DE10105445B4 - Ratchet closure - Google Patents

Abstract

Rotary latch lock with a housing (3) and with a rotary latch (6) held in the locking position by a pawl (9), which pawl (9) is driven by an electric motor and has a spindle nut (16, 40) and a screw spindle (14) can be released, the spindle gear remaining in its position releasing the pawl (9) as long as the electric motor (19, 36) is energized and is then displaced back by means of the force of an energy storage device charged during axial displacement, the screw spindle (14) or the spindle nut (16, 40) is secured against rotation during the axial displacement in above the housing (3), characterized in that the anti-rotation device relative to the housing (3) is canceled for the return displacement into the position assigned to the pawl (9).

Description

The invention relates to a rotary latch closure according to the preamble of claim 1.

A rotary latch lock is out of the EP 0159 238 known. An electric motor drives there a screw spindle, which is inserted in a threaded portion of a spindle nut. The spindle nut is acted upon by a force storage spring and engages a transmission lever in order to displace a pawl in a release position in a linear displacement of the spindle nut in the direction of the rotated screw. The bore of the spindle nut, which is penetrated by the screw, not only has a section with internal thread, but also an angular offset section lying, which is thread-free, so that by tilting the spindle nut, the latter can move axially over the screw spindle.

The DE 196 27 076 C1 also describes a rotary latch closure, wherein the pawl can be brought from a blocking position into a release position by means of a spindle nut riding on a screw spindle. A similar closure also describes the DE 35 33 721 ,

The invention has for its object to increase the utility value of a generic rotary latch closure.

The object is achieved by the invention specified in the claims.

The task of the electric motor consists exclusively in axially displacing the spindle nut or the screw spindle via the spindle gear, whereby the pawl reaches the release position for the catch. During this displacement, the screw spindle or the spindle nut is secured against rotation, so that the axial displacement is possible. For return displacement of the screw or the spindle nut in the pawl to collapse releasing position, the anti-rotation is released. There is thus superimposed an axial movement of the screw or the spindle nut and a rotational movement thereof. This movement results from the stored in the forward displacement energy storage. In detail, according to the invention, the procedure is such that the screw spindle or the spindle nut is held in a first rotationally secured position during the axial displacement and leaves it shortly before reaching the displaced end position and, by a slight partial rotation, assumes a second rotationally secured position, which after only minor, is left by the spring induced return displacement, so that only by spindle or Spindelmutterdrehung at substantially non-co-rotating spindle nut or spindle, the starting position is reached. The slight partial rotation in the second rotationally locked position is required so that the backward displacement is possible. As soon as the second rotationally secured position is left, the screw spindle or the spindle nut can return to the initial position by the superimposed rotation. To realize the first rotation lock a housing-side slide shoulder is provided. Along this slides the radially projecting cam of the screw or the spindle nut. When leaving the slide shoulder then takes over the second rotation lock the radially projecting cam. This looks in detail so that the second rotation lock arranged an angle offset to the sliding shoulder, housing-fixed stop forms. Then it is provided according to the invention that after leaving the stop freely turning back on a helix cam almost makes a 360 ° rotation or a more than 360 ° rotation. This rotation is limited by the housing-side slide shoulder. Alternatively, however, it is also possible that the second rotation lock is achieved by a flattening of the pawl facing the spindle end in cooperation with a wide surface of the pawl. While the cam leaves the housing-side slide shoulder during the unlocking process, the flattening facing the pawl in conjunction with the wide surface takes on the task of the second rotation lock. However, during the return displacement of the screw spindle, flattening and wide surface are removed before the cam has reached the slide shoulder. It can therefore be superimposed on the spring-induced rotation of the screw spindle by the longitudinal movement, wherein the rotation is then limited by the slide shoulder. Another version is characterized in that the cam extends radially by applying a stop associated with the rearward position against the force of a spring to slide on the radially farther sliding shoulder, wherein the radial distance of the sliding shoulder of the spindle is so large that the Cam when relocating past it runs.

