DE102022209279A1 - Electronic lock cylinder - Google Patents

Abstract

An electronic locking cylinder has a locking mechanism (3) with a rotatable blocking element (13) for selectively supporting or releasing the movement of a locking element (4). An actuator (10) of the locking mechanism (3) has a piezo motor for driving a drive shaft (14) coupled to the blocking element (13) in two rotational positions. In one rotational position, projections (17) of the blocking element (13) face a shoulder (18) of the locking element (4), while in the other rotational position the projections (17) face recesses (21) of the locking element (4).

Description

The invention relates to an electronic locking cylinder with a core that can be rotated in a housing, with an electronic locking mechanism for selectively blocking or releasing the movement of the core, with a locking element that can be moved into one of the components of the housing or the core, and a locking element in the component of the core opposite the locking element or the housing arranged locking recess and with an electrically controllable actuator, the actuator being arranged to support the locking element within the locking recess.

A locking mechanism for such a locking cylinder is, for example, from EP 1 626 142 A2 known. In this locking mechanism, a holding element that can be controlled by the actuator is slidably guided into a recess in a housing pin parallel to the axis of rotation of the core. When the actuator is de-energized, the holding element penetrates into the recess in the housing pin, whereby a core pin is held in a separating plane between the housing and the core. This blocks the movement of the core and the locking cylinder is in a locking position. As a result, the core is directly connected to the housing in a form-fitting manner in the locking position. The disadvantage is that the locking mechanism has many components that need to be assembled.

The invention is based on the problem of developing an electronic locking cylinder of the type mentioned in such a way that it is particularly simple and particularly tamper-proof.

This problem is solved according to the invention in that the actuator has a blocking element that can be driven by a motor between two positions, one position of the blocking element corresponding to a blocking position of the movement of the blocking element, in which the blocking element is held in the blocking recess, and the other position of the blocking element corresponds to the release position of the locking element, in which the locking element can be moved out of the locking recess.

This design means that only a single locking element is required, meaning that the locking cylinder has a particularly simple structure. Furthermore, in the best case scenario, the actuator only requires electrical power when its position is changed. The locking recess is preferably designed as a blind hole in the core and is therefore not accessible via a locking channel in the core. This significantly increases the security against manipulation of the electronic locking cylinder.

According to another advantageous development of the invention, the holding of the blocking element in the blocking position and the release position can be permanently ensured if the blocking element is held in a self-locking manner in both positions. As a result, no electrical current is required to permanently hold the blocking element in one of its positions. Thanks to the self-locking mechanism, vibrations do not lead to the locking cylinder being manipulated.

According to another advantageous development of the invention, the control of the blocking element is particularly simple if the motor of the actuator is designed as a piezo motor. Such a piezo motor uses the physical piezo effect to generate a linear or rotational movement and can be easily switched between two positions that remain independently in their position. In addition, such a piezo motor consists of a particularly small number of components that need to be assembled.

The locking element can be easily pushed out of the locking recess when the blocking element of the initial movement of the core is in the release position if the locking recess is designed as a funnel-shaped trough and the end of the locking element protruding into the locking recess is hemispherical.

According to another advantageous development of the invention, blocking the blocking element in the position in the blocking recess is particularly simple if the blocking element has at least one shoulder and if the shoulder is engaged behind by the blocking element in the blocking position.

According to another advantageous development of the invention, the components of the locking mechanism are constructed in a particularly simple manner if one of the components of the locking element or the blocking element has a radially projecting projection and the opposite component of the blocking element or the locking element has a wide recess corresponding to the projection and if in in one rotational position of the blocking element the projection of the recess and in another rotational position the projection faces the shoulder.

According to another advantageous development of the invention, it contributes to further structural simplification of the locking mechanism if the blocking element is rotatably mounted.

According to another advantageous development of the invention, the locking mechanism is particularly compact when longitudinal axes of the Locking element and blocking element are aligned. This design enables the locking mechanism to support particularly high forces, even with small dimensions in the locking cylinder, and security against manipulation is increased.

According to another advantageous development of the invention, the design effort for moving the locking element can be kept particularly low if the locking element is biased into the locking recess by a spring element.

According to a further advantageous development of the invention, the security against manipulation of the locking cylinder can be increased in that the positional energy of the blocking element is at a minimum in the blocking position. Through this configuration, the blocking element strives to assume the blocking position at all times. For example, overcoming the self-locking mechanism due to vibration introduced into the locking cylinder from outside cannot result in the release position being reached. The setting of the minimum positional energy can be implemented constructively using a restoring force. This can be generated, for example, by a leg spring, which biases the blocking element in the direction of the blocking position. Alternatively, the blocking element can be displaced against gravity when moving into the release position via a ramp in the locking mechanism.

