lever 2 in normal operation and when the external actuating lever 2 is acted upon. In the event of a crash, the first mass inertia element 6 can no longer follow the movements of the actuating lever or external actuating lever 2, so that the first mass inertia element 6 transfers the coupling element 3 from its engaged or unlocked state E to the disengaged or locked state V, as shown by the corresponding arrows in the 1 imply.

Later or at the same time, the second mass inertia element 7 ensures that the locking lever 4 “locks” or V changes from its previously assumed state to the unlocked state or E. This is again indicated by corresponding arrows in the 1 implied. In this way, the motor vehicle lock is in the “unlocked” state E of the locking lever 4 even after the crash and the associated accelerations have ceased assumed disengaged state V is transferred back into the engaged state E again.

As soon as the coupling element 3 is engaged, the locking mechanism 1 can be opened using the external actuating lever 2. This is because the locking lever 4 simultaneously assumes its unlocked or E position, so that the locking lever 4 can no longer ensure that the coupling element 3 is held in the disengaged state and the actuating lever chain 2, 3, 4, 5, 11 is interrupted. After the crash, the locking mechanism 1 can be opened via the closed actuating lever chain 2, 3, 4, 5, 11, namely - also - via the external actuating lever 2. Opening the locking mechanism 1 via the internal actuating lever 5 is possible anyway and at any time . This ensures that the locking lever 4 assumes its unlocked position even in the event of an acceleration-related failure of the electrical energy supply of the electromotive drive or central locking drive 8 .

In principle, the electric motor drive or central locking drive 8 can also be used to unlock the locking lever 4 in the event of a crash, for example in such a way that the electric motor drive 8 is energized with an emergency energy source. This emergency energy source ensures that the electric motor drive 8 ensures and can also ensure the unlocking of the locking lever 4 even if the energy source in the motor vehicle fails. However, the assumption of the unlocking position of the locking lever 4 is usually realized and implemented in such a way that the second mass inertia element 7 takes care of this in the event of a crash.

Not shown is the further possibility that instead of the two mass inertia elements 6, 7, only one mass inertia element 6, 7 is used, as explained in the introduction to the description.

Reference List

1

lock

2, 3, 4, 5, 11

operating lever chain

2

operating lever (external operating lever)

5

operating lever (internal operating lever)

3

coupling element

4

locking lever

6.7

mass inertia element

8th

electric motor drive (central locking drive)

9, 10

Feather

11

release lever

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 102017102549 A1 [0006, 0030]
• WO 2019/210905 A1 [0008]

Claims (10)

Motor vehicle lock, in particular motor vehicle door lock, with a locking mechanism (1) consisting essentially of a rotary latch and a pawl, and also with an actuating lever chain (2, 3, 4, 5, 11) for the locking mechanism (1), which has at least one actuating lever (2nd , 5), a coupling element (3) and a locking lever (4), and with at least one mass inertia element (6, 7) which, at least in the event of a crash, transfers the coupling element (3) from its engaged to the disengaged state, characterized in that in the event of a crash, the locking lever (4) is also unlocked as required. Motor vehicle lock after claim 1 , characterized in that an electric motor drive (8) is provided for unlocking the locking lever (4). Motor vehicle lock after claim 1 or 2 , characterized in that for unlocking the locking lever (4) the mass inertia element (6) or a further second mass inertia element (7) is realized. Motor vehicle lock after claim 3 , characterized in that the mass inertia element (6, 7) interacts with a control lever. Motor vehicle lock according to one of Claims 1 until 4 , characterized in that the coupling element (3) is spring-biased towards its engaged position. Motor vehicle lock according to one of Claims 1 until 5 , characterized in that in normal operation the mass inertia element (6, 7) follows the movement of the actuating lever (2, 5). Motor vehicle lock according to one of Claims 1 until 6 , characterized in that in the event of a crash the mass inertia element (6, 7) does not (any longer) follow the movements of the operating lever (2, 5) and transfers the coupling element (3) from its engaged to the disengaged state. Motor vehicle lock according to one of Claims 1 until 7 , characterized in that the disengagement of the coupling element (3) and the unlocking of the locking lever (4) coincide in time or differ. Motor vehicle lock after claim 8 , characterized in that the coupling element (3) is disengaged first and then the locking lever (4) is unlocked. Method for operating a motor vehicle lock, in particular a motor vehicle door lock, with a locking mechanism (1) consisting essentially of a rotary latch and pawl, and also with an actuating lever chain (2, 3, 4, 5, 11) for the locking mechanism (1), which has at least one actuating lever (2, 5), a coupling element (3) and a locking lever (4), and with at least one mass inertia element (6, 7) which, at least in the event of a crash, transfers the coupling element (3) from its engaged to the disengaged state , characterized in that in the event of a crash, the locking lever (4) is unlocked additionally and as required.

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