DE10043574A1 - Device for driving a cam lever controlled rotating spring lock includes a locking part for locking up a latch part moved by a motor-driven swiveling cam from a locking position into an opening position. - Google Patents

Abstract

A locking part (2) is moved by a motor-driven swiveling cam (3) from a locking position into an opening position that releases a latch part (1). To make the operating form safe, the swiveling cam that stops in a swiveling position corresponding to the opening position switches over during release triggered by movement in the latch or locking parts in such a way that the locking part take up its locking position.

Description

The invention relates to a drive arrangement for a a locking part locking part, the locking part by a motor-driven swivel cam from a locking position in a releasing the hook part Open position is shiftable.

Such a drive arrangement shows the DE 197 47 211. A drive pulley by a Snail is motor driven, carries a cam. This cam acts on one arm of a two-armed Lever, the other arm of which forms a pawl, to keep a catch in a locked position, in which the catch a counter closing part in the Ge closed position of a flap, door or the like can hold a motor vehicle. If the cam is ge swings, he moves the two-armed lever with the Consequence that the pawl from its locking position in the opening position is shifted. In this opening position the rotary latch from its locking position swivel into an open position so that the Emerge counter-locking part from the rotary latch mouth and can be caught again by the rotary trap mouth.

The invention has for its object a genus appropriate rotary latch lock to make it more reliable.

The invention specified in the claims serves for Solving this task. In particular, it is provided that the one corresponding to the open position Swing cams stopping at one of a movement of the hook part or the locking part derived trip evades such that the lock  can take part of its locked position. According to one preferably elastic deflection movement of the swivel cam to the motor drive, the locking part can Stopping the swivel cam in the open position corresponding position back to the locked position be moved back because the swivel cam is elastic can dodge. In particular, it is provided that the energy accumulator when swiveling the cam one of the blocking positions corresponds to the opening position appropriate swivel position from the motor drive that will. The lift mechanism discharges after tripping solution. Preferably, the discharge of the energy accumulator with the result that the swivel cam continues to rotate. For this purpose, the energy accumulator can be a torsion member Area of the drive shaft for the swivel cam. The energy store is preferably used by an intermediate Swivel cams and a drive pulley arranged biased spring formed. Between swivel cams and drive pulley can turn a stop limited clearance should be provided. The release of the power spit chers can after an application of the hook glie of the done. This is particularly as a catch educated. It can be triggered by swiveling the catch from a catch position for a counter locking part in a lock that can be locked at the front position. The trigger can be in the way an additional torque application of the swivel cams are made, so that frictional forces that pivot cam in the position corresponding to the open position Hold swivel position, be overcome. The torque can be applied by tensioning a spring conditions that attack the swivel cam. The spring can between the hook part or .. rotary latch and swivel cam be excited. It can further be provided that the Triggered by swiveling the rotary latch from a lock  position in one of the counter locks held by her the releasing release position takes place. It can the pawl when swung open by spring force the catch of this from the sphere of influence of the Be pivoted. The turn release the lock when swinging open on a control edge slide along the pawl. When the arrangement according to the invention rotates the pivot cam continuously with a closing operation of 360 °. He turns from one of the locked positions neten swivel position and passes through the ratchet ke swiveling in an open position lung. The swivel cam has in this swivel position the pawl is shifted by an eccentric scher extension of the swivel cam a control shoulder the pawl is applied. This loading works along with friction. The opening position is continuous run over in a rotating manner. The swivel cam swivels only again in a swivel position in which the Pawl can assume its locking position if the when reaching the open position from the locks swiveled-out catch is stored. In the event of a malfunction, at wel the swivel cams are in the swivel position remains in which he pawl in its opening position has pivoted, can be arranged according to the rotary latch did not lose the state of the art be valid. Will the catch in the prior art pivoted back from the catch position, so is the Pawl on pivoting back into its locked position blocked. The swivel cam can according to the invention dodge elastically, so that the blocking part is ingested Allow blocking position, although the swivel cam in a position corresponding to the open position Swivel position has stopped. In a variant  the invention provides that the pivot cam escapes from the sphere of influence of the blocking part and remains in the evaded position. He can a further rotation of the drive wheel from the alternative position back to its active position be tied. The swivel cam can radially ver sit slidably on the driven pulley. That remains Swing cams in one of the opening positions of the lock part corresponding swivel position, so lies preferably a control shoulder of the swivel cam in Area of influence of a control extension of the hook part. The hook part can also be designed as a catch his. The control extension can be a wedge-shaped Have shape so that the opening or closing of the The catch engages the control shoulder in such a way that the swivel cam is pushed into its evasive position becomes. The eccentric fort enters this position set of swivel cams from the area of influence of the Blocking part. The swivel cam can tilt as a result spring held in its two bistable states his. The control shoulder of the swivel cam can be opened a separate control disc, which is fixed with the swivel cam is connected. The control disc can form a wedge-shaped control cam, which for Move the swivel cam back out of the alternative position together with a control cam fixed to the housing works.

