EP0627536A1 - Lock especially for vehicle doors - Google Patents

Abstract

Lock, in particular for vehicle doors, with a rotary latch (2) cooperating with a locking bolt (1) or the like, which is pivoted into a closed position and locked by a locking element (pawl 4) and with a supporting element (pivot lever 13) and a rotary latch in the closed position (2) in an open position loading elastic seal. The support element (pivot lever 13) causes an unlocking movement of the locking element (pawl 4) or initially a pivoting movement of the unlocked rotary latch (2) from the closed position to the open position on the rotary latch or on the locking element (pawl 4) or on the locking bolt or the like a resistance force that slows the unlocking movements of the locking element (pawl 4) or the pivoting movement of the unlocked rotary latch into the open position. <IMAGE>

Description

The invention relates to a lock, in particular for vehicle doors, with the features specified in the preamble of claim 1.

Such a lock is provided in DE 37 32 138 A1 on a motor vehicle door and has a control cam which is adjustable by an electric motor and which causes a delayed opening of the lock when unlocked. The delayed opening of the lock is not due to a force effect, but rather as a function of the motorized rotary movement of the control cam. A force acting between the control cam and the rotary latch is not mentioned in this document. It also has no influence on the unlocking movement of the pawl or the opening movement of the rotary latch. The lock requires an electric motor or a comparable drive. If this fails, the control cam is decoupled from the rotary latch. In this case, the lock behaves like a conventional lock that can be unlocked mechanically.

The motor vehicle door lock of DE-OS 29 11 680 contains a spring which loads the pawl for the catch, which In the usual way, the pawl automatically engages in front of a catch of the rotary latch when it is pivoted into a closed position by a locking bolt or the like when the lock is closed.

The invention has for its object to develop a lock with the features in the preamble of independent claims 1 and 2 so that when unlocking an opening bang is avoided or at least reduced so that it hardly or not disturbing.

This object is achieved in each case by the features of independent claims 1 and 2. During the unlocking movement of the locking element, an increasing pre-cut forms at the point of contact of the locking element with the rotary latch, which after the initially forced unlocking movement leads to the force of the prestressed seal in the closed position acting between the locking element and the rotary latch removing the locking element automatically from the opening adjustment range of the Spin catches out. In a particularly advantageous manner, the unlocking movement of the locking element and / or the pivoting movement of the unlocked rotary latch into the open position is slowed down by the support element. This is done in a simple manner in that the support element either with an unlocking movement of the locking element or initially with a pivoting movement of the unlocked rotary latch from the closed position into the open position on one of the lock parts, on the rotary latch or on the locking element or on the locking bolt or the like, a resistive force causes the opening of the lock slows down. In this way, an opening bang when unlocking the lock is avoided or at least reduced so that it does not or hardly disturbs. The resistance force generated by the support element can be in different ways, for example be generated by coulombic, viscous, inductive or pneumatic friction and / or an elastomer damping and / or by inertia of the support element or a component connected to it.

Advantageous embodiments of the invention are the subject of dependent claims.

Figur 1

ein erstes Ausführungsbeispiel mit einem durch einen Schwenkhebel gebildeten Stützelement,

Figur 2

ein zweites Ausführungsbeispiel mit einem Dämpfungsrad,

Figur 3

ein drittes Ausführungsbeispiel mit einem Elastomer-Dämpfer und

Figur 4

ein viertes Ausführungsbeispiel mit einem an der Drehfalle angreifenden Trägheitsdämpfer.

Four embodiments of the invention are explained in more detail with reference to a drawing. Show it

Figure 1

a first embodiment with a support element formed by a pivot lever,

Figure 2

a second embodiment with a damping wheel,

Figure 3

a third embodiment with an elastomer damper and

Figure 4

a fourth embodiment with an inertia damper acting on the rotary latch.

