DE29803484U1 - Mechanically and electrically coded device - Google Patents

Description

Kuhnke GmbH
Lütjenburger Strasse 101
23714 Malente

Mechanically and electrically coded device

This invention is based on a mechanically and electrically coded device for locking and unlocking a second part movably mounted in a first fixed part with the aid of at least one locking means, which is separate from an actuator designed as an electrical converter and which can be adjusted by an adjusting element assigned to the actuator to carry out the locking and unlocking, that the locking means engages in a receptacle in the locking state and by this engagement prevents the movement of the part movably mounted in the fixed part within the fixed part and that the locking element is disengaged from the receptacle in the unlocking state and in this state allows a predetermined movement of the movably mounted part within the fixed part, provided that the user codes match the defined codes mentioned above.

DE Gm 297 15 137.1 describes a locking device in which the movement of an actuating element acts on locking means which can be brought into engagement or disengagement on a fixed surface and at a predetermined angle inclined to the axis of the actuating element.

With this design, there is a considerable amount of effort involved in producing the guideways, as on the one hand they have to run at a predetermined angle to the direction of movement of the actuating element! At the same time, these complicated to produce tracks must be made with a high surface quality, so that the locking means do not get caught. Since this design preferably uses two locking means that are moved by a common actuating element, this actuating element must be designed in such a way that no lateral forces act on the actuator via the actuating element when the actuator is actuated. This also requires complex production, as the actuating element is sensibly designed to be roof-shaped in the area of action with the locking means. These two roof surfaces also require a high surface quality. Another feature of the locking device mentioned is that when balls or cylindrical locking means are used, a high surface pressure can occur, which in the worst case can lead to deformation of the slideways and the roof surface of the actuating element.

The object of this invention is to create a mechanically and electrically coded device that can be manufactured easily and inexpensively using simple means and is safe to use.

This object is achieved in that at least one locking means is movably mounted in or on the movably mounted part and the locking means can be brought into engagement by the movement of at least one adjusting element in at least one receptacle of the fixed part or disengaged from the receptacle by the opposite direction of movement of the adjusting element.

The movable part of this device is preferably a cylinder with rotational symmetry on the outside, which in the unlocked state is mounted so that it can rotate around its longitudinal axis in the fixed part around its center point M. This movable part has a recess in or parallel to its longitudinal axis for receiving a mechanically and/or

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electrically coded key or locking means. The mechanical part of this key interacts with mechanical locking means in the coded device (not described in more detail), as is generally known. At the same time, however, the key also has an electrical coding, which is also interrogated in a known manner within the device according to the invention. For electrically coded locking and unlocking of the device, the movable part has a receptacle in which a locking means that can be actuated by an actuator is movably mounted. This receptacle in the movable part corresponds to an associated receptacle in the fixed part, into which the locking means engages in the locked state. The engagement of the locking means in the fixed part can be supported by the force of a spring or, if installed in the appropriate position, occurs exclusively through the force of gravity acting on the locking means.

The locking means can be designed as a cylindrical pin, for example. The receptacle provided in the movable part for this cylindrical locking means would then preferably be a depth-limited bore, whereby in the unlocked state the front face of the locking means facing away from the actuator comes into contact with the depth limit of the receptacle bore. This receptacle bore in the movable part corresponds to another receptacle in the fixed part. This receptacle in the fixed part serves on the one hand to accommodate and movably support the actuating element, and in the locked state also to partially accommodate the locking means. The actuating element works together with an actuator designed as an electrical converter and transmits the actuator movement to the locking means. If, for example, a lifting magnet is used as the actuator, its movement and thus also the movement of the actuating element - will run on a straight axis between two end positions. Depending on the respective position of the actuating element, the locking means is brought into engagement with or disengaged from the fixed part.

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Instead of the lifting magnet mentioned as an example, it is also possible to use an electric motor with a limited swivel angle or a rotating electric motor as an actuator. The respective motor axis is then preferably arranged at a right angle to the direction of movement of the locking means. For example, an eccentric disk can be provided as an actuating element for a motor with a limited swivel angle, the eccentric course of which is designed in such a way that the locking means can be brought into or out of engagement. A rotating motor is used together with a gearbox, the output shaft of which also has an eccentric design that acts accordingly on the locking means.

In a simple design, however, a lifting magnet as an actuator is preferred.

It has also proven to be useful to arrange the locking means in the movable part in such a way that, in the unlocked state and with a predetermined movement, it moves around the same center point M around which the movable part is also moved within the fixed part. In this case, the surface of the locking means inclined towards the actuating element is supported on the same circular surface within the fixed part, which accommodates the movable part of the device in an axial extension.

