DE102004056988B4 - Locking device and method for actuating a locking device - Google Patents

Abstract

Keyless locking device with a locking cylinder (2), an inner and an outer handle, which are rotatably arranged on opposite ends of the locking cylinder (2), a pivot bit (24) mounted in a housing (3) of the locking cylinder (2) and an electronic one Control unit for checking the access authorization and control of a clutch (32), by means of which an operative connection can be established between one of the handles and the locking bit (24), the clutch (32) being designed such that in a first operating mode the inner handle with the Locking bit (24) coupled and the outer handle is decoupled from the locking bit (24) and that in a second operating mode the outer and the inner handle are coupled to the locking bit (24), characterized in that in a third operating mode the outer and the inner handle are decoupled from the lock bit (24) and that the third operating type can be set in addition to the first and second operating modes by operating the clutch (32) ...

Description

The present invention relates to a locking device with a lock cylinder, an inner and an outer handle, which are rotatably disposed at opposite ends of the lock cylinder, a pivotally mounted on a housing of the cylinder cam and an electronic control unit for checking the access authorization and control of a clutch which an operative connection between one of the handle and the cam is producible. The present invention further relates to a method for actuating such a control device.

Locking devices of the type mentioned are used for keyless access control and are adapted in terms of their design essentially in mortise locks for doors according to DIN 18251, especially by forming a lock cylinder according to DIN 18252. Such lock cylinders have a cylinder housing and a pivotally mounted therein a locking bit on the Longitudinal side of the cylinder housing can be pivoted to lock the lock on and. In conventional lock cylinders, the cylinder housing comprises a cylinder core, which can be rotated with a matching key in the housing and which acts on the cam.

The known mechanical lock cylinders leave many wishes unfulfilled in terms of safety, lock layout and flexibility. Conventional keys can be easily copied. In a locking system, the keys must have a hierarchical structure and the loss of the central key usually requires an exchange of all locks the locking system.

In order to remedy the situation, so-called keyless locking devices have been proposed in the past several times, which have an electronic control unit with an electronic and carried by the user key, which also identifies as an identifier for wireless communication with access control electronics of the electronic control unit is, cooperates. This is usually a transponder whose identity code is queried by the electronic control unit as part of a query protocol. With suitable access authorization, the control unit controls a coupling, by means of which an operative connection between one of the handles and the lock bit can be produced.

From the DE 198 51 308 A1 a generic locking device is known in which one of the handles is formed by an outside door knob which receives in itself a battery and is rotationally fixed to a rotary shaft which is rotatably mounted in the cylinder housing and extends approximately to the cam. This is arranged against rotation on a cylinder core, which is rotatably mounted on the other side of the rotary shaft in the cylinder housing and rotationally connected to the other handle, which is provided on the inside of the door in the form of another rotary knob connected. Between the rotary shaft and the cylinder core is a controlled via a magnet clutch. By turning the inside door knob, the lock can be opened and closed at any time. The outside door knob usually turns freely. Only after successful query of the access authorization, the magnet controls the clutch and causes an operative connection between the rotary shaft and the cylinder core, so that by a rotation of the handle on the outside of the door lock can also be opened and closed.

This prior art device has the disadvantage that the clutch is controlled by a magnet and therefore can not be ruled out that bridged by a magnetic force applied from the outside, the access authorization request and the clutch is externally controlled. The previously known locking device can then be manipulated from the outside. In addition, there is a problem that not all modules required for the access permission request are arranged on the inside of the door. Thus, for example, in the case of this prior art locking device, the knob provided on the outside surrounds the battery, which leads to the further problem that the power source must be electrically connected to the control unit via the coupling. In addition, this electrical connection must take into account the fact that a rotational movement must be permitted between the battery and the control unit. Furthermore, there is the disadvantage that the intended for communication with the identifier on the locking device antenna is provided on the inside of the door, so that the control unit must be operated with the access electronics for authorization request with relatively high radio power, so that an authorization request of standing on the outside of the door person successfully can be carried out. Finally, in the previously known closure means are missing, which allow a power-saving operation of the same. Thus, the previously known locking device must constantly send out signals for the authorization query in order to determine the presence of a person equipped with identifiers and demanding admission.

The latter problem is already attributable to the inventor of the present application DE 100 44 723 C1 Invoice having a switching means by manual operation of the Handle is activated. This is followed by an energization of the access authorization request performing control unit only when a person operates the handle. In all other cases, the handle is de-energized, so that provided in this prior art device battery has a long life.

