The invention relates to a lock for a flap or a door with the characteristics of the generic term of claim 1. The door or flap can be a door or flap of a motor vehicle or of a building.
The aforementioned lock contains a locking mechanism with a rotary latch and at least a pawl with which the rotary latch can be latched in the closed position. The locking mechanism is mounted on a lock plate, generally made of metal or a lock case generally made of metal. Generally, such a lock also contains a lock housing, which is generally made of plastic and which can protect components of the lock against external influences. Furthermore, the arrangement can contain a lock cover, made in particular of plastic and/or a cover for a central locking, made in particular of plastic and that also provides protection.
The invention relates, in particular to a lock with a pawl for the main locking position of the rotary latch (hereinafter referred to as “main locking pawl”), a pawl for the intermediate locking position of the rotary latch (hereinafter referred to as “intermediate locking pawl”) and a blocking lever for the said main locking pawl. Such a lock is known from printed publication DE 10 2007 003 948 A1.
The rotary latch of the motor vehicle lock known from DE 10 2007 003 948 A1 contains a fork-like intake slot into which a locking bolt of a motor vehicle door or of a motor vehicle flap is moved when the motor vehicle door or motor vehicle flap is closed. The locking bolt pivots the rotary latch in this case from an open position to a closed position. Once the rotary latch has reached a closed position, the locking bolt can no longer leave the intake slot of the rotary latch. In the closed position the pawl latches the rotary latch so that it can no longer be turned back into the open position. The lock is then in a latched arrangement or position.
The lock disclosed in DE 10 2007 003 948 A1 contains two detent positions, that can be assumed in succession by the rotary latch during closing, i.e. the so-called intermediate locking position of the rotary latch and the so-called main locking position of the rotary latch.
In order to avoid that a pawl is inadvertendly moved out of its detent position, a blocking lever can be provided that blocks such a movement when the rotary latch is latched. In the lock disclosed in printed publication DE 10 2007 003 948 A1, such a blocking lever is required for the main locking pawl, as the rotary latch and the main locking pawl are designed in such a way that the rotary latch can introduce an opening moment in the main locking pawl in the main locking position.
The above characteristics, already known from prior art, can be individually or in any combination combined with the object of the present invention.
A lock of the aforementioned type thus has components such as a pawl, blocking lever or rotary latch that can and should be pivoted. Regularly such arrangements also include at least one pretensioned spring producing such a desired pivoting movement of such a component by a spring force. Such a pretensioned spring can, for instance, move a pawl into its detent position, move a blocking lever into its blocking position or a rotary latch into its open position. DE 10 2007 003 948 A1 discloses a spring-loaded rotary latch, i.e. a rotary latch, which can be pivoted by the spring force of the respective spring.
It is the task of the invention to further develop a lock of the aforementioned type.
The task of the invention is solved by a lock with the characteristics of the first claim. Advantageous embodiments are disclosed in the sub-claims.
To solve this task, the invention provides a lock for a door or flap with a locking mechanism consisting of a rotary latch and at least a pawl and a spring. The spring can move a pivotable component of the lock by means of the spring force from an initial position in the direction of an end position. The spring, in particular, a leg spring is held by a bearing mandrill connected to the lock housing of the lock to form a single piece. In this embodiment no separate mandrill has to be rivetted by which the spring is being held. In particular, the bearing mandrill for the spring is simply produced together with the lock housing by injection moulding and is generally made of plastic. In addition, the arrangement includes a stop for a spring connected to the lock housing and the bearing mandrill to form a single piece, ensuring that the pivotable component is not spring loaded in its end position. In the end position no spring force of the spring is, however, exerted on the pivotable component. The pivotable component thus enters the end position without the pressure of the spring. This results in a considerable noise reduction compared to the case where the spring acts onto the pivotable component up into the end position. The stop is therefore also produced, in particular, by injection moulding together with the lock housing and is generally made of plastic.
The stop ensures that in the end position and preferably shortly before this position is reached, no spring force of the spring is acting on the pivotable component. In this embodiment, the spring can be pretensioned in any manner. The pretensioning of the spring can thus be selected in such a way that the pivotable component is pivoted at a desired speed and/or with a sufficient force. The stop also ensures that no spring force is acting on the pivotable component in the end position. The pivotable component is thus certainly not spring loaded in the end position, even if the spring is subjected to relative considerable pretensioning, for instance in the initial position.
In one embodiment of the invention the arrangement is a leg spring. Preferably, the lock housing contains at least two stops for the negs of the leg spring. The locks are then also connected to the lock housing to form a single piece and are again, in particular, made by injection moulding and generally from plastic. The single-piece production reduces the number of parts that have to be produced.