Another variant of the invention stands out through out that the unencumbered swivel cam in one in two opposite directions by overwin the means that can be evaded by a restoring force position is held and when stopping the swivel cam in the area of influence of the blocking part from the to Locking position swiveling locking part out of  Middle position is shifted. Here too is real that in an unfavorable standstill position of the Swivel cam this can be shifted from the locking part, that the locking part is in the locked position towards the hook part can swing. In this particular case happens this is because the swivel cam from the middle part lung is moved accordingly. This is how it looks in detail that the locking part forms a control shoulder, which with a particular in the form of a pin trained counter-control shoulder of the swivel cam cooperates. Associated with the coming in of the lock partly its tax shoulder acts on the counter school ter of the swivel cam and turns it into one such position that the complete collapse of the Allows locking part in the locked position. One deviate de Design of the invention is that the Swivel cams two meeting in one vertex Tax curves trains with a tax advantage of the locking part cooperate such that the locking part of the rotary-driven swivel cam by sliding ten of the control lead on a control curve in the swivel position corresponding to the open position pivots, the swivel cam from one side reliable by overcoming a restoring force Middle position is brought into which middle position the swivel cam again after relocating the locking part returns, and wherein the tax advance on impact fen on one of the two control curves of the middle position held swivel cam this from the Mit position shifted. Depending on the standstill of the in flow area of the blocking part standing swivel cam acts the tax advantage of the locking part with one or other control curve together to then due to the suspended middle position of the swivel cam twisting in one direction or another, what that  then swiveling the locking part into the blocking position allowed. It is envisaged that the control curves meet at a peak. Opti The control is lubricated by the fact that the tax projection is pointed. The acute angle of the control curve and the control projection can preferably be between 30 ° and 60 °. A double function fulfills that Hook part and tension spring loading the locking part there through that the power to tax-controlled Relocation of the swivel cam from the on the locking part attacking tension spring comes. It is also possible Lich that the swivel cam form several extensions det. These in turn form two in one Top-fitting control curves. It turns out to be invented In accordance with the fact that the extensions are star-shaped are arranged. Then it is possible according to the invention that triggering by one of the hook or lock partially displaceable pawl. It is with it achieved that the locking part according to the regulations Closing the lock in the blocking position Hook part kicks. It makes sense that the Thrust pawl is designed as a tappet and with teeth attacks on a driving projection of the locking cam. The teeth themselves are sawtooth-shaped, and cause the pawl to only move in one direction works. The pawl, on the other hand, is owned by one Release finger actuated. The latter can on the hook part be provided so that when pivoting the hook partly by a locking block or striker Release finger comes into contact with the pawl and thereby the swivel cam from an unfavorable position also twisted so that the locking catches partly in the blocking position is possible.

Embodiments of the invention are as follows explained with the accompanying drawings. Show it:

Fig. 1 shows a schematic representation of a erfindungsge Permitted assembly according to a first embodiment form the example of a rotary latch lock in the closed position,

Fig. 2 is a section along the line II-II,

Fig. 3 is a sequence view of FIG. 1, wherein the swing cam in a stops the lung corresponding pivotal position of the opening Stel,

Fig. 4 shows a representation according to capture a mating closure member, not shown,

Fig. 5 is a sequence view of FIG. 4,

Fig. 6 is a view corresponding to Fig. 3, wherein the swing cam shortly before one of the open position stops corresponding pivot lung Stel,

Fig. 7 is a sequence view of FIG. 6 after triggering,

Fig. 8 shows an illustration according to FIG. 1 of a second embodiment,

Fig. 9 shows a representation according to FIG. 8, wherein the swing cam stops corresponding pivotal position in one of the open position,

Fig. 10 is a representation of the trigger,

Fig. 11 is a sequence view of FIG. 10,

Fig. 12 shows a representation according to capture a mating closure element at the opening in a corresponding pivotal position Stel lung geschwenk te swing cam,

