EP3060735A1 - Motor vehicle door lock - Google Patents

Abstract

The invention relates to a motor vehicle door lock equipped with a locking mechanism (2, 3), an actuation lever mechanism (6a, 6b) acting on said locking mechanism (2, 3), and a locking element (14). The locking element (14) disables the actuation lever mechanism (6a, 6b) when accelerating forces (F) of a defined magnitude occur, for example in the event of an accident. According to the invention the locking element (14) is a transmission lever (14) which can be impinged upon by a locking unit (11, 12) and is located between the actuation lever mechanism (6a, 6b) and the locking mechanism (2, 3).

Description

 Motor vehicle door lock

Description:

The invention relates to a motor vehicle door lock, with a locking mechanism, further with an operating lever mechanism operating on the locking mechanism, and with a blocking element which sets the actuating lever mechanism inoperative when acceleration forces of a predetermined magnitude occur, for example in the case of an accident (crash case).

By centrifugal forces or corresponding mass barriers acted upon motor vehicle locking systems or motor vehicle door locks are known in many ways. Essentially, it is important to prevent inadvertent opening of the vehicle door equipped with the motor vehicle door lock in question during strong accelerations, as occur, for example, in the event of a crash. This is the only way to ensure that the occupants in the motor vehicle are maximally protected and, for example, safety devices such as side airbags etc. in the motor vehicle door develop their effect accurately.

One distinguishes in practice so-called active and passive systems. Active systems are distinguished by the fact that movement occurs both in the case of strong and at low acceleration of the lock kinematics or of the motor vehicle door lock and in particular of the actuating lever mechanism, in order to achieve a secure functional capability over the entire service life. In contrast, passive systems react only at unusually high acceleration, that is, in the event of a crash. All previously known centrifugal force or mass barriers to prevent unwanted door opening in the event of a crash require additional components that increase the weight of the vehicle door and the cost. Thus, for example, in the context of EP 2 133 496 A2, the associated outside door handle with a as Equipped with mass locking pivoting locking member. A corresponding handle can only be operated in a release position of the mass lock or the pivotable locking member. In the event of a crash, the handle is blocked. Due to the necessary and relatively complex constructed locking member not only the mass of the known outside door handle is significantly increased, but also not inconsiderable costs associated with this.

Although the generic state of the art according to DE 10 2010 049 393 A1 also works with an additional blocking element. However, this attacks directly on the locking mechanism and can therefore be made compact and small. In addition, the operating lever mechanism is not touched, so that its functional reliability undergoes no impairment. But this is done with a particularly solid worked blocking element, which increases the overall weight of the known motor vehicle door lock.

Thus, it is important overall not only to maintain the functional reliability of the blocking element over the entire service life of the motor vehicle door lock, but in the prior art ultimately no convincing solutions are made available which connect the inherently resisting requirements of the secure functionality with low weight and reduced costs. In addition, sometimes prescribe legal requirements that the crash must be controlled especially when unlocked motor vehicle door lock. This is where the invention starts.

The invention is based on the technical problem of further developing a motor vehicle door lock of the structure described at the beginning in such a way that, with perfect functionality, costs and weight are reduced compared to previous designs. To solve this technical problem, a generic motor vehicle door lock according to the invention is characterized in that the blocking element is designed as a can be acted upon by a locking unit transfer lever between the operating lever mechanism and the locking mechanism.

It can be worked in detail so that the locking unit works by means of a coupling lever on the transmission lever. As a rule, the transmission lever is in its "locked" position. For this reason, the design is further made so that the locking unit blocks the transmission lever motor in the "locked" position. This is done by a clutch lever.