This ensures that when driving the spindle gear in one direction, the cam is effectively applied to the slide shoulder and thus forms a rotational security. On the other hand, the return displacement ensures that the cam moves past this sliding shoulder. According to the invention, the cam may be a pivoting cam. In detail, this may look like the cam is one end of a rocker. The possibility is then given that the cam of the spindle nut is assigned. Along with a rotary displacement of the spindle, this and thus also the cam moves in the axial direction. As soon as the cam leaves the sliding shoulder, the stop fixed to the housing comes into action. This acts with a radial recess of the Spindle nut together and thus holds the same in the axially advanced position. A reversal solution may consist in that the cam associated with the spindle or the spindle nut is associated with a sliding shoulder displaceable radially inwards by the cam against the force of a spring. In detail, this then looks like that the movable slide shoulder pivots radially inwardly according to a cam engagement of one of the movable slide shoulder associated stop. To achieve high reliability, a measure is taken that the screw remains in its second rotationally secured position as long as no rotation of the rotary latch has taken place in the opening direction. This opening rotation must be done so far that then in the return displacement of the screw and releasing the pawl to shift to its blocking position, this can no longer occur in the pre-locked position. It can therefore not be the case that after triggering the pawl only a slight opening rotation of the catch occurs with concomitant return displacement of the screw in the starting position. This could then cause the pawl enters the catch position in Vorraststellung. It would then have the tailgate again closed and reopened. To avoid this, the invention provides a locking lever holding the screw in its axially displaced position, which is brought by displacing the catch from the locking position to an open position in an automatic return displacement of the screw in its starting position permitting alternate position. For this purpose, the safety lever is in particular spring-loaded from its evasive position in its the screw back-displacement locking locking position displaced and locked there, which latching is canceled in particular cam-controlled by pivoting the catch. Accordingly, the rotary latch is used to control the safety lever itself. The modulation is then in the position in which the pawl could no longer occur in a detent position to the catch. To realize this cam control in a simple manner, the safety lever is designed as a fork-shaped, spring-loaded in one direction against a stop lever whose one fork leg cooperates with the screw and the other fork leg is acted upon by a control cam of the rotary latch.

Hereinafter, several embodiments of the invention will be explained with reference to the drawings. It shows:

1 a view of an inventively designed rotary latch closure in the locked position, shown partially in section,

2 one of the 1 comparable representation, wherein deviating the pawl is rotated by the screw into a position releasing the catch,

3 the following presentation of the 2 , but with screwed back into the starting position screw,

4 a perspective view of the screw drive with the screw associated with the sliding shoulder along with angular offset arranged to this, fixed housing stop,

5 a representation like 4 , wherein the radially projecting cam of the screw spindle is no longer supported on the slide shoulder, but on the stop,

6 an end view of the 4 .

7 an end view of the 5 .

8th the second embodiment of the rotary latch closure in the locked position,

9 the following presentation of the 8th wherein the pawl is brought by the screw in its release position, allowing the opening rotation of the rotary latch,

10 the following presentation of the 9 , wherein the return displacement of the screw spindle has taken place in the starting position,

11 in a schematic representation of the view in the direction of arrow XI in 8th .

12 the essential components of the rotary latch closure according to the third embodiment with befindlichem in its initial position safety lever,

13 the following presentation of the 12 , wherein the forward displacement of the screw has taken place, the return displacement is locked by the drehfallenaussteubaren safety lever,

14 a plan view of the partially illustrated rotary latch closure according to the fourth embodiment, in the region of the spindle gear in the locking position engaging pawl,

15 one of the 14 corresponding plan view, wherein the pawl controlling, acted upon by the spindle nut carriage is indicated by dash-dotted lines,

16 the section on the line XVI-XVI in 14 .

17 the section according to the line XVII-XVII in 15 .

18 one of the 14 comparable representation, but with an intermediate position of engaging spindle nut,

19 the following presentation of the 18 in which the spindle nut has reached its pre-displaced, stop-secured position,

20 the section along the line XX-XX in 18 and

21 the section along the line XXI-XXI in 19 ,

The in the 1 to 7 illustrated rotary latch is as a whole with the numeral 1 designated. He finds particular use in non-illustrated tailgates of passenger cars. The closure 1 This is mainly on the tailgate 1 set and works together with a body-side, in 1 dash-dotted lines indicated counter-closing part 2 , With respect to the same may be, for example, a U-shaped bent striker.

