Lock for a motor vehicle

Abstract

A lock with a locking mechanism includes a rotary catch and a pawl for engaging the rotary catch, and a releasing lever for opening or releasing the locking mechanism. The lock may include a blocking lever capable of blocking the pawl if the latter is located in its catching position. If the releasing lever is actuated, the pawl or the blocking lever is thereby moved out of its blocking position if the releasing lever is not excessively accelerated. If excessively large accelerations of the releasing lever occur, as can be caused by a crash, then an arresting device of the lock prevents the releasing lever from being able to move the pawl or the blocking lever out of its blocking or latching position, respectively. The lock is therefore incapable of opening if the releasing lever is accelerated in the event of a crash.

Claims

1. Lock for a motor vehicle comprising a locking mechanism with a rotatably mounted rotary catch for receiving a locking bolt, a pawl with which the rotary catch can be engaged for retaining the locking bolt, a releasing lever for disengaging the locking mechanism; and an arresting device which is configured such that in response to a first accelerating force applied to the releasing lever, the arresting device permits the releasing lever to disengage the locking mechanism, and in response to a second accelerating force that is excessively large relative to the first accelerating force, the arresting device prevents the releasing lever from being able to disengage the locking mechanism; wherein the arresting device comprises an inertia lever, a blocking lever that blocks the pawl for retaining the locking bolt, and a spring that directly interconnects the inertia lever and the blocking lever, and wherein the inertia lever, the blocking lever, and the spring are interconnected in such a way that the spring acts as a rigid connection between the inertia lever and the blocking lever whereby rotation of the blocking lever by the releasing lever rotates the inertia lever in response to the first accelerating force, and the spring does not act as a rigid connection between the blocking lever and the inertia lever by acceleration of the releasing lever in response to the second accelerating force such that the blocking lever rotates while the inertia lever does not rotate.

2. The lock of claim 1, wherein one leg of the spring rests against the inertia lever and the other leg of the spring rests against the blocking lever.

3. The lock of claim 2, wherein the blocking lever is rotatably mounted on the inertia lever.

4. The lock of claim 3, wherein the blocking lever comprises a lug which can be moved by the releasing lever for moving the blocking lever.

5. The lock of claim 4, wherein a leg of the spring rests against a contour of the lug in a biased manner.

6. The lock of claim 1, wherein the mass of the inertia lever is several times larger than the mass of the blocking lever to enable lack of the rigid connection between the blocking lever and the inertia lever in response to the second accelerating force.

7. The lock of claim 1, comprising an arresting profile connected to a lock casing or a plate of the lock.

8. The lock of claim 7, wherein a rotatably mounted safety lever arresting profile comprises the arresting profile and rests against a contour of the inertia lever in a biased manner.

9. The lock of claim 1, wherein the blocking lever is capable of blocking the pawl in a catching position of the lock.

10. The lock of claim 9, wherein the rotary catch is capable of introducing an opening moment into the pawl if the pawl is in its catching position.

11. The lock of claim 1, wherein the arresting device further comprises a safety lever, and in response to the second accelerating force the blocking lever moves until it reaches the safety lever such that the safety lever acts as a stop that limits movement of the blocking lever sufficiently to preclude a further rotation of the release lever in response to the second accelerating force.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention is described hereinafter with reference to accompanying drawings, in which:

(2) FIG. 1 is a schematic side view of a locking mechanism in accordance with an exemplary embodiment of the invention;

(3) FIG. 2 is a first detailed view of the arresting device in accordance with the exemplary embodiment of the invention;

(4) FIG. 3 is a second detailed view of the arresting device in accordance with the exemplary embodiment of the invention;

DETAILED DESCRIPTION OF THE INVENTION

(5) As shown in FIG. 1, the locking mechanism of a lock comprises a rotary catch 1, a pawl 2, a blocking lever 3, an inertia lever 4 below the blocking lever 3 and a safety lever 5. Rotary catch 1, pawl 2, inertia lever 4 and safety lever 5 are rotatably mounted on a metal plate 6. In addition, there is a releasing lever. FIG. 1 shows a section 7 of the releasing lever. The release lever 7 can be placed above the pawl 2 and can be rotatably mounted on axis 9.