That is, the function position "locked" of the motor vehicle door lock according to the invention is typically implemented and realized that the already mostly in its "locked" position located transmission lever with the help of the locking unit in this position "locked" motor blocks. Any movements of the transmission lever to open the locking mechanism are therefore "locked" in this position not possible. In contrast, the "unlocked" position of the locking unit and consequently of the motor vehicle door lock according to the invention on the whole means that the locking unit enables the transmission lever in the respective position "unlocked" to have a freewheel. That is, to realize the functional position "unlocked" the locking unit or acted upon by the locking unit clutch lever is moved by a motor so that the transmission lever with respect to the clutch lever can run a freewheel. In contrast, the clutch lever in question in the "locked" position ensures that the transmission lever is blocked. As already explained, the transmission lever assumes the position "locked" as the basic position or rest position. This has the consequence that a so-called normal operation first transferred the transmission lever with the help of the operating lever mechanism in its "unlocked" position. Here, the transmission lever is coupled to the operating lever mechanism. The further movement of the operating lever mechanism in this normal operation now opens the possibility that the pawl is lifted as part of the Gesperres indirectly or directly by means of the transmission lever of the rotary latch. That is, the transmission lever provides in the normal operation for a locking opening. For this corresponds a regular rotation of the blocking element or according to the invention of the transmission lever, so that caking, corrosion, etc. are not to be feared. Rather, the permanent reliability of the transmission lever is guaranteed. The fact that the transmission lever can be transferred from its "unlocked" position into the "locked" position by means of the locking unit, for example, also contributes to this. For this purpose, the locking unit operates by motor on the clutch lever, which pivots the transmission lever. This also ensures a regular actuation of the blocking element or according to the invention of the transmission lever. The locking unit can basically be a central locking unit.

In the event of a crash, the operating lever mechanism, in contrast, performs an idling relative to the transmission lever. That is, in the event of a crash, the transmission lever remains in its functional position "locked". So it does not happen that the operating lever mechanism and the transmission lever are mechanically connected by the clutch located between them. Rather, the transmission lever retains its position in the event of a crash, whereas the actuating lever mechanism pivots in contrast. As a result From this, the transmission lever can not open the locking mechanism either directly or indirectly and consequently develops the desired locking action.

In contrast, as already explained, the actuating lever mechanism, in a normal operation-in contrast to the crash case-transfers the transmission lever to the "unlocked" position for opening the locking mechanism. At the same time it comes with this normal operation that the operating lever mechanism is coupled to the transmission lever or engages the transmission lever relative to the operating lever mechanism. This allows the operating lever mechanism to work mechanically on the transmission lever and ultimately ensure in its further actuation that with the help of the pivoted transmission lever, the locking mechanism is opened directly or indirectly.

For this purpose, the operating lever mechanism and the transmission lever are hinged together. The realized at this point clutch is ensured by the articulated connection on the one hand and the actuating lever and the transmission lever interconnecting spring on the other hand. The spring may be a leg spring connected to a (joint) pin defining the articulated connection. In addition, a stop for the transmission lever is usually still provided. This stop may be stored stationary in a lock case or a lock housing.

Due to the interplay between the stop and the spring for resilient mechanical coupling between the operating lever mechanism and the transmission lever on the one hand ensures that in a normal operation and consequently "slow" loading of the operating lever mechanism of the transmission lever can follow this movement and is engaged accordingly compared to the operating lever mechanism. As a result, will the transmission lever is first unlocked and then used for the opening of the locking mechanism.

On the other hand, a "rapid" action on the operating lever mechanism (in the event of a crash) causes the spring forces to be overcome for coupling the actuating lever mechanism with the transmission lever and thus the actuating lever mechanism performs the freewheel already described in relation to the transmission lever which is "locked" in its "locked" position. This is the desired functionality for the representation of the crash safety and to prevent an unwanted opening of the locking mechanism.

Finally, it has proved to be particularly favorable when a center of mass of the transmission lever functioning as a blocking element and consequently a mass barrier is arranged in the region of its axis of rotation. In this case, the invention initially starts from the knowledge that the transmission lever can in principle perform pivoting movements about the rotation axis in question. In the context of the invention, only certain pivoting movements in connection with the stationary stop are possible, as will be explained in more detail below with reference to the description of the figures.

