EP3117057A1 - Motor vehicle door lock - Google Patents

Abstract

The invention relates to a motor vehicle door lock comprising a locking mechanism (1, 2) that essentially consists of a rotary latch (1) and a pawl (2). Furthermore, an actuation lever assembly (4, 5, 6, 7) acts on the locking mechanism (1, 2). Finally, a locking lever (10) blocks the locking mechanism (1, 2) at least when acceleration forces of a given magnitude occur, e.g. during an accident (crash), said locking lever (10) being elastically coupled to the actuation lever assembly (4, 5, 6, 7). According to the invention, the locking lever (10) additionally controls a blocking unit (13, 14, 15) for the locking mechanism (1, 2).

Description

 Power Vehicles Description:

The invention relates to a motor vehicle door lock, with a locking mechanism consisting essentially of catch and pawl, also with an operating lever mechanism operating on the locking mechanism, and with a locking lever which blocks the locking mechanism at least when acceleration forces of predetermined magnitude occur, for example in the event of an accident ("crash") wherein the locking lever is elastically coupled to the actuating lever mechanism.

In motor vehicle door closures with an inertia lock or an "inertia lever", the primary concern is to prevent inadvertent opening of the locking mechanism, in particular in the event of an accident or crash. In fact, acceleration forces occur in accidents, which typically exceed 5 g (with g of acceleration due to gravity).

As a consequence thereof act on door handles, in particular the outer door handle, high forces that can cause unintentional locking mechanism without countermeasures. This is particularly disadvantageous for Kraftfah rzeuginsassen and must be prevented because the motor vehicle doors have additional security measures such as a side impact protection, side airbags, etc., which naturally no effect (more) can unfold with the door open for the occupants. The locking lever in this context, due to its inertial forces, typically ensures that the operating lever mechanism and thus locking mechanisms are blocked and accordingly an associated motor vehicle door does not experience an unintentional opening. In the prior art according to DE 10 2008 063 318 A1 a door closing device for motor vehicles is described, which has a jack,

CONFIRMATION COPY one end of which is hinged to an outside handle lever. At the other end of the jack, a counterweight is mounted to generate a force toward the outside of the door in the event of a vehicle collision, in such a way that the outside handle lever performs only a resilient movement.

In the context of the generic state of the art according to DE 10 2011 010 815 A1, the locking lever acts in normal operation and in the event of a crash, the pawl for the locking mechanism, in the direction of their blocking position. Only in the opening normal operation of the locking lever allows the release position of the pawl and thus the locking mechanism. In this way, the reliability is to be increased at the same time simple structure, because the locking lever undergoes a deflection during normal operation of the operating lever mechanism. As a result, every normal actuation and triggering operation corresponds to the fact that the locking lever is moved and any corrosion, caking, etc. can not occur. That has proven itself.

Despite this convincing solution in the generic state of the art, there is an additional need for improvement in the event that the motor vehicle door or the associated motor vehicle door lock tends to so-called "bouncing". For example, if a motor vehicle door lock closed very quickly, so that the locking pin or lock holder interacts with the locking mechanism at high speed, it may happen that the catch opens again or remains open before the pawl engages in the main catch. That is, the sequence of functions "Vorrast-Hauptrast" is passed through so fast and with such great force that the associated motor vehicle door bounces from its end position as it were, but the pawl (not yet) has fallen into the main catch of the catch. It comes to the already mentioned bouncing. As a result, the vehicle door can jump up again.

Of course, such a popping of the motor vehicle door as well as indifferent functional states of the locking mechanism must be avoided in any case for the reasons already described above. Although there are already approaches to this effect with the DE 10 2012 203 734 A1 to catch the previously described "bouncing" and to prevent. However, in this context, a complex mechanical solution is pursued and lacks approaches to precaution in the event of a crash. Here, the invention aims to provide a total remedy.

The invention is based on the technical problem of further developing such a motor vehicle door lock in such a way that, when the mass lock or the locking lever functions properly, additional indifferent functional states and in particular the so-called "bouncing" are prevented taking into account a simple construction.

To solve this technical problem, the invention proposes in a generic motor vehicle door lock, that the locking lever is not only elastically coupled to the operating lever mechanism, but additionally controls a blocking unit for the locking mechanism.