Another generic locking device, similar to that of the DE 198 51 308 A1 is described with the device DE 199 23 786 A1 disclosed. In this prior art device, the lock cylinder is penetrated by a drive shaft having a central recess for receiving a lock cylinder also passing through the central element, which projects beyond the lock cylinder to adapt to different lock cylinder lengths. On the inside of the door, the drive shaft carries a plate-shaped unit carrier, which is held rotationally fixed to the drive shaft via the central element and which carries the control unit and a battery for supplying the same. Via electrical lines provided in the central element, an antenna arranged in the outer knob is connected directly to the control unit accommodated in the inner knob.

The inner knob is rotatably mounted on the cylinder housing via a bearing sleeve, which partially surrounds the bearing sleeve and which end is permanently connected rotationally fixed to the cam.

Between the bearing sleeve and the continuous drive shaft, a coil for a magnetic coupling is provided, which pivot a radially disposed between the rotary shaft and the bearing sleeve magnet armature when activated radially outward. As a result, the rotary shaft is coupled to the bearing sleeve, so that an operative connection between the outer handle and the cam is created. In this coupling, so the door can be opened and closed from the outside.

The activation of the control unit via a magnetic switch which is formed between the unit carrier and a closing cylinder side end cap of the inner handle. Upon rotation on the outer handle, a pulse is generated by this magnetic switch, through which the electrical control unit is switched.

Due to the aforementioned design principle, the points from the DE 199 23 786 A1 Known locking device with regard to the required security against manipulation the same disadvantages as those from the DE 198 51 308 A1 known locking device. Although at the DE 199 23 786 A1 the magnet armature pivots radially outward, which impedes magnetic manipulation from the end faces of the lock cylinder ago. However, this can not be completely excluded. Further, the central member is designed as a flat rod for torsion-proof recording in the unit carrier on the one hand and the outside door knob holding knob carrier on the other hand and should include between the inner and outer knob extending electrical conductors, whereby the formation of the locking device is complicated.

The DE 102 25 649 A1 discloses a lock cylinder having an inner knob and an outer knob, the knobs each being rotatably disposed at opposite ends of the lock cylinder. The lock cylinder with the outer rotary knob has a first clutch with a mechanical cylinder lock and a second clutch with an electrical confirmation device. This makes it possible, regardless of the operability of the electrical actuator, to gain access to secured with the locking devices rooms. The first clutch is located in the outer half of the lock cylinder, whereas the second clutch is provided inside the door. The first and second clutch can connect a pivotably mounted between the two clutches cam with the outer knob alternatively or simultaneously rotationally. The inner knob can be connected either rotationally independent of the switching state of the couplings directly to the cam or indirectly via the couplings with the cam. In the latter case, there is a connection between the cam and the inner knob only if one of the clutches is confirmed. The connection between the inner knob and the cam is made by a plurality of transverse bores, which are provided in the inner knob.

The DE 198 24 713 A1 discloses a lock cylinder with a housing and therein rotatably mounted closing member and with a drive shaft for driving the closing member. In order to realize in the lock cylinder, the possibility of a further connection from the outside to the closing member, a drive shaft and the closing member penetrating central element in the form of an independent of the closing member operation existing operative connection is provided from one cylinder side to the other. The drive shaft can be coupled by a coupling with the closing member in a rotational driving position. In this case, the coupling is influenced by the central element which is non-rotatable relative to the housing, with electromagnetic couplings in particular offering themselves. The central element is non-rotatably seated in the inner housing of the ends of the designed as a double lock cylinder lock cylinder rotary knobs.

After the aforementioned lock cylinder, the coupling is not formed such that the outer and the inner knob is coupled to the closing member, as will be disclosed below by the second operating mode according to the invention.

The present invention is based on the problem of further developing a locking device of the generic type such that the usability of the locking device is increased and the risk of unauthorized access is reduced. The present invention is further intended to specify a method suitable for controlling the closing device.

To solve the above problem, as regards the device, a closure device having the features of claim 1 is provided. This differs from the generic state of the art in that the coupling is designed such that in a first mode of operation, the inner handle is coupled to the lock bit and the outer handle is decoupled from the lock bit, that in a second mode of operation, the outer and the inner Handle is coupled to the lock bit and in a third mode, the first and the second handle are decoupled from the cam and that the third mode in addition to the first and the second mode by actuating the clutch is adjustable.

The locking device according to the invention offers the completely new possibility of a third mode in which neither a rotation on the outer handle, nor a rotation on the inner handle leads to a pivoting movement of the cam. In this third mode of operation no conceivable manual actuation of the handles may allow the lock to be unlocked. Thus, for example escape doors can be permanently secured against unauthorized opening and only then be operated from the inside, when brought in the escape door recorded secured identifiers in the receiving area of the locking device and after successful passage of the authorization protocol, the third mode is set. As useful in the same sense, the locking device according to the invention proves where there is a possibility of reaching through from the outside to the inside. This access from the outside can be made possible, for example, by cutting a small hole in a glass pane of the door or a pane of glass adjacent to the door. Incidentally, burglars are now regularly transported the burglary objects by a door to be opened from the inside without further ado. Such transport is made impossible by the locking device according to the invention.