The lock shown in Figure 1 is provided on a vehicle door of a motor vehicle and has a rotary latch 2 which interacts with a locking pin 1 and which can be pivoted about the axis 3 between an open position releasing the locking pin 1 and the illustrated closed position. In the closed position, the catch 2 is locked by a pawl 4, which in the exemplary embodiment can be pivoted about a pawl axis 5. The rotary latch 2 has in the usual way a preliminary catch 6 and a main catch 7, which cooperate in an assigned angular position with a locking lug 8 on the pawl 4. If the locking lug 8 has completely fallen into the main catch 7 of the catch 2, as shown, the locking lug 8 rests on the main catch 7 with an area which is curved approximately around the pawl axis 5. If the pawl 4 is loaded in the direction of arrow 9 via an outside door handle or an inside door handle (not shown), the locking lug 8 interacts with an area 10 of the main catch 7 which forms an increasing pre-cut with the main catch 7 until the catch 2 is completely unlocked. As a result of this preliminary cut, the pretensioning force of a door seal pretensioned in the closed position of the lock and a spring which loads the catch 2 into an open position at the point of contact of the locking lug 8 with the main catch 7 causes a transmission force which causes a moment on the pawl 4 counterclockwise about the pawl axis 5 . This moment causes the pawl 4 to be automatically shifted from the opening adjustment range of the rotary latch 2 shortly before the rotary latch is unlocked. In order to prevent the pawl 4 from being thrown out of the opening adjustment range of the rotary latch 2, an eccentric surface 12 of a pivot lever 13 bears against a lever arm 11 of the pawl 4 in the shown closed position of the lock. A mass 14 formed on the pivot lever 13 indicates that the pivot lever 13 causes a resistance force on the pawl 4 when the catch 2 is unlocked due to its inertia, which slows down the automatic unlocking process shortly before the catch 2 is unlocked. In order to keep the mass of the pivot lever 13 as small as possible, the eccentric surface 12 is designed so that the rotational speed of the pivot lever 13 has the greatest possible value when the catch 2 is unlocked. In order to bring the eccentric surface 12 into contact with the lever arm 11 of the pawl 4 in the illustrated closed position, a spring 15 acts on the pivot lever 13, which loads the pivot lever 13 against the pawl 4. In the present embodiment, the pawl is 4 in Usually loaded from a spring 16 to the catch 2, in the closed position shown in front of the main catch 7. The direction of force of the door seal acting on the locking bolt 1 immediately after complete unlocking via the latch 2 is indicated by the arrow 26.

The second exemplary embodiment according to FIG. 2 has components comparable to the lock according to FIG. 1. To avoid a repeated description, these comparable components are provided with the same reference numbers and, in the embodiment according to FIG. 2, also provided with a superscript character. In this embodiment, too, the locking lug 8 'forms a pre-cut with an area 10' shortly before the catch 2 'is unlocked, through which the pretensioning force of the door seal and the spring acting on the catch 2' catch the pawl 4 'from the opening adjustment range of the catch 2 tried to throw out. In order to slow down this movement process, in the embodiment according to FIG. 2 a pivot lever 13 'is provided which can be pivoted about the pawl axis 5' and which forms a gear segment with an external toothing 17 which is curved in a circular arc about the pawl axis 5 '. The external toothing 17 of the pivoting lever 13 'meshes with counter-toothing 18 on a damping wheel 20 which can be rotated about the axis 19. The damping wheel 20 is immersed in a viscose liquid in a manner not shown and has blades 21, 21' projecting approximately radially outwards. When the damping wheel 20 rotates in the viscous liquid, the blades 21, 21 'bring about a resistance through which the pivoting lever 13' coming into contact with the pawl 2 'when the rotary latch 2' is unlocked before the rotary latch 2 'is fully unlocked on the pawl 4 'causes a resistance force that the specified automatic displacement of the pawl 4' from the opening adjustment range of the rotary latch 2 'slowed down. So that the pivot lever 13 'bears against the pawl 4' in the illustrated closed position or comes into contact with it after an initial unlocking movement of the pawl 4 ', there is an arm 22 of the pawl 4' and a support shoulder 23 arranged at a distance from the pawl axis 5 ' the pivot lever 13 'a spring element 24 is provided which loads the pivot lever 13' against the lever arm 11 'of the pawl 4'. The pawl 4 'is loaded in a manner similar to the first exemplary embodiment according to FIG. 1 from a fixedly supported spring 16' to the rotary latch 2 ', in the closed position in front of the main catch 7'. In this embodiment according to FIG. 2, the swivel lever 13 'on the pawl 4' only causes a resistance force which counteracts the unlocking of the rotary latch 2 '. When the lock is locked, the pawl 4 'engages in the usual way by the force of the spring 16' in front of the preliminary catch 6 'or the main catch 7', the pivoting lever 13 'being adjusted via the spring element 24.