In a further embodiment, it is possible to create a circumferential groove in the fixed part, in which the locking means slides when the moving part moves. In this case, the radius of the groove and the radius of the moving part are preferably related to the same center point M and to the same longitudinal axis of the moving part. However, it is also possible for the center points of the groove to be created to be offset from the center of the circular surface. This would bring about a change in the movement force to be applied.

Depending on the task underlying the respective design of the encodable device, it is also possible to engage or disengage this device using several electrically coded locking devices. Each locking device can be assigned its own actuator, with each locking device in turn being assigned its own, different code. This results in a multiple increase in code security compared to a single locking device with an associated actuator code. However, it is also possible to engage or disengage several locking devices using a common actuator, or to engage or disengage a group of several locking devices using a single actuator per group.

In the embodiment described above, a cylindrical, spring-loaded pin was provided as the locking means. However, this locking means can also take on a different shape, e.g. the shape of a rectangular disk with a defined length, width and thickness. Of course, the receptacles in the movable and fixed parts of the device must be adapted to these designs. It is also possible to design the locking means as a pivoting lever, with the bearing of this lever being carried out, for example, by a shaft or by choosing a suitably designed cutting bearing. Here too, it is possible to equip the actuating element with a spring, the force of which counteracts the actuation of the actuator.

It goes without saying that the depth of the receptacle is adjusted to the length of the locking means in such a way that, in the unlocked state, the specified freedom of movement of the movably mounted part in the fixed part is achieved without hindrance. It has proven useful to fix this adjustment by having the stop surface of the locking means rest on the depth-limited stop surface of the receptacle for the locking means.

In order to ensure that the locking means slides unhindered out of its locking position in the unlocked state, the locking means and the actuating element must be provided with appropriately broken edges on their respective facing surfaces, whereby these edge breaks can be a molded radius, for example in the case of a cylindrical locking means. An example of an embodiment is described below using the drawing. Here:

Fig. 1 a partial section through the device in the area of the locking means in the locked state,

Fig. 2 shows a partial section according to Fig. 1, but in the unlocked state, Fig. 3 shows a further partial section in the locked state.

The mechanically and electrically coded device 1 consists of a fixed part 2 that has an elongated recess in which the movable part 3 is preferably mounted so that it can rotate around the center point M. A recess 5 of limited depth is made in the rotatably mounted part 3 from its outer surface. The depth T of this recess ends at the stop surface 9. This receptacle 5 can, for example, be a circular hole that continues in its extension beyond the stop surface 9, reduced in diameter, e.g. until it penetrates the opposite surface. This hole, which has a reduced diameter, is the receptacle 7 for a spring 6. The spring 6 rests on the one hand on the abutment 8 introduced into the receptacle 7 and acts on the stop surface 10 of a locking means 4 introduced into the recess 5. In the case of a receptacle 5 designed as a hole, the locking means 4 will be a cylindrical pin with the length L. The outer diameter of this locking means 4 is slightly smaller than the diameter of the receptacle 5, so that the locking means can be inserted into the receptacle without tilting sideways.

is guided axially movably. It goes without saying that the inner surface of the receptacle 5 as well as the outer diameter of the locking means 4 must have a high surface quality so that only a small amount of friction has to be overcome during the movement of the locking means 4.

The length L of the locking means 4 expediently corresponds to the depth T of the receptacle 5. In the unlocked state, the stop surface 10 of the locking means 4 comes to rest on the stop surface 9 of the receptacle 5.

The side 4.1 of the locking means facing the actuating element 12 expediently has a rounded transition 18 at its transition to the outer surface of the locking means. This then enables an unhindered rotary movement of the movable part 3 about its center point M in the unlocked state.

Correspondingly, the adjusting element 12 has a rounded, convex shape on its surface 12.1 inclined towards the locking element 4.

Due to the design of the surface 4.1, in the unlocked state the locking means 4 can move over the locking means receptacle 16 in the fixed part without hindrance. This means that in the unlocked state the movable part 3 can be easily rotated by more than 360 degrees around the center point M within the fixed part 2 by unlocking.

The unlocking process takes place when an actuator 11 arranged as an electrical converter is energized. This actuator 11 is located in a holder 15 within the fixed part and is secured in its position by an abutment 13. The actuating element 12 transmits the actuator movement to the locking means 4, which, when the actuator 11 is energized, comes to rest with its stop surface TO against the depth-limited stop surface 9 of the holder.