As a coupling in the context of the present invention, any coupling can be understood that causes an operative connection between one of the handle and the cam. A mechanical coupling is merely to be regarded as a preferred embodiment. Other couplings, such as magnetic or electromagnetic couplings are also conceivable. Essential for the locking device according to claim 1 is only the possibility to set in addition to the known first and second modes of operation, the third mode in which the cam is completely decoupled from the outer or inner handle.

Preferred developments of the closing device according to the invention are given in the dependent device claims.

To solve the procedural problem of the present invention, a method for operating a locking device with a lock cylinder, an inner and an outer handle, which are rotatably disposed at opposite ends of the lock cylinder, a pivotably mounted in a housing of the cylinder cam and an electronic control unit to Examination of the access authorization and control of a clutch, by means of which an operative connection can be produced between one of the handles and the lock bit, in which the clutch is switched between the first, second and third aforementioned modes.

Preferably, the clutch is set in the same direction when switching from the first to the second mode, as when switching from the second to the third mode, which has the advantage that approximately the same coupling paths are required to the door from the outside be able to unlock, which is beneficial for the interpretation of a clutch moving drive. The control to the drive is further simplified in that a coupling member of the clutch is set at a movement from the first operating position to the second operating position by approximately the same amount as in a position from the third mode to the second.

Further details, advantages and features of the present invention will become apparent from the following description of an embodiment in conjunction with the drawings. In this show:

1 a longitudinal sectional view of an embodiment of the essential parts of an embodiment of the locking device according to the invention;

2 the non-rotatably connected to the outer handle part of the embodiment according to 1 in an exploded view;

3 the camshaft hollow shaft of in 1 shown embodiment;

4 a side view of an embodiment of an actuator for decoupling imposed by a motor movement and the movement of a coupling element according to 1 ;

5 the non-rotatably connected to the inner handle part of the in 1 shown embodiment;

6 an embodiment of a coupling member moving the drive;

7 a side view of an alternative embodiment of an actuator for decoupling imposed by the motor movement and the movement of the coupling member;

8th the drive plate of in 7 shown embodiment;

9 the output gear of in 7 shown embodiment; and

10 the drive wheel of in 7 shown embodiment.

The 1 shows a longitudinal sectional view of the essential parts of a locking device comprising a lock cylinder 2 with a housing 3 , which is designed in accordance with DIN 18252 and a central bore 4 having. In this hole 4 is at one end of the lock cylinder 2 a journal 6 rotatably mounted, which via a snap ring, not shown in the axial direction relative to the lock cylinder 2 is fixed. That the lock cylinder 2 end of the journal protruding at the end 6 has in on its outer peripheral surface receiving bores 8th on that with respect to the axial extent of the journal 6 are provided at different positions and which accommodates at least one of the external handle forming and not shown here provided knob grub screw. Due to the different position of the mounting holes 8th in the axial extension, the position of the outer knob can be adjusted depending on a arranged on the outside of the lock cylinder panel. Such panels are for example as Ausziehsicherung against destructive pulling out of the bore 4 of the lock cylinder 2 recorded actuators sometimes used.

The journal 6 carries one in a wave shot 10 rotationally received hollow shaft 12 that the entire lock cylinder 2 interspersed and that the journal 6 opposite end of the lock cylinder housing 3 surmounted. The hollow shaft 12 carries a driver forming a clutch gear 14 , which at one on the hollow shaft 12 pressed-on gear sleeve 16 is arranged, the bearing journal-side end to form a hollow shaft bearing surface 18 for a camshaft hollow shaft 20 is enlarged in the radial direction.

The camshaft hollow shaft 20 Bearing journal side comprises a cylinder section 22 that leads to the formation of a lock bit 24 receiving groove 26 slotted in the longitudinal direction. The cambar 24 is about one in the area of the groove 26 trained threaded hole 28 on the camshaft hollow shaft 20 held. The camshaft hollow shaft 20 has a cylindrical bore with a circular cross section, the inner peripheral surface at least partially on the hollow shaft bearing surface 18 the gear sleeve 16 rests and whose diameter is chosen such that the gear sleeve 16 through the camshaft hollow shaft 20 can be passed. At her the journal 6 facing away from the hollow camshaft 20 a plurality, in the present case four counter-claws extending in the axial direction 30 one of the cam hollow shaft 20 on the journal 6 opposite side upstream clutch 32 on. These counter-claws 30 extend in the axial direction in about half of the axial extent of the projections (teeth) of the clutch gear 14 , The corresponding embodiment of clutch gear 14 and counter-claws 30 is such that opposite and extending in the axial direction longitudinal side surfaces 34 the clutch claw 30 together with the corresponding surfaces of the clutch gear 14 a preferably in the radial direction relative to the hollow shaft 12 extending planar contact surface for a coupling member 36 the clutch 32 form.

