EP2886756A1 - Locking cylinder - Google Patents

Abstract

The invention relates to a lock cylinder (10) with a lock core (16) rotatable in a housing (12), wherein the lock core can be locked to the housing by means of at least one locking element (24) which can be actuated by a key, the key being in a release sliding position of the lock core into the lock core and executable therefrom, wherein an independent of the locking element and the key and by means of a motor drive (28) actuatable additional lock (26) is provided for locking the lock core with the housing, wherein the additional locking a locking element (30) comprising, which prevents in a locking position, a rotational movement of the lock core relative to the housing and in a release position allows a rotational movement of the lock core relative to the housing, wherein the additional lock a spatially displaceable by means of the motor drive and zusammenwi with the locking element rkende spring (54), wherein in a release position of the spring, the locking element (30) is not transferred to its locking position and wherein in a locking position of the spring, the spring acts on the locking element with a force which the locking element in one of the release rotation position of the lock core deviating rotational position biases in the direction of its locking position and which transfers the locking element in the release rotational position of the lock core in the locked position.

Description

The invention relates to a lock cylinder with a lockable in a housing lock core, wherein the lock core is locked by means of at least one operable with a key locking element with the housing, wherein the key in a release rotation position of the lock core in the lock core insertable and executable from this, wherein a is provided independently of the locking element and the key and actuated by means of a motor drive additional locking mechanism for locking the lock core with the housing, wherein the additional locking comprises a locking element which prevents in a locking position, a rotational movement of the lock core relative to the housing and in a Release position allows a rotational movement of the lock core relative to the housing.

From the EP 0 743 412 A1 a profile cylinder is known, with a movable by a drive, additional locking element (hereinafter locking element), which prevents the rotational movement of a locking core in a locking position. The drive can be controlled as a function of a user identifier stored, for example, on the key.

In the known profile cylinder, a locking of the lock core by means of the additional locking element only in a certain rotational position of the lock core is possible, namely in the Freigabedrehlage, in which the key is inserted into the lock core and executable from this. But it is possible that such a profile cylinder with inserted key longer time remains in a deviating from the release rotational position. During this time, a cyclic activation of the additional locking element means that it can not be transferred to its locking position, but each individual activation attempt is accompanied by considerable energy consumption. This is particularly disadvantageous when the drive of the additional locking element is battery operated.

On this basis, there is a need, one from the EP 0 743 412 A1 to improve known arrangement so that it is well suited for battery operation.

This object is achieved in that the additional locking comprises a means of the motor drive locally displaceable and cooperating with the locking element spring, wherein in a Release position of the spring, the locking element can not be converted into its locking position and wherein in a locking position of the spring, the spring acts on the locking element with a force which biases the locking element in a deviating from the Freigabedrehlage the lock core rotational position in the direction of its locking position and which the locking element in the Release sliding position of the lock core transferred to the locking position.

According to the invention, the additional locking comprises a spring which not only provides a locking force for the locking element, but is locally displaceable by means of the motor drive. This makes it possible in a release position of the spring to arrange the locking element in an unlocked state. In a deviating from the release position of the lock core rotational position allows the spatially displaceable spring to store energy and bias the locking element. This stored energy is available for a transfer of the locking element in the locking position, immediately after the lock core has been transferred to its release position.

The lock cylinder according to the invention makes it possible to dispense with a cyclical query of the motor drive for driving the locking element. It is sufficient that the motor drive on recognition of an authorized user, the spring is transferred to its release position and that, for example, after a predetermined period of time, the spring is transferred to its locking position. When transferring the spring in the locking position, it is irrelevant whether the lock cylinder is already in the release position or not. If the lock cylinder occupies a deviating from the release rotational position, the energy required for a transfer of the locking element in its locking position is stored by means of the spring located in its locking position. This energy is used in transferring the lock cylinder in the release position to move the locking element from its biased position out into the locking position.

Preferably, the locking element is designed in the form of a locking pin. This allows a comparatively compact and space-saving design of an additional lock.

Furthermore, it is preferred that the spring is designed as a compression spring. This also contributes to a compact design of Zusatzverrieglung. But it is also conceivable to form the spring as a tension spring.

It is further preferred if the spring interacts with the locking element at a first end and at least indirectly with the motor drive at a second end. The spring is thus in the power flow between the motor drive and locking element, so that the motor drive indirectly acts on the locking element with the interposition of the spring.

It is conceivable that the spring is fully relaxed in its release position, but spaced so far from the lock core, that the locking element is not locked to the lock core and allows a rotational movement of the lock core. However, it is preferred that the locking element in the release position of the spring with a stop cooperates, which prevents a transfer of the locking element in its locking position. In this way, it is possible that also in the release position of the spring acts a bias on the locking element, so that in the locking position of the spring a comparatively higher, acting on the locking element spring force can be provided. This contributes to a reliable transfer of the locking element in its locking position.

