DE19934883C1 - Key-operated door lock has lock cylinder rotated by inserted key and blocked against manipulation by clamp element contained in bore in lock cylinder housing - Google Patents

Abstract

The lock has a housing (12) with a reception space (16) for a rotatable lock cylinder (14) having an insertion channel (18) for a key (20) and at least one bore (24) for a locking pin (30), with a corresponding bore (28) in the housing containing a spring-loaded locking pin (32) and a further bore (36) in the housing containing a clamp element (38) in the form of a wire, used for blocking the rotation of the lock cylinder.

Description

The invention relates to a locking device such as. B. for door locks is used.

Such locking devices have a housing with a substantially Chen cylindrical receiving space in which a cylinder core against axial Movements secured rotatably. Axially through the cylinder core extends an insertion channel for a key. From the entry channel lead several first mounting holes radially to the outside of the Cylinder core. Closures are located in these first mounting holes pencils. There are second receiving bores in the housing of the locking device stanchions formed in a first rotational position of the cylinder core align the first mounting holes. The second mounting holes are open to the inside of the receiving space and have locking pins, the (by means of helical compression springs) in the direction of the receiving space of the Are biased.

Not inserted into the cylinder core when it is in the first rotational position The key extends the locking pins into the first slot holes and prevent twisting of the cylinder core. The locks are made by means of projections or depressions on the key pins extending radially outward into the key insertion channel moves when the key is in the insertion channel. The length the locking pins is selected such that all locking pins are turned on key with the outside of the cylinder core and thus aligned all locking pins from the first mounting holes in the cylinder core are moved out, so that the cylinder core in the mounting holes can be twisted.  

Such locking devices have proven themselves in practice and who used in a variety of configurations. You are relatively mani tamperproof, as it is particularly useful when running with several rows of locking and locking pins is quite difficult without the associated one Key all pins at the same time to align the cylinder core to be able to twist.

As an absolute protection against manipulation of those in question Locking devices do not exist, the industry's endeavors to that the function of the locking devices is automatically impaired, if it succeeds, the cylinder core without the associated key to twist (manipulation).

FR 2 312 630 A1 is a locking device according to the preamble of claim 1 known. This locking device has in its housing a third mounting hole that is offset to the second mounting bores of the housing is arranged and in a certain rotation tion of the cylinder core opposite one of its first receiving bores is arranged horizontally. In the third mounting hole there is a spring-loaded locking element that moves when the cylinder core rotates without that there is a key in the insertion channel of the cylinder core into which opposite first receiving bore of the cylinder core into it presses against each other when the third and first locating holes overlap. Then both the locking pin and part of the the compression spring surrounding the locking pin in the first up bore into it, causing the cylinder core to lock is coming. By positioning the cylinder core in such a way that the third and the first mounting hole (exactly) opposite each other, it is possible Lich, through a special tool that is inserted into the key insertion channel is, the locking pin in contact with the locking pin for Move the locking pin into the third mounting hole  manipulate. So you could lock the cylinder core again cancel.

From US 3 802 234 a further locking device is known, which, like that Closing device described above, a third mounting hole in Has housing that is offset to the second mounting holes arranges and in a certain rotational position of the cylinder core one of whose receiving holes are opposite. In the third receiving hole tion is located next to a spring-loaded activation pin Longitudinal splitting pin divided by the spring-loaded actuator crossing pin in the direction of the peripheral surface of the cylinder core is tense. The section of the third receptacle facing the cylinder core The bore has a larger diameter than the rest of the opening receiving bore. As long as the expansion pin from the outside on the peripheral surface of the cylinder core, it also extends partially in the Diameter narrower section of the third mounting hole. Is at this known locking device of the cylinder core rotated without a key is inserted, the spreader pin is pre-springed clamped activation pin in the opposite of the third mounting hole lying in the first receiving bore of the cylinder core when the cylinder core has reached the corresponding rotational position. The consequence there of is that the spreader pin is now completely in diameter Outer section of the third mounting hole is located and from the Akti crossing pin is spread. So that the cylinder core are facing away th ends of the two halves of the spreader pin on the transition shoulder between the larger in diameter and the smaller in diameter section of the third location hole. The activation pen dips partially between the two halves of the expansion pin, so it moves radially outwards. This release movement can then no longer can be reversed if now inserted into the insertion channel via guided tool against the relevant locking pin of the cylinder core ge is pressed. This is the blocking of this known locking device cannot be canceled. The locking device according to US 3 802 234 requires  however, a large number of individual parts for manipulation protection or for the uselessness in the event of manipulation, which on the one hand affects the service costs and adversely affects the assembly costs.