The rotary latch closure 1 has a lock housing 3 with arranged in the closing direction entrance slot 4 for the counter-closing part 2 , On one side of the entry slot 4 stores around an axis 5 a catch 6 with a rim-sided fork opening 7 for catching the counter-closing part 2 ,

On the other side of the entry slot 4 carries the lock housing 3 a journal 8th around which a pawl 9 is rotatably arranged. A not shown, between the catch 6 and pawl 9 extending tension spring loaded the pawl 9 clockwise in the direction of the catch 6 while this has the tendency to pivot counterclockwise in its open position.

The pawl 9 molds in its middle area at the catch 6 facing side a locking projection 10 , which with a Hauptrastausnehmung 11 and a downstream Vorrastausnehmung 12 the catch 6 interacts.

The free earth 13 the pawl 9 extends according to located in the locking position rotary latch closure 1 with a slight distance in front of the front end of a screw spindle 14 which transversely directed to the closing direction in one in the closure housing 3 used bearing housing 15 is angordnet. The screw spindle 14 passes through a spindle nut 16 , which in turn rotatably with a spur gear 17 connected is. At the latter engages the drive pinion 18 one in the bearing housing 15 accommodated electric motor 19 at.

That of the pawl 9 opposite end of the screw 14 is the carrier of a disc firmly attached to it 20 , This is from a radially extending, pin-like cam 21 surmounted. Between the disc 20 and the spindle nut 16 is the screw spindle 14 from a compression spring 22 covered, the ends of which on the one hand on the disc 20 and on the other hand on the spindle nut 16 are fixed. In this way, a certain rotational bias can be achieved, which is used to ensure that the radial cam 21 in the in 1 . 3 . 4 and 6 drawn starting position on the upper side of a housing-side slide shoulder 23 supported. This puts the slide shoulder 23 a first rotation lock for the screw spindle 14 Immediately following the slide shoulder 23 extends angularly offset to the sliding shoulder 23 a the second rotation fuse forming housing fixed stop 24 compare in particular 4 to 7 , The rotation angle offset is chosen so large that the transition of the cam 21 from the first rotation lock to the second rotation lock the slide shoulder 23 at such a distance to the stop 24 which is larger than the diameter of the cam 21 ,

The following mode of action occurs:
Take the rotary latch lock 1 in the 1 illustrated locking position and should take place the opening of the rotary latch closure or tailgate, so first is the electric motor 19 to initiate or energize. This can be caused for example via a remote control or by an operation by a handle, key, etc. Together with a current supply of the electric motor 19 drives this over the drive pinion 18 and spur gear 17 the spindle nut 16 at. Because the screw spindle 14 through the radially aligned cam 21 in cooperation with the sliding shoulder 23 secured to a rotation, this drive leads to an axial advancement of the screw 14 , which in this process with its free front end the end 13 the pawl 9 and put them into position according to 2 pivoted. This gives the locking projection 10 the catch 6 free for rotation in the open position. With reaching the Endverlagerungsstellung the screw 14 to 2 has the cam 21 the sliding shoulder 23 leave. About the compression spring 22 now inevitably the screw is rotated so that the cam immediately against the stop 24 occurs and thus holds the screw in the second anti-rotation position. This is done by the force of the spring 22 after only leave slight Rückerlagerung, so that by simply spindle rotation with substantially non-rotating spindle nut 16 the starting position according to 3 is reached. That means the screw spindle 14 doing a superimposed rotary and axial movement. After leaving the stop 24 goes through the cam 21 a helical line, turning slightly less than 360 °. When closing the tailgate is then by the counter-closing part 2 the closing rotation of the catch 6 enforced, with the pawl 9 after overrunning the Vorraststellung in the main rest position according to 1 arrives.