It is also preferred if in the locking position of the spring and in a deviating from the release rotational position of the lock core rotational position of the lock core, the locking element is biased against a sliding surface of the lock core. The sliding surface is, in particular, the cylindrical outer surface of the locking core. This outer surface preferably has a depression into which the (prestressed) locking element can be immersed.

In a preferred embodiment of the invention it is provided that the spring is supported on a Federabstützelement. This allows a simple local displacement of the spring, in particular an o.g. second end of the spring.

It is preferred that the Federabstützelement is spatially displaceable parallel to or along an axis of action of the spring. As a result, an at least as far as possible transverse force-free arrangement can be created.

It is further preferred that the axis of action of the spring extends radially relative to a rotational axis of the lock core. This supports a reliable transfer of the locking element from a biased position into the locking position and regardless of which direction of rotation of the lock core is rotated in its release position.

In a preferred embodiment, the Federabstützelement is guided in a thrust bearing. This allows a simple and reliable displacement of a support surface of the Federabstützelements.

A particularly compact design results when the thrust bearing is integrated into the housing.

Preferably, the Federabstützelement is coupled via a rotary thrust bearing with the motor drive. This allows the use of a motorized rotary drive. However, it is also conceivable to use a linear drive, which shifts the spring support along a straight axis.

When using a rotary thrust bearing, it is particularly preferred if this one, based on a rotational axis of the motor drive eccentric, drivable in a rotational direction crank, which cooperates with a crank receiving the Federabstützelements. This allows a simple implementation of a rotational movement of the motor drive in a rectilinear movement of the Federabstützelements.

Particular advantages arise when the motor drive is powered by a battery with energy. In this case, the lock cylinder has a significantly prolonged, maintenance-free operating life compared to arrangements known from the prior art.

A cyclic actuation of the locking element in a Nichtfreigabedrehlage the lock cylinder could possibly also be prevented by the fact that a means for detecting the rotational position of the lock core is provided within the housing. However, the present invention makes it possible to dispense with such a device, which is expressly not provided in a preferred embodiment.

Advantages and embodiments of the lock cylinder according to the invention and further features and advantages of the invention are the subject of the following description and the drawings of a preferred embodiment.

Fig. 1

eine Seitenansicht einer Ausführungsform eines Schließzylinders;

Fig. 2

eine Vorderansicht des Schließzylinders entsprechend einer in Fig. 1 mit II - II bezeichneten Sichtebene, wobei ein Schließkern eine Freigabedrehlage einnimmt und ein Verriegelungselement mit dem Schließkern verriegelt ist;

Fig. 3

einen Ausschnitt aus Fig. 2 in vergrößerter Darstellung;

Fig. 4

eine der Fig. 2 entsprechende Ansicht, wobei das Verriegelungselement unverriegelt ist und eine Drehung des Schließkerns erlaubt; und

Fig. 5

eine der der Fig. 2 entsprechende Ansicht, wobei der Schließkern eine von der Freigabedrehlage abweichende Drehlage einnimmt und das Verriegelungselement in Richtung seiner Verriegelungsposition vorgespannt ist.

In the drawing show:

Fig. 1

a side view of an embodiment of a lock cylinder;

Fig. 2

a front view of the lock cylinder according to a in Fig. 1 with II - II designated viewing plane, wherein a locking core occupies a release position and a locking element is locked to the lock core;

Fig. 3

a section from Fig. 2 in an enlarged view;

Fig. 4

one of the Fig. 2 corresponding view, wherein the locking element is unlocked and allows rotation of the lock core; and

Fig. 5

one of the Fig. 2 corresponding view, wherein the lock core occupies a deviating from the release rotational position rotational position and the locking element is biased in the direction of its locking position.

An embodiment of a lock cylinder is in the FIGS. 1 to 5 represented and designated there by the reference numeral 10. The lock cylinder 10 includes a housing 12 having a substantially hollow cylindrical receptacle 14 for receiving a lock core 16. In the embodiment shown in the drawing, an additional lock core 18 is aligned with the lock core 16. The lock core 16 and / or the lock cores 16 and 18 are rotatable about a lock core axis 20 for actuating a lock bolt 22.

The lock core 16 and / or the lock cores 16 and 18 can be locked to the housing 12 by means of a plurality of locking elements 24. The blocking elements 24 are made of their (in Fig. 1 shown) by means of an inserted into the lock core 16 key (not shown) spent in its release position to allow rotation of the lock cylinder 16 and / or the lock cylinder 16, 18 about the lock cylinder axis 20 within the housing 12.

The lock cylinder 10 comprises a generally designated by the reference numeral 26 additional lock for locking at least one of the lock cores 16, 18 with the housing 12. The auxiliary lock 26 includes a motor drive 28 and a locking member 30. The locking member 30 is actuated independently of the locking elements 24 and serves as additional security.