The invention is therefore based on the object of having a locking device To create locking and locking pins with simple construction Long-term functionality in the event of manipulation unusable becomes.

To solve this problem, the invention uses a locking device proposed according to claim 1.

The locking device according to the invention has minde in its housing at least a third location hole that is like the second location hole is open to the recording room. This third location hole is aligned in a (second) rotational position of the cylinder core with one of the first mounting holes. Located in the third mounting hole a flexible wire, which is due to its own weight or by spring force is applied to the outside of the cylinder core. Will the cylinder core but brought into the second rotary position, then that of the first open bore holes that match the third location bore of the housing aligned, only closed by the locking pin when there is Cylinder core the key is located. Otherwise, the wire in the second rotational position in the alignment with the third mounting holes the first mounting holes (associated first mounting hole) ge long. The wire thus extends like a locking pin from the third mounting hole from into the associated first mounting hole tion.

In contrast to a locking pin, the wire does not have the task lock the cylinder core in the housing. The wire of the invention according locking device is rather for jamming the Zylin derkerns worry if this forwards or out of the second rotary position  is turned back. Then the wire becomes Verbie Formation / deformation of the same taken from the cylinder core and ge reaches into the (ring) space between the inside of the recording space and the outside of the cylinder core. By appropriate thicknesses dimensioning of the wire, which is a slight excess compared to the eccentric storage of the cylinder core in the receiving space largest possible radial distance between the cylinder core and housing. Like this as soon as the cylinder core is jammed, it can be removed no longer turn back and forth, with the security against manipulation or at least the possibility of detecting a manipulation attempt given is.

The flexible wire is preferably a spring wire which is expediently designed as a helical compression spring or leaf spring. Alternatively or additionally, the wire is made from one material, so that on the one hand when the cylinder core rotates further or back does not come to shear, but on the other hand is for the closure device manipulating no noticeable resistance against one Forwards or backwards rotation of the cylinder core results.

In an advantageous embodiment of the invention it is provided that proceeding from that of the at least one third receiving bore Neten second receiving hole of the cylinder core on the outside extends a groove that extends in the circumferential direction. This groove extends starting from the second mounting hole in the direction of rotation of the Zylin derkerns to open the locking device. On the opposite Such a groove can also be provided on the side of the second receiving bore be seen. Each groove expediently has one of its second End facing away from the receiving bore a decreasing depth. Before each groove is preferably facing the second receiving bore widened end, tapering towards its other end.  

The groove has the function of an intake or capture device for the Wire. If the wire is in the at least one third receiving hole tion of the housing associated with the second mounting hole of the cylin derkerns is immersed, so it comes to the opening of the closing device rotation of the cylinder core to move the Inlet or catch groove on the third mounting hole and therefore because the radially recessed relative to the outside of the cylinder core Groove base for a "gentle" bending of the wire and one "Pulling" it into the groove.

The wire is bent without noticeable resistance to one Continued rotation of the cylinder core, so that the locking device mani pulsating person did not notice this process. However, as soon as - and this applies regardless of the design of the groove - the wire is bent and extends in the groove, the locking device is ultimately no longer to use. Because a further rotation of the cylinder core leads because to the bottom of the groove rising to the outside of the cylinder core jamming of the wire between the cylinder core and the housing and thus a blockage of the cylinder core while one is closed by Zu return movement of the cylinder core due to the bending of the wire Do not use tools inserted into the key insertion channel more out of the second mounting hole and into the third mounting can move the bore into it.