In the context of the invention, the locking lever thus comes to a multiple and especially two-fold function. First of all, the locking lever primarily and as usual ensures that at least in an accident or crash, the locking is blocked. For this purpose, the invention is comparable, as described in the generic DE 10 201 1 010 815 A1. Because the locking lever is also acted upon or pivoted by the elastic coupling with the operating lever mechanism at each actuation of the operating lever mechanism in normal operation. This ensures that any normal actuation and release operation to a movement of the locking lever corresponds. Any corrosion, caking, etc. can not occur.

Moreover, the elastic coupling of the locking lever with the actuating lever mechanism ensures that the locking lever can remain at rest during the occurring acceleration forces of predetermined magnitude, for example in the event of an accident or crash, and any movements of the actuating lever mechanism are permitted. This is ensured by the elastic coupling. However, such movements of the operating lever mechanism are not transmitted to the locking lever or blocked by him locking mechanism. In detail may be elastically coupled to the locking lever with an external operating lever as part of the operating lever mechanism.

At this point, a leg spring has proven to be particularly favorable. The leg spring may be mechanically connected with its one leg with the locking lever, while the other leg of the leg spring rests on the external actuating lever.

An action on the actuating lever mechanism and consequently the external actuating lever in normal operation now leads via the intermediate leg spring to the locking lever following and also being able to follow the movements of the external actuating lever or, in general, the movements of the actuating lever mechanism. As a result, the locking lever is transferred from a position blocking the locking mechanism into a position releasing the locking mechanism. In this way, the locking mechanism (spring-assisted) can open and release a previously captured locking pin or the lock holder.

If, on the other hand, an accident or crash occurs, the locking lever remains in its locking position due to its inertia. This applies even if the operating lever mechanism or the external supply lever applied via the already mentioned leg spring the locking lever. Because the forces acting on the locking lever in the accident inertia forces are significantly larger than the force exerted by the spring on the locking lever spring forces.

As previously explained, the locking lever is elastically coupled to the operating lever mechanism, usually with the external operating lever as part of the operating lever mechanism. According to the invention, the locking lever now takes on an additional secondary function to the effect that the locking lever controls the blocking unit for the locking mechanism. That is, depending on the position and movement of the locking lever, the blocking unit is acted upon for the locking accordingly. In fact, the blocking unit may ultimately be transferred by means of the locking lever into a blocking or releasing position.

For this purpose, the blockade unit generally interacts with the catch. In normal operation, the blocking unit and the locking lever are separated from each other. At the same time the previously blocked lock is released. That is, in normal operation, the locking lever follows the movements of the actuating lever mechanism via the elastic coupling with the actuating lever mechanism and at the same time the locking lever and the blocking unit are mechanically separated from one another. As a result, the previously blocked lock is released in total. In the event of a crash, on the other hand, the blocking unit and the locking lever remain engaged with each other. Consequently, the locking mechanism remains in its locked position.

The blocking unit is usually formed in several parts with a blocking lever, a transmission lever and a clutch lever. The transmission lever is usually designed as the blocking lever connecting the clutch lever to the transmission slide. The blocking lever is in detail mostly elastically coupled with the transmission lever. For elastic coupling may be provided a prestressed spring or return spring.

The blocking lever as part of the blocking unit interacts with the locking lever. In contrast, the clutch lever is generally engaged with the catch. In normal operation, the clutch lever releases the catch only when the locking lever in conjunction with the blocking lever exits the previously blocked operating lever mechanism. At the same time, the already described mechanical separation of the locking lever and the blocking lever corresponds to this. In general, the locking lever in conjunction with the blocking lever jointly ensure that a release lever is blocked as part of the operating lever mechanism.

Finally, it has proven useful if the pawl and the actuating lever mechanism are mechanically connected to one another via at least one coupling element. In most cases, the pawl is mechanically connected to the previously mentioned release lever as part of the operating lever mechanism via the at least one coupling element. The coupling element may be a foot protruding from the release lever or else a pin which engages in a recess on the pawl. In most cases, two more or less diametrically opposed feet or pins with respect to a common axis of rotation of the pawl and release lever are realized. The feet or pins may also be formed on an additional plastic part, which is connected to the release lever.