According to another advantageous development of the invention, the locking cylinder can be assembled particularly easily if the locking mechanism has an actuator housing for receiving the actuator, the blocking element and the locking element. This allows the actuator housing, the actuator, the blocking element and the locking element to be combined into a pre-assembled assembly and assembled together.

According to another advantageous development of the invention, it contributes to further simplifying the assembly of the locking mechanism if the actuator housing has an external thread and a hole in the housing has a correspondingly designed internal thread.

• 1 einen Teilschnitt durch einen elektronischen Schließzylinder,
• 2 vergrößert eine Schnittdarstellung durch einen Aktor des Schließzylinders aus 1 in Blockierstellung,
• 3 eine Schnittdarstellung durch den Aktor aus 2 entlang der Linie III - III,
• 4 den Aktor aus 2 in einer Freigabestellung,
• 5 eine Schnittdarstellung durch den Aktor aus 4 entlang der Linie V - V,
• 6 eine weitere Ausführungsform eines Aktors des elektronischen Schließzylinders in Blockierstellung,
• 7 den Aktor aus 6 in Freigabestellung.

The invention allows numerous embodiments. To further clarify their basic principle, two of them are shown in the drawing and are described below. This shows in

• 1 a partial section through an electronic locking cylinder,
• 2 Enlarges a sectional view through an actuator of the locking cylinder 1 in blocking position,
• 3 a sectional view through the actuator 2 along the line III - III,
• 4 the actuator 2 in a release position,
• 5 a sectional view through the actuator 4 along the line V - V,
• 6 a further embodiment of an actuator of the electronic locking cylinder in the blocking position,
• 7 the actuator 6 in release position.

1 shows an electronic locking cylinder with a core 2 that can be rotated in a housing 1 and with an electronic locking mechanism 3 for selectively blocking or releasing the movement of the core 2. The locking mechanism 3 has a locking element 4 which is guided in a longitudinally displaceable manner in the housing 1 and a locking element 4 in the core 2 opposite locking recess 5. The locking recess 5 is designed as a funnel-shaped trough in side walls, while the end of the locking element 4 protruding into the locking recess 5 is designed hemispherical. The locking element 4 is biased into the locking recess 5 by a spring element 6. If the movement of the locking element 4 is not blocked by the locking mechanism 3, the locking element 4 can be pressed out of the locking recess 5 against the force of the spring element 6 when the core 2 rotates. If the movement of the locking element 4 is blocked by the locking mechanism 3, the locking element 4 is prevented from being pushed out of the locking recess 5 and thus the core 2 is prevented from rotating. The electronic locking mechanism 3 has an actuator housing 7 with an external thread 8 for screwing into a correspondingly designed internal thread 9 of the housing 1. The electronic locking mechanism 3 can be activated, for example, by a key (not shown) inserted into the core 2 or via a reading device (also not shown). control a transponder chip. An energy storage device arranged, for example, in the housing 1 and electrical lines for supplying the electronic locking mechanism 3 with electrical current and control signals are not shown to simplify the drawing.

2 shows the electronic locking mechanism 3 1 in an enlarged sectional view through the actuator housing 7 with an actuator 10 arranged therein. The actuator housing 7 is pot-shaped to accommodate a motor 11 designed as a piezo motor and an outer guide part 12. The outer guide part 12 supports a rotatably mounted blocking element 13 and one of the motor 11 drive shaft 14 rotatable in two positions. An inner guide part 15 is in the outer guide part 12 fastens and guides the locking element 4. In addition, the inner guide part 15 supports the spring element 6. The drive shaft 14 is positively coupled in the direction of rotation to the blocking element 13 via a coupling device 16. In the blocking position shown, the blocking element 13 is supported by means of several projections 17 on a shoulder 18 on the underside of the blocking element 4. As a result, the blocking element 4 cannot descend into the blocking element 13. The blocking position can be defined as the most energetically advantageous position of the blocking element 13 using elements not shown, such as a leg spring. Usual mechanical manipulation attempts would lead to the locking mechanism being moved into the blocking position and the locking cylinder could not easily be released.

3 shows a sectional view through the electronic locking mechanism 3 2 along the line III - III on the coupling device 16. The coupling device 16 has positively interlocking coupling claws 19, 20 arranged on the drive shaft 14 and the blocking element 13.