This coupling member 36 includes a coupling sleeve 38 , pointing towards the hollow camshaft 20 extending clutch claws 40 wearing. In the present case, two coupling claws are provided, which are formed in the form of webs extending in the axial direction. The clutch claws 40 have at their front free end in each case a driving projection 42 on, essentially down to a cylindrical base 44 the gear sleeve 16 range with respect to the clutch gear 14 and the hollow bearing surface 18 between both areas of the gear sleeve with a smaller radius on the gear sleeve 16 is formed.

The clutch claws 40 overhang in the radial direction of the coupling sleeve 38 and are there permanently engaged in elongated guide slots 46 attached to a bearing sleeve 48 are omitted. The bearing sleeve 48 is rotatable in the hole 4 held and carries the cylinder housing 3 towering end of a flange 50 , The inner circumference of the bearing sleeve 48 is chosen so that two axially spaced from each other on the coupling sleeve 38 trained ring protrusions 52 with their frontal surfaces in the bearing sleeve 48 are guided. The bearing sleeve 48 carries an inner handle, not shown here, that is usually located on the inside of a door to be closed. This inside handle regularly surrounds a control unit for checking the access authorization and also surrounds a battery for the electrical supply of the control unit and a motor explained in more detail below 54 , which is also included in the inner handle. The journal 6 , the shooter hollow shaft 20 and the bearing sleeve 48 have on their outer peripheral surface circumferential grooves for engagement of snap rings, not shown here, located at the edges of slots 56 or recesses 58 of the cylinder housing 3 support.

In the embodiment shown, the coupling member 36 in the axial direction of the bore 4 movably mounted, this storage not present on the hollow shaft 12 takes place, which would be readily possible. The storage is rather via a guide cylinder 60 , which is the central element of a preassembled unit 62 that forms in 4 is shown and the decoupling of an actuating movement of the engine 54 from the movement of the coupling member 36 serves and which may be essential to the invention.

The guide cylinder 60 has a cylinder housing remote stop 64 on, by a one-piece on the guide cylinder 60 molded ring is formed, and a cylinder housing side stop 66 on, by one in one on the guide cylinder 60 recessed groove held snap ring 68 is formed. The housing-side stop 66 acts with the coupling member 36 together and forms a stop surface for the front side of the coupling sleeve 38 out. The guide cylinder 60 also carries an actuator 70 , which in the form of a setting sleeve 72 is formed, which at their respective ends at least one circumferential ring 74 carries, which integrally on the adjusting sleeve 72 is trained. In the present case, the cylinder housing distal end of the adjusting sleeve 72 a plurality of rings arranged one behind the other in the axial direction 74 on. This plurality of rings 74 forms on the outer peripheral surface of the adjusting sleeve 72 a gearing 76 out.

Between the actuator 70 and the coupling member 36 There is a storage element specifically in the form of a mechanical storage element, in this case by a spring 78 is formed. This spring 78 is between the front of the coupling sleeve 38 and the end face of the actuator 70 kept under tension. On the other side of the actuator 70 there is another storage element in the form of another spring 80 that is under preload between the stop 64 and the other end of the adjusting sleeve 72 , is present. In the in 4 shown rest position are the spring forces of the spring 78 and the spring 80 in balance.

For energy-saving movement of the pre-assembled unit 62 are the guide cylinder 60 and the actuator 70 made of plastic. It makes sense to produce these parts by means of plastic injection molding.

In 6 is the on the actuator 70 acting drive unit 82 shown in the presently presented embodiment. This drive unit 82 includes a motor housing 84 for receiving an electric motor, not shown in detail, which is fed by the aforementioned battery and whose motor shaft is a drive worm 86 carries the motor housing 84 surmounted. The drive screw 86 acts with a worm wheel 88 together, which is on a wave 90 held rotationally, between two parallel extending arms 92 attached to the motor housing 84 are attached, held. The wave 90 also carries a driven wheel 94 , which is designed as a gear. The teeth of the driven wheel 94 engage in the gearing 76 of the actuator 70 one.