Of course, as it were integral solutions are included in the invention. That is, those in which the feet or pins on the release lever (made of plastic) are directly present or are formed on this. The coupling between the respective foot or pin on the release lever and the associated recess on the pawl for their engagement may be positive and / or non-positive. In any case, a pivoting movement of the release lever is converted into a corresponding pivotal movement of the pawl about the common axis of rotation in this way. Because the release lever and the pawl are arranged parallel to each other or one above the other. As a result, the pawl leaves the previously caught catch, which then released (spring assisted) and releases the captured locking pin. In normal operation and with the locking mechanism engaged (pawl located in the main catch), the locking mechanism is practically blocked twice. On the one hand, the locking lever in conjunction with the blocking lever as part of the blocking unit ensures that the release lever and consequently the pawl mechanically coupled to the release lever are blocked. On the other hand, the clutch lever acts as a further component of the blocking unit on the rotary latch.

As a result, the "bouncing" already described above can no longer occur.

Because when the locking mechanism is closed as in the example described above by a fast and powerful closing movement of the associated motor vehicle door by the retracting lock pin or lock holder, ensures at least the clutch lever or generally the blocking unit that the catch is held in its closed position (main position) ,

Following or at the same time, the pawl can then securely engage in the main catch. Any opening movements of the rotary latch with not yet fallen into the main ratchet pawl are thus prevented.

The locking lever is now according to the invention not only elastically coupled to the operating lever mechanism, but also controls the blocking unit for the locking mechanism. In fact, the locking lever from the previous already provides discussed closed position of the locking mechanism respectively the catch that in normal operation not only the operating lever mechanism or the previously blocked by means of the locking lever release lever is released. But in normal operation, the locking lever and the blocking unit are also separated from each other. As a result, the blockade unit leaves its previously occupied and the locking or the catch fixing position. This releases the previously blocked lock.

Because with the separation of locking lever and blocking unit in normal operation from each other is accompanied by a spring-assisted movement of the blockade unit, which separates the clutch lever and the catch from each other. The spring-assisted movement results from the blocking lever being elastically coupled to the transmission lever or transmission slide. As soon as the locking lever leaves its blocking position in normal operation, the locking lever and the blocking unit or the locking lever and the blocking lever are mechanically separated from each other. As a result, the spring connected to the blocking lever and biased spring or return spring for the elastic coupling of the blocking lever with the transmission lever ensure that the Ü transfer slider learns a linear application of the spring in question. Since the transfer slider is pivotally coupled to the clutch lever, which in turn holds the catch, the released from the locking lever in conjunction with the blocking lever and mechanically coupled to the pawl release lever not only the catch for (spring assisted) opening movements free. But this opening movement of the catch is simultaneously supported by the clutch lever respectively admitted, which in turn is acted upon by the transfer slider accordingly. In the event of a crash, the locking mechanism remains in its locked position. In this blocked position is in detail the trigger lever or the actuating lever end of the blockade lever, which in turn is held in this position by means of the locking lever. In the event of a crash, the locking lever remains in this position due to the attacking inertial forces, even if the operating lever factory respectively of the example acting on the locking lever external operating lever is deflected. Such deflections only lead, when the locking lever remains stationary, to the compression of the leg spring between the locking lever and the actuating lever mechanism or the external actuating lever in the example case.

Since the locking lever in the event of a crash fixes the blocking lever in its blocking position and consequently the release lever and with it the mechanically connected pawl are blocked, the locking mechanism can not open. In addition, the blockade unit ensures that in the described Blockadestellung the catch and with it the locking mechanism are fixed.

The blockade unit thus ensures overall that the locking mechanism remains in the closed position or main latching position and, moreover, that the previously mentioned bouncing is prevented. In addition, the position of the rotary latch is queried with the help of the blockade unit. In detail, the locking lever controls the blocking unit for the locking mechanism. If the locking lever is in the blocking position, the clutch lever additionally ensures that the locking mechanism retains its main locking position. Only when the locking lever is disconnected from the blocking unit in normal operation, the clutch lever releases the then opening catch. Here are the main benefits. In the following the invention will be explained in more detail with reference to a drawing showing only one exemplary embodiment; show it:

1 shows the motor vehicle door lock according to the invention with a closed locking mechanism,

Fig. 2A to 2C, the motor vehicle door lock of FIG. 1 at an opening operation in normal operation and

3A and 3B, the motor vehicle door lock according to FIGS. 2A to 2C in

 Crash.