If the movable part 3 is pivoted around the center point M in this unlocked position, the surface 4.1 of the locking means slides on the inner surface of the fixed part, shown as a circle. If the actuator 11 is de-energized, the actuating element 12 returns to the position shown in Fig. 1, so that the holder 16 is again freed up for the locking means. If the movable part 3 is now rotated so far that the holders 5 and the corresponding holder 16 are on the same axis, the locking means 4 is reinserted into the holder 16 by the force of the spring 6 until it rests on the actuating element 12, thus engaging the locking mechanism again.

Fig. 3 shows a further embodiment in which the locking means 4 is received in a groove 19 associated with it in the unlocked state. When the movable part 3 moves around the center point M, the surface 4.1 now slides on the surface 20 of the groove base. In this embodiment, it is expedient not to design the locking means 4 cylindrically, but rather as a disk-shaped body, for example. The associated recess 5 can be made in the movable part 3, for example, by milling. It should be noted here that the width of the groove 19 and of the locking means 4 sliding therein are correspondingly wider than the diameter of the penetration 21. This penetration 21 can be provided as an assembly aid if necessary, but is not required for functional reasons.

Finally, it should be mentioned that the locking means 4, as well as the fixed part 2 and the movable part 3, must be made of suitable material so that the aforementioned parts can withstand an impermissible force without being destroyed.

The proposed solution offers very simple manufacturing processes for the individual parts, as well as the corresponding assembly. The required individual parts are reduced to a minimum. The multiple arrangement of the locking devices, which can be controlled individually, in groups or together, results in an additional distribution of the forces to be absorbed, as well as the possibility of enabling extremely high code security through redundancies.

Claims (14)

Expectations 1. Mechanically and electrically coded device for locking and unlocking a second part (3) movably mounted in a first fixed part (2) with the aid of at least one locking means (4) which is separated from an actuator (11) designed as an electrical converter and which can be adjusted by an actuating element (12) assigned to the actuator to carry out the locking and unlocking, that the locking means (4) engages in a receptacle (16) in the locking state and by this engagement prevents the movement of the part (3) movably mounted in the fixed part (2) within the fixed part (2) and that the locking means (4) is disengaged from the receptacle (16) in the unlocking state and in this state allows a predetermined movement of the movably mounted part (3) within the fixed part (2), provided that the user codes correspond to the above-mentioned defined codes fit, characterized in that at least one locking means (4) is movably mounted in or on the movably mounted part (3) and the locking means (4) can be brought into engagement by the movement of at least one adjusting element (12) in at least one receptacle (16) of the fixed part (2) or disengaged from the receptacle (16) by the opposite direction of movement of the adjusting element (12). 2. Device according to claim 1, characterized in that the locking means (4) in the unlocked state and with a predetermined movement slides with its surface (4.1) inclined towards the actuating element (12) around the same centre (M) and on the same circular surface (17) within the fixed part (2) which accommodates the movable part (3). ' . . 3. Device according to claim 1, characterized in that the locking means (4) slides in a groove (19) running around the fixed part (3). 4. Device according to claim 3, characterized in that the radius of the groove (19) and the radius of the movable part (3) preferably start from the same center point M on the same longitudinal axis. 5. Device according to one of the preceding claims, characterized in that several locking means (4) can be brought into engagement or disengaged. 6. Device according to claim 5, characterized in that several locking means (4) can be brought into engagement or disengagement by a common actuator (11). 7. Device according to claim 5, characterized in that several locking means (4) can be brought into engagement or disengagement by an associated actuator (11). 8. Device according to claim 5, characterized in that at least two groups with at least two locking means (4) each can be brought into engagement or disengagement by at least one actuator (11) per group. 9. Device according to one of the preceding claims, characterized in that the adjusting element (12) is convex on its side (12.1) facing the locking means (4). 10. Device according to one of the preceding claims, characterized in that the locking means (4) is provided on its side (4.1) facing the actuating element (12) with a preferably circumferential bevel or radius (18). 11. Device according to one of the preceding claims, characterized in that the locking means (4) can be brought into locking engagement by the force of a spring (6). 12. Device according to one of claims 1 to 11, characterized in that the locking means (4) can be brought into engagement by gravity. 13. Device according to one of claims 1 to 12, characterized in that the depth (T) of the receptacle (5) in relation to the length (L) of the locking means (4) is dimensioned such that in the unlocked state the predetermined freedom of movement of the movably mounted part (3) in the fixed part (2) is unhindered. 14. Device according to claim 13, characterized in that in the unlocked state the stop surface (10) of the locking means (4) comes to rest on the depth-limited stop surface (9) of the receptacle (5).