For mounting the embodiment discussed above, the first in 2 shown assembly on the hollow shaft 12 deferred cam hollow shaft 20 from the outside into the hole 4 pushed until one on the outer peripheral surface of the journal 6 formed flange against the front end side of the cylinder housing 3 encounters. Thereafter, from the opposite side of the preassembled unit 62 on the hollow shaft 12 postponed. Finally, in the same direction, the bearing sleeve 48 into the hole 4 inserted, being sure that the coupling claws 40 in opposite guide slots 46 be introduced. After that, the in 1 illustrated unit created. This is done by inserting the snap rings in the recess 58 or the slots 56 together. Now are journals 6 , Camshaft hollow shaft 20 and bearing sleeve 48 in the axial direction on the cylinder housing 3 secured. All coupling parts are located on the journal 6 opposite side of the cam hollow shaft 20 and are accordingly best possible against mechanical manipulation of the future outside of the lock cylinder 2 protected. That in the axial direction in the cylinder housing 3 slidably mounted coupling member 36 becomes through the end-side ends of the forwardly open guide slots 46 limited, against which the front ends of the coupling claws 40 can come across. In the opposite direction of movement, the mobility of the coupling member 36 through the axial end of the between the counter-jaws 30 limited recesses formed. Here forms the camshaft hollow shaft 20 level frontal ring surface segments.

In 1 is the above-described embodiment in a first mode in which the inner handle with the cam 24 is coupled. This coupling is effected in this case by a direct mechanical coupling and in fact by the fact that the coupling member 36 on the one hand rotationally fixed between the guide slots 46 in relation to the bearing sleeve 48 is held and with the clutch claws 40 between the counter-claws 30 the camshaft hollow shaft 20 intervenes. One over the inner handle on the flange 50 and from there to the bearing sleeve 48 transmitted rotational movement accordingly leads to a rotation of the cam 24 , Starting from this first mode, the coupling member 36 axially displaced to the outside in a second mode, in which the outer and the inner handle with the cam 24 is coupled. In this second mode of operation is the coupling member 36 in a respect to the representation according to 1 shifted to the right position, in which the Mitnehmervorsprünge 42 the clutch claw 40 at the height of the clutch gear 14 lie and between adjacent projections of this clutch gear 14 intervention. A rotational movement on the inner handle, which over the bearing sleeve 48 is transmitted, thus leading to a rotational movement of the coupling member 36 which is both the locking bolt hollow shaft 20 as well as the hollow shaft 12 entraining. A corresponding effect is shown by a rotation on the outer handle, which leads to a rotation of the receiving bolt 8th together with the hollow shaft 12 which, in turn, transmits the torque via the clutch gear 14 with the interposition of the coupling song 36 on the cam hollow shaft and the bearing sleeve 48 transfers.

Starting from this second mode, the coupling member 36 be moved axially in a third mode, in which neither the outer, nor the inner handle with the cam 24 are coupled. The coupling 32 is in the present case designed such that equal amounts of movement of the coupling member 36 must be traveled in order to get from the first mode to the second mode or from the second mode to the third mode. In this third mode of operation are the Mitnehmervorsprünge 42 the clutch claw 40 the counter-claws 32 as well as the clutch gear 14 axially upstream. Although a rotation on the inner handle leads to entrainment of the coupling member 36 , However, this rotates freely around the hollow shaft 12 , A rotation on the outer handle leads to a free rotation of the hollow shaft 12 because the clutch gear 14 is out of engagement. But it is possible to design the coupling so that both handles are rotationally locked together.

With regard to manufacturing tolerances to be maintained, the counter-claws extend 32 in not up to the bearing sleeve end of the clutch gear 14 , but in the present case end approximately in the middle of the clutch gear 14 , At this front side of the guide cylinder 60 so that a unique axial association between the preassembled unit 62 and the axially fixed parts of the coupling 32 is guaranteed.

In the embodiment discussed above, the drive of the coupling member takes place 36 by an electric motor, so that the known from the prior art disadvantages of magnetic drives can be avoided. When between the coupling member 36 and the camshaft hollow shaft 20 or the hollow shaft 12 transmitted torque, however, usually no axial displacement of the coupling member 36 at least not with the engines used in the present case and their performance. This must be designed as low as possible in view of a possible energy-saving operation of the locking device. Consequently, the movement of the coupling member 36 from the feed motion of the motor 54 decoupled, as will be explained in more detail below.

At the in 1 shown first operating position is the output gear 94 on the lock cylinder 2 opposite side of the toothing 76 like this in 1 is shown.

