DE10163355C1 - Key-operated lock cylinder has electromagnetically-operated blocking device preventing rotation of cylinder core - Google Patents

Abstract

The lock cylinder has a cylinder housing (2) receiving a rotatable cylinder core (3,3') with a key insertion slot, an electromagnetically-operated blocking device preventing its rotation controlled by an electronic coding, with energy and data exchange between a control electronic of the key and a cylinder electronic within the cylinder housing. The electromagnet (15) and the armature (16) is enclosed by a housing (13), a slider (23) cooperating with the armature and coupled via a transmission element (27) to a control element (26) within the cylinder core.

Description

The invention relates to a lock cylinder, in particular for a mortise lock, best hend from a cylinder housing with a locking part recess and at least one rotatably mounted cylinder core, a key channel provided in the cylinder core, in which a key can be inserted, the profiling of at least one intended pin guard locking controls that from a core pin guided in a bore in the cylinder core and a spring-loaded locking pin provided in the cylinder housing is formed and one that can be actuated by an electromagnet with an armature, the rotatability of the Locking device influencing locking device by electronic coding on the basis of the energy and data exchange between the control electronics the key and the cylinder electronics in the cylinder housing can be actuated.

A locking cylinder is known from EP 0 882 858 A2, in which the cylinder is inserted in the direction of insertion the key last of the pin tumblers with a locking device in the form of a additional locking pin is provided. For this purpose, the core pin has a blind hole that with a through hole of the housing pin is aligned. In this coaxial to the housing the additional locking pin is guided and has one diameter enlarged foot, the diameter of the foot the diameter corresponds to the housing pin. The diameter of the locking pin is less than that Diameter of the pin hole, so that the foot by means of a surrounding the locking pin Spring can be cushioned against the housing pin. This will close the pen tion pressed in the direction of the cylinder core. The base of the locking pin rests on the one with egg equipped with an armature. In this case, the displaceable in the axial direction re anchor a large-diameter and a small-diameter area, where these two areas from each other by a frustoconical bevel are separate.

The electromagnet is on the face below the pin tumblers and parallel to the longitudinal one Axis of the locking cylinder arranged in its cylinder housing. For the Energy and data exchange required to operate the additional locking pin a connecting cable connects an antenna located in the cylinder housing and the Electromagnets with a transmitter, control electronics and an energy ver supply. The transmitter, the control electronics and the energy supply in shape Batteries are provided in a separate housing, which is below or above can be arranged half of a mortise lock behind the cuff of the door. The mortise lock  is by means of the lock bit provided on the lock cylinder Locking part can be actuated. Ultimately, the key is equipped with a transponder. Receives the control electronics from a magnet on the first pin tumbler switch the signal that a key is to be inserted, the control will initiate erelektronik the transmitter via the antenna to emit an electromagnetic signal. This signal is taken up by the transponder of the key as energy, which the transponder is required to send an electromagnetically coded signal to the antenna to send back. The control electronics then evaluate the signal picked up by the antenna. Is this signal the rich the document that documents the access authorization, the electromagnet is activated tiviert and the anchor retracted, whereby the foot of the locking pin on the through knife-low area of the anchor comes to rest. The locking pin has now reached this point shifted downwards, that its front edge below and the contact surfaces between Core and housing pin on the joint between the cylinder housing and cylinder core lie. In this position, the key can be found in the cylinder housing with the cylinder core turn it, which creates the operative connection to the locking part via a coupling and its lock bit subsequently the mortise lock for realizing the lock can operate.

This solution has many disadvantages. So is an elaborate and prone to failure Wiring of the assemblies of the electromechanical locking device and additional cher space in the door for the separate housing with transmitter, control electronics and the energy supply (batteries) required. The additional electromechanical Locking device is indeed in one of the mechanical pencils already present integrated, but this requires that this mechanical pin tumbler at Be Damage to the components (electromagnet, Anchor, foot of the locking pin) of the additional locking device no longer their mechani can maintain the blocking function. There are also high security requirements due to the small number of predictable and effective mechanical pin tumblers only partially achievable. This shortcoming could be caused by an axial extension of the Lock cylinders are encountered, but are regularly due to the installation conditions for the integration of the lock cylinder in the mortise lock, in particular also under safety-relevant aspects (avoidance of a protrusion of the lock cylinder opposite the door fitting), not given.  

