DE102019127445A1 - Motor vehicle lock, in particular motor vehicle door lock - Google Patents

Abstract

The subject of the present invention is a motor vehicle lock and in particular a motor vehicle door lock, which is equipped with a locking mechanism (1, 2) consisting essentially of a rotary latch (1) and a pawl (2), and also with an actuating lever mechanism (3, 4, 5, 7) to trigger the locking mechanism (1, 2), and is equipped with a crash unit (3, 7, 9, 10, 11). The crash unit deactivates the actuating lever system (3, 4, 5, 7) and / or the locking mechanism (1, 2) at least when decelerating forces of a predetermined magnitude and direction occur, for example in the event of an accident (crash). For this purpose, the crash unit (3, 7, 9, 10, 11) is equipped with at least one spring (11) which acts on a lever (9). According to the invention, the lever (9) is designed as a control lever (9) of the crash unit (3, 7, 9, 10, 11), which is set up to control a clutch lever (7) of the actuating lever mechanism (3, 4, 5, 7). The clutch lever (7) is continuously in its "locked" position and only goes into its "unlocked" position during normal operation by the control lever (9), which is then moved together with the operating lever system (3, 4, 5, 7).

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, furthermore with an actuating lever mechanism for triggering the locking mechanism, and with a crash unit which activates the actuating lever mechanism and / or the locking mechanism at least when deceleration forces of a predetermined magnitude and direction occur, For example, in the event of an accident (crash), it becomes ineffective, the crash unit being equipped with at least one spring which acts on a lever.

The locking mechanism essentially consists of a rotary latch and a pawl. Then a so-called single lock is implemented. In principle, a multiple lock can also be provided. In this case, a rotary latch, a comfort pawl securing the rotary latch and a pawl for securing the comfort pawl are typically implemented. Alternatively, you can also work with an additional pre-locking pawl and the locking pawl. In all of these cases, deceleration forces occurring in connection with an accident can lead to the locking mechanism being opened unintentionally. Because the deceleration forces in question act - also - on the actuating lever mechanism for triggering the locking mechanism.

In such a case, the crash unit prevents such unintentional opening of the locking mechanism. For this purpose, the locking mechanism or the actuating lever mechanism acting on the locking mechanism is set ineffective in the event of a crash. The mentioned decelerations or vehicle accelerations, which can reach several g, mostly act in the transverse direction of the motor vehicle and mainly occur in the event of a side impact.

The operating lever system is usually composed of one or more levers. Usually, an internal operating lever, an external operating lever and a release lever are used as a minimum. In addition, the actuating lever mechanism often has one or more clutch levers, with the aid of which individual securing positions of the actuating lever mechanism can be implemented. The locking mechanism is usually opened via the release lever as part of the actuating lever system. For this purpose, the release lever typically engages the pawl, a comfort pawl or both pawls and lifts the pawl or the multiple pawls, in particular from the associated rotary latch, so that the locking mechanism can open with spring support as a result.

In the prior art according to DE 10 2011 100 090 A1 a motor vehicle lock is implemented in which the crash unit or a locking means implemented at this point is designed to be changeable with regard to its shape. In its normal form, the locking means has no function with the actuating lever mechanism. In contrast, a locking form of the locking means corresponds to the actuation lever mechanism and / or the locking mechanism being set ineffective. In this way, the overall functional reliability is to be increased with a simple structure at the same time. However, the locking means, which can be changed in shape, has a relatively complex design.

The generic prior art according to the WO 2015/014341 A1 proceeds in such a way that the crash unit there has a locking lever with a connected spring. In normal operation, the spring is acted upon by an actuating lever that crosses the locking lever as part of the actuating lever mechanism for deflecting the locking lever. In the event of a crash, the spring in question is compressed. This is intended to reduce the mass of the crash unit or the locking element or locking lever or the crash barrier in general while maintaining the functionality.

The state of the art has basically proven itself. However, structural simplifications are still possible and unchanged. Such structural simplifications offer the option of equipping even low-priced motor vehicle locks with an effective crash barrier and consequently ensuring extensive market penetration.

The invention is based on the technical problem of developing such a motor vehicle lock and in particular a motor vehicle door lock in such a way that the structural form is simplified while the functionality is unchanged and a particularly cost-effective variant is thus available.