Because of between the engine 54 and the output gear 94 intermediate worm gear is a self-holding causes, ie the actuator can without controlled drive of the motor 54 not over the output gear 94 "hike". Should the coupling member 36 from the in 1 shown first operating mode are placed in a second mode, it is dependent on a successfully completed access authorization request via the control unit, an operation of the engine 54 , Because the spring 78 in the first operating position, the actuator 70 against the driven wheel 94 presses, the gearing becomes 76 of the actuator 70 in the toothing of the driven wheel 94 crowded. The actuator thus moves in the axial direction along the hollow shaft 12 , guided on the surface of the guide cylinder 60 , After the required to set the second operating position displacement has been traversed, holds the control unit the engine 54 at. The wheel 94 is now at about the middle of the toothing 76 , The case covered this way is the memory element, ie the spring 78 on the coupling member 36 transfer. This remains fixed within the clutch, for example because the Mitnehmervorsprünge 42 the clutch claw 40 do not align with clearances between the protrusions of the clutch gear 14 are formed, only follows a movement of the actuator 70 relative to the guide cylinder 60 , This remains stationary on the hollow shaft 12 , The movement parts become elastic by compression of the spring 80 saved. Now by turning on one of the handles between the counter-jaws 30 trained free spaces with the between the projections of the clutch gear 14 trained clearances brought to cover and the coupling member 36 from a direct attachment to one of the longitudinal side surfaces 34 solved, takes in the spring 80 stored elastic portion of the coupling member 36 with, until the actuator 70 again in balance between the two springs 78 and 80 located. In this position are the Mitnehmervorsprünge 42 at the height of the clutch gear 14 ,

If the third operating mode is actuated by this second operating mode, then the above-mentioned process is repeated, if necessary, when the coupling member 36 by transmitting a torque in the clutch 32 is held. Even then, one of the first movement of the coupling member 36 Decoupled movement of the actuator 70 which by the spring 80 is tracked as soon as the coupling member 36 is released by rotation on one of the handles.

To set the third mode, the output gear 94 set in rotation again, and that until the gearing 76 completely from the teeth of the output gear 94 has come out. The driven wheel 94 is now located between the teeth 96 and the lock cylinder side ring 74 , Due to this configuration can be dispensed with an exact driving of the motor for adjusting the first and third operating position. Only for setting the second operating mode, the engine 54 rotate by a predetermined amount, which is the same for the position from the third to the second and from the position of the first to the second position. By this measure, the control of the engine 54 much easier. Accordingly, it is preferably controlled such that the second operating mode is always initially set from the first to the third or from the third to the first operating mode.

If, for example, the first operating mode is to be set starting from the second operating mode, then the actuator becomes 70 by activating the engine 54 in the in 1 shown position. Remains the coupling member 36 stationary, so there is a compression of the spring 78 , which stores elastic components, which upon release of the coupling member 36 this pushes in the position of the first mode.

Due to the between engine 54 and actuator 70 intermediate worm gear meet all positions of the actuator 70 the requirement of self-retention.

In a relatively simply designed identifier, the latter has an active or passive transponder, which is detected in the vicinity of the locking device after a user has activated the control unit by rotation on one of the handles, as in the present inventor DE 100 44 723 is described. A simply designed identification carrier preferably has a magnet which cooperates with a magnetic switch of the control unit surrounded by the inner handle when the identifier is brought into the vicinity of this inner handle. Activation of the magnetic switch causes the third mode to be set. The magnetic switch is preferably designed so that a magnetic activation can also take place from the outside of the door, ie when the identifier is held directly to the outer handle. By the magnetic switch can then be set the third mode, which can also be referred to as a "holiday position" and in the rotation by any handle no operation of the lock bit 24 he follows.

The embodiment discussed above avoids a magnetic drive to the position of the clutch and is therefore largely protected against manipulation. In addition, the embodiment can be operated energy-saving, since the parts are relatively light and a low-power motor can be installed. Finally, through the hollow shaft 12 the conduction of an antenna, which is provided by the outer handle, ie within an outer knob, whereby the required radio power can be kept low, which is required for communication with the identifier in the access request. The hollow shaft 12 is also suitable for carrying cables for acoustic and / or optical signals, which may be required on the outside of the door, to indicate the closed state of the door, such as monitoring of locking systems by personnel of a security and locking company.

An alternative embodiment of the in 4 shown preassembled unit 62 for decoupling imposed by the engine Movement and movement of the coupling member is in the 7 to 10 shown.