As a result of the frontal arrangement of the electromagnet with subsequent components in the cylinder This assembly can easily be damaged and manipulated by external attacks be what to cancel the effectiveness of the additional electromechanical Locking device leads. A breakdown in energy supply inevitably causes a malfunction of the entire locking device and therefore causes problems me, because that doesn't mean the compartment for the necessary replacement of the batteries in the door accessible and thus an emergency opening is inevitable. Another significant disadvantage is that the electromechanical locking device only directly on the assigned Zy linderkern acts, which makes it in the case of locking cylinders designed as a double cylinder a separate electromechanical lock is required for each of the cylinder cores direction. This considerably increases the amount of components and the costs climb.

A generic solution that some of the above. Disadvantages are eliminated from EP 0 401 647 B1 known. The energy source with the control electronics is in the key and the locking device that performs the locking with the cylinder electronics in the Lock cylinder arranged. The locking device is as an electromagnetic be Actuable, mechanical flip-flop with a magnetic armature designed as a trap formed when the electromagnet takes effect against the force of a spring, releasable locking element along the longitudinal axis of the lock cylinder. to ordered the unlocking device is essentially on the side of the locking part, the is facing away from the mechanical pin tumblers. This is to block the spin Availability of the locking part, the locking element in the longitudinal grooves of the cylinder housing and Locking part held positively. Is after inserting the key and to apt electronic coding excites the electromagnet and thereby the axial Movement of the locking element obstructing latch tightened, it can Locking element, acted upon by the spring compressed by the key and de Ren subsequently effective spring force, be from the area of the locking part because of. This is the rotational blocking of the locking part in relation to the cylinder housing canceled. Subsequently, with the lock bit, with the coupling still given between the cylinder core and locking part as well as provided that the key also the mechanical pin tumblers of the lock cylinder designed as a half cylinder linders could classify correctly, by rotating together with the cylinder core the mortise lock is closed.

This solution has the disadvantage that it unites through its axial mode of operation takes up considerable space in the cylinder core and cylinder housing, so that a  Possibility of arranging a second cylinder core with mechanical pin lock not only does not exist, but an action of the locking device on the cylinder cores located on both sides of a double locking cylinder due to the si securing axial movement of the locking device is impossible.

In addition, from DE 195 24 567 C1 a lock cylinder with a displaceable Coupling and an additional electromagnetic lock known in which the anchor of the Electromagnets with a sleeve partially surrounding the locking ring ring Blocking or release interacts. The electromagnet is the lock on the side cash recess arranged.

Ultimately, a solution is disclosed in DE 198 56 292 A1, the locking cylinder of which is equipped with an additional electronic coding, in which the lock side Ge electromagnetic locking and the associated cylinder electronics suggestive are arranged below the locking part recess, not shown. Farther the structural design of the assembly is not dealt with.

The object of the invention is to propose a lock cylinder in which the electromechanical locking device for releasing and producing the non-rotating Connection between the locking part and the cylinder core itself does not require space within the area reserved for the pin tumblers in the cylinder core and / or the Zylin dergehäuses claimed and with only one electromagnet with armature and locking device Both a double-sided lockable double cylinder and a one-sided lockable rer half cylinder can be operated.

The task is in a generic lock cylinder with the in the license plate of claim 1 specified features.

The advantages of the invention are that by the exclusive arrangement of the Components - electromagnet, armature and slide - in the lock part recess of the lock cylinder housing or the components - transmission part and control element - outside the area reserved for the mechanical pin tumblers in the cylinder core and Zy lindergehäuse, the possibility is given to both a trained as a half cylinder Deten lock cylinder and a double cylinder to provide, the latter No restrictions and therefore safety disadvantages with regard to use  of mechanical pin tumblers on both sides of the locking part recess and without any restrictions on the number per page need to be. In addition, both sides of the Dop fur cylinder with only one electromagnet and associated armature with locking device apply.