(6) Rotary catch 1 may rotate around its axis 8. Pawl 2 may rotate around its axis 9. Inertia lever 4 may rotate around its axis 10. The weight of the inertia lever 4 is much higher than the weight of the blocking lever 3, at least two, three, four or more times.

(7) As shown in FIG. 1, the pawl 2 blocks a clockwise rotation of the rotary catch 1. Therefore, the pawl 2 is in its catching position. In order to unlock the locking mechanism, it is necessary to rotate the pawl 2 clockwise. When the pawl 2 has leaved its catching position, the rotary catch 1 can rotate clockwise in the direction of its opened position. When the rotary catch 1 arrives at its opened position, the lock holder 11 of a vehicle door or vehicle flap can leave the locking mechanism. It is then possible to open the corresponding door or flap.

(8) The blocking lever 3 is rotatably mounted on the inertia lever 4 adjacent to a lever arm of the releasing lever 7. Further, blocking lever 3 and inertia lever 4 are interconnected by a biased spring 12. A first leg 13 of the spring 12 rests against a projection 14 of the inertia lever 4 in a biased manner. The second leg 15 of the spring 12 rests against a projection 16 of the blocking lever in a biased manner as shown in greater detail in the FIGS. 2 and 3.

(9) Projection 16 acts in addition as a lug. The above mentioned lever arm of the releasing lever 7 can catch the lug 16 in order to move the blocking lever 3 to the left. The blocking lever 3 may rotate around its axis 17 or together with the inertia lever 4 around the axis 10.

(10) Activation by a driver or a further person of a corresponding grip of a vehicle connected to the locking mechanism, such as by a Bowden cable or other known means, results in rotating the releasing lever 2 in a clockwise manner. In such a case, the corresponding arm of the releasing lever moves the blocking lever 3 to the left. When the acceleration is low, the spring 12 acts as a rigid connection between the inertia lever 4 and the blocking lever 3. For this reason, movement of the blocking lever 3 to the left results in rotating the inertia lever 4 together with the blocking lever 3 in a counterclockwise manner around the axis 10. The releasing lever 7 catches a lug respectively a projection 18 of the pawl 2 in order to remove the pawl from its catching position. At the end, it is possible to open the corresponding door or flap.

(11) During motor vehicle collisions, parts of the door handle or other vehicle components may accelerate and cause unwanted actuation of the grip resulting in a strong acceleration of the releasing lever 7. A strong acceleration of the releasing lever 7 results in a strong acceleration of the blocking pawl 3 to the left. In this case, the spring 12 does not act as a rigid connection between the blocking lever 3 and the inertia lever 4 due to the high weight and the resulting inertia of the inertia lever 4 and/or due to a friction force between the inertia lever 4 and the safety lever 5 since the safety lever 5 rests in a biased manner at a contour of the inertia lever 4. As a result, the inertia lever 4 does not rotate around its axis 10. Instead of that, the blocking lever 3 rotates in a clockwise manner in the direction of the position as shown in FIG. 3 around its axis 17.

(12) When the blocking lever arrived at the position as shown in FIG. 3, the safety lever 5 may block a movement of the blocking lever 3 to the left. In such a case, a further clockwise rotation of the release lever 7 is not possible. As a result, the pawl 2 will rest in its catching position as shown in FIG. 1.

(13) The movement of the inertia lever 4 back to its starting position as shown in FIG. 1 can be achieved by gravity and/or by a further spring.

(14) The rotatably mounted safety leaver is rotatable around its axis 19. Due to a spring 20, the safety lever rests against a contour of the inertia lever in a biased manner.