Since the center of mass of the transmission lever is arranged in the region of the axis of rotation, on the one hand the transmission lever can be pivoted particularly simply or by small forces and on the other hand massive designs of the transmission lever can be dispensed with. Because such massively constructed mass barriers are typically (only) used where a shift of the center of gravity away from the axis of rotation is deliberately required. However, since according to the invention the center of gravity is arranged in the region of the axis of rotation, recourse can be made to a conventional or almost conventional design of the transmission lever, namely one in which the center of mass and the axis of rotation are approximately in line are, as is the case with most multi-armed pivoting levers. In fact, the transmission lever is designed as such a multi-arm pivoting lever. In this way, the motor vehicle door lock according to the invention initially has a significantly reduced weight compared to the prior art. Because the blocking element or the mass barrier is presently designed as a transmission lever, which in turn is designed in the form of a multi-arm lever with center of mass in the region of its axis of rotation. That is, additionally attached masses, a particularly massive design, etc. are expressly not required.

In addition, the transmission lever according to the invention is pivoted in a normal operation as well as in the course of locking each about its axis of rotation, so the reliability can be ensured over the entire life of the motor vehicle door lock secure. Another advantage is that the transmission lever is only mechanically connected to the opening of the locking mechanism in a normal operation with the operating lever mechanism by engaging. That is, for an operator, there are no significantly increased actuation forces at this point as consistently observed in the prior art active mass locks. The fact that according to the invention - as described - a massive design of the blocking element or transmission lever can be dispensed with contributes to this described low actuating force.

A further and particular advantage is that the blocking element or the transmission lever is, so to speak, functionally integrated in the motor vehicle door lock, that is, does not represent a separate component to be manufactured and additional. Rather, the transmission lever acts comparable to a triggering lever for the locking mechanism. Moreover, it is even conceivable that the transmission lever assumes a total of three functions, namely the function of the blocking element, the function of the release lever for the locking mechanism and finally the function of a locking lever.

Because in the position "locked" performs an actuation of the operating lever mechanism both in normal operation and in the event of a crash respectively not to the fact that the locking mechanism is opened or the transmission lever - in its function as a release lever - lifts the pawl of the catch. This ensures each locking unit, which blocks the transmission lever motor in the "locked" position. If, on the other hand, the locking unit is in the "unlocked" position and consequently the transmission lever can execute a freewheeling action relative to the clutch lever, then the normal operation corresponds to engaging the transmission lever in relation to the actuating lever mechanism and, as a triggering lever, upon further actuation of the actuating lever mechanism the pawl lifts off the catch.

That is, the operating principle of the mass or centrifugal force lock respectively the associated blocking element is as it were locked in the motor vehicle and in the present case - if you will - integrated into a local locking lever chain or a locking lever mechanism. Because the transmission lever ultimately reflects the positions "unlocked" and "locked" of the motor vehicle door lock according to the invention as a whole.

This integrated solution and the transfer of the mass lock on the locking lever mechanism is ultimately dispensed with an additional and extra to be made and mounted locking element. As a result, considerable costs are saved and can also be the weight of the motor vehicle door lock according to the invention compared to previous Significantly Reduce Management Guidelines. In addition, the assembly is simplified because the number of components could be reduced, resulting in a further cost advantage. In conjunction with the unchanged given and safe operation also seen over the entire life of the motor vehicle door lock overall special advantages are achieved.

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 in a detailed overview,

2A to 2C, the object of FIG. 1 in the "unlocked" position and in a normal operation,

3A to 3C, the object according to FIGS. 2A to 2C in the event of a crash and

4A to 4C, the motor vehicle door lock of FIG. 1 in its position

 "locked" and an associated functional sequence.

In the figures, a motor vehicle door lock is shown, which is reduced to the components essential to the invention. It can be seen first of all a lock housing 1, which may be a lock case and / or a lock cover and which serves for storage and recording of the individual elements to be described in detail below. In addition, a locking 2, 3 is realized, which is composed in a known manner from a rotary latch 2 and a pawl 3. The rotary latch 2 is rotatably mounted on a pin defining a rotation axis 4 in the lock housing 1. The same applies to the pawl 3, which is rotatable by a a further axis of rotation 5 defining bolt is received in the lock housing 1.