In the figures, a motor vehicle door lock is shown, which has a locking mechanism 1, 2 of rotary latch 1 and pawl 2 in its basic structure. The rotary latch 1 and the pawl 2 are each mounted in a lock case 3. The lock case 3 is part of a motor vehicle door lock, which interacts with a locking pin or lock holder, not shown. The basic construction also includes an operating lever mechanism 4, 5, 6, 7 operating on the ratchet mechanism 1, 2. The actuating lever mechanism 4, 5, 6, 7 consists of an internal operating lever 4, a connecting lever 5, an external operating lever 6 and finally a Release lever 7 together. Of course, even more levers or elements can be realized, which is not shown in the embodiment and for reasons of clarity.

In order to open the locking mechanism 1, 2 located in the closed state or in the main locking position according to FIG. 1, either the inside operating lever 4 or also the outside operating lever 6 can be acted upon by a correspondingly connected inside door handle or outside door handle, respectively, as determined by the respective door handle Arrows in Fig. 1 is indicated. As a result This opening movement is largely linearly displaced in the direction indicated by the arrow with the help of the internal operating lever 4 of the connecting lever 5. In contrast, the external operating lever 6 undergoes an anti-clockwise pivoting about its axis or axis of rotation 8 during an opening operation.

Coaxially to the external actuating lever 6, the release lever 7 and the pawl 2 mechanically coupled to the release lever 7 are mounted in the exemplary embodiment. On the other hand, the rotary latch 1 has a respective own axis respectively axis of rotation 9 in the lock case 3.

The indicated in Fig. 1 opening movements of on the one hand the inner operating lever 4 and on the other hand the outer actuating lever 6 are each elastically transmitted to a locking lever 10 to be described in more detail below. For the elastic coupling of the inner actuating lever 4 and the acted upon by the internal operating lever 4 connecting lever 5 with the locking lever 10 provides a leg spring 11. The external operating lever 6, however, is coupled via a further leg spring 12 elastically with the locking lever 10 in question.

The locking lever 10 thus has the already described elastic coupling with the operating lever mechanism 4, 5, 6, 7. These are in the example and not limiting the two torsion springs 11, 12 are provided. In addition, the locking lever 10 ensures that the locking mechanism 1, 2 is blocked, at least when acceleration forces of a predetermined magnitude occur, for example in the event of an accident ("crash"). In fact, in the example shown, the design is such that the locking mechanism 1, 2 is blocked in the closed state by means of the locking lever 10 throughout. Only in an opening operation of the locking mechanism 1, 2 in normal operation is the lockout lever 10 so acted that the previously existing blockade of the locking mechanism 1, 2 lifted and the locking mechanism 1, 2 is opened.

For this purpose, the locking lever 10 according to the invention takes on an equally double function. Thus, the locking lever 10 is not only - as described - elastically coupled to the operating lever mechanism 4, 5, 6, 7, but controls the locking lever 10 in addition a blocking unit 13, 14, 15 for the locking mechanism 1, 2nd The blocking unit 13, 14, 15 interacts with the rotary latch 1 and ensures that the rotary latch 1 or the locking mechanism 1, 2 as a whole in the main latching position undergoes an additional backup. As a result, the rotary latch 1 conveyed, for example, during a closing operation of the locking mechanism 1, 2 into the main latching position can not (more) be unintentionally loaded in the opening direction. The "bouncing" already described above is thus prevented by means of the blocking unit 13, 14, 15.

In normal operation and to open the locking mechanism 1, 2, the blocking unit 13, 14, 15 on the one hand and the locking lever 10 on the other hand are mechanically separated from each other. As a result, the previously blocked locking mechanism 1, 2 is released. In contrast, the blockage unit 13, 14, 15 and the locking lever 10 remain in the event of a crash in engagement with each other or in engagement with each other and together ensure that the locking mechanism 1, 2 is blocked.

