EP0805905A1

EP0805905A1 - Door-closing mechanism and actuating means therefor

Info

Publication number: EP0805905A1
Application number: EP96900492A
Authority: EP
Inventors: Rolf Jäger
Original assignee: Dorma Deutschland GmbH
Current assignee: ROLF JAEGER
Priority date: 1995-01-24
Filing date: 1996-01-22
Publication date: 1997-11-12
Anticipated expiration: 2016-01-22
Also published as: ATE192207T1; EP0805905B1; DK0805905T3; WO1996023120A1; ES2145422T3; DE59605053D1

Abstract

The description relates to a closing mechanism for a door (4) with a spindle (7), an actuating means (1) turning the spindle, a locking component in functional connection with the spindle to lock the door (4) and a coupling component fitted in the actuating means which acts on the rotation of the spindle. The coupling component has a pin (25) movable to and fro axially to the spindle which can be engaged with a locking component (33; 41) independent of the actuating means (1) in order either to transmit the rotation of the freely rotatable actuating means (1) to the spindle (7) or to release the rotation of the actuating means (1) rotatively connected to the spindle (7). This closing mechanism is preferably used with an electronic control.

Description

Locking mechanism for a door and actuator for a locking mechanism for a door

The present invention relates to a locking mechanism for a door according to the preamble of patent claim 1 and an actuating member for a locking mechanism of a door according to the preamble of patent claim 10.

Such a locking mechanism is generally known as a security cylinder lock (see, for example, Brockhaus der Naturwissenschaften und Technik, D-Wiesbaden 1972, pages 662 and 663), in which a socket wrench forms the master key with the cylinder core. The cylinder core is secured against unauthorized rotation by several pairs of locking pins of different lengths. These adapt to the incisions of the key in such a way that their dividing surfaces coincide with the lateral surface of the cylinder core. The cylinder is then unlocked and can be turned.

An electronically controlled locking mechanism is known, for example, from the "VingCard 1090" brochure from the "VingCard System" company from 1989. The one described there. Locking mechanism consists of a lock case with a mechanical lock and a door handle as an actuator. The lock case has a slot and an electronic control unit with which a punched key card is optically read out and the lock is released when access is authorized. The electronic control unit of the lock is connected to a central computer which determines the type of use, the duration of use and the like of a programmed or punched key card. The locks above must be installed as a whole, which is why the existing locks must be removed and disposed of.

Another system can be found in the "CONTAS" brochure from March 1990, which can be used in combination with NingCard locks and consists of a central unit with external readers for each lock. The outside readers are designed as an additional box with a slot for a punched key card. This known locking mechanism can also be used only as a whole unit with a certain type of lock, so that the old locks have to be replaced on all room doors. It understands that this involves considerable effort and the existing locks must all be disposed of.

The invention is based on the object of improving a locking mechanism and an actuating member for a locking mechanism of the generic type in such a way that simple and safe operation of a door lock is provided which enables electronic control without having to replace existing door locks. It should be possible to achieve an equal or higher security standard, as with the existing electronic door security devices.

This object is achieved by a locking mechanism with the features of patent claim 1 and by an actuator with the features of patent claim 8.

The invention has the great advantage that any locks can be retrofitted in a few simple steps to provide a modern and practical mechanical to obtain door security with a high degree of security, which is particularly suitable for electronic control. Furthermore, it is now irrelevant whether the lock is left-handed or right-handed, because the actuator of the new locking mechanism is suitable for both types of locks.

Further advantages of the invention follow from the dependent claims and from the description below. There, the invention is explained in more detail using an exemplary embodiment shown in the schematic drawings.

It shows:

1 shows a cross section through a circular cylindrical knob for external mounting on a door,

2a shows a cross section through the rotary knob of Figure 1 along the line A-A,

2b shows a cross section through the rotary knob of Figure 1 along the line B-B,

3 shows a cross section through the end shield of the rotary knob along the line C-C,

4a shows a cross section through the rotary knob of Figure 1 along the line D-D,

4b shows a part of the cross section through the rotary knob as in Figure 1, Fig. 5 shows a cross section through a rotary knob for one-sided actuation, and

6 shows a cross section through two rotary knobs arranged on the opposite sides of a door.