By forming at least two wires having a third receptacle bores slightly in the circumferential extent of the receiving space staggered and two different from the second Location holes are assigned to the cylinder core, it is achieved that when the person manipulating the locking device detaches the thaw Chen the first wire into the associated of the second receiving holes should notice the second wire while trying to get the first wire through To move the tool completely back into the third mounting hole, due to the associated slight back and forth movement  of the cylinder core in the second receptacle assigned to the second wire bore reached.

So that when using the locking device according to the invention Hooking the wire with the due to the insertion of the key in the insertion channel from the assigned to the second receiving bore Do not fear cylinder core with the outside of the locking pin aligned tet must be, it is appropriate if the wire to the recording space of the housing facing widened head end preferably in Form of a plate, a plate or the like. On which the locking pin per can slide past easily.

The invention is explained below with reference to the drawing. in the single show:

Fig. 1 is a view of a pin locking device in longitudinal section in the locked state without the key,

Fig. 2, the closing device shown in Fig. 1, however, with an inserted key

Fig. 3 a section through the locking device taken along the line III-III of FIG. 2 with an inserted key,

Fig. 4 shows a section through the locking device along line IV-IV of FIG. 2 with an inserted key to illustrate the arrangement of a wire receiving (third) On receiving bore in the housing,

Figure 5 is a plan view of the circumferential or circumferential surface of the cylinder core for clarifying the arrangement of inlet or pull-in grooves on both sides of at least one of the locking pins receiving (second) receiving bore of the cylinder core.

Fig. 6 is an illustration of the interaction of the wire in the housing and opposite this closing pin of the cylinder core, upon rotation of the cylinder core, so the locking pin on the wire that moves past,

, However, is inserted in the cylinder core without a key Fig. 7 to Fig. 4,

Fig. 8 shows the situation in which it has been possible to twist the cylinder core without a key by manipulating the locking pins of the locking device from the locking position shown in FIG. 1 to the rotational position in which the wire is opposite one of the receiving bores of the cylinder core containing the locking pins and because of the free displaceability of the locking pin is immersed in the receiving bore due to spring force and / or due to its gravity,

Figure 9 that phase., In which the wire for further rotation (forward or backward rotation) of the cylinder core is pulled into the gap Zvi's housing and cylinder core,

Fig. 10 shows the state in which the wire is finally wedged / jammed between the cylinder core and the housing, so that a further (forward or backward) rotation of the cylinder core is no longer possible, and

Fig. 11 shows the situation of FIG. 10 along the Li never XI-XI.

Figs. 1 to 3 show different sectional views and states of a pin locking device 10 of conventional design which is difiziert to create the OF INVENTION to the invention Manipulation detection device and the erfindungsge MAESSEN automatic function destruction in the event of a manipulation mo, which is shown in Figs. 4 to 11.

The locking device 10 has a housing 12 and a cylinder core 14 which is rotatably arranged in a receiving space 16 of the housing 12 . The cylinder core 14 is provided with an eccentric axial insertion channel 18 into which the key 20 can be inserted. In the cylinder core 14 there are a plurality of locking pins 30 arranged in rows (in the exemplary embodiment from 5 pins in a row), which are in (first) receiving holes 24 of the cylinder core 14 . This receiving bores 24 he extends radially through the cylinder core 14 between the insertion channel 18 and the outside 26 of the cylinder core 14 .

