DE4038551C1 - Pivot bearing for door lock setting drive in motor vehicle - - Google Patents

Abstract

The pivot bearing for a door lock setting drive in an automobile uses 2 coaxial bearing pins (9) attached to the housing (8) of the setting drive (7) on opposite sides, fitting in respective C-shaped seatings (11) provided by 2 parallel arms (10) of a holder. The seating (11) has an insertion slit (12) of slightly lesser width than the bearing pin dia. and deformable to allow insertion of the bearing pin (9). Pref. each hollow bearing pin (9) has an outer dia. of between 8 and 15 mm and a wall thickness of between 1 and 3 mm. ADVANTAGE - Simplified assembly.

Description

The invention relates to a pivot bearing for one Actuator with the features of the preamble of the patent Proverb 1. A pivot bearing with these features is known (DE 28 29 770 C2).

It is used for the semi-gimbal suspension of an actuator, whose actuator with a lock component (there a latch bel) is connected. When the actuating movement of the actuator who the slight angular deflections in relation to its longitudinal axis forced so that the actuator itself, in which the Is guided to avoid stiffness and Compliant damage to these angular deflections, so in particular must be pivotally mounted about an axis. The actuator housing has two in the known arrangement on the outside cantilevered, massive bearing journals, each in one slotted receptacle of a resilient support part can be used are, the necessary holding force in the bearing part of the recording due to a tight fit between the bearing journal and the Legs of the slotted recordings should be ensured. If the lock linkage is blocked, you can the journals mechanically out of the respective receptacles be pressed to avoid damage to the actuator itself the.  

Because the recordings in sheet metal legs of the carrier part mentioned are molded with a wedge-shaped insertion slot can have the thighs limiting them due to the high Bending moment of resistance in the flat material level not ver be shaped. For this reason, the admission to be did not know pivot bearing no C-shape in the manner of known stops have clips for cables, which in themselves because of the positive connection with the inserted component are advantageous. Rather run the lateral boundaries of the receptacle bearing parts in parallel to each other.

In another known holder for cylindrical components (US 33 66 356) is also in a carrier part made of flat mate rial with a high bending moment of resistance in its plane slotted receptacle molded in. This has the above be written C-shape, the free cross-section of their insertion slot to the outside diameter of the corresponds to the supporting component, but is not immediate ble recording of the component to be held provided. Rather, it is attached to the holder in its own slotted, deformed elastically to attach to the component cash intermediate part provided. This can be done after plugging in ver along the component in the bearing part of the receptacle to be pushed as a coupling between the component and the To serve legs of the receptacle in which the cylindrical Component can also be rotated about its longitudinal axis.

From DE 33 06 273 A1 one is not for supporting a Actuator provided rotary bearing with resilient, C-för slotted receptacles for unyielding journals knows. In each shot follows one narrowing the insertion slot each ent the journal diameter speaking rounded and with a preloaded spring clip reinforced bearing part.

The previously mentioned clips with C-shaped holders for Rods, pipes, lines etc. (e.g. US 49 00 184, FR 26 13 436 A1, GB 22 21 718 A) are all dimensioned so that at least the largest part of the elastic deformation that the Introduce a component to be held in their bearing part is required to be absorbed by her thighs.  

For actuators that are free to move during operation, i.e. to special pneumatic diaphragm piston actuators or in Hydraulic actuators are not in the idle state further measures against damage or blocking are required such. Rather, these actuators can be stored permanently which, as a rule, no frequent removal and reinstallation after initial assembly is necessary.

The invention has the task of a generic Schwenkla training in a simple manner, with simple assembly with a mold conclusive support high holding forces safely absorbed who that can.

This task is carried out with the characteristic features of Pa Claim 1 solved according to the invention.

The characteristic features of the sub-claims reveal partial developments of the pivot bearing according to the invention.

Further details and advantages are shown in the drawing Embodiment and their subsequent here detailed description.

Show it

Fig. 1 is a pivotal mounting for an actuator of egg nem lock carrier in an overall view,

Fig. 2 is a partially sectioned view of the pivot bearing compared to Fig. 1 by 90 °.

On a lock carrier 1 , which carries a door lock of a motor vehicle door, which is not described in any more detail - it should be mentioned only the indicated receptacle 2 for a locking wedge -, according to FIG. 1, a pivot lever 3 is pivotally mounted about an axis 3 A, which in turn has a Linkage 4 can act on a locking latch engaging in the receptacle 2 and defining an inserted locking wedge in the closing direction.

The overall configuration of the actuator lock forms one in itself known door closing aid device. A similar arrangement with an electromotive actuator is the subject of DE 34 14 475 C1, so that here no closer to the castle components and their interaction must be entered into. It understands however, that also an actuator of a central lock tion system, the actuator with a locking lever one Lock is coupled articulated, if necessary in the here in gela pivoted gela following manner described can be replaced.

In a pivot axis 5 , which runs parallel to the axis 3 A, the pivot lever 3 is articulated with an actuator 6 of an actuator 7 with a housing 8 . The actuator 6 guided in the housing 8 is linearly adjustable by the actuator 7 along a stroke axis 6 A, which intersects the articulation axis 5 at a right angle. With each stroke of the actuator 6 , a slight angular deflection with respect to the stroke axis 6 A is forced on it by the pivoting movement of the pivot lever 3 . In one piece with the housing 8 are therefore two outside cylindrical, inside hollow journals 9 coaxial - in a parallel to the axis 3 A of the pivot lever 3 and to the articulation axis 5 and the stroke axis 6 A at right angles intersecting pivot axis 8 S of the housing 8 - molded, of which only one is visible in Fig. 1.

Fig. 2 shows both journals 9 , which are arranged on both sides of the housing 8 , one of which is cut Darge presents.