Fig. 13 shows a third embodiment of the invention in the closed position,

Fig. 14 is a motion sequence view of FIG. 13, in which the swing cam position, the opening of the locking member corresponding pivot passes through position,

Fig. 15 is a representation of the motion sequence, in which the swing cam has been further pivoted from the sphere of influence of the blocking member,

Fig. 16 is an illustration according to FIG. 14, in which the swing cam in the open position of the stops corresponding pivot position,

Fig. 17 a of FIG. 16, the following representation in which the rotary latch swings open and Gert verla the swing cam in the alternate position,

Fig. 18 is a representation of the motion sequence by again closed rotary latch,

Fig. 19 is a movement sequence shown at rotated further drive,

Fig. 20 shows a fourth embodiment of the invention in the closed position,

Fig. 21 is a view as in Fig. 20, wherein the swing cam has moved the locking member in the release position,

Fig. 22 is a view like Fig. 21, but at a standstill in an unfavorable position of swing cam

Fig. 23, the sequence diagram of FIG. 22, wherein the lock is in its closed position and the lock member has moved the swing cam from the center position lung,

Fig. 24, the fifth embodiment of the invention is in the closed position, secured by the latch member hook portion,

Fig. 25, the arrangement in the opening phase under clamping NEN a center neutral pen,

FIG. 26 shows the follow-up view of FIG. 25, the arrangement being open and the pivot cam being turned into the central position by the central zero spring, which pivot cam continues to rotate,

Fig. 27, the sequence diagram of FIG. 26, wherein the rocking cams is in an unfavorable position to a stop,

Fig. 28, the sequence diagram of FIG. 27, during the closing phase,

Fig. 29, the sequence diagram of FIG. 28, wherein direction by the blocking part of the swing cam in clockwise rotated,

Fig. 30 permits the follow-up illustration of Fig. 28, is being rotated pointer direction by the blocking part of the swing cam counter clock and the incidence of the blocking part in the blocking position of the rotary latch,

Fig. 31 is a front view of a swing cam deviating designed with star-shaped projections,

Fig. 32 shows a sixth embodiment of a lock illustrative arrangement in which the swing cam is stopped in an unfavorable position and the beginning of closing the lock and

Fig. 33, the follow-up view of Fig. 32, namely in the locking position engaging Drehfal le and sunken locking part, with the rotary latch on a release finger and pawl of the swivel cam in a setting of the pawl enabling Stel is rotated further.

The essential elements of the arrangement, which is explained with the aid of a rotary latch lock, are the hook part 1 , the locking part 2 and the pivot cam 3 seated on an axis of rotation 17 . In the exemplary embodiment, the hook part 1 is formed by a rotary latch and the locking part 2 by a pawl. The rotary latch 1 has a hook jaw 1 'for capturing a counter-locking part, not shown, for example a locking bolt or striker, which can be attached to the frame of the body of a motor vehicle. The lock having the rotary latch 1 can be arranged in a door or in a flap of a motor vehicle.

The catch 1 is pivotable about a pivot axis 15 and forms with one arm a hook 1 ". This hook 1 " is engaged in the locking position by a locking shoulder 2 'of the pawl 2 . The pawl 2 is pivotable about a pawl axis of rotation 16 and connected by means of a tension spring 9 with the rotary latch 1 such that the catch is acted upon by the tension spring 9 in an opening pivot position and the pawl 2 is pulled into its blocking position. The pawl 2 forms a one-armed lever. At its free end, the pawl 2 forms a tax shoulder 12 . This control shoulder 12 can be struck by an eccentric extension 3 'of the pivot cam 3 , so that the pawl 2 can be pivoted from its locking position shown in FIG. 1 into an opening position shown in FIG. 3. In the embodiment shown in Fig. 3 open position of the hook 1 'out of engagement occurs to the locking shoulder 2', so that the tension spring 9, the rotary latch 1 in the open position pivots. The swing cam 3 5 is driven disc of a drive and is resiliently with the drive pulley 5 In the exemplary embodiment there is a pretensioned spring 4 between the drive disk 5 and the swivel cam 3. The pretension of the spring 4 is maintained in that a pin 7 assigned to the drive disk 5 passes through an elongated hole 6 of the swivel cam 3 and in the prestressed position strikes at one end of the elongated hole 6 .