To solve this technical problem, a generic motor vehicle lock and in particular a motor vehicle door lock is characterized within the scope of the invention in that the lever is designed as a component of the crash unit as a control lever of the crash unit, which is set up to control a clutch lever of the actuating lever system, the clutch lever continuously changing its position " locked ”and only moves into its“ unlocked ”position during normal operation by the control lever, which is then moved along with the operating lever mechanism.

In the context of the invention, the crash lock that is implemented is initially composed of the clutch lever and the control lever. In most cases, an inertia lever is also assigned to the control lever. In principle, however, the control lever and the inertia lever can also functionally coincide. With the help of the control lever, the clutch lever is now held in its "locked" position throughout. The clutch lever is not only a component of the crash unit, but also a component of the actuating lever system. In its "locked" position, the clutch lever - as usual - ensures that the actuating lever system is mechanically interrupted so that its actuation typically does not result in actuating movements of the release lever corresponds, because the actuation of the actuating lever system is empty in relation to the locking mechanism. The closed locking mechanism therefore remains in its closed state.

In contrast, the "unlocked" position of the clutch lever corresponds to the fact that the actuating lever system provides a continuous mechanical connection up to the release lever, so that pressures on the actuating lever system correspond to pressurization of the release lever and thus to releasing the locking mechanism.

According to the invention, the clutch lever is now kept in its “locked” position throughout. This also and especially applies to a crash. Because in the event of a crash, the control lever, due to its inertia alone or due to the combined inertia of the control lever in conjunction with the inertia lever, ensures that the clutch lever remains unchanged in its "locked" position. Any loading of the actuating lever system is absorbed by the spring. This is because the control lever and an actuating lever of the actuating lever system are coupled to one another with the aid of the spring.

If, in the event of a crash, the actuating lever mechanism and consequently the actuating lever are deflected, the spring between the actuating lever and the control lever ensures that the actuating lever can be adjusted, the control lever nevertheless maintaining its position due to its inertia. This also applies to the clutch lever, which is controlled with the aid of the control lever and remains in its "locked" position unchanged.

Only in normal operation does it happen that the actuation lever mechanism and consequently also the actuation lever are subjected to the control lever via the spring. The control lever, which is consequently moved with the actuating lever mechanism, then in turn ensures that the clutch lever, starting from its “locked” position, moves into its “unlocked” functional position or is pivoted into this position. Depending on the design of the actuating lever mechanism, the control lever and also the inertia lever assigned to the control lever, normal operation corresponds to actuation speeds that are typically below 1 m / s. On the other hand, speeds of well over 1 m / s of the actuating lever system are interpreted as a crash and lead to the control lever ensuring that the clutch lever maintains its "locked" position due to its inertia. Any deflections of the operating lever system are absorbed by the spring between the control lever and the operating lever.

All of this can be implemented in a particularly simple and cost-effective manner. Because the crash unit according to the invention essentially has the control lever controlling the clutch lever. The clutch lever is usually implemented anyway in order to be able to represent different securing positions of the actuating lever mechanism, such as, for example, “locked” or “unlocked”. According to the invention, the clutch lever is now also included in the crash lock or is a component of the crash unit. This is ensured by the control lever that controls the clutch lever and is additionally provided, which in the event of a crash ensures that due to its own inertia or inertia in conjunction with the optional inertia lever, that the clutch lever remains in its "locked" position unchanged.

At the same time, this increases the functional reliability enormously. Because the continuous assumption of the "locked" position of the clutch lever ensures that practically the locked state of the actuating lever mechanism is the normal state. The clutch lever only takes its "unlocked" position when opening during normal operation. After the opening process has been completed, the clutch lever returns to its "locked" position in normal operation. As a result, the motor vehicle lock is permanently secured in normal operation, namely due to the additional inertia of the control lever controlling the clutch lever, at the same time also in the event of a crash. This can be implemented in a particularly simple manner in terms of construction and thus in terms of costs. This is where the main advantages can be seen.

According to an advantageous embodiment, the control lever and the actuating lever are mounted coaxially to one another. In addition, the control lever advantageously has a control contour for a control pin engaging in the control contour Clutch lever. With the help of the control contour, the clutch lever is controlled by the control lever. The clutch lever is generally rotatably mounted about an axis parallel to the axis of the control lever.