A third exemplary embodiment according to FIG. 3 likewise has parts comparable to the exemplary embodiment according to FIG. In order to avoid a repeated description, these are provided with the same reference numbers and in FIG. 3 with a superscript character that has been changed from FIG. 2. In this embodiment, the support element is formed by an elastomer damper 25, which rests on the pawl 4 ″ when the rotary latch 2 ″ is unlocked or comes into contact in the exemplary embodiment and, due to its elastic deformation upon further unlocking, the resistance force on the pawl 4 '' causes. Due to the resistance force, the pawl 4 "is moved more slowly out of the opening adjustment range of the rotary latch 2".

The fourth exemplary embodiment shown in FIG. 4 has parts comparable to the other exemplary embodiments, which are provided with the same reference numbers in order to avoid a repeated description of these components. To distinguish them, the same reference numerals in FIG. 4 are provided with a superscript character that has been changed compared to the embodiments according to FIGS. 2 and 3. In the embodiment according to FIG. 4, in the closed position of the catch 2 '' 'locked by the pawl 4' '', there is a pivot lever 13 '' 'which can be pivoted about an axis 27 and has a support surface 12' '' on one, for example, by the pre-catch 6 '' 'formed shoulder of the catch 2' ''. The pivot lever 13 '' 'has a mass symbolized by the molding 14' ''. Initially when the rotary latch 2 '' 'is unlocked by actuating the locking pawl 4' '', the area 10 '' 'of the locking lug 8' '' reaches a pre-cut to the main catch 7 '' 'of the rotary latch 2' ''. As a result of this pre-cut, the elastic tensioning force of a door seal pretensioned in the closed position causes the pawl 4 ″ ″ to move automatically from the opening adjustment range of the rotary latch 2 ″ ″. In order to avoid a loud noise, in particular an unpleasant opening bang, the pivoting lever 13 '' 'pivoted about the axis 27 during the unlocking of the rotary latch 2' '' by its inertia effect causes a resistance force on the rotary latch 2 '' 'which slows down the unlocking process. without completely blocking it. The support element 13 '' 'is loaded by a spring 15' '' against the catch 2 '' ', which means that when the catch 2' '' is locked, the support surface 12 '' 'on the pivot lever 13' '' automatically in front of the the embodiment formed by the preliminary catch 6 '' 'on the rotary latch 2' ''.

The invention can also be implemented in a manner that differs from the four exemplary embodiments, without giving up the idea of the invention. As in the exemplary embodiments, the locking element can be a pivotable pawl or, in a modification of the exemplary embodiments, a part that can be adjusted in a straight line, for example in a straight line. The resistance force slowing the unlocking process can be brought about by coulombic, viscous, inductive or pneumatic friction on the catch, on the locking bolt or the like or on the locking element. Likewise, the resistance can be caused by elastomer damping or by inertia of a lock part directly or indirectly on one of the parts mentioned. In addition, the resistance force can be caused by a speed-dependent and / or acceleration-dependent damper, which preferably does not or hardly increases the actuating force for unlocking the locking element. If the resistance force acts on the rotary latch, this takes place at least initially when the unlocked rotary latch swivels from the closed position into the open position. The unlocking process can also be slowed down by the fact that when the locking bolt or the like is displaced relative to the rotary latch, a resistance force on the locking bolt or the like which inhibits the relative movement is brought about. The locking bolt can be formed in the usual way by a tube or a bushing, which is arranged, for example, rotatably about a pin. The pivot lever formed by a gear segment in the exemplary embodiment according to FIG. 2 can be formed by an externally or internally toothed gear.