The drive pulley 5 can be designed as a worm wheel and can be driven by a motor-operated worm. When the drive pulley 5 rotates, the swivel cam 3 is dragged along with the swivel cam 3 via the spring 4 . If the swivel cam 3 opposes resistance, for example by running up its eccentric circumferential surface against the control shoulder 12 of the pawl 2 , the spring 4 can continue to tension, the pin 7 in the slot 6 being able to shift to the opposite end of the slot. The swivel cam can stop when charging. It rotates at least slowly until the energy accumulator is loaded. Then the peg assumes the position shown in FIG. 3.

Against the restoring force of the tension spring 9 , the pawl 2 is pivoted. In trouble-free operation, the pivot position of the pawl 2 shown in Fig. 3 is reached only fleetingly. A slight Wei terrehung the drive pulley 5 has the consequence that the eccentric extension of the pivot cam 3 leaves the control shoulder 12 . Thereafter, the energy accumulator formed by the spring 4 discharges, so that the pin 7 travels through the elongated hole, since the swivel cam 3 leads to the drive disk 5 due to the release of the torque application for a short time.

Fig. 3 shows a fault scenario in which the drive pulley 5 stops at the exact moment when the pawl 2 is moved to its opening position. In this position, the rotary latch swings open to release the locking bracket, not shown. If the flap is closed, the locking bracket is caught by the hook jaw 1 '. Along with this catch movement, the catch 1 is pivoted back again. This takes place on the one hand by tensioning the tension spring 9 and on the other hand by tensioning a leg spring 8 . The leg spring 8 is supported on a pin 18 adjacent to the hook 1 '. With its other leg, the leg spring 8 acts against a pin 19 assigned to the eccentric extension 3 ′ of the pivot cam 3 . The tensioning of the torsion spring 8 during the pivoting of the catch 1 has the consequence that the rocking cam is drehmomentbeaufschlagt. 3 The frictional force between the eccentric extension 3 'of the pivot cam 3 and the control shoulder 12 can be wounds. The energy accumulator 4 can be discharged, the pivot cam 3 pivoting further into the pivot position shown in FIG. 5, in which the pawl 2 can pivot back into its locked position.

Fig. 6 shows a second scenario. There, the swivel cam 3 stopped due to failure of the drive in a swivel position that is just before the open position. In this position, the energy accumulator 4 is tensioned. In this position, the pawl 2 is manually pivoted ver into the open position, which can be done by attacking an access point 14 on which a linkage engages, which interacts with a lock cylinder, the frictional connection between the control shoulder 12 and the eccentric extension 3 is canceled, so that the energy accumulator 4 can be discharged until it assumes the pivot position shown in FIG. 7. In this pivoting position, the pawl 2 can pivot back into its locking position.

The pivoting clearance defined by the stop, which is realized by the pin 7 engaging in the elongated hole 6 , is sufficient to further shift the pivoting cam 3 in such a way that the pawl 2 can always assume its locking position, so that the device can be used with such a device provided door or flap can be securely closed even in the event of a fault.

In this embodiment, the triggering of the Energy storage either from the movement of the hook duck les or the blocking part derived.

In the embodiment shown in FIGS. 8 to 12, the triggering of the energy store 4 takes place, which has a pivoting of the pivot cam 3 from the area of influence of the control shoulder 12 of the pawl 2 , derived from the movement of the hook part 1 when the hook part 1 pivoted from its locking position shown in FIG. 8 into the release position of the counter-locking part shown in FIG. 10. In the embodiment shown in Fig. 9 intermediate position acts on a control shoulder 11 that is associated with the hook 1 'of the hook part 1, a control cam 10 of the locking pawl 2. This sliding of the tax trained 11 along the control cam 10 has a Ver pivot the pawl 2 in the direction away from the pivoting cam 3 , so that the frictional rotation inhibition that the control shoulder 12 exerts is canceled. The pivot cam 3 pivots after cancellation of the frictional engagement in the pivot position shown in Fig. 11, in which the pawl 2 can pivot back into its locking position, which is shown in Fig. 12.

It is also conceivable that the elastic coupling between the swivel cam and the drive does not take place via a torsion link, but via a linearly acting elastic element. For example, the eccentric extension of the swivel cam can be cushioned in the radial direction with respect to the drive disk. The elastic evasive movement of the swivel cam can also take place in the tangential direction. For example, the swivel cam can be struck directly by the rotary latch, dodge tangentially, so that the control shoulder can dip into the locking position under the eccentric extension of the swivel cam. The swivel cam can then sit on a drive pulley 3 as a slide. By means of a spring, the slide can be held in the functional position in which the eccentric extension can control the pawl 2 . In the event of a malfunction, the swiveling rotary latch can shift the slide, so that the eccentric extension is brought out of the effective range of the control shoulder of the pawl.