In one embodiment of the invention, the said stops are a side wall of the lock housing extending, in particular, parallel to the bearing mandrill. Preferably, the side wall contains a projection, which is, in particular triangular. The bottom of the projection then preferably extends at least essentially vertically to the side wall, on which the projection is mounted. The bottom of the projection thus forms in the embodiment a right angle with the side wall. In the assembled state of the spring, a leg of the spring abuts against this bottom side and is held by the projection, i.e. in the installation position, when the spring has been installed. The top of the projection extending diagonally downwards relative to the side wall then functions as a ramp, allowing the leg of the spring to be easily arranged in the correct installation position by simply pushing it down during assembly.
Another stop for a leg of the spring can be connected to the lock housing to form a single piece, irrespective of the spring leg. This stop extends, in particular, parallel to the bearing mandrill of the spring. Preferably it contains a cantilever arm serving as a guide of the respective leg of the leg spring. The leg of the leg spring then abuts this guide. This leg pivots at a certain time during the operation of the lock, in order to move a spring-loaded pivotable component from a starting position into an end position.
All in all, this embodiment allows installation of the spring before the lock housing is placed on the lock plate together with the spring or is inserted in a lock case of the lock. The lock plate or the lock case are generally made of metal. The locking mechanism is pivotably mounted on the lock plate or the lock case. This embodiment provides for a particularly simple installation.
The spring loading of the pivotable component ends preferably shortly before reaching the end position. It is thus particularly reliably ensured that the pivotable component reaches its end position. This means that as soon as the pivotable component reaches a position at which it is no longer spring loaded, it only has to be turned by several degrees to reach the end position. In this case, the component has, in particular, only to move a small distance without the support of the spring force. In one embodiment, the component does then not have to be moved more than 5° or preferably more than 3° or particularly preferably more than 1°, to reach the end position with any spring force being applied.
The pivotable component can be a pawl and/or a blocking lever. The respective component is then spring loaded in the initial position but not in the end position. In the end position the spring force does thus not act on the pivotable component. Where the pivotable component is a pawl, the opening forces required to move the pawl out of its detent position are reduced. Apart from a considerable noise reduction this case thus produces another advantage.
Below, a preferred embodiment of the invention, shown in the figures, is explained in detail. With the aid of the example embodiment, advantages of other embodiments of the invention are disclosed.
In which:
If the rotary latch 4 is not pretensioned by a spring, at least the locking bolt 3 produces a pivoting movement of the rotary latch 4 in the direction of the open position as indicated by arrow 11, when a respective motor vehicle door or a motor vehicle flap is opened. The resulting torque then pushes the main locking pawl 6 out of the detent position.
In the main locking position of the rotary latch with the motor vehicle door or motor vehicle flap closed, this is however, prevented by a pivotably mounted blocking lever 8, as shown. The blocking lever 8 is also pivotably mounted on the wall 1 and can be pivoted around its fixing axis 9. An arm 10b of a spring 10 rests against a lateral contour area of the blocking lever 8. The spring 10 is pretensioned in such a way that the arm 10b of the spring 10 pushes the blocking lever 8 in the direction of the shown blocking position. The resulting pivoting movement of the blocking lever is restricted, as shown, by a stop 12, mounted on the wall 1 as a protruding bolt.
In the embodiment shown in
The intermediate locking pawl 13 can also latch the rotary latch 4 when a protruding bolt 18 of the rotary latch 2 makes contact with the lateral blocking surface 19 of the intermediate locking pawl 13 and thus prevents pivoting of the pawl in the direction of the open position as indicated by arrow 11. Preferably, the intermediate locking pawl 13 is pretensioned by a spring, not shown, in the direction of the detent position and is spring-loaded like the blocking lever. A protruding bolt 20 mounted on the wall 1 and used as a stop, prevents further turning of the intermediate locking pawl past the detent position.
The lock according to
The invention also includes the case that the pivotable component, which is not spring-loaded in its end position, i.e. in this case the main locking pawl 6 can also be pivoted by other components. In this case, such additional pivoting can, for instance, be supported by a pivoting movement of the blocking lever 8 into the blocking position. Such additional pivoting is, however, not absolutely mandatory. The kinetic energy generated by pivoting with the aid of the spring force, regularly suffices for moving the pivotable component up to its end position, although the pivotable component is no longer spring loaded in its end position. The spring 23 is preferably retained by a mandrill 22 which is part of a lock housing made of plastic, i.e. which has been produced as a single piece with the lock housing.
Preferably the main locking pawl 6 is still spring-loaded once the intermediate locking position has been reached. If the rotary latch 4 is moved from the Intermediate locking position to the main locking position, this spring-loading suffices for moving the main locking pawl 6 into its detent position.
Number | Date | Country | Kind |
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202011000341.8 | Feb 2011 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE2012/000047 | 1/19/2012 | WO | 00 | 3/27/2014 |