According to the second embodiment of the 8th to 10 same components bear the same reference numbers. Deviating now the second rotation is realized. The sliding shoulder 23 is shorter than the first embodiment. Then this is the pawl 9 facing end 14 ' the screw spindle 14 with a flattening 25 provided so that about a half moon stops in the local area, which is slightly smaller than half of the end 14 ' , see. 11 , Due to this, the screw can 14 with the end 14 ' along a broad surface of the free end 13 the pawl 9 pass by, whereby the second rotation lock is realized. This looks in detail so that after a triggering operation of the rotary latch closure 1 first one through the shortened slide shoulder 23 effected rotation lock takes place. The second rotation lock can occur in this version before the cam 21 the sliding shoulder 23 leaves. The unlocked position goes off 9 out. Then the screw spindle has 14 axially displaced to its extreme end. After stopping the electric motor 19 becomes the compression spring 22 effective, which the screw spindle 14 according to their starting position 10 transferred, wherein the first rotation lock comes into force, namely by the fact that the cam 21 turn on the slide shoulder 23 supported while the second rotation lock is released. Before in this return displacement of the cam 21 the sliding shoulder 23 reached, is the second rotation lock between wide surface of the end 13 the pawl 9 and flattening 25 lifted, causing the screw spindle 14 spring-driven in addition to its longitudinal displacement is able to turn, which rotational movement with reaching the slide shoulder 23 is ended.

The third embodiment according to the 12 and 13 largely corresponds to the first embodiment. Again, the same components carry the same reference numerals. In addition, now is the screw 14 in its pre-translated position retaining safety lever 26 intended. It is fork-shaped and supports a housing-fixed pin 27 , A set around this torsion spring 28 loads the safety lever 26 counterclockwise. The rotary displacement is limited by that on the screw spindle 14 sitting disc 20 , The one on this supporting fork legs 29 forms a barrier shoulder at its free end 30 while the other fork leg 31 with a control cam 32 the catch 6 interacts. The lock-up 30 upstream section assumes the function of the sliding shoulder 23 for the cam 21 ,

Opening the rotary latch lock 1'' according to this third embodiment also requires the initiation of the electric motor 19 , The screw spindle shifts in unison 14 as in the first embodiment, from the first anti-rotation position to the second anti-rotation position. In this occurs the safety lever 26 Fedebeaufschlagt with his locking shoulder 30 in front of the free front end of the disc 20 and thus concludes a return displacement of the screw 14 first off. This position is in 13 illustrated. So that the return displacement can take place, the tailgate is open to be connected with a rotary displacement of the catch 6 , Only when the Vorrastausnehmung 12 the locking projection 10 happens, the control cam can 32 the catch 6 take effect by the fork leg 31 is charged. This leads to a pivoting of the safety lever 26 against spring loading in the clockwise direction. This will cause the screw spindle 14 Released to return to their starting position, so that then the position of the screw according to 12 established.

The pawl 9 can then turn on the edge of the catch 6 so that it is ready for a new closing operation to step over the pre-restraint in the Hauptastastposiion.

According to the fourth embodiment, shown in FIGS 14 - 21 , is with the numeral 33 denotes a bearing housing, which is assigned to the unillustrated closure housing. Of this is only partially the pawl 9 illustrates which serves to lock the catch in the locked position.

In the longitudinal extension of the bearing housing 33 is in this an externally toothed spur gear 34 stored, of which material uniformly centrally the screw 14 emanates. Their free end also finds storage in the bearing housing 33 , The spur gear 34 meshes with a bearing pinion 35 , which on the drive shaft of a bearing housing 33 used electric motor 36 ,

On a part of its length becomes the free end of the screw spindle 14 from a tax sled 37 flashed. The latter is by means of longitudinal rails 38 of the bearing housing 33 guided. A compression spring 39 grabs the steering slide 37 and loads it in the direction of one on the screw 14 running spindle nut 40 , The tax sled 37 in turn is in cooperative engagement with the free end of the pawl 9 , That means that along with a displacement of the tax sled 37 also the pawl 9 is pivoted.