An actuating lever mechanism 6a, 6b operates on the locking mechanism 2, 3. In the exemplary embodiment, the operating lever mechanism 6a, 6b is composed of two lever sections 6a, 6b of an external actuating lever 6a, 6b which are connected to one another in an articulated manner. The lever sections 6a, 6b are - as I said - articulated to each other via a coupling pin 7 coupling them together. At the hinge pin 7, a spring 8 is connected.

The spring 8 is a leg spring 8, which clamps or elastically couples the two lever sections 6a, 6b in such a way that, with the aid of the spring 8, a force is applied in a clockwise direction with respect to the hinge pin 7, as a corresponding arrow in FIG 1 indicates. The force of the spring 8 thus ultimately ensures that the lever portion 6a is moved towards the lever portion 6b while reducing the angle between them. In this context, a stop 10 for the rest position of the actuating lever mechanism 6a, 6b ensures that the two lever sections 6a, 6b act like a continuous lever or external operating lever 6a, 6b in this rest position.

For applying the actuating lever mechanism 6a, 6b or the external actuating lever 6a, 6b, an outside door handle 9 indicated only by an arrow is provided. In principle, the operating lever mechanism 6a, 6b may also be an internal operating lever mechanism instead of the external operating lever mechanism illustrated in the exemplary embodiment. Then, the outside operating lever 6a, 6b is designed as an inside operating lever. However, this is just as little and shown for reasons of clarity, as the further basic procedure, according to which both a Innenbetäti- generally be implemented in such motor vehicle door locks.

In addition to this operating lever mechanism 6a, 6b, a locking unit 11, 12 is still realized. The locking unit 11, 12 is composed of an electric motor 11 and a driven pulley 12 pivotable by the electric motor 11 or its output shaft. With the help of the electric motor 1 1, the driven pulley 12 can be pivoted in rotations in a clockwise and counterclockwise directions. As a result, a clutch lever 13 hingedly connected to the driven pulley 12 can be linearly moved. In this case, two different basic positions of the clutch lever 13 are implemented and defined in the core.

Thus, the position of the coupling lever 13 in Figs. 2A to 2C and in Figs. 3A to 3C to the functional position "unlocked" the locking unit 11, 12. In contrast corresponds to the position of the clutch lever 13 in Figs. 4A to 4C and in the In the "unlocked" position according to FIGS. 2A to 2C and 3A to 3C, a transmission lever 14 to be described in more detail below can perform a freewheeling action relative to the clutch lever 13. In contrast, the respective transmission lever 14 in the "locked" position of the locking unit 11, 12 is blocked according to the representations in Figures 1 and 4A to 4C respectively. In the context of the invention, the transmission lever 14 already mentioned above is a blocking element 14 which deactivates the actuating lever mechanism 6a, 6b when acceleration forces F of predetermined magnitude occur, for example in the event of an accident (crash case). The crash case is shown in FIGS. 3A to 3C. Here one recognizes that the acceleration forces F in question deflect the actuating lever mechanism 6a, 6b and remove from the stop 10 for the rest position, however, that such deflections of the operating lever mechanism 6a, 6b correspond to a freewheeling of the operating lever mechanism 6a, 6b relative to the holding in its position transfer lever 14, which consequently can neither indirectly nor directly open the locking mechanism 2, 3, as will be explained in more detail below.

As described above, according to the invention, the transmission lever 14 functions as a blocking element 14 or mass barrier and prevents the occurrence of acceleration forces F of predetermined size that the motor vehicle door lock or a motor vehicle door equipped therewith is opened unintentionally. For this purpose, the blocking element 14 is not only designed as a transmission lever 14, but can be the transmission lever 14 also act on the locking unit 11, 12. In addition, the transmission lever 14 is disposed between the operating lever mechanism 6a, 6b and the locking mechanism 2, 3.