To supply energy to the motor drive 28, an electrical energy store, in particular in the form of a battery 32, is provided. The battery 32 is preferably disposed within the housing 12 of the lock cylinder 10.

In order to control the additional locking device 26, the locking cylinder 10 comprises a transmitting / receiving unit 34, which cooperates with a user identification (not shown), for example a transponder. The transmitting / receiving unit 34 is coupled to an evaluation / control unit 36, which serves to control the motor drive 28. The transmitting / receiving unit 34 and the evaluation / control unit 36 are preferably arranged within the housing 12 of the lock cylinder 10.

In an alternative embodiment it is provided that at least one of the parts battery 32, transmitting / receiving unit 34, evaluation / control unit 36, preferably all parts 32, 34, 36, are arranged outside the housing 12 of the lock cylinder 10, in particular on or a connected to the housing 12 component or on or in a housing 12 adjacent to the arranged component, such as a rosette.

The lock core 16 has a cylindrical sliding surface 38 which, viewed in the circumferential direction of the outer surface of the lock core 16, is interrupted in the region of a locking element receptacle 40. The locking element receiving 40 is set back relative to the sliding surface 38 and relative to the lock core axis 20 in the radial direction.

The position of the locking element 40 along the circumference of the sliding surface 38 is seen such that in a Release position of the lock core 16, in which a key in the lock core 16 can be inserted and executable from this, the locking element receptacle 40 is aligned with the locking element 30.

The motor drive 28 is designed as a rotary drive and has an axis of rotation 42. The rotation axis 42 is connected to a drive part 44 (see FIG. Fig. 1 ), which carries a crank 46, which is arranged eccentrically offset relative to the axis of rotation 42. The crank 46 is integrally formed with the drive member 44, or the crank 46 is provided as a separate part and connected to the drive member 44. The crank 46 dips into a crank receptacle 48 of a Federabstützelements designated overall by the reference numeral 50. The crank receptacle 48 is formed in the form of a backdrop.

The spring support element 50 comprises a spring receiving space 52 for receiving a spring 54, which is designed in particular as a compression spring. The spring 54 cooperates with a first end 56 with the locking element 30 and with a second end 58 with a Federabstützfläche 60 of the Federabstützelements 50th

The locking element 30 has a shoulder 62 on which the first end 56 of the spring 54 is supported. The shoulder 62 also cooperates with a stop 64 of the Federabstützelements 50, in such a way that a movement path of the locking member 30 is limited in the direction of the lock core axis 20.

An effective axis 66, along which the spring 54 is compressible and can be relaxed, extends in the radial direction with respect to the lock core axis 20. The spring support element 50 is in parallel direction in a built-in housing 12 thrust bearing 68 out. In this way, the Federabstützelement 50 within the housing 12 along a parallel to the axis of action 66 of the spring 54 or identical thereto axis is displaceable.

The operation of the auxiliary latch 26 will be described below with reference to the FIGS. 2 to 5 described.

In the in Fig. 2 shown state, the lock core 16 assumes its release position, so that the locking element receptacle 40 is aligned with the locking element 30 of the additional latch 26. The locking element 30 is immersed in the locking element receptacle 40 and prevents regardless of the position of the locking elements 24, a rotational movement of the lock core 16 within the housing 12. The spring 54 also assumes its locking position, in which the Federabstützelement 50, the spring 54 towards the lock core 16th displaced as in a release position of the spring 54 and the locking element 30 (see. Fig. 4 ).

In the in Fig. 2 illustrated locking state is the additional lock 26 in a stable locking position, in which the crank 46 is arranged slightly offset to a top dead center as seen in a clockwise direction.

Based on the state according to FIGS. 2 and 3 For example, the additional interlock 26 can be actuated, for example by recognizing an authorized user who carries a transponder with him and who cooperates with the transceiver 34 so that the evaluation / control unit 36 controls the motor drive 28, that this is rotated counterclockwise. This causes a rotation of the crank 46 about the rotation axis 42 in the counterclockwise direction and a displacement of Federabstützelements 50 within the thrust bearing 68, so that the spring 54 assumes its release position, in which it is located further away from the lock core 16, as in the locking position according to FIGS. 2 and 3. In the release position of the spring 54, the shoulder 62 of the locking element 30 cooperates with the stop 64 of the Federabstützelements 50. The free end of the locking element 30 is disposed out of engagement with the locking element receptacle 40 of the lock core 16, so that the lock core 16 within the housing 12 is rotatable. This rotation takes place by means of an inserted into the lock core 16 key which actuates the locking elements 24, so that the locking elements 24 release the lock cylinder 16.