In detail, the blocking unit 13, 14, 15 according to the embodiment of multi-part design. In fact, the blocking unit 13, 14, 15 is composed of a blocking lever 13, a transmission lever 14 and finally a clutch lever 15. The transmission lever 14 is designed as the blocking lever 13 with the clutch lever 15 connecting transfer slide 14. That is, the transfer slider 14 performs primarily linear movements, as will be explained in more detail below. The blocking lever 13 interacts with the locking lever 10 to block the locking mechanism 1, 2nd In contrast, the clutch lever 15 ensures that the catch 1 is held in its main latching position and does not perform any unintentional openings, thus the previously already extensively described "bouncing" does not occur (anymore). The action of the clutch lever 15 is independent of the pawl 2, which normally holds the catch 1 in its main latching position (and pre-latching position).

The blocking lever 13 is elastically coupled to the transmission lever or transmission slide 14. For this purpose, a spring 16 is provided between the blocking lever 13 and the transfer slider 14. The spring 16 is formed as a prestressed return spring or prestressed spring 16. In fact, this is a leg spring, which is connected with one leg of the lock case 3, while the other leg on the transfer slider 14 operates such that it is acted upon in the figure representation of FIG. 1 with a rightward force.

The clutch lever 15 is the catch 1 and consequently the locking mechanism 1, 2 in normal operation only then released when the locking lever 10 in conjunction with the blocking lever 13, the previously blocked actuating lever mechanism 4, 5, 6, 7 or in the embodiment, the trigger lever 7 leaves as will be explained in more detail below with reference to FIGS. 2A to 2C in detail. Finally, it can be seen that the pawl 2 and the actuating lever mechanism 4, 5, 6, 7 or the local release lever 7 are mechanically connected to one another via at least one coupling element 17. In fact, two coupling elements 17 are realized at this point. In the case of the two coupling elements 17, it is evident from the enlarged view in FIG. 2C that teeth or pins on the release lever 7 engage in correspondingly shaped recesses in the pawl 2. It may be a positive and / or non-positive Coupling be realized. In any case, in this way, the pawl 2 follow pivotal movements of the release lever 7 about the common axis 8, as will be explained in more detail below. The operation is as follows. FIG. 1 shows the motor vehicle door lock according to the invention in the main latching position and when the locking mechanism 1, 2 is blocked. Starting from this closed position of the locking mechanism 1, 2, an opening operation will now be described with the aid of the external actuating lever 6 in the context of the functional sequence according to FIGS. 2A to 2C. In the context of FIG. 2A, a loading of an outer door handle (not shown) results in the outer actuating lever 6 being pivoted about its axis of rotation 8 in the counterclockwise direction.

As a result, this pivotal movement of the external actuating lever 6 is transmitted counterclockwise about the axis of rotation 8 to the leg spring 12. In fact, the leg spring 12 is connected with its one leg to the locking lever 10, while the other free leg rests on the external operating lever 6. The described pivotal movement of the external actuating lever 6 in the counterclockwise direction about its axis 8 now has the consequence that the corresponding rotational movement is transmitted to the locking lever 10 via the leg spring 12. As a result, performs the locking lever 10 in the transition from Fig. 2A to Fig. 2B also a pivotal movement in the counterclockwise direction, namely about its axis 18. As long as the locking lever 10 assumes its blockage position shown in FIG. 1, the locking lever 10 ensures that on the blocking lever 13 of the trigger lever 7 maintains its position and in particular can not perform a counterclockwise movement about the axis 8 associated opening movement. However, as soon as the locking lever 10 follows the counterclockwise movement of the external operating lever 6 in normal operation and also performs a counterclockwise movement about its axis 18, leaves a blocking lever 13 previously detaining nose 10a of the locking lever 10 the blocking lever 13. As a result, the blocking lever 13 can pivot in the transition from Fig. 2B to Fig. 2C in the counterclockwise direction, because the blocking lever 13 associated prestressed spring 16 performs an opening movement with its two legs. This opening movement of the leg spring 16 causes the fixed leg or fixed to the lock case 3 leg maintains its position, whereas the free leg acts on the transfer slider 14 with a force to the right, as indicated in Fig. 2C by an arrow.

In the context of normal operation or at the end of the opening movement by the external operating lever 6 in the context of FIG. 2C, therefore, the locking lever 10 and the blocking unit 13, 14, 15 are separated from each other. At the same time the locking mechanism 1, 2 is released. Because the trigger lever 7 can now perform an opening movement in the counterclockwise direction about the common axis with the external actuating lever 6 axis or axis of rotation 8. In addition, the external operation lever 6 takes the release lever 7 in its counterclockwise motion.