Advantageous developments of the invention are in claims 2 to 17 cha character-.

The embodiments of the invention ensure according to claims 2 and 3, that a short voltage pulse is enough to throw the armature off the electromagnet  and the anchor in the engaged position with the closing part to hal th.

The development of the invention according to claim 4 makes it possible to no electrical tightening of the armature and a stable disengaged position of the Anchor can be secured against the striker.

Through the developments of the invention according to claims 5 and 6 the prerequisites for a purely mechanical and thus no electrical energy return set the anchor for the release of the striker created.

The claim 7 documents a feature that an optimal arrangement of the Ge housing in relation to the cylinder cores.

The embodiment of the invention according to claim 8 ensures that Rotatable housing accommodates the electromagnet, armature, spring and slide components can.

Furthermore, the embodiment according to claim 9 enables a non-rotatable Connection between the locking part and the housing can easily be established.

The feature according to claim 10 causes the operative connection between the respective cylinder core and the housing can be produced in a simple manner.

The training courses according to patent claims 11 and 12 ensure optimal cooperation the slider and the anchor act with regard to the manufacture or release of the non-rotatable connection with the locking part and the resetting of the anchor.

In addition, the features offered in claims 13 to 16 aim that to release the locking part an easy way to support the only mechanical reset of the armature is provided.

Ultimately, the training of the invention according to claim 17 key-controlled relocation of the control element to actuate the components running pin, stop pin and slide as well as anchor.  

The invention is based on an embodiment and associated drawing nations are explained in more detail.

Show it:

Fig. 1 shows a longitudinal section of the lock cylinder according to the invention, wherein the key is removed

Fig. 2 is a broken view of the lock cylinder according to the invention according to arrow A of Fig. 1, in which the assembly formed from control elements 26 , transmission parts 27 and slide 23 is still in its initial position (state of equilibrium) and in which the armature is in surface contact with the electromagnet stands

Fig. 3 shows a longitudinal section of the lock cylinder according to the invention, wherein the key is inserted

Fig. 4 is a sectional view of the lock cylinder according to the invention with the key inserted, but the key and thus also the left cylinder core is shown rotated by 90 ° and the positive locking of the locking part has been effected by the coupling element located on the armature

Fig. 5 is an enlarged view of the enlarged area around the closing member recess according to FIG. 4

In FIG. 1, an inventive lock cylinder 1 is illustrated in the form of a double cylinder. This essentially consists of a cylinder housing 2 and two cylinder cores 3 , 3 'rotatably mounted therein with a key channel 4 , 4 ' into which a key 5 designed as a flat key (see also FIGS. 3 to 5) can be inserted. In the cylinder cores 3 , 3 'and in the cylinder housing 2 , mutually aligned bores are arranged which radially lead several core pins 6 located in different cross-sectional planes and along the longitudinal median plane of the cylinder cores 3 , 3 ', which in turn lead from in the cylinder housing 2 held and spring-loaded housing pins 7 , so that these housing pins 7 protrude into the bores of the cylinder cores 3 , 3 'when the key 5 is not inserted and thus lock them against rotation relative to the cylinder housing 2 (see FIG. 1 and the right-hand side in FIG. 3 ). The introduced into the left cylinder core 3 key 5 is provided in FIG. 3 on its key breast with variable locking notches 8, the pins turn upon insertion of the key 5 in the key channel 4 of the cylinder core 3 guided in bores of the cylinder core 3 along the longitudinal center plane of the core 6 interact. This is known to occur in such a way that the cylinder housing ends of the core pins 6 with the cylinder core ends of the housings pins 7 form a common parting line which then runs along the core torsional joint between the cylinder core 3 and the cylinder housing 2 . In the area between the cylinder cores 3 , 3 ', the cylinder housing 2 is equipped with a locking part recess 9 in which a locking part 10 suitable for actuating a mortise lock, not shown, can be connected to the respective cylinder core 3 , 3 ' and is rotatably held. The locking part 10 is formed by a bush 11 to which a locking bit 12 is connected radially. In the locking part recess 9 , a hollow cylindrical housing 13 with closed end faces is arranged coaxially with the cylinder core 3 , 3 ', on which the bushing 11 of the locking part 10 is rotatably mounted. In particular, according to FIGS. 3 to 5, a cylinder electronics 14, a solenoid 15 having an armature 16 is located in the housing 13, whereby the electromagnet 15, a spring 17 and on the Elek tromagnet 15 facing side of the armature 16 a permanent magnet 18 are provided. In addition, the armature 16 on its side facing the housing 13 is equipped with a coupling element 19 which extends through a recess 20 in the outer surface of the housing 13 and can engage in an opening 21 located in the socket 11 of the closing part 10 in a locking manner. On the side facing the electromagnet 15 , the armature 16 has an opening 22 through which a slide 23 mounted in the housing 13 and positively secured against rotation extends. This slide 23 includes two roof-shaped depressions 24 , 24 ', which interact with an equivalent roof-shaped elevation 25 at the opening 22 of the armature 16 . In each of the two cylinder cores 3 , 3 'is in a recess, not shown, a control element 26 in the form of a ball, which can be acted upon by the broad side of the inserted flat key 5 , which also contains the control electronics. Between the control element 26 and the armature 16 , a transmission part 27 is also arranged, which consists of a run-up pin 27 ', spring element 30 and stop pin 31 . Here, the thrust pin 27 'on the control element side an inclined slope 28 and at its other end a blind hole 29 into which the spring element 30 and the smaller diameter shoulder of the stop pin 31 can be used.