With non-driven electric motor 36 displaces one on the free end of the screw spindle 14 arranged, on the front side of the bearing housing 33 supporting compression spring 41 the spindle nut 40 in an in 14 and 15 illustrated stop position in which the spindle nut 40 a transverse wall 42 of the bearing housing 33 is adjacent. The spindle nut 40 stores a seesaw 43 by means of these molded pins 43 ' , which in marginally open Lagerern 44 on the circumference of the spindle nut 40 are clipped. At one end forms the rocker 43 a cam 45 , which is thereby formed as a pivoting cam. This swing cam 45 tangentially projects beyond the outer circumference of the spindle nut 40 while the other seesaw end 46 is aligned with the outer circumference of the spindle nut and is thus aligned concentrically to the spindle axis.

One the one pin 43 ' associated torsion spring 47 loads the rocker 43 in a stop position to the spindle nut 40 , where the swing cam 45 at a radial shoulder 50 the spindle nut 40 supported, cf. 16 , In this position is the swing cam 45 at the same time support on a housing-side stop 48 , which one parallel to the screw spindle 14 running shoulder 49 is upstream. The radial distance of the slide shoulder 49 from the screw spindle 14 is greater than the one of the stop 48 so that the cam 45 during the return displacement of the spindle nut 40 on the slide shoulder 49 can pass by.

The the control slide 37 facing end face of the spindle nut 40 is with a radial recess 51 Mistake. One flank continues into a peripheral surface of the spindle nut 40 outstanding stop bridge 52 , which with a housing-fixed stop 53 interacts. The latter is according to 15 in overlap with the screw spindle 14 and is at an axial distance beyond the slide shoulder 49 arranged.

According to this fourth embodiment, the following mode of action is established:
To open the rotary latch closure is the electric motor 36 to initiate. This is followed by the screw spindle 14 in the direction of arrow according to 16 driven. This leads to a displacement of the spindle nut 40 in the direction of the control slide 37 , that is, that the cam 45 for now at the stop 48 supports, then radially extends to on the radially distant shoulder 49 slide along. An intermediate position is required 18 and 20 out. Before the cam 45 the sliding shoulder 49 leaves, is the radial recess 51 in the area of the housing side stop 53 arrives. Due to the now released for rotation spindle nut 40 this can be taken to a small angle of rotation due to the frictional engagement with the screw. This is limited by the fact that the stop bar 52 the radial recess 51 , as in 21 is shown, the housing-fixed stop 53 applied and thus the rotation of the spindle nut 40 shuts down. Coming in is over the control sled 37 the pawl 9 pivoted into its release position. The electromotive drive is switched off. Now the compression spring 41 be effective. Their power is supported by the control slide 37 associated compression spring 39 , so that an application of the spindle nut 40 takes place in the direction of the relocated position. Once the spindle nut 40 from the sphere of action of the housing fixed stop 53 she can step on the screw spindle 14 Relocate connected with a self-rotation, wherein the cam 45 then on the slide shoulder 49 passes in order to return to the area of the stop in the final phase of the reverse rotation 48 to arrive, so that the position according to 14 to 17 is present again. In this position, the control slide acts 37 two limit switches assigned to it 54 . 55 what is communicated to the controller.

A reversal solution could be realized by associating with the cam, which is fixedly connected to the spindle or the spindle nut, a sliding shoulder which can be displaced radially inwardly against the force of a spring. The latter then pivots in a radial inward direction as a result of a cam engagement of a stop assigned to the movable slide shoulder.

Claims (16)