It has proven itself here if the clutch lever is rotatably mounted on the release lever as part of the actuating lever mechanism. As a result, the clutch lever can easily be moved into an "unlocked" position that mechanically couples the actuating lever to the release lever, as well as into its "locked" position, in which the mechanical connection between the actuating lever and the release lever is interrupted.

In order to realize this in detail, the clutch lever generally interacts with a contour on the release lever in such a way that, in its pivoted-in or “unlocked” state, the actuation lever acts on the release lever in normal operation. In this normal operation, loading of the actuating lever consequently results in the actuating lever taking along the control lever via the interposed spring and also being able to take it along. The joint movement of the actuating lever and control lever now leads to the control pin engaging in the control contour of the control lever in a contour area of the control contour, which allows the clutch lever to be pivoted in and thus "unlocked". The pivoted-in state of the clutch lever here corresponds to the fact that the clutch lever can interact with the contour on the release lever, usually resting on the contour. As a result, in the "unlocked" state, a continuous mechanical connection from the actuating lever to the control lever, the clutch lever and finally the release lever to the lock is implemented, so that pressures on the actuation lever and thus on the actuation lever system as a whole lead to the release of the locking mechanism, typically to its opening.

In the event of a crash, however, the clutch lever retains its swiveled-out state with respect to the contour in question on the release lever. The "locked" position of the clutch lever, which is assumed and maintained throughout, corresponds to this. As a result, the actuating lever is decoupled from the control lever and can perform pivoting movements with respect to the control lever. During these pivoting movements, the spring coupling the actuating lever to the control lever is compressed or elongated, depending on the design.

As already explained, the control lever is usually coupled to an inertia lever. In the event of a crash, the control lever maintains its position with the help of the inertia lever. In this maintained position of the control lever, it ensures that the clutch lever is fixed in its "locked" position via the control lever. In the event of a crash, the clutch lever, which is still in the “locked” position, ensures that, as desired, there is no continuous mechanical connection from the actuating lever system to the release lever, so that the locking mechanism also maintains its closed position in the event of a crash. For this purpose, the inertia lever typically has a contour for receiving a pin of the control lever.

• 1A bis 1C das erfindungsgemäße Kraftfahrzeugschloss reduziert auf die für die Erfindung wesentlichen Bestandteile bei einer Normalbetätigung bzw. im Normalbetrieb, und zwar jeweils in Front- und Rückansicht,
• 2A bis 2C den Gegenstand nach den 1A bis 1C im Crashfall, erneut in Front- und Rückansicht und
• 3A und 3B die Crasheinheit in perspektivischer Ansicht erneut aus unterschiedlichen Richtungen.

The invention is explained in more detail below with the aid of a drawing showing only one exemplary embodiment; show it:

• 1A to 1C the motor vehicle lock according to the invention reduced to the essential components for the invention in normal operation or in normal operation, in each case in front and rear view,
• 2A to 2C the subject after the 1A to 1C in the event of a crash, again in front and rear view and
• 3A and 3B the crash unit in a perspective view again from different directions.

In the figures, a motor vehicle lock is shown, which is a motor vehicle door lock. For this purpose, the motor vehicle lock or motor vehicle door lock is equipped with a locking mechanism consisting of a rotary latch 1 and pawl 2 equipped, which is in the 1 is only indicated in the top view or in the 1A to 1C only in section in the form of the pawl 2 is reproduced. Next to the lock 1 , 2 from essentially rotary latch 1 and pawl 2 is an operating lever mechanism 3 , 4th , 5 , 7th planned and implemented. The operating lever system 3 , 4th , 5 , 7th according to the exemplary embodiment and not by way of limitation, consists of an external actuating lever 3 , an internal operating lever 4th and a release lever 5 together that are equiaxed with respect to a common axis 6th are stored in a lock housing not shown. It also belongs to the operating lever system 3 , 4th , 5 , 7th a clutch lever 7th , which around another and to the axis 6th parallel axis 8th on the release lever 5 is stored.

For the following considerations, the external operating lever is primarily used 3 and the release lever 5 as well as the clutch lever 7th relevant. In fact, the following considerations can also be applied to the internal operating lever 4th transfer. In any case, the outside operating lever is 3 to an external handle (not shown), respectively connected to an outside door handle, with the help of which the outside operating lever 3 to trigger the locking mechanism 1 , 2 so with one in the 1A indicated force F. is acted upon that the external operating lever 3 in this case a clockwise movement around its axis indicated in the figures 6th performs.