When in FIGS. 13 to 19 shown variation of the swing cam is displaced lung by applying a control projection 23 of the catch 1 in an alternative Stel. 3 In this alternative position, the pivot cam 3 remains until it is turned further. Then a control curve 26 of the swivel cam 3 runs against a housing-mounted reverse control cam 24 and moves the swivel cam back again.

The pivot cam 3 has an eccentric extension 3 ', which interacts with the control shoulder 12 of the locking pawl 2 such that rotation of the eccentric extension 3 ' shifts the locking pawl 2 into its open position. In this open position, the rotary latch 1 can swing open. This pivoting he follows in the normal case when the pivot cam 3 has reached its pivot position shown in Fig. 15, in which a control shoulder 21 is pivoted from the effective area of the control extension 23 . The control shoulder 21 is a control disc 20 zugeord net, which is rotatably connected to the pivot cam 3 . The control disc 20 forms approximately on the tax shoulder 21 opposite side of the control cam 26 in the form of a rotary wedge. The swivel cam 3 and the control disk 20 firmly connected therewith form an elongated hole 22 , which is penetrated by the axis of rotation 17 of the drive disk 5 . The swivel cam 3 and the control disk 20 are rotationally coupled to the drive disk 5 . The swivel cam 3 and the control disk 20 , however, can be displaced in the radial direction relative to the drive disk 5 as a result of the elongated hole 22 . The position of the elongated hole 22 is selected such that the elongated hole 22 faces the control shoulder 21 . As a result, the control shoulder 21 can deflect radially when the control extension 23 of the rotary latch acts on it.

The control cam 24 fixed to the housing interacts with the control cam 26 in such a way that the deflected control disk 20 is displaced back on the control cam 24 by running up the control cam 26 .

With the reference numeral 25 is designed as a leg spring rocker spring 25 which holds the pivot cam 3 together with the control disc 20 in its two thrust end positions. This is done in a known manner by over-centering the Kippfe of the 25th This over-center shift occurs either by loading the control shoulder 21 with the control extension 23 or by loading the control curve 26 by the reverse control cam 24 .

This arrangement works as follows:
For opening the closure, as it is in FIG. 13 Darge, the drive pulley 5 is driven gerrichtung against Time. She takes the swivel cam 3 with her. Its eccentric extension 3 'acts on the control shoulder 12 at the free end of the pawl 2 . The pawl 2 pivots on, so that the locking shoulder 2 'the hook 1 "of the catch 1 releases see. Fig. 14. According to a spring, not shown, the catch 1 swing open. During the Aufschwenkens the catch 1 continues to pivot the swing cams 3, so that its control shoulder 21 is pivoted out of the control extension 23 .

If, due to a malfunction of the swivel cam 3 , it remains in its swivel position assigned to the pawl 2 , so that normally the pawl 2 cannot swivel back into its locked position, the control shoulder 21 remains in the area of influence of the control extension 23 , so that the edge 23 'of the control extension 23 when the catch 1 swings open the edge 21 ' of the control shoulder 21 . This results in a linear evasive movement of the pivot cam 3 in the direction of the arrow in FIG. 16, during which the rocker spring 25 is brought over its dead center position. In the avoidance position, the swivel cam 3 is shifted such that the pawl 2 can again assume its locked position, cf. Fig. 18.

If the drive disk 5 rotates further, the control cam 26 of the control disk 20 comes into contact with the stationary reverse control cam 24 in the course of further rotation, which has the consequence that the pivot cam is moved back in the direction of the arrow shown in FIG. 19.

In the fourth embodiment shown in FIGS . 20 to 23, which is similar to the first embodiment, the same components have the same reference numerals. The worm 27 , which is driven by an electric motor 28 , meshes with the drive disk 5 designed as a worm wheel. The pin 7 extending from this extends through the arch slot 6 of the swivel cam 3 . An unillustrated, extending between the pivot cam 3 and the drive pulley 5 center zero spring holds the unloaded pivot cam 3 in one in two opposite directions by overwin each of a restoring force evasive middle position. This means that the pin 7 is located approximately in the middle of the arch slot 6 , cf. Fig. 20.