In one piece with the lock carrier 1 , which is preferably made of strong sheet metal, two parallel retaining legs 10 are ausgebil det, in each of which a receptacle 11 with an insertion slot 12 and a round bearing part 13 is formed. Obviously, the insertion slot 12 has a smaller clear width than the bearing part 13 , so that there is a clip or C-shaped contour of the receptacles 11 . The lateral limits of the insertion slot 12 run in a wedge shape on its narrowest free cross section or constriction 14 , so that there is a flat funnel contour which facilitates the insertion of the bearing pins 9 . The center axis of the insertion slot - through which the insertion direction of the bearing pin is predetermined - is inclined relative to the stroke axis 6 A of the actuator 6 . In the vorste standing constellation, the actuating force of the actuator 7 pivots the pivot lever 3 in a clockwise direction, while the opposite movement is caused by a return spring, not shown, of a specialist actuator 7 . By the angle of the insertion slot is thus additionally ensured that the actuating force of the actuator 7 can not push the bearing pin 9 out of the receptacles 11 . In other words, a component of the actuating force of the actuator 7 , which is supported by the bearing pins 9 on the holding legs 10 , acts in the insertion direction.

In the fully inserted position, which is shown in FIG. 1, the externally cylindrical bearing pins 9 can rotate freely in the respective bearing parts 13 of the receptacles 11 , with little radial play at best. To insert the bearing pin 9 into the receptacles 11 through the insertion slot 12 narrowed relative to the bearing parts 13 , because the holding legs 10 have a high bending moment of resistance to support the actuating forces of the actuator 7 acting along the stroke axis 6 A of the actuator 6 , the bearing pins 9 or their relatively thin walls endure the entire necessary elastic deformation.

It is sufficient for the purpose described above if the narrow point 14 is formed by a one-sided projection 15 on one of the lateral boundaries of the insertion slot 12 , while the opposite lateral boundary passes approximately tangentially into the bearing part 13 . This further limits the necessary deformation of the journal 9 . It is also possible to roll the journals 9 into the receptacles 11 via the lower lateral boundary of the insertion slot 12 . They are temporarily deformed into an oval cross-section which is inherently detrimental to a pivoting bearing, which, however, can easily be accepted in view of the relatively rare installation and removal of the actuators. Experiments have shown that a pivot bearing of the type described above survives several thousand load cycles of the actuator operated with a pneumatic pressure of 2.5 bar even after repeated installation and removal.

With an outer diameter of the pipe socket-shaped bearing journals between 8 and 15 mm, these preferably have a wall thickness of 1-3 mm, depending on the type of material used. Of course they are directly at the respective warehouse part of the receptacle, subsequent narrowing of the insertion slot and dimension the wall thicknesses of the trunnions so that the The casual elastic deformation of the trunnion should not be exceeded will. Preferably an elastically deformable art fabric for the housing of the actuator and thus also for the integrally molded bearing journal used.

The execution of the storage described above enables the installation of the actuator with just one hand, whereby additional parts are eliminated and assembly costs are reduced can. Nevertheless, because of the unyielding shape  Holding leg a reliable support even high positions Forces achieved because the trunnions on a large scale angle (approx. 250 °) of the bearing parts of the recordings the.

Claims (7)

1. pivot bearing for an actuator, in particular for a door lock actuator in a motor vehicle, comprising

• two coaxial bearing journals fastened on opposite sides of a housing of the actuator,
• - A bracket with two mutually parallel holding legs, each having a slotted receptacle for transversely to the axis direction of the trunnion insertion and pivoting bearings of one of the trunnions, the receptacles are adamant to support transverse to the trunnion holding and actuating forces of the actuator ,

marked by

• - Execution of each receptacle ( 11 ) in a C-shape with a bearing part corresponding to the bearing diameter rounded bearing part ( 13 ) into which the insertion slot ( 12 ) opens, the insertion slot ( 12 ) in the region of the mouth having a narrow width compared to the bearing pin diameter ( 14 ), and by
• - Execution of the bearing pin ( 9 ) than when inserted into the La gerteil ( 13 ) within the insertion slot ( 12 ) temporarily elastically deformable pipe socket.

2. swivel bearing according to claim 1, characterized by design of the hollow bearing pin ( 9 ) with an outer diameter between 8 and 15 mm with a wall thickness between 1 and 3 mm. 3. pivot bearing according to claim 1 or 2, characterized by the formation of the bearing pin ( 9 ) in one piece with the housing ( 8 ) of the actuator ( 7 ). 4. swivel bearing according to claim 1 or 2 or 3, characterized by wedge-shaped on the constriction ( 14 ) in the region of the confluence lateral boundaries of the insertion slot ( 12 ) of each receptacle ( 11 ), the constriction directly on the bearing part ( 13 ) each Recording ( 11 ) connects. 5. swivel bearing according to claim 4, characterized by execution of the constriction ( 14 ) by one on one of the lateral boundaries of the insertion slot ( 12 ) of each receptacle ( 11 ) provided projection ( 15 ), the opposite boundary being approximately tangential in the bearing part ( 13 ) the recording ( 11 ) passes. 6. pivot bearing according to one of the preceding claims, characterized by inclined adjustment of the center axis of the insertion slot ( 12 ) of each receptacle ( 11 ) - by which the direction of insertion of the bearing pin ( 9 ) is predetermined - with respect to a lifting axis ( 6 A) of an actuator ( 6 ) of the actuator ( 7 ) such that a component te acting in the direction of the lifting axis ( 6 A), via the bearing pin ( 9 ) on the holding legs ( 10 ) supported actuating force of the actuator ( 7 ) acts in the insertion direction.