In this embodiment, the decoupling of the movement of an actuator, which takes the form of a drive plate 96 is formed, and an output gear acting directly on a coupling member 98 via springs, which form the storage element. These are a torsion spring 100 between the drive plate 96 and the output gear 98 and another torsion spring 102 between the drive plate 96 and a drive wheel 104 intended. The driving disc 96 has several distributed on the circumference arranged holes 105 on, extending in the axial direction with respect to the drive plate 36 extend ( 8th ). One of these holes carries a Mitnehmerstab 106 , The further holes formed on the peripheral surface serve to receive the drive-plate-side ends of the torsion springs 100 and 102 , For adjusting the preload of the springs 100 . 102 are more recesses than necessary omitted distributed in the circumferential direction.

The drive and the driven wheel 94 . 98 are held together with the drive plate on a guide cylinder, not shown in the schematic representation, which forms an axis of rotation for these components. All components are freely rotatable on this guide cylinder, but preferably fixed in the axial direction.

As 9 clarifies, is the output gear 98 formed by a gear whose teeth on a cut-free circumferential segment 108 absence. The this circumferential segment 108 limiting teeth 110 . 112 of the gear form stops with their mutually facing flank surfaces 114 out. Between these attacks 114 this is one end of the driver rod 106 added. The torsion spring 100 is located with its output end, which is parallel to the Mitnehmerstab 106 extends between two adjacent teeth of the regular toothing.

The drive wheel 104 has a spherical peripheral surface and also has a cutaway circumferential segment 116 on, which by stop surfaces 118 is limited and which is the other end of the Mitnehmerstabes 106 receives. Furthermore, the drive wheel 104 at least one bore for receiving the other end of the torsion spring 102 on.

That in the 7 to 10 embodiment shown can act directly on a displaceable or rotary actuator of a clutch. The driven wheel 98 For example, can interact directly with a slidably mounted coupling member. On the convex outer peripheral surface of the drive wheel 104 For example, an oscillating driven back and forth drive element of a piezo motor, not shown, be supported under bias, by the oscillating movement, a rotation of the drive wheel 104 takes place in one direction, whereas in the other direction of movement the drive wheel 104 remains locked. Accordingly, successive oscillatory movements lead to a rotation of the drive wheel 104 in one direction

The rotation of the drive wheel 104 initially leads to a takeover of the Mitnehmerstabes 106 due to the bias of the torsion springs 102 at the stop 118 is applied. The driving disc 94 turns accordingly with the drive wheel 104 With. If the output gear remains stationary, since a relative movement of the same is not possible due to the mounting of the coupling member in the coupling, then the carrier rod pivots 106 in the circumferential segment 108 and pulls the torsion spring 100 on. The rotational movement of the drive plate 96 is terminated by the driver rod 106 against the attack 114 the driven wheel 98 strikes. The further actuation of the piezomotor only leads to the fact that the drive element of the motor on the peripheral surface of the drive wheel 104 slipping without causing a rotation of the drive wheel. If the coupling member is now released, gets the output gear 98 the rotational movement due to the embedded elastic moments of the torsion spring 100 after, until the output gear 98 with his other stop 114 against the driver rod 106 encounters. Reversed movements and a resilient bias of the torsion spring 102 arise with a provision of the drive wheel 104 by reversible drive via the piezo electric motor.

LIST OF REFERENCE NUMBERS

2

shooting cylinder

3

cylinder housing

4

drilling

6

pivot

8th

location hole

10

shaft mount

12

hollow shaft

14

clutch gear

16

gear sleeve

18

Hollow shaft bearing surface

20

Cam hollow shaft

22

cylinder section

24

Cam

26

groove

28

threaded hole

30

against claws

32

clutch

34

Longitudinal side face

36

coupling member

38

coupling sleeve

40

coupling claw

42

driver projection

44

Gear sleeve base

46

guide slot

48

bearing sleeve

50

flange

52

annular projection

54

engine

56

slot

58

recess

60

guide cylinder

62

pre-assembled unit

64

attack

66

attack

68

snap ring

70

actuator

72

adjusting sleeve

74

ring

76

gearing

78

feather

80

feather

82

drive unit

84

motor housing

86

drive worm

88

worm

90

wave

92

poor

94

output gear

96

driver disc

98

output gear

100

torsion spring

102

further torsion spring

104

drive wheel

105

drilling

106

carry-along rod

108

peripheral segment

110

tooth

112

tooth

114

Stop, driven wheel

116

peripheral segment

118

Stop, drive wheel

Claims (15)