In addition, since the transfer slider 14 has been moved to the right in the illustration of FIG. 2C, the clutch lever 15 also performs a counterclockwise movement about its axis 19. The counterclockwise movement of the clutch lever 15 follows the opening of the rotary latch 1. Because the catch 1 can now ( spring-assisted) pivot about its axis 9 in a clockwise direction, because the pawl 2 has been lifted by the trigger lever 7 coupled to it from the catch 1. As a result, the locking mechanism 1, 2 assumes its open position as a whole, as the dashed Position of the catch 1 in Fig. 2C makes clear. A previously captured and unillustrated locking bolt is released.

In the case of an accident or in the event of a crash, the sequence of functions is configured as shown in FIGS. 3A and 3B. Here you can see that in the event of a crash, the outer door handle may be deflected by attacking inertial forces. As a result, the external operating lever 6 performs the already discussed counterclockwise movement about its axis 8 in the transition from FIG. 3A to FIG. 3B.

In this case, however, results from the counterclockwise movement of the external actuating lever 6, no action on the locking lever 10. Because the locking lever 10 maintains its position due to its inertial mass. In the same way, the locking lever 10 also ensures that the blocking lever 13 with the help of the nose 10a of the locking lever 10 also remains at rest. Consequently, the transfer slider 14 can perform no movement, which then applies in the same way for the clutch lever 15. That is, the ratchet 1, 2 is held in its locked position, because the release lever 7 by the locking lever 10 (in conjunction with the blocking lever 13) is held. In addition, the rotary latch 1 is also fixed by means of the clutch lever 15, which remains unchanged in its position. Any movements of the external actuating lever 6 are absorbed by the spring 12, which is compressed in this process.

Claims

claims: 1. Motor vehicle door lock, with a locking mechanism (1, 2) consisting essentially of a rotary latch (1) and pawl (2), further with a on the locking mechanism (1, 2) operating lever mechanism (4, 5, 6, 7), and with a blocking lever (10) which blocks the locking mechanism (1, 2) at least when acceleration forces of a predetermined magnitude occur, for example in the event of an accident ("crash"), wherein the locking lever (10) engages with the actuating lever mechanism (4, 5, 6, 7) is elastically coupled, characterized in that the locking lever (10) additionally controls a blocking unit (13, 14, 15) for the locking mechanism (1, 2). 2. Motor vehicle door lock according to claim 1, characterized in that the blocking unit (13, 14, 15) interacts with the rotary latch (1). 3. Motor vehicle door lock according to claim 1 or 2, characterized in that the blocking unit (13, 14, 15) and the locking lever (10) are separated from each other in normal operation and the previously blocked locking mechanism (1, 2) released. 4. Motor vehicle door lock according to one of claims 1 to 3, characterized in that the blocking unit (13, 14, 15) and the locking lever (10) in the event of a crash remain engaged with each other and block the locking mechanism (1, 2). 5. Motor vehicle door lock according to one of claims 1 to 4, characterized in that the blocking unit (13, 14, 15) in several parts with blocking lever (13), transmission lever (14) and coupling lever (15) is formed. 6. Motor vehicle door lock according to claim 5, characterized in that the transmission lever (14) as the blocking lever (13) with the coupling lever (15) connecting transfer slide (14) is designed. 7. Motor vehicle door lock according to claim 5 or 6, characterized in that the blocking lever (13) is elastically coupled to the transmission lever Ü (14). 8. Motor vehicle door lock according to claim 7, characterized in that for the elastic coupling of the blocking lever (13) with the transmission lever (14) a prestressed spring (16) is provided. 9. Motor vehicle door lock according to one of claims 5 to 8, character- ized in that the clutch lever (15) in normal operation, the rotary latch (1) releases only when the locking lever (10) in connection with the blocking lever (13) previously blocked Actuator lever mechanism (4, 5, 6, 7) leaves. 10. Motor vehicle door lock according to one of claims 1 to 9, characterized in that the pawl (2) and the actuating lever mechanism (4, 5, 6, 7) are mechanically connected to one another via at least one coupling element (17).