Rotary latch closure with a housing ( 3 ) and with one of a pawl ( 9 ) in the locking position held catch ( 6 ), which pawl ( 9 ) by means of an electric motor driven, a spindle nut ( 16 . 40 ) and a screw spindle ( 14 ) Spindle gear is releasable, the spindle gear so long in his the pawl ( 9 ) releasing position, as the electric motor ( 19 . 36 ) is energized and then shifted back by means of the force of a charged in the axial displacement force accumulator, wherein the screw spindle ( 14 ) or the spindle nut ( 16 . 40 ) during the axial displacement into which the pawl ( 9 ) releasing position relative to the housing ( 3 ) is rotationally secured, characterized in that the return displacement in the pawl ( 9 ) assigned position the Anti-rotation against the housing ( 3 ) is canceled. Rotary latch closure according to claim 1, characterized in that the screw spindle ( 14 ) or the spindle nut ( 16 . 40 ) is held during the axial displacement in a first anti-rotation position and this leaves shortly before reaching the displaced end position and by a slight partial rotation occupies a second, rotationally secured position, which after only slightly, by the spring ( 22 . 41 ) is left back displacement, so that by simply spindle or Spindelmutterdrehung ( 16 . 40 ) with a substantially non-rotating spindle nut ( 16 . 40 ) or spindle ( 14 ) the starting position is reached. A rotary latch closure according to claim 2, characterized in that the first rotation lock of a housing-side slide shoulder ( 23 . 49 ) is formed along which a radially projecting cam ( 21 . 45 ) of the screw spindle ( 14 ) or the spindle nut ( 16 . 40 ) slides. A rotary latch closure according to claim 3, characterized in that the second rotation lock is angularly offset from the sliding shoulder ( 23 . 49 ) arranged fixed housing stop ( 24 . 53 ). Rotary latch closure according to one of claims 3 or 4, characterized in that after leaving the stop ( 24 ) freely rotating cams on a helix ( 21 . 45 ) makes almost a 360 ° turn or a more than 360 ° turn. A rotary latch closure according to any one of claims 2 to 5, characterized in that the second anti-rotation of a flattening ( 25 ) of the pawl ( 9 ) facing spindle end ( 14 ' ) in cooperation with a wide surface of the pawl ( 9 ) is achieved. Rotary latch closure according to one of claims 3 to 6, characterized in that the cam ( 45 ) by applying a stop assigned to the rearward position ( 48 ) against the force of a spring ( 47 ) radially extends to on the radially farther sliding shoulder ( 49 ), wherein the radial distance of the sliding shoulder ( 49 ) from the spindle ( 14 ) is so large that the cam ( 45 ) when relocating past it. A rotary latch closure according to any one of claims 3 to 7, characterized in that the cam ( 45 ) is a swing cam. A rotary latch closure according to any one of claims 3 to 8, characterized in that the cam ( 45 ) one end of a rocker ( 43 ). Rotary latch closure according to one of claims 3 to 9, characterized in that the cam ( 45 ) of the spindle nut ( 40 ) assigned. Rotary latch closure according to one of claims 4 to 10, characterized in that the housing-fixed stop ( 53 ) with a radial recess ( 51 ) of the spindle nut ( 40 ) cooperates. Rotary latch closure according to one of claims 3 to 11, characterized in that the stationary of the spindle ( 14 ) or the spindle nut ( 16 . 40 ) associated with the cam is assigned a radially inwardly displaceable from the cam against the force of a spring sliding shoulder. A rotary latch closure according to claim 12, characterized in that the movable slide shoulder pivots radially inwardly as a result of a cam engagement of a stop assigned to the movable slide shoulder. Rotary latch with one of a pawl ( 9 ) in the locking position held catch ( 6 ) which pawl ( 9 ) by means of a motor driven by a spindle nut ( 16 ) axially displaceable screw spindle is releasable, wherein the screw spindle ( 14 ) so long in their the pawl ( 9 ) releasing position remains as the electric motor is energized and then by means of the force of a charged in the axial displacement force accumulator ( 22 ), wherein the screw spindle ( 14 ) during the axial displacement in the pawl ( 9 ) releasing position is secured against rotation, characterized by a the screw spindle ( 14 ) holding in its axially displaced position securing lever ( 26 ), which by shifting the catch ( 6 ) from the locking position into an open position into an automatic return displacement of the screw spindle ( 14 ) is brought into its starting position allowing evasive position. Rotary latch closure according to claim 14, characterized in that the safety lever ( 26 ) Federkraftbagt in particular by its evasive position in his the screw spindle ( 14 ) backlash blocking locking position is verlagaberbar and locked there, which latching by pivoting the catch ( 6 ) is canceled in particular cam-controlled. Rotary latch closure according to one of claims 14 or 15, characterized in that the safety lever ( 26 ) is formed as a fork-shaped, spring-loaded in one direction against a stop lever whose one fork leg ( 29 ) with the screw spindle ( 14 ) and interacts whose other fork leg ( 31 ) of a control cam ( 32 ) the catch ( 6 ) can be acted upon.

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