The same reference numerals are used in the drawings for the same elements, and the description is intended for all drawings, unless stated otherwise.

In Figure 1, a rotary knob 1 is shown in cross section with a circular cylindrical, pot-shaped housing 2. The housing 2 of the rotary knob 1 is preferably metallic, but can also be made of a hard plastic. The rotary knob 1 is mechanically connected to a door lock (not shown here) instead of a conventional door handle. A bearing plate 3 is fastened to a door 4, which is only partially indicated, and has a central opening 5 with a pivot bearing 6, through which a shaft 7 passes. The shaft 7 is square and coupled to a door lock, not shown. Within the housing 2, the shaft 7 is designed as a round axis 8, on which the housing 2 is freely rotatable via a support body 9 with an axial bore 10. In the end region of the axis 8, an annular groove 11 is provided, in which a locking ring 12 engages. A stop ring 13 is fastened on the axis 8 on the side of the support body 9 opposite the end face, so that the support body is axially secured between the locking ring 12 and the stop ring 13. The housing 2 consists of a circular cylinder 14 and a circular end cover 15, which is shown by dashed lines Longitudinal bores 16 in the support body 9 passing screws 17 are attached to the circular cylinder 14. The longitudinal bores 16 are widened stepwise on the side facing the end cover 15, into which extensions 18 corresponding pins 19 of the end cover 15 with internal threads 20 provided for the screws 17 fit. In a receptacle opening 23 of the supporting body 9 provided parallel to the axis 8, a sleeve 24 is embedded, into which a pin 25 is screwed. At the inner end of the pin 25, a small cam 26 is formed, to which a spindle 27 of an electric motor 28 is axially opposite at a distance. The cam 26 is provided with an external thread 29, onto which a spiral spring 30 connected to the spindle 27 is screwed. Between the bearing plate 3 and the support body 9, a radially continuous bore 32 is provided on the axis 8, through which a driver bolt 33 extends and is arranged symmetrically to the axis 8. In the arrangement shown, the pin 25 engages with this driving pin 33. The end cover 15 is provided with a central circular opening 34, which has an annular groove 35 on the inside, in which a spherical cap-like contact disk 36 is embedded. It is guided by an insulation ring 37 which fits into the annular groove 35. A circular printed circuit board 38 having electrical conductor tracks is provided with the pins 19 corresponding holes and thus clamped against the inner end face of the end cover 15. Between the contact disk 36 and the circular printed circuit board 38 there is a spring element 39 which at the same time ensures the electrical contact of the contact disk 36 with the printed circuit board 38. Below the supporting body 9 there is a further electrical circuit board 40 with an electronic circuit and underlying conductor tracks which are electrically connected via the conductor tracks of the circular circuit board 38 on the one hand to the spherical cap-like contact disk 36 and on the other hand to the electric motor 28.

In Figure 2a, the support body 9 is shown in a view from the front and in Figure 2b from the back. Furthermore, the bearing plate 3 is shown in plan view in FIG. 3 and the cross sections through the support body 9 along the line A-A or along the line B-B in FIG. 2a are shown in FIGS. 4a and 4b. The further reference numerals in these figures are explained with reference to the embodiments in FIGS.

The function of the rotary knob l described above is now as follows:

In the closed state of the door 4, the rotary knob 1 can be freely rotated on the round axis 8, ie the spindle 27 of the electric motor 28 is in a position retracted against the end face of the rotary knob 1, so that the pin 25 is disengaged from the driver bolt 33 is. The spiral spring 30 functions as a tension spring for transmitting the tensile forces to the pin 25. In this state, the contact disk 36 lies against the connection cover 15 electrically connected to the bearing plate 3 and in this way is constantly electrically connected to ground, ie serves as transient suppression the contact disk 36, as prescribed in the relevant standard IEC 801. Details on this can be found, for example, in the article "EMC does not Problem be "in" Electronics ", Issue 4, 1992, pages 104-109.

The contact disk 36 can be activated by an electronic key (not shown here), available under the name "CABLOCK" (registered trademark) from the company CABCOM Engineering Rolf Jäger in CH-8181 Höri. The contact disk 36 is preferably a "Touch Memory Probe DS9092" from DALLAS SEMICONDUCTOR, Dallas, Texas (USA), and the key contains an electronic circuit called "Touch Memory DS199x" from this company.