Has the operating lever system 3 , 4th , 5 , 7th a continuous mechanical connection to the locking mechanism 1 , 2 on so is the release lever 5 able to release the pawl 2 in the representation after the 1A to 1C to act on the left according to the indicated arrow, so that the pawl 2 in supervision of the lock 1 , 2 swiveled clockwise and the previously locked rotary latch 1 releases. The rotary latch 1 then swivels open with the aid of spring force and releases a previously caught locking bolt. The lock 1 , 2 is opened. The "unlocked" state of the clutch lever corresponds to this 7th how he in the individual representations after the 1B and 1C is shown.

However, if there is an accident or a crash, the operating lever system is 3 , 4th , 5 , 7th to trigger the locking mechanism 1 , 2 not able because in such a crash case an additionally provided crash unit 3 , 7th , 9 , 10 , 11 ensures that in the case of deceleration forces of a given magnitude and direction occurring in connection with such a crash, the locking mechanism 1 , 2 respectively the lever mechanism 3 , 4th , 5 , 7th is set ineffective. The ones in the 3A and 3B Crash unit shown in detail 3 , 7th , 9 , 10 , 11 is composed according to the embodiment of an actuating lever or the external actuating lever 3 and the clutch lever 7th first of all together that also includes the operating lever system 3 , 4th , 5 , 7th belong.

In addition, there is a control lever to be described in more detail below 9 realized which is used to control the clutch lever 7th is set up. It also belongs to the crash unit 3 , 7th , 9 , 10 , 11 another one on the control lever 9 working inertia lever 10 . After all, it is part of the crash unit 3 , 7th , 9 , 10 , 11 a feather 11 , which the operating lever or external operating lever 3 one hand and the control lever 9 on the other hand, elastically coupled to one another.

The control lever 9 the crash unit 3 , 7th , 9 , 10 , 11 is to control the clutch lever 7th set up. The control lever does this 9 about a particular in the 3A and 3B shown control contour 9a , 9b . In the control contour 9a , 9b engages backwards on the clutch lever 7th connected and in the control contour 9a , 9b engaging control pin 7a of the clutch lever 7th a. The control contour 9a , 9b is with two contour areas 9a , 9b equipped, which include an obtuse angle between them according to the embodiment, so that the control pin 7a is fixed in the area of a vertex of the obtuse angle. The "locked" position of the clutch lever corresponds to this 7th as in the 1A and the 2A to 2C is shown in detail.

On the other hand, the clutch lever takes 7th its "unlocked" position as it is the subject of the 1B and 1C is, so can the control pin 7a of the clutch lever 7th in the contour area 9a the control contour 9a , 9b of the control lever 9 dodge. As a result, the clutch lever pivots 7th starting from the "locked" position after the 1A to the "unlocked" position as shown in the 1B and 1C a. A counterclockwise movement of the clutch lever corresponds to this 7th around its axis 8th on the release lever 5 . At the same time, this is the clutch lever 7th able to with a contour 3a on the operating lever 3 to be able to interact. The clutch lever actually moves 7th "unlocked" in its position or pivoted against the contour in question 3a so that the operating lever or external operating lever 3 and the release lever 5 are mechanically interconnected. Any pivoting movements of the external operating lever 3 around its axis 6th in the indicated clockwise direction to trigger the locking mechanism 1 , 2 are consequently on the release lever 5 transferred, which is also around the common axis 6th is pivoted clockwise and thereby the pawl 2 of their engagement with the rotary latch 1 when transitioning from the 1A to 1B and on to 1C can take off.

The clutch lever 7th or its axis 8th is parallel to the axis according to the embodiment 6th of the control lever. The axis 6th of the control lever also acts as an axis for the release lever 5 and the operating lever or external operating lever 3 . One recognizes the transition from the 1A to 1B that the action of an external handle on the external operating lever, for example 3 attacking force F. the operating lever or external operating lever 3 indicated clockwise around its axis 6th pivoted. Because the outside operating lever 3 with the joystick 9 about the pen 11 is coupled, one leads into the 1A to 1C normal operation shown to the fact that the control lever 9 the clockwise movement of the external control lever 3 follows.