In the exemplary embodiment, the transmission lever 14 not only acts as a blocking element 14 or mass lock, but ultimately also assumes the function of a triggering element or release lever, namely such that with its help directly or indirectly the locking mechanism 2, 3 can be opened. For this purpose, the transmission lever 14 in its unlocked state and in a so-called normal operation of the operating lever mechanism 6a, 6b in the sequence of functions shown in FIGS. 2A to 2C at the end of the movement in a position to lift the pawl 3 of the catch 2, as shown in the 2C is shown.

In addition, the transmission lever 14 as it were a part of a lock lever chain 1 1, 12, 13, 14 represents. This lock lever chain 1 1, 12, 13, 14 is composed of the locking unit 1 1, 12, the clutch lever 13 and said transmission lever 14 together , Consequently, the initially described and practically triple functionality of the transmission lever 14 as locking element 14 or mass lock, as a release lever for the locking mechanism 2, 3 and finally as part of the locking lever chain 1 1, 12, 13, 14 and thus as a kind of locking lever.

Actually, the transmission lever 14 assumes the position "locked" as the basic position. This basic position is shown in FIGS. 1, 2A, 3A to 3C and finally 4A to 4C. In contrast, the functional position according to FIGS. 2B and 2C corresponds to the fact that the transmission lever 14 assumes or can assume the position "unlocked" because, in the sequence of functions shown in FIGS. 2A to 2C, the clutch lever 13 allows a freewheeling of the transmission lever 14 , as will be explained in more detail below. Here, a so-called normal operation is shown, in which the operating lever mechanism 6A, 6B, the transfer lever 14 first in the "unlocked" position according to Fig. 2B transferred and then the opposite the Betätigungshebelwerk 6A, 6B coupled transfer lever 14 ultimately for the opening of the locking mechanism 2, 3 as shown in FIG. 2C provides.

To implement this overall constructive, the operating lever mechanism 6A, 6B and the external actuating lever 6A, 6B and the transmission lever 14 are pivotally connected together. In fact, another hinge pin 15 is realized at this point. In addition, a spring 16, which is arranged on the hinge pin 15 and is connected to the hinge pin 15. The spring 16 is the outer actuating lever 6a, 6b and the transmission lever 14 are mechanically coupled to each other such that the spring 16, a force indicated in FIG. 1 counterclockwise with respect to the joint bolt 15 produced. In the illustration of FIG. 1 provides a stop 17 for the Transmission lever 14 that the transmission lever 14 retains its rest position shown there or the position "locked" and is not pivoted by the force of the spring 16 in the direction of the external operating lever 6a, 6b counterclockwise about the hinge pin 15 as a rotation axis 15.

Finally, it can still be seen with reference to FIG. 1 that the transmission lever 14 can pivot about an axis of rotation 18 relative to the lock housing 1. The transmission lever 14 is in the present case designed as a three-armed lever, wherein a stop arm 14a of the transmission lever 14 rests against the stop 15 in the rest position according to FIG. In contrast, the release arm 14b, in the context of the functional position according to FIG. 2C, ensures that with its aid the pawl 3 is lifted off the catch 2 or the catch 2, 3 experiences an opening during normal operation. Finally, in addition to the stop arm 14a and the release arm 14b, a rotary arm 14c of the transfer lever 14 is also provided, which defines the axis of rotation 18 and also has the center of gravity of the transfer lever 14 provided in the region of the axis of rotation 18. The operation is as follows. In Figs. 2A to 2C, the movement sequence is shown in a normal operation. In this normal operation, the external operating lever 6a, 6b is (slowly) pivoted by an operator so that the operator acts on the outside door handle 9 and thereby the external operating lever 6a, 6b at the transition from Fig. 2A to Fig. 2B to the bolt or hinge pin 15th pivoted as a rotation axis 15 in the counterclockwise direction. The locking unit 1 1, 12 or the entire locking chain 1 1, 12, 13, 14 is in this normal operation in its "unlocked" position, so that as a result of the pivotal movement of the external actuating lever 6 a, 6 b of Ü transmission lever 14 in the operating lever mechanism 6a, 6b engages.