This stop pin 31 realizes on its side facing the housing 13 a surface contact with the slide 23 , for which purpose it penetrates a through opening 32 located in the end face of the housing 13 . Thus, the components spring 17 coupling element 19 , recess 20 , opening 21 , opening 22 , slide 23 , Steuerere elements 26 in the form of a ball and the transmission parts 27 , consisting of thrust pin 27 ', spring element 30 and stop pin 31 , the increase 25 of the armature 16 in connec tion with the electromagnet 15 represents the actual locking device, by which the rotational connection between the cylinder core 3 and the locking part 10 for actuating the locking part 10 is made or removed.

The control electronics are integrated in the cover of the key 5 , an antenna 33 being guided from the control electronics to the tip of the key 5 .

The locking cylinder works as follows:
It is assumed that there is a locking cylinder 1 according to FIG. 2, in which the construction group formed from slider 23 and from control elements 26 and transmission parts 27 is in its starting position (equilibrium state). The spring 17 is compressed and the armature 16 is initially in surface contact with the electromagnet 15 through its permanent magnet 18 , as a result of which the coupling element 19 of the armature 16 does not engage in the opening 21 of the bushing 11 of the closing part 10 and thus the rotationally fixed connection between the cylinder core 3 and locking part 10 for actuation of a lock, not shown (z. Mortise lock) is prevented. After the following is a mechanically and electronically authorized key 5 z. B. introduced into the key channel 4 of the cylinder core 3 (see Fig. 3). Due to its closing notches 8, the mechanical pin tumblers (core pins 6 and housing pins 7) are arranged on the associated side of the lock cylinder 1 so that the cylindrical housing-side ends of the core pins 6 with the cylindrical core-side ends of the housing pins 7 form a common parting line, the rotary joint along the core between Cylinder core 3 and cylinder housing 2 runs.

At the same time, actuated by the broad side of the key 5, the control element 26 ( FIG. 2), which is designed as a ball, is displaced radially, which in turn causes the axial displacement in the direction of the slant 28 of the thrust pin 27 'with the resilient stop pin 31 (= transmission part 27 ) Locking part recess 9 takes place ( FIGS. 4 and 5). In this case, starting from FIG. 2, there is also an inevitable axial movement of the slide 23 to a point at which its roof-shaped recess 24 has assumed an opposite position with respect to the roof-shaped elevation 25 at the opening 22 of the armature 16 . On the part of the cylinder core 3 ', the axial displacement of the slide 23 causes the stop pin 31 on this side against the force of the spring element 30 to be moved out of the housing 13 until it clears the through opening 32 in the end face of the housing 13 and thus the operative connection between the housing 13 and cylinder core 3 '(see FIG. 5 in connection with FIG. 2).