If starting from the in Fig. 4 shown state of the lock cylinder 10 of the lock core 16 is rotated, so that the locking element holder 40 is no longer aligned with the locking member 30, the locking member 30 can not be immersed in the locking element receptacle 40. Starting from the in Fig. 4 shown state of the additional latch 26, but this can already be converted back into a "Vorverriegelungszustand", namely by the motor drive 28 is driven in a clockwise direction, so that the crank 46 via the crank 48, the Federabstützelement 50 moves in the direction of the lock core 16 (see. Fig. 5 ). In this way, the spring 54 from the release position according to Fig. 4 in the locking position according to Fig. 5 spent. Since the locking element 30 can not dip into the locking element receptacle 40, but to the sliding surface 38 of the lock core 16 is applied, the spring 54, which is clamped between the shoulder 62 of the locking element 30 and the Federabstützfläche 60, compressed. In this way, the locking element 30 is biased in the direction of its locking position. As soon as the lock core 16 is rotated into its release rotational position, the locking element receptacle 40 comes into alignment with the locking element 30, which is then transferred by means of the compressed spring 54 from the prestressed state on the sliding surface 38 into the locking position (cf. Fig. 2 ).

The lock cylinder according to the invention has the advantage that the lock core 16 with inserted key in the in Fig. 5 shown, deviating from a release rotational position rotational position may remain without a cyclic actuation of the additional lock 26 is required in this time. The transfer to the locking position is ensured by the bias of the spring 54.

As an alternative to a spring 54, which is designed as a compression spring, it is also conceivable to use a leaf spring.

Claims (15)

Locking cylinder (10) having a locking core (16) which can be rotated in a housing (12), wherein the locking core (16) can be locked to the housing (12) by means of at least one locking element (24) which can be actuated by a key, the key being in a release sliding position the lock core (16) into the lock core (16) insertable and executable therefrom, wherein an independent of the locking element (24) and the key and by means of a motor drive (28) actuatable additional lock (26) for locking the lock core (16) is provided with the housing (12), wherein the additional lock (26) comprises a locking element (30) which prevents in a locking position rotational movement of the lock core (16) relative to the housing (12) and in a release position, a rotational movement of the lock core ( 16) relative to said housing (12), characterized in that the additional locking element (26) (by means of the motor drive 28) locally displaceable and cooperating with the locking element spring (54), wherein in a release position of the spring (54) the locking element (30) is not in its locked position can be transferred and wherein in a locking position of the spring (54), the spring (54) the locking element (30) acted upon by a force which biases the locking element (30) in a direction deviating from the release rotational position of the lock core (16) rotational position in the direction of its locking position and which the locking element (30) in the release rotational position of Lock core (16) transferred to the locking position. Lock cylinder (10) according to claim 1, characterized in that the locking element (30) is designed in the form of a locking pin. Lock cylinder (10) according to one of the preceding claims, characterized in that the spring (54) is designed as a compression spring. Lock cylinder (10) according to one of the preceding claims, characterized in that the spring (54) with a first end (56) with the locking element (30) and with a second end (58) at least indirectly with the motor drive (26) cooperates , Lock cylinder (10) according to one of the preceding claims, characterized in that the locking element (30) cooperates in the release position of the spring (54) with a stop (64) which prevents a transfer of the locking element (30) in its locking position. Locking cylinder (10) according to one of the preceding claims, characterized in that in the locking position of the spring (54) and in one of the Freigabedrehlage the lock core (16) deviating rotational position of the lock core (16) the locking element (30) against a sliding surface (38 ) of the lock core (16) is biased. Locking cylinder (10) according to one of the preceding claims, characterized in that the spring (54) is supported on a Federabstützelement (50). Locking cylinder (10) according to claim 7, characterized in that the Federabstützelement (50) parallel to or along an axis of action (66) of the spring (54) is locally displaceable. Lock cylinder (10) according to claim 8, characterized in that the active axis (66) of the spring (54) with respect to a rotational axis (20) of the lock core (16) extends radially. Lock cylinder (10) according to one of claims 7 to 9, characterized in that the spring support element (50) is guided in a thrust bearing (68). Lock cylinder (10) according to claim 10, characterized in that the thrust bearing (68) in the housing (12) is integrated. Lock cylinder (10) according to one of claims 7 to 11, characterized in that the spring support element (50) via a rotary thrust bearing with the motor drive (28) is coupled. Locking cylinder (10) according to claim 12, characterized in that the rotary thrust bearing comprises a relative to a rotational axis (42) of the motor drive (28) eccentric, drivable in one direction crank (46), which with a crank receptacle (48) of Federabstützelements (48) 50) interacts. Lock cylinder (10) according to one of the preceding claims, characterized in that the motor drive (28) by means of a battery (32) is supplied with energy. Lock cylinder (10) according to one of the preceding claims, characterized in that the lock cylinder (1) has a device for detecting the Has rotational position of the lock core (16) within the housing (12) expressly not.

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