In other words, the operator's or user's initiated pivotal movement of the outer actuating lever 6a, 6b counterclockwise about the axis 15 causes the transmission lever 14 to be "taken along" in this process, because the outer actuating lever 6a, 6b on the one hand and the transmission lever 14 on the other are mechanically connected to each other by the biased in the direction of this counterclockwise movement spring 16. That is, the transmission lever 14 is engaged with the operation lever mechanism 6a, 6b in this process.

As a result, the transmission lever 14 is also pivoted about its axis 18 in the counterclockwise direction and leaves its position "locked" according to FIG. 2A and goes in contrast to a position "unlocked" according to FIG. 2B on. Such a movement is permitted because the locking unit 11, 12 is also in its "unlocked" position and the clutch lever 13 allows a corresponding freewheeling of the transmission lever 14 relative to the clutch lever 13 and a pin there 13a. The further movement of the outer actuating lever 6a, 6b in the counterclockwise direction and also initiated thereby counterclockwise movement of the transmission lever 14 about the axis 18 now have the consequence that the stop arm 14a of the transmission lever 14 slides along the stop 17 and finally a further pivotal movement of the Außenbetäti- supply lever 6a 6b causes the transmission lever 14 in the functional position of FIG. 2C due to the contact with the stop 17 performs a slight pivotal movement in the clockwise direction about the axis 18, which corresponds to the fact that the pawl 3 is lifted from the catch 2. This is represented by a corresponding arrow in FIG. 2C. That is, at the end of the sequence of functions according to FIGS. 2A to 2C in the course of

Normal operation and when in position "unlocked" befindlicher locking unit 11, 12 finally acts the trigger arm 14b of the transmission lever 14 as a working on the locking mechanism 2, 3 triggering element respectively a corresponding trigger lever.

In the sequence of figures according to FIGS. 3A to 3C, the occurrence of acceleration forces F of predetermined size, that is to say the crash case in the "unlocked" position of the locking unit 11, 12, is now shown. That is, the coupling member 13 has maintained its position compared to the transferring operation of FIGS. 2A to 2C as compared with the transferring lever 14. As a result, in principle, the transmission lever 14 again perform a freewheel compared to the clutch lever 13, thus leaving his assumed in the illustration of FIG. 3A basic position "locked". However, this does not happen for the reasons described below.

Because the occurring acceleration forces F given size in a crash ensure that again - as in a normal operation - the external operating lever 6a, 6b and the operating lever 6a, 6b performs a counterclockwise movement about the axis respectively with respect to the hinge pin 15. In this operation, however, the transmission lever 14 is not able to follow the rapid movement of the operating lever mechanism or the external operating lever 6a, 6b due to its inertia. Rather, the transmission lever 14 remains due to its inertia in the position "locked" according to FIG. 3A. That is, in the deflection of the outer operating lever 6a, 6b in the transition to Figs. 3B and 3C, the transmission lever 14 retains its originally already occupied position "locked" as shown in FIG. 3A at. As a result, the outer actuating lever 6a, 6b moves away from its stop 10 for the rest position, but without being able to take the transmission lever 14. Consequently, the trigger arm 14b of the transmission lever 14 is not able to interact with the pawl 3 in an opening sense, as is apparent in the maximum deflection of the actuating lever mechanism 6a, 6b as shown in FIG. 3C. That is, due to the inertia of the blocking element or transmission lever 14, the actuating lever mechanism 6a, 6b is inactivated in the event of the occurring acceleration forces F of a predetermined magnitude, in the present case a freewheeling action is performed with respect to the blocking element or transmission lever 14 in question.