If the contact disk 36 is pushed back against the spring element 39 by the electronic key (not shown) so that it no longer makes contact with the connection cover 15 and is therefore activated, the electric motor 28 drives the spindle 27 in the direction against the Door 4 so that the pin 25 can come into engagement with the driving pin 33 via the spiral spring 30 as a compression spring. If the driving pin 33 is exactly in the direction of displacement, so that the pin 25 comes to stand on the driving pin 33, the spiral spring 30 causes the pin 25 to jump past the driving pin 33 with a slight rotation of the rotary knob 1, even if the spindle 27 is already in the end position. In this sense, the spiral spring 30 acts as a force storage element during the reciprocating movement of the pin 25. Since it is irrelevant whether the pin 25 engages on the left or right with the driving pin 33, the rotary knob 1 described above is both suitable for door locks with a left as well as a right turn. Another variant of the rotary knob 1 is now shown in FIG. 5, in which the pin 25 engages with a receptacle 41 in the end shield 3 (see also FIG. 3). The receptacle 41 is designed as an oval, conically tapering opening, which still allows a slight rotation of the engaged pin 25 of approximately 5 ^* . In this case, the shaft 7 is also formed in the area of the rotary knob 1 square, and the support body 9 with the central bore 10 formed in the square is fixedly attached to the shaft 7. For this purpose, two radial continuous threaded bores 42 are provided, into which stud bolts 43 are screwed onto the shaft 7 for fastening. Furthermore, a hook-shaped wire pin 44 is provided which engages in the pin 25 and can be pushed through the end cover 15. In this way, it is easy to check from a distance whether the rotary knob 1 is in the locked state or whether the shaft 7 can be rotated and the door lock is thus released. Instead of the hook-shaped wire pin 44, a sensor or a switch can also be provided on the circuit board 38, which is connected via the conductor tracks of the circuit board 38 to the electronic circuit of the circuit board 40 and to a light-emitting diode in the end cover 15, and which controls the position of the pin 25 checked. The function of this rotary knob 1 is similar to that described above with reference to the embodiment in FIG. 1. The rotary knob 1 designed in this way can advantageously be used on wall cupboards in sports facilities, such as swimming pools and the like.

FIG. 6 shows a further variant with two knobs 1 and 1 'of identical design. In this case, the contact disk 36 is located in the outside rotary knob 1 'and the lock can be moved back and forth. Ren pin 25 is provided in the opposite, arranged on the inside of the door 4 knob 1. For the electrical connection of the contact disk 36 to the electrical printed circuit board 40 and to the electric motor 28 via the printed circuit board 38, the shaft 7 is provided with a small through bore or milling 47, from which two cylindrical long pins 48 protrude on both sides. which are pressed apart by a thin spiral spring 49. If these pins 48 are too long for a given door thickness, they can easily be cut to size on the spot. For this purpose, the printed circuit board 38 of the inner rotary knob 1 has an electrical plug contact or the like at a corresponding point. As can be seen in FIG. 6, the supporting body 9 is not held in place with stud screws but with spring screws 50 having a spring-loaded ball in a locking position defined by spherical recesses 51 in the shaft 7. With a long stud 52, which is screwed into a radial through bore 53 in the end region of the shaft 7, and an oval guide slot 54 in the circular cylinder 14, the rotary knob 1 is connected to the shaft 7 in a rotationally fixed manner. The function of the rotary knob 1 in the illustrated state is exactly the same as in the embodiment according to FIG the door 4 is pulled away, whereby the spring screws 50 snap into the two free spherical recesses 55, and the pin 25 disengages from the receptacle 41.

As can be seen from FIGS. 1, 5 and 6, the same elements can be used for the different designs be by, for example, the same support body 9 can be used with the appropriate shape both with and without pin or spring screws 43 or 48. This results in a much simpler inventory management and, depending on the application, rotary knobs can be produced for a wide variety of requirements. The rotary buttons 1 and 1 'all have in common that they are axially fixed to the shaft 7 or to the round axis 8 and cannot be removed from the outside without extreme force. As a result, the rotary knob 1 or 1 'described in the various variants is extremely secure. It is understood by the person skilled in the art that the housing 2 of the rotary knobs 1 or 1 'described above does not necessarily have to be circular cylindrical, but other suitable shapes in the manner of a hollow body can also be used for this purpose.