The clockwise movement of the control lever 9 now has the consequence that the area of the apex between the two contour areas 9a , 9b fixed control pin 7a of the clutch lever 7th in the area of the control contour 9a of the control lever 9 so that the clutch lever 7th based on its "locked" position in the 1A around the axis 8th can pivot counterclockwise because this causes the control pin 7a in the contour area 9a of the control lever 9 at the same time can evade. In addition, I like the clutch lever 7th in a corresponding sense by a spring, not shown, counterclockwise with respect to its axis 8th be biased.

In any case, the common pivoting movement of the actuating lever or external actuating lever leads 3 together with the control lever 9 in normal operation as well as clockwise around the common axis 6th to that the control pin 7a of the clutch lever 7th in the contour area 9a of the control lever 9 can evade, so that as a result of this, the clutch lever 7th counterclockwise around the axis 8th in the position after the 1B can swing in. This brings the clutch lever 7th for contact with the contour 3a of the external control lever 3 and are therefore the external operating lever 3 and the release lever 5 through the swiveled-in clutch lever 7th mechanically coupled to one another in its "unlocked" position.

This results in the continued pivoting movement of the external operating lever 3 when transitioning from the 1B to 1C around the common axis 6th clockwise so that the release lever 5 the pawl 2 of their engagement with the rotary latch 1 takes off in normal operation. As soon as the operating lever or external operating lever 3 in its original position after the 1A returns again, the clutch lever becomes 7th again out of engagement with the contour 3a of the operating lever 3 swiveled out, with the control pin 7a of the clutch lever 7th again in the vertex between the two contour areas 9a , 9b the control contour of the control lever 9 is fixed. That is, the clutch lever 7th then takes (after opening the locking mechanism 1 , 2 ) again “locked” its position, which it has assumed throughout, according to the illustration after 1A a.

The crash case is now in the functional sequence according to the 2A to 2C shown. In the event of a crash, the actuation lever or external actuation lever can be acted upon again 3 in the sense of opening the locking mechanism 1 , 2 come. That is, the outside operating lever 3 becomes when transitioning from the 2A to 2 B again - due to the deceleration forces - clockwise around its axis 6th applied. In this case, however, the control lever remains 9 in peace. This is ensured by the inertia of the control lever 9 , which according to the embodiment by its interaction with the inertia lever 10 is realized. Basically, the control lever 9 but also be designed in such a way that, due to its own mass, it has the required inertia to cope with the (rapid) movements of the external operating lever 3 to withstand in the event of a crash.

Based on the perspective view of the crash unit 3 , 7th , 9 , 10 , 11 in the representation after the 3A and 3B you can see that the control lever 9 in the event of a crash by means of the inertia lever 10 maintains its position. The inertia lever is used for this purpose 10 rotatably mounted about its own axis 12. At the same time, the control lever fixes 9 the clutch lever in the event of a crash 7th in its "locked" position. That is, the clutch lever 7th retains consistently in the event of a crash and in all functional representations according to the 2A to 2C consistently "locked" position at. This is the operating lever mechanism 3 , 4th , 5 , 7th to trigger the locking mechanism 1 , 2 interrupted, so the lock 1 , 2 maintains its closed position as desired in the event of a crash.

In detail, the inertia lever has 10 over a contour 10a for receiving a pin 9c on the control lever 9 . In fact, the spigot extends 9c of the control lever 9 predominantly perpendicular to the areal extent of the control lever 9 and engages in the contour 10a of the inertia lever 10 a. The axis 12 of the inertia lever 10 runs parallel to the axes 6th , 8th .

In the event of a crash, according to the 2A to 2C retains the inertia lever 10 his position at. This also becomes the control lever 9 held, which in turn, the clutch lever 7th fixed in the "locked" position. The control pin 7a on the clutch lever 7th So remains in the area of the apex between the two angled contour areas 9a , 9b of the control lever 9 . Any and on the operating lever system 3 , 4th , 5 , 7th Delay forces acting in the event of a crash now lead to the external actuation lever 3 those in the 2A to 2C shown pivoting movements about its axis 6th clockwise. Such pivoting movements are permitted because the external operating lever 3 via the intermediate spring 11 with the joystick 9 is coupled. As a result, the spring in question becomes 11 compressed or elongated and leaves the deflections of the external operating lever associated with the acting deceleration forces 3 to.