4 shows a sectional view through the electronic locking mechanism 3 in a position that releases the movement of the locking element 4. The blocking element 13 is opposite that in 2 shown position with the projections 17 rotated into a position in which these projections 17 are aligned with elongated recesses 21 in the locking element 4. As a result, the locking element 4 can be turned by rotating the in 1 shown core 2 are pressed out of the locking recess 5 and dive into the blocking element 13.

5 shows a sectional view through the locking mechanism 3 4 along the line V - V, that the inner contour of the blocking element 13 with the projections 17 corresponds to the outer contour of the blocking element 4 with the recesses 21, so that the blocking element 4 can only dive into the blocking element 13 in the intended rotational position shown.

6 shows a sectional view through a further embodiment of a locking mechanism 103 with an actuator 110 in a blocking position. This embodiment differs from the one in 2 in that a projection 117 of a blocking element 113 is designed as a flag projecting radially from a drive shaft 114. In the blocking position shown, the projection 117 is supported on a shoulder 118 arranged in the central region of a locking element 104. A motor 111 designed as a piezo motor drives the drive shaft 114 in two 6 and 7 positions shown.

7 shows the locking mechanism 103 6 in a release position. Opposite the in 6 In the position shown, the drive shaft 114 is rotated through 90 °, so that the projection 117 of the blocking element 113 is moved out of the range of movement of the blocking element 104. This means that the locking element 104 can be removed from the in 1 locking recess 5 shown are pushed out and plunge into the locking mechanism 103.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1626142 A2 [0002]

Claims (12)

Electronic locking cylinder with a core (2) which can be rotated in a housing (1), with an electronic locking mechanism (3) for selectively blocking or releasing the movement of the core (2), with one in one of the components of the housing (1) or the core (2) movable locking element (4) and a locking recess (5) arranged in the opposite component of the core (2) or the housing (1) to the locking element (4, 104) and with an electrically controllable actuator (10, 110), wherein the Actuator (10, 110) for supporting the locking element (4, 104) is arranged within the locking recess (5), characterized in that the actuator (10, 110) is a blocking element (11) which can be driven between two positions by a motor (11, 111). 13, 113), one position of the blocking element (13) corresponding to a blocking position of the movement of the blocking element (4, 104), in which the blocking element (4, 104) is held in the blocking recess (5), and the other position of the Blocking element (13, 113) corresponds to the release position of the blocking element (4, 104), in which the blocking element (4, 104) can be moved out of the blocking recess (5). Lock cylinder after Claim 1 , characterized in that the blocking element (13, 113) is held in a self-locking manner in both positions. Lock cylinder after Claim 2 , characterized in that the motor (11, 111) of the actuator (10, 110) is designed as a piezo motor. Locking cylinder according to at least one of the preceding claims, characterized in that the locking recess (5) is designed as a funnel-shaped trough and the end of the locking element (4, 104) which projects into the locking recess (5) is hemispherical. Locking cylinder according to at least one of the preceding claims, characterized in that the blocking element (4, 104) has at least one shoulder (18, 118) and that the shoulder (18, 118) is engaged behind by the blocking element (13, 113) in the blocking position . Locking cylinder according to at least one of the preceding claims, characterized in that one of the components of the blocking element (4) or the blocking element (13) has a radially projecting projection (17) and the opposite component of the blocking element (13) or the blocking element (4) has a wide recess (21) corresponding to the projection (17) and that in one rotational position of the blocking element (13) the projection (17) faces the recess (21) and in another rotational position the projection (17) faces the shoulder (18). . Locking cylinder according to at least one of the preceding claims, characterized in that the blocking element (13, 113) is rotatably mounted. Locking cylinder according to at least one of the preceding claims, characterized in that the longitudinal axes of the locking element (4) and the blocking element (13) are aligned. Locking cylinder according to at least one of the preceding claims, characterized in that the locking element (4, 104) is biased into the locking recess by a spring element (6). Locking cylinder according to at least one of the preceding claims, characterized in that the positional energy of the blocking element (13, 113) has a minimum in the blocking position. Locking cylinder according to at least one of the preceding claims, characterized in that the locking mechanism (3, 103) has an actuator housing (7) for receiving the actuator (10, 110) of the blocking element (13, 113) and the locking element (4, 104). Locking cylinder according to at least one of the preceding claims, characterized in that the actuator housing (7) has an external thread (8) and a bore in the housing (1) has a correspondingly designed internal thread (9).

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