Claims (10)

Lock, in particular for vehicle doors, with a rotary latch which is locked by a locking bolt pivoted into a closed position by a locking element loaded by the force of a spring to the rotary latch, and with a seal loading the rotary latch into an open position and a support element which, when unlocked, is in the closed position Delayed opening of the lock, characterized in that after an initially forced unlocking movement of the locking element (locking pawl 4, 4 ', 4'',4'''), at which the contact point of the locking element (locking pawl 4, 4 ', 4 '', 4 ''') with the rotary latch (2, 2', 2 '') forms an increasing pre-cut, then the locking element (pawl 4, 4 ', 4'',4''') is formed by the pre-tensioning force the seal automatically moves from the opening adjustment range of the rotary latch (2, 2 ', 2'') and thereby the support element (pivot lever 13, 13', 13 ''', elastomer damper 25) on the rotary latch or on the locking element (Pawl 4, 4 ', 4'',4''') or on the locking bolt or the like causes a resistance force that the automatic Unlocking movement of the locking element (pawl 4, 4 ', 4'',4''') slowed down. Lock, in particular for vehicle doors, with a rotary latch which is locked by a locking bolt pivoted into a closed position by a locking element loaded by the force of a spring to the rotary latch, and with a seal loading the rotary latch into an open position and a support element which, when unlocked, is in the closed position Delayed opening of the lock, characterized in that after the complete unlocking of the rotary latch, the support element initially causes a resistance force with an automatic pivoting movement of the rotary latch from the closed position into the open position on the rotary latch or on the locking element or on the locking bolt or the like the automatic pivoting movement of the unlocked rotary latch slows into the open position. Lock according to claim 1 or 2, characterized in that the resistance is caused by coulombic, viscous, inductive or pneumatic friction and / or elastomer damping and / or by inertia. Lock according to one of claims 1 to 3, characterized in that the resistance is caused by a speed- and / or acceleration-dependent damper which does not or hardly increases the actuating force for unlocking the locking element. Lock according to one of claims 1 to 4, characterized in that the support element is a pivot lever (13, 13 ', 13''') which is supported by a spring (15, 24, 15 ''') against the locking element (pawl 4, 4') or the rotary latch (2 '''). Lock according to claim 5, characterized in that the pivot lever (13) bears with an eccentric surface (12) on the locking element (pawl 4) or on the rotary latch and is designed such that the rotational speed of the pivot lever (13) when unlocking the rotary latch (2) or initially when the pivoting movement of the unlocked rotary latch into the open position has the greatest possible value in order to correspondingly reduce the mass (14) of the pivoting lever (13) causing the resistance force due to inertia. Lock according to claim 5, characterized in that the pivoting lever (13 ') is a gearwheel or gearwheel segment which meshes with counter-teeth (18) on a damping wheel (20) which engages with blades (21, 21') engaging in a viscous liquid. the resilience causes. Lock according to claim 7, characterized in that the gear or gear segment (swivel lever 13 ') against the lever arm (11') by a spring element (24) arranged between the locking element (pawl 4 ') and the gear or gear segment (13'). ) of the locking element (pawl 4 ') is loaded. Lock according to one of claims 1 to 4, characterized in that the support element is an elastomer damper (25) which, when the rotary latch (2 '') is unlocked, bears against the locking element (pawl 4 '') or comes to rest and passes through its elastic deformation upon further unlocking causes the resistance to the locking element (pawl 4 ''). Lock according to one of claims 1 to 9, characterized in that the locking element is a pivotable pawl (4, 4 ', 4'',4''') which is supported by a spring (16, 16 ', 16'', 16 ''') to a locking shoulder (pre-locking 6, 6', 6 '', 6 ''', main locking 7, 7', 7 '', 7 ''') of the rotary latch (2, 2', 2 '', 2 ''').

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