Keyless locking device with a lock cylinder ( 2 ), an inner and an outer handle which rotatably at opposite ends of the lock cylinder ( 2 ) are arranged, a pivotable in a housing ( 3 ) of the lock cylinder ( 2 ) mounted cam ( 24 ) and an electronic control unit for checking the access authorization and control of a clutch ( 32 ), by which an operative connection between one of the handle and the cam ( 24 ) can be produced, wherein the coupling ( 32 ) is designed such that in a first mode, the inner handle with the lock bit ( 24 ) and the outer handle of the cam ( 24 ) is decoupled and that in a second mode, the outer and the inner handle with the lock bit ( 24 ), characterized in that in a third mode of operation the outer and inner handles of the lock bit ( 24 ) are decoupled and that the third operating mode in addition to the first and the second mode by operating the clutch ( 32 ) is adjustable. Keyless locking device according to claim 1, characterized in that the coupling ( 32 ) a coupling member ( 36 ), which in the longitudinal direction of the lock cylinder ( 2 ) is designed to be movable. Keyless locking device according to claim 2, characterized in that the coupling member ( 36 ) displaceable in the cylinder housing ( 3 ) is stored. Keyless locking device according to claim 2, characterized in that between the cam ( 24 ) and one of the handling a bearing sleeve ( 48 ) is provided, which is rotatably mounted on the cylinder housing ( 3 ) and rotationally fixed with the one handle is that between the cam ( 24 ) and the other of the handle a journal ( 6 ) is provided, which is rotatably mounted on the cylinder housing ( 3 ), with the other of the handle is rotationally fixed and with a cylinder housing ( 3 ) at any rate partially enforcing wave ( 12 ) and that the coupling ( 32 ) on the journal ( 6 ) facing away from the cam ( 24 ) is provided. Keyless locking device according to claim 4, characterized in that the coupling member ( 36 ) in the longitudinal direction of the lock cylinder ( 2 ) displaceable, but rotationally fixed to the bearing sleeve ( 48 ) is and at least one clutch claw ( 40 ) which, in the second mode of operation, is operatively connected to one of the shafts ( 12 ) associated drivers ( 14 ). Keyless locking device according to claim 5, characterized in that the cam ( 24 ) rotationally fixed to one of the shaft ( 12 ) enforced cam hollow shaft ( 20 ) is held on the cylinder housing ( 3 ) is rotatably mounted and coupling side at least one axially to over the driver ( 14 ) extending counter-claw ( 30 ) having. Keyless locking device according to claim 5 or 6, characterized in that the driver ( 14 ) by one on the shaft ( 12 ) pressed on sprocket ( 14 ) is formed. Keyless locking device according to claim 6 or 7 in its relation to claim 6, characterized in that the camshaft hollow shaft ( 20 ) arranged in the circumferential direction counter-claws ( 30 ), which in the first and second operating modes between them the at least one coupling claw ( 40 ), and that in the second mode of operation the at least one coupling claw ( 40 ) with the driver ( 14 ) is engaged. Keyless locking device according to any one of claims 6-8, characterized in that in the third mode, the at least one coupling claw ( 40 ) on the cam ( 24 ) facing away from the driver ( 14 ) and the camshaft hollow shaft ( 20 ) is upstream. Keyless locking device according to claim 5, characterized in that the coupling member ( 36 ) a clutch claw ( 40 ) having coupling sleeve ( 38 ) which is displaceable relative to the shaft ( 12 ) is stored. Keyless locking device according to claim 10, characterized in that the coupling sleeve ( 38 ) slidably on a guide cylinder ( 60 ) which is freely rotatable on the shaft ( 12 ) and which is an actuator ( 70 ) displaceably supports, with the interposition of a memory element ( 78 . 80 ) on the coupling sleeve ( 38 ) acts. Keyless locking device according to one of claims 4-11, characterized in that the shaft as a hollow shaft ( 12 ) is formed and the bearing sleeve ( 48 ) passes through and the bearing sleeve side provided provided electrical control device. Method for actuating a keyless locking device with a locking cylinder ( 2 ), an inner and an outer handle which rotatably at opposite ends of the lock cylinder ( 2 ) are arranged, a pivotable in a housing ( 3 ) of the lock cylinder ( 2 ) mounted cam ( 24 ) and an electronic control unit for checking the access authorization and control of a clutch ( 32 ), by which an operative connection between one of the handle and the cam ( 24 ), characterized in that in the method the coupling ( 32 ) between a first mode in which the inner handle with the lock bit ( 24 ) and the outer handle of the cam ( 24 ) is decoupled, a second mode in which the outer and the inner handle with the cam ( 24 ) and a third mode of operation, in which the outer and inner handle of the lock bit ( 24 ) are decoupled, switches. Method according to claim 13, characterized in that the coupling ( 32 ) a coupling member ( 36 ), which is set approximately equal amounts when switching from the first to the second mode and when switching from the second to the third mode. Method according to claim 13, characterized in that the coupling ( 32 ) a coupling member ( 36 ), which is set in the same direction of movement when switching from the first to the second mode and when switching from the second to the third mode.

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