The tension spring 9 then extends between the catch 1 and the pawl 2 . The pawl 2 or the locking part thereby has the tendency to pivot in the direction of the catch 1 to be able to block it in the closed position. At its free end, the locking part forms a control shoulder 29 which cooperates with a counter-school 30 of the pivot cam 3 designed in the form of a pin. This counter shoulder 30 extends at the level of the root of the eccentric extension 3 '.

The following mode of action occurs:
In the closed position of the lock, the chassis-side counter-locking part 31 lies in the fork mouth 1 'of the rotary latch 1 . In its closed position, this is secured against turning back by the locking part 2 , namely by the fact that its locking shoulder 2 'engages under the hook 1 "and thus secures the turning of the catch 1. The Zugfe 9 serves to secure this position. The lock is located thus in the position shown in Fig. 20.

In Fig. 21 it is illustrated that the drive disk 5 is driven by initiating the electric motor 28 via the screw 27 . Whose pin 7 has shifted against the force of the intermediate spring relative to the swivel cam 3 and is now located at the right end of the arch slot 6 with entrainment me the swivel cam 3 , the extension 3 'of the control shoulder 12 of the locking part 2 and this from the Blocking position brings. As a result, the rotary latch 1 can turn into its open position, releasing the counter-closing part 31 .

In Fig. 22 a fault is illustrated, wherein the rocking cam is eccentric 3 with its extension 3 'within the control of the locking part 2. This means that problems could arise when the rotary latch is closed if the control shoulder 29 and the counter shoulder 30 were not present.

Fig. 23 shows that in the closing end phase by the counter-locking part, the rotary latch 1 has entered its limited pivot position. Along the pressurized in the direction of the rotary latch lock 1 part 2 via the control shoulder 29 and counter shoulder 30 has the swing cam 3 in the counter clockwise direction in Fig. 23 is rotated position illustrated. In this way, the hook engagement between locking part 2 and rotary latch 1 can be generated. Fig. 23 illustrates that the control shoulder 29 like a wedge moves below the counter school ter 30th

The fifth embodiment shown in FIGS . 24 to 29 is similar to that described above. The same parts are therefore provided with the same reference numbers. The eccentric extension 3 'now forms two in a Schei tel 32 meeting control curves 33 , 34 . The control curves 33 , 34 are designed in a straight line and meet at a tip, namely the apex 32 . Together, the control curves 33 , 34 cooperate with a control projection 35 of the locking part 2 . In this version, too, the swivel cam 3 is held in a central position by an unillustrated center zero. Then the control projection 35 tapers in a tip. The tip angle in question is approximately. 60 °, while the tip angle between the control curves 33 , 34 has about 30 °.

The operation of this fifth embodiment is as follows:
The closed position of the lock is illustrated in FIG. 24. This means that the rotation of the catch 1 is secured by the locking part 2 . The opening of the lock requires the drive of the pivoting cam 3 counterclockwise, with the eccentric extension 3 ', which jumps against the Steuerervor 35 , the locking part is shifted into the release position. The catch 1 is thus released to pivot in its open position, cf. Fig. 25. The pin 7 is in this case at the right end of the arc slot 6.

As soon as the swivel cam 3 is rotated further and the extension 3 'has moved away from the locking part 2 , the swivel cam can return to the central position due to the central zero spring, see FIG. 26. The case can occur during the rotational displacement of the swivel cam 3 , that the swivel cam 3 comes to a standstill in the position according to FIG. 27. The eccentric extension 3 'is accordingly in the area of influence of the locking part. If a door or flap provided with the lock is now closed, the position according to FIG. 28 occurs as a result. This illustrates that the locking part 2 can now not occur immediately. There are two ways in which the locking part 2 can still enter its blocking position. In Fig. 29, it is indicated that the tip of the control projection 35, the cam 33 acted upon, and thereby forces a rotational displacement of the swing cam 3 in Uhrzeigerrich processing. This is possible due to the central position of the pivot cam 3 illustrated in FIG. 28. Thereupon, the locking part 2 is able to step under hook grip to the hook part 1 or to the rotary latch. However, it is also possible that the tip of the Steuerervor jump 35 is slightly below the apex 32 of the eccentric extension 3 '. Then the control projection 35 cooperates with the control cam 34 and rotates the swivel cam 3 counterclockwise into the position illustrated in FIG. 30, which is possible by the central position of the swivel cam 3 .