In the subsequent and via the antenna 33 at the top of the key 5, energy and data exchange made between the control electronics of the key 5 and the cylinder electronics 14 , the electronic coding of the key 5 is read out and, if there is a match, the electromagnet 15 is excited in such a way that the armature 16 is pushed off by the electromagnet 15 with the aid of the prestressed spring 17 . As a result, the roof-shaped elevation 25 at the opening 22 of the armature 16 can move in the direction of the roof-shaped recess 24 of the slider 23 and engage in it. If the coupling element 19 of the armature 16 , which is fixed in the recess 20 of the lateral surface of the hollow cylindrical housing 13, is aligned with the opening 21 in the socket 11 of the closing part 10 ( FIGS. 4 and 5), then the coupling element 19 engages in this opening 21 and thereby locks the locking part 10 with respect to the housing 13 , so that the mortise lock (not shown) can be actuated by turning the key 5 by means of the locking bit 12 of the locking part 10 . The further he necessary active connection between the cylinder core 3 and housing 13 is made by the impact pin 31 , because this engages through the through opening 32 of the housing 13 and thus when driving the key 5 together with the cylinder core 3 also the entrainment of the locking part recess 9th mounted hollow cylindrical Ge housing 13 allows independent of the cylinder core 3 '.

If the key 5 is removed and thus removed from the key channel 4 of the cylinder core 3 , the spring element 30 located in the blind bore 29 of the run-up pin 27 'and now relaxing presses the control element 26 back into the key channel 4 via the run-up slope 28 , whereby the equilibrium state shown in FIG. 2 between the spring elements 30 on both sides of the closing partial recess 9 is set again. In this process, the slider 23 is simultaneously moved in the direction of the cylinder core 3 , so that the right flank of the roof-shaped recess of the slider 23 and the right flank of the roof-shaped elevation 25 at the opening 22 of the armature 16 converge, resulting in a transverse movement of the Armature 16 against the force of the spring 17 arranged in the electromagnet 15 results. If the ker 16 has sufficiently approached the electromagnet 15 , the permanent magnet 18 located on the armature 16 becomes effective, as a result of which the armature 16 now comes to rest on the electromagnet 15 in its initial position ( FIG. 2) without this Electrical energy would be required. In this position of the armature 16 , the coupling part 19 has left the opening 21 of the socket 11 of the closing part 10 again and moves back into the recess 20 in the lateral surface of the hollow cylindrical housing 13 . Thus, the rotationally fixed connection between the closing part 10 and the housing 13 , which was formerly produced via the electronic coding, and via the stop pin 31 to the cylinder core 3 and ultimately to the key 5 is canceled again. An actuation of the mortise lock associated with the locking cylinder 1 according to the invention is now even impossible if a key 5 is used which, although it can prove that the mechanical coding is correct, does not include the electronic coding authorizing access. An analogous functional sequence takes place when a key 5 is inserted into the key channel 4 'of the second cylinder core 3 ' of the locking cylinder 1 designed as a double cylinder. In this position of the key 5 , the roof-shaped elevation 25 has assumed an opposite position at the opening 22 of the armature 16 in relation to the roof-shaped recess 24 'located on the slider 23 , the repulsion triggered by a current pulse then being triggered when a lock is present the armature 16 of the electroma 15 causes an interlocking of the elevation 25 and the depression 24 '. This ultimately makes it possible again for the coupling element 19 to engage in the opening 21 for fixing the locking part 10 .