In the housing 12 there are several second receiving bores 28 , the number and arrangement of the number and arrangement of the first receiving bores 24 and the same arrangement. The second mounting holes 28 extend radially with respect to the mounting space 16 of the housing 12 and are arranged in alignment with the first mounting holes 24 in the rotational position of the cylinder core 14 according to FIGS. 1 to 3. In the first receiving holes 24 there are locking pins 30 of different lengths, while 28 locking pins 32 are accommodated in the second receiving holes, which are biased by means of helical compression springs 34 in the direction of the locking pins 30 . The helical compression springs 34 press the locking pins 32 against the locking pins 30 against the arranged in the insertion channel 18 En the first receiving holes 24 (see Fig. 1). In this situation, the locking pins 32 extend both within the first and the second receiving bores 24 , 28 , so that a rotation of the cylinder core 14 is prevented by the locking pins 32 . With inserted key 20 (see FIGS . 2 and 3), the locking pins 30 are moved radially outwards, namely by the key. The adjustment of the width of the key 20 is so matched to the length of the locking pins 30 that they are aligned with the outside 26 of the cylinder core 14 when the key 20 is inserted. In this situation, the locking pins 32 are pressed completely into the second receiving bores 28 , so that the cylinder core 14 can now be rotated.

Referring to Figs. 4 to 11 will be discussed below on the specificity of the closing device 10 OF INVENTION to the invention. As can be seen in FIG. 4, there is at least one further (third) receiving bore 36 in the housing 12 . This at least one third receiving bore 36 is arranged along one of the circumferential lines described by the first receiving bores 24 when the cylinder core 14 rotates and is accordingly in a rotational position which is different from the rotational position according to FIGS . 1 to 3, in alignment with a the first receiving holes 24 . In the third receiving bore 36 there is a clamping element 38 which is designed in the form of a helical compression spring 40 with a plate element 42 at one of its ends. The third receiving bore 36 is open to the receiving space 16 ; in the receiving bore 36, the compression coil spring 40 is supported on the outer bottom 44 on the third receiving bore 36, while the plate element 42 has the receiving space sixteenth

In addition, at least that first receiving bore 24 , to which the third receiving bore 36 is assigned, has in its outer side 26 two circumferentially extending grooves 46 which extend diametrically opposite one another on both sides of the first receiving bore 24 . As shown in FIGS. 5 and 11, the grooves 46 have a widened end 48 facing the receiving bore 24 and a narrow end 50 facing away from this. Referring to Fig. 6, 8, 9 and 10 it can be seen that the grooves, as secantially introduced into the outer surface 26 of the cylinder core 14 can be flat on their ends 50 and have the greatest depth at ih ren ends 48.

The task of the compression spring 40 located in the third receiving bore 36 is to dip into the associated receiving bore 24 if the cylinder core 14 is rotated without a key 20 having previously been inserted (manipulation of the locking device 10 ). Fig. 4 to 6 show first the situation in which the cylinder core 14 be rotated pursuant humor. For this purpose, the key 20 has previously been inserted into the insertion channel 18 , in order to then rotate the cylinder core 14 . The locking pins 30 are disengaged radially outward by the key 20 , so that the one of the first mounting holes 24 assigned to the third mounting hole 36 is also closed by the locking pin 30 located therein. When the cylinder core 14 continues to rotate, this first receiving bore 24 comes into alignment with the third receiving bore 36 (see FIG. 6). The wire 38 cannot dip into the receiving bore 24 in this situation. The cylinder core 14 can be rotated further without problems. The normal operation of the locking device 10 is therefore not affected by the wire 38 .

The situation is different if, starting from the situation according to FIGS. 1 and 7, an attempt is made to manipulate the locking device 10 . This manipulation is that the locking pins 30 by means of a nipulationswerkzeuges Ma at the same time the cylinders are brought core 14 in flush alignment with the outer side 26 so that the cylinder core 14 can be rotated without a key is inserted 20th If, in this situation, the third receiving bore 36 associated with the most receiving bore 24 moves past the helical compression spring 40 , it can be immersed in the receiving bore 24 , since the locking pin 30 located in this receiving bore 24 is not disengaged due to the