After the deceleration forces have ceased, the external operating lever reverses 3 - acted upon by the spring 11 - in its original position after the 2A (back again. In contrast, in the normal actuation already described above, the design is such that the pivoting movement of the external actuation lever 3 about the pen 11 the joystick 9 takes away. Since the swivel movement in normal operation is slowly below a limit speed to be determined by the dimensioning of the individual components, the interposed spring takes care of it 11 making sure the control lever 9 the pivoting movements of the external operating lever 3 can follow. The same applies to the inertia lever 10 which over the tenon 9c on the control lever 9 by engaging the contour 10a is also taken along during the pivoting movement and is pivoted about its axis 12 in normal operation. As a result, the control lever 9 in normal operation around the common axis 6th with the external operating lever 3 Swivel clockwise so that - as described - the control pin 7a on the clutch lever 7th in the contour area 9a of the control lever 9 and consequently in the "unlocked" position according to the illustration after 1B and 1C can swing in. The lock 1 , 2 can therefore be opened in normal operation.

In contrast, the clutch lever takes 7th consistently in its rest position as well as in the 2A to 2C the "locked" position shown in the crash scenario. This is ensured by the control lever in the event of a crash 9 , which according to the embodiment in connection with the inertia lever 10 builds up the required inertia forces.

List of reference symbols

1

Rotary latch

1, 2

Lock

2

Pawl

3

External operating lever

3, 4, 5, 7

Operating lever mechanism

3,7,9,10,11

Crash unit

3a

contour

4th

Internal operating lever

5

Release lever

6th

axis

7th

Clutch lever

7a

Control pin

8th

axis

9

Control lever

9a

Contour area

9a, 9b

Control contour, contour areas

9c

Cones

10

Inertia lever

10a

contour

11

feather

F.

force

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed 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 102011100090 A1 [0005]
• WO 2015/014341 A1 [0006]

Claims (10)

Motor vehicle lock, in particular motor vehicle door lock, with a locking mechanism (1, 2) essentially consisting of rotary latch (1) and pawl (2), furthermore with an actuating lever mechanism (3, 4, 5, 7) for releasing the locking mechanism (1, 2), and with a crash unit (3, 7, 9, 10, 11), which the actuating lever mechanism (3, 4, 5, 7) and / or the locking mechanism (1, 2) at least when decelerating forces of a predetermined size and direction occur, for example in the event of an accident (Crash case), ineffective, the crash unit (3, 7, 9, 10, 11) is equipped with at least one spring (11) which acts on a lever (9), characterized in that the lever (9) as a control lever (9) of the crash unit (3, 7, 9, 10, 11) is designed, which is set up to control a clutch lever (7) of the actuating lever system (3, 4, 5, 7), the clutch lever (7) continuously changing its position "Locked" and only in normal operation by the then together with the lever mechanism ( 3, 4, 5, 7) moves the control lever (9) into its "unlocked" position. Motor vehicle lock after Claim 1 , characterized in that the control lever (9) and an actuating lever (3) of the actuating lever mechanism (3, 4, 5, 7) are coupled to one another by means of the spring (11). Motor vehicle lock after Claim 1 or 2 , characterized in that the control lever (9) and the actuating lever (3) are mounted coaxially to one another. Motor vehicle lock according to one of the Claims 1 to 3 , characterized in that the control lever (9) has a control contour (9a, 9b) for a control pin (7a) of the coupling lever (7) engaging in the control contour (9a, 9b). Motor vehicle lock according to one of the Claims 1 to 4th , characterized in that the coupling lever (7) is rotatably mounted about an axis (8) parallel to the axis (6) of the control lever (9). Motor vehicle lock according to one of the Claims 1 to 5 , characterized in that the clutch lever (7) is rotatably mounted on a release lever (5). Motor vehicle lock according to one of the Claims 1 to 6th , characterized in that the clutch lever (7) interacts with a contour (3a) on the actuating lever (3) in such a way that in its pivoted unlocked state the actuating lever (3) acts on the release lever (5) in normal operation. Motor vehicle lock according to one of the Claims 1 to 7th , characterized in that the clutch lever (7) in the event of a crash maintains its locked out state relative to the contour (3a), so that the actuating lever (3) is decoupled from the control lever (9) under the action of the spring (11). Motor vehicle lock according to one of the Claims 1 to 8th , characterized in that in the event of a crash the control lever (9) maintains its position by means of an inertia lever (10) and fixes the clutch lever (7) in its “locked” position. Motor vehicle lock after Claim 9 , characterized in that the inertia lever (10) has a contour (10a) for receiving a pin (9c) of the control lever (9).

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