LIST OF REFERENCE NUMBERS

1

lock cylinder

2

cylinder housing

3

cylinder core

3

'' Cylinder core

4

keyway

4

'' Key channel

5

key

6

core pin

7

housing pin

8th

locking notches

9

Closing part recess

10

closing part

11

Rifle

12

Cam

13

casing

14

cylinder electronics

15

electromagnet

16

anchor

17

feather

18

permanent magnet

19

coupling member

20

recess

21

opening

22

opening

23

pusher

24

deepening

24

' Deepening

25

increase

26

control

27

transmission part

27

'Ramp pin

28

approach ramp

29

blind hole

30

spring element

31

stop pin

32

Through opening

33

antenna

Claims (17)

1. Lock cylinder, in particular for a mortise lock, consisting of a cylinder housing with a locking part recess and at least one rotatably mounted cylinder core, a key channel provided in the cylinder core, into which a key can be inserted, the profiling of which controls at least one intended pin tumbler, which from a A bore of the cylinder core guided core pin and a spring-loaded locking pin provided in the cylinder housing is formed, as well as a locking device which can be actuated by an electromagnet with an armature and which influences the rotatability of the locking part. The locking device uses electronic coding on the basis of the energy and data exchange between the Control electronics of the key and the cylinder electronics in the cylinder housing can be actuated, characterized in that the electromagnet ( 15 ) with the armature ( 16 ) is enclosed by a housing ( 13 ) and is designed exclusively in the lock The recess ( 9 ) of the cylinder housing ( 2 ) is arranged, a slide ( 23 ) mounted in the housing ( 13 ) cooperating with the armature ( 16 ) and with a transmission part ( 27 ) provided in the cylinder core ( 3 , 3 ') and a key-side Control element ( 26 ) can be brought into operative connection and the armature ( 16 ) on its side facing the housing ( 13 ) contains a coupling element ( 19 ) which is in a recess in the outer surface of the housing ( 13 ) ( 20 ) and is designed such that it can be engaged in an opening ( 21 ) in the socket ( 11 ) of the closing part ( 10 ). 2. Lock cylinder according to claim 1, characterized in that between the armature ( 16 ) and the electromagnet ( 15 ) of a spring ( 17 ) is provided. 3. Lock cylinder according to claim 2, characterized in that the spring ( 17 ) is arranged on the armature side in the core of the electromagnet ( 15 ). 4. Lock cylinder according to claim 1, characterized in that the armature ( 16 ) on its side facing the electromagnet ( 15 ) is equipped with a permanent magnet ( 18 ). 5. Lock cylinder according to claim 1, characterized in that the armature ( 16 ) on its side facing away from the electromagnet ( 15 ) has an opening ( 22 ), on which an increase ( 25 ) is located on the side facing the slide ( 23 ) , 6. Lock cylinder according to claim 5, characterized in that the elevation ( 25 ) is roof-shaped. 7. Lock cylinder according to claim 1, characterized in that the housing ( 13 ) is arranged coaxially to the cylinder core ( 3 , 3 '). 8. Lock cylinder according to claim 1, characterized in that the housing ( 13 ) is hollow cylindrical. 9. Lock cylinder according to claim 1, characterized in that a recess ( 20 ) is provided on the casing surface side of the housing ( 13 ). 10. Lock cylinder according to claim 1, characterized in that the housing ( 13 ) is equipped on its end faces with a through opening ( 32 ). 11. Lock cylinder according to claim 1, characterized in that the slide ( 23 ) has on its elevation ( 25 ) of the armature ( 16 ) side facing two roof-shaped depressions ( 24 , 24 '). 12. Lock cylinder according to claim 1, characterized in that the slide ( 23 ) is held against rotation on the housing ( 13 ). 13. Lock cylinder according to claim 1, characterized in that the transmission part ( 27 ) of a run-up pin ( 27 ') and a spring element ( 30 ) loaded stop pin ( 31 ) is formed. 14. Lock cylinder according to claim 13, characterized in that the run-up pin ( 27 ') on its side facing the control element ( 26 ) is designed with a run-up slope ( 28 ). 15. Lock cylinder according to claim 13, characterized in that the run-up pin ( 27 ') on the stop pin side has a blind bore ( 29 ) in which the spring element ( 30 ) is received. 16. Lock cylinder according to claim 13, characterized in that the stop pin ( 31 ) has a smaller diameter heel with which this is arranged in the blind bore ( 29 ) of the thrust pin ( 27 '). 17. Lock cylinder according to claim 1, characterized in that the control element ( 26 ) is designed as a ball.