Furthermore, the electronic operation of the locking mechanism increases security, since the access coding for the contact disk 36 can be reprogrammed at any time by means of special higher-level programming devices. There is also the option of only granting access authorization for certain periods and / or for certain people (i.e. holders of a specific electronic key). The security of the entire system can be increased further by the fact that the data transmission is carried out in an electronically encrypted form, which can be carried out in a manner known per se by suitable coding and decoding of the data signals.

The rotary knob 1 described in various variants is particularly suitable for use with an automatic door lock, such as the latch bolt. closed 2126 of the company BKS GmbH, D-42502 Velbert. In such an automatic lock, the latch bolt and the automatic bolt can both be operated from the rotary knob 1, so that mechanical keys can be dispensed with. These can either be disposed of or kept in a safe for emergencies. A replacement with a master key or Passe-Partout would also be conceivable for this purpose.

Claims

claims

1. Locking mechanism for a door (4), with a shaft (7), an actuating member (1) rotating the shaft, an interlocking element which is operatively connected to the shaft for locking the door (4) and a coupling element arranged in the actuating member, which acts on the rotation of the shaft, characterized in that the coupling element has a pin (25) which can be moved axially back and forth and which engages with a locking element (33; 41) which is arranged independently of the actuating member (1) can be brought in order to either transmit the rotation of a freely rotatable actuating member (1) to the shaft (7) or to release the rotation of an actuating member (1) non-rotatably connected to the shaft (7).

2. Locking mechanism according to claim 1, characterized in that the pin (25) can be moved to and fro by means of a force storage element (30) and a spindle (27) acting thereon.

3. Locking mechanism according to claim 1 or 2, characterized ge indicates that the actuating member (1) on a coaxial to the shaft (7) arranged axis (8) is freely rotatable and the locking element (33) extends radially and rotatably to the shaft .

4. Locking mechanism according to claim 1 or 2, characterized in that the actuating member (l) rotatably connected to the shaft (7) and the locking element is a stationary on the door (4) provided receptacle (41).

5. Locking mechanism according to one of claims l to 5, characterized in that the actuating member (l) is a hollow body, preferably circular cylindrical as a rotary knob.

6. Locking mechanism according to one of claims 1 to 5, characterized in that the pin (25) can be moved to and fro by an electric motor (28) which can be rotated by means of an electronic control.

7. Locking mechanism according to claim 6, characterized gekenn¬ characterized in that a cam (26) is formed on the pin (25) and a coil spring is clamped as an energy store between the cam (26) and a spindle (27) of the electric motor (28).

8. Locking mechanism according to claim 6 or 7, characterized in that a contact disk (36) is provided on the end face of the actuating member (1), via which the electronic control from an electronic information carrier can be controlled by data exchange.

9. Locking mechanism according to one of claims 6 to 8, characterized in that a second operating element (1 ') which has a contact disk (36) having an operating element (1) on the other side of the door (4) in the shaft axis opposite.

10. Actuating member (1) for a locking mechanism of a door (4), with a coupling element acting on the rotation of the actuating member (1), characterized in that the coupling element has an axial Pin (25) which can be moved back and forth to the axis of rotation and can be brought into engagement with a locking element (33) which is arranged independently of the actuating element (1).

11. Actuator according to claim 10, characterized in that the pin (25) by means of a force storage element (30) and a spindle acting thereon

(27) can be moved back and forth.

12. Actuator according to claim 10 or 11, characterized in that it is a hollow body, preferably circular cylindrical as a knob (1).

13. Actuating element according to one of claims 10 to 12, characterized in that the coupling element can be moved to and fro by an electric motor (28) which can be rotated by means of an electronic control.

14. Actuator according to claim 13, characterized gekenn¬ characterized in that a cam (26) is formed on the pin (25) and a coil spring as an energy store between the cam (26) and a spindle (27) of the electric motor

(28) is clamped.

15. Actuating element according to claim 13 or 14, characterized in that a contact disk (36) is provided on the end face of the actuating element (1), via which the electronic control from an electronic information carrier can be controlled by data exchange.