Finally, FIGS. 4A to 4C illustrate the scenario in which the locking unit 11, 12 and consequently the motor vehicle door lock as a whole is in the "locked" position. In this position, the transmission lever 14 is blocked by means of the clutch lever 13. Because the clutch lever 13 ensures with its pin 13a that this pin 13a holds the release arm 14b of the transmission lever 14 and accordingly the transmission lever 14 in this position "locked" can perform any pivoting movements in the counterclockwise direction, as they do for the unlocking and finally opening of the locking mechanism 2, 3 according to the sequence of functions according to FIGS. 2A to 2C would be required.

In fact, in the "locked" position of the transmission lever 14 is fixed by means of one hand, the stop 17 for the rest position of the transmission lever 14 and on the other hand by means of the bolt 13 a to the clutch lever 13 such that the transmission lever 14 is not in the position "unlocked" by a Counterclockwise movement about its axis 18 can be pivoted. As a result, an actuation of the operating lever mechanism or external operating lever 6a, 6b by an operator by corresponding pulling movements on the outside door handle 9 again causes the operating lever mechanism or the external operating lever 6a, 6b to execute an empty movement relative to the transmission lever 14. Even if the external operating lever 6a, 6b has completed its maximum travel, as already shown in Fig. 3C in the event of a crash and Fig. 4C shows a then taking clockwise rotation of the transmission lever 14 about its axis of rotation 18 does not cause the Auslösearm 14b of the transmission lever 14 enters or can reach the effective range of the pawl 3.

That is, this even at the end of the normal operation in the "unlocked" position of FIG. 2C observed clockwise movement of the transmission lever 14 about the rotation axis 18 in the case of "locked" does not cause the trigger arm 14b moves against the pawl 3. For the clutch lever 13 and its pin 13 a ensures that the transmission lever 14 is held outside the effective range of the pawl 3 and consequently the taking place in Fig. 2C when opening the locking mechanism 2, 3 acting on the pawl 3 by the trigger arm 14 b of the transmission lever 14 can not take place. That is, it is the usual functionality "locked" shown and performs in this context, the operating lever mechanism 6a, 6b from a desired idle stroke.

Claims

claims:

1. Motor vehicle door lock, with a locking mechanism (2, 3), further with a on the locking mechanism (2, 3) operating lever mechanism (6a, 6b), and with a locking element (14) which the Betätigungshebelwerk (6a, 6b) in occurring Acceleration forces (F) predetermined size, for example, in an accident, ineffective sets, characterized in that the blocking element (14) as by a locking unit (1 1, 12) acted upon transfer lever (14) between the actuating lever mechanism (6a, 6b) and the locking mechanism ( 2, 3) is formed.

2. Motor vehicle door lock according to claim 1, characterized in that the locking unit (11, 12) by means of a coupling lever (13) on the transmission lever (14) works.

3. Motor vehicle door lock according to claim 1 or 2, characterized in that the locking unit (1 1, 12) blocks the transmission lever (14) by motor in the "locked" position.

4. Motor vehicle door lock according to one of claims 1 to 3, characterized in that the locking unit (1 1, 12) allows the transmission lever (14) in the "unlocked" position a freewheel.

5. Motor vehicle door lock according to one of claims 1 to 4, characterized in that the transmission lever (14) assumes the position "locked" as a basic position.

6. Motor vehicle door lock according to one of claims 1 to 5, characterized in that the actuating lever mechanism (6a, 6b) performs an idle in the event of a crash relative to the transmission lever (14) remaining essentially in its position.

7. Motor vehicle door lock according to one of claims 1 to 6, characterized in that the actuating lever mechanism (6a, 6b) in a normal operation, the transmission lever (14) in the position "unlocked" transferred to the opening of the Ge-barrier (2, 3).

8. Motor vehicle door lock according to one of claims 1 to 7, characterized in that the actuating lever mechanism (6a, 6b) and the transmission lever (14) are hinged together.

9. Motor vehicle door lock according to one of claims 1 to 8, characterized in that the transmission lever (14) relative to the actuating lever mechanism (6a, 6b) is biased by a spring (16).

10. Motor vehicle door lock according to one of claims 1 to 9, characterized in that the center of mass of the transmission lever (14) in the region of its axis of rotation (18) is arranged.