From the above it can be seen that the force for the control projection-controlled displacement of the swivel cam 3 comes from the tension spring 9 acting on the locking part 2 . Accordingly, it fulfills a double function.

In Fig. 31, a deviating shaped swing cam 3 is shown. However, this now forms four stern-shaped extensions 36 in a uniform angular distribution. Each extension 36 has two straight control cams 33 , 34 which meet in a tip 32 .

The sixth embodiment according to FIGS. 32 and 33 is constructed similarly to the first embodiment. The same components are also provided with the same reference numbers. The drive pulley 5 is coupled to the swivel cam 3 as in the first embodiment. This means that in the closed position of the lock, the pin 7 extending from the drive disk 5 is located at one end of the elongated hole 6 as in FIG. 3 of the first embodiment.

In a departure from this, the pivot cam 3 is now provided with a pawl tooth 37 which is permanently assigned to it and which is in engagement with the saw teeth 38 of a pusher pawl 39 which can be displaced in the direction of the catch 1 . One of the push pawl 39 associated compression spring 40 loads the pawl 39 in a downward displacement according to FIG. 32, by a stop (not shown) to the impact-limited end position. At its free end, the pawl 39 forms a head 41 with a kick groove 42 . This acts together with a release finger 43 attached to the rotary latch 1 .

In Fig. 32 the malfunction is shown that the pivot cam 3 remains in an unfavorable position that does not allow the proper pivoting of the locking part 2 in the blocking position to the rotary latch 1 . Is closed now that the lock and rotated counter-closing part 31, the rotary latch counter 1 Time gerrichtung so pivoted accompanied Auslösefin the ger 43 which in the throat Schließendphase in the inlet 42 of the pusher pawl 39 is immersed, and these Gert verla. Via the saw teeth 38 , the driving projection 37 of the swivel cam 3 is acted upon, which accordingly rotates into the position according to FIG. 33. The eccentric extension 3 'leaves the Schwenkbe rich of the locking part 2 , whereupon this can occur in the blocking position shown in FIG. 33. During the rotation of the pivot cam 3 , the pin 7 has reached the other end of the arch slot 6 .

A corresponding pulse must be given to open the closure, whereupon the drive disk 5 rotates counterclockwise and the pin 7, after charging the corresponding coupling spring, reaches the other end of the arch slot 6 . Along with a rotation of the swivel cam 3 , the eccentric extension 3 'then acts on the free end of the locking part 2 and lifts it into a release position for the hook part or rotary latch, so that the lock can be opened.

All disclosed features of the invention are (in themselves) essential to the invention. In the disclosure of the application here also the disclosure content of the belonging gen / attached priority documents (copy of Pre-registration) included in full, also to the purpose, features of these documents in claims including this application.

Claims (33)

1. Arrangement for a locking part ( 1 ) locking part ( 2 ), the locking part ( 2 ) of a motor-driven swivel cam ( 3 ) from a locking position in a the hook part ( 1 ) releasing opening position, characterized in that the swing cam ( 3 ) stopping in a pivot position corresponding to the open position during a movement derived in particular from a movement of the hook part ( 1 ) or the blocking part ( 2 ), in such a way that the blocking part ( 2 ) can assume its blocking position. 2. Arrangement for a locking part ( 1 ) locking part ( 2 ), the locking part ( 2 ) of a motor-driven pivot cam ( 3 ) from a locking position in a the hook part ( 1 ) releasing opening position, characterized by a the swivel cam bearing from one of the blocking position to a swivel position corresponding to the open position charged by a motor drive force accumulator ( 4 ) which, when the drive stopping in the swivel position corresponding to the release solution causes the swivel cam ( 3 ) to swivel into a swivel position, in which the blocking part ( 2 ) can assume a blocking position. 3. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the swivel cam ( 3 ) elastically gives way. 4. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the energy accumulator ( 4 ) is a torsion member. 5. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the energy accumulator ( 4 ) is formed by a prestressed spring arranged between swivel cams and a drive disk ( 5 ). 6. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized by a stop-limited rotation-free gear ( 6 , 7 ) provided between swivel cams ( 3 ) and drive disc ( 5 ). 7. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the triggering of the energy store ( 4 ) is carried out by moving the hook member ( 1 ), which is designed in particular as a rotary latch, the triggering then being carried out by pivoting the Rotary latch ( 1 ) from a catch position for a counter-locking part into a locking position lockable by the locking part. 8. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that triggering takes place by means of an additional torque application of the pivot cam ( 3 ). 9. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the torque is applied by span NEN a spring ( 8 ) which acts on the pivot cam ( 3 ). 10. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the spring ( 8 ) between the hook part ( 1 ) or rotary latch and swivel cam ( 3 ) is tensioned. 11. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the triggering of the energy store ( 4 ) is carried out by moving the hook member ( 1 ), which is designed as a rotary latch, the triggering then by pivoting the rotary latch ( 1 ) from a blocking position into one of the counter-locking part held by her in the open position. 12. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the locking part formed as a pawl under spring force ( 9 ) controlled pivoting of the catch ( 1 ) of the catch ( 1 ) from the area of influence of the pivot cam ( 3 ) is pivoted. 13. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the rotary latch ( 1 ) along pivoting on a control curve ( 10 ) of the pawl ( 2 ) tet and pivots. 14. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the triggering of the energy store and the associated further pivoting movement of the eccentric extension ( 3 ') of the pivoting cam ( 3 ) from the sphere of influence of the control shoulder ( 12 ) the pawl (2) is carried out by manual pivoting of the pawl (2). 15. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the swivel cam ( 3 ) from the leg flow area of the locking part ( 2 ) evades and remains in the evaded position. 16. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the evaded pivot cam ( 3 ) is stored back again when the drive ( 5 ) continues to rotate. 17. The arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the pivoting cam ( 3 ) sits radially displaceably on the drive disk ( 5 ). 18. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the swivel cam ( 3 ) is displaced from a swivel movement of the hook part ( 1 ) into the evasive position. 19. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the pivot cam ( 3 ) is held in its two states according to a toggle spring ( 25 ). 20. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the rotary latch ( 2 ) forms a control extension ( 23 ) which has a control shoulder ( 21 ) of the control cam stopping in the pivot position corresponding to an open position of the pawl ( 3 ) acted upon pivoting on. 21. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the control shoulder ( 21 ) is associated with a control disc ( 20 ) which is fixedly connected to the swivel cam ( 3 ). 22. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the control disc ( 2 ) forms a rotary cam control cam ( 26 ) which, for releasing the pivot cam ( 3 ), from the evasive position with a housing-mounted control cam ( 24 ) works together. 23. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the unstressed swivel cam ( 3 ) is held in a position in two opposite directions by overcoming the restoring force that can be reset in each case and when the swivel cam stops ( 3 ) is shifted in the area of influence of the locking part ( 2 ) from the locking part ( 2 ) pivoting back into the locking position from the central position. 24. The arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the locking part (2) forms a control shoulder (29) provided with an opening formed in particular in the form of a peg counter control shoulder (30) of the swing cam (3) cooperates. 25. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the swivel cam ( 3 ) forms two control cams ( 33 , 34 ) which meet in a vertex ( 32 ) and which have a control projection ( 35 ) Locking part ( 2 ) cooperate in such a way that the locking part ( 2 ) of the rotary pivoting cam ( 3 ) pivots by sliding the control projection ( 35 ) on a control cam ( 33 , 34 ) into the pivot position corresponding to the open position, the pivoting cam ( 3 ) is brought from a bilaterally by overcoming a restoring force releasable middle position, into which middle position the pivot cam ( 3 ) returns after the locking part shift, and wherein the control projection ( 35 ) when hitting one of the control cams ( 33 , 34 ) in the middle position held swivel cam ( 3 ) this shifted from the middle position. 26. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the control cams ( 33 , 34 ) meet in a tip ( 32 ). 27. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the control projection ( 35 ) is pointed. 28. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the force for the control projection-controlled displacement of the swivel cam ( 3 ) comes from the tension spring ( 9 ) acting on the locking part ( 2 ). 29. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the swivel cam ( 3 ) forms a plurality of extensions ( 36 ). 30. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the extensions ( 36 ) are arranged in a star shape. 31. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that it is triggered by a push pawl ( 39 ) which can be displaced by the hook or locking part ( 1 , 2 ). 32. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the pawl ( 39 ) is designed as a plunger and engages with teeth ( 38 ) on a driving projection ( 37 ) of the locking cam ( 3 ). 33. Arrangement according to one or more of the preceding claims or in particular according thereto, characterized in that the push pawl ( 39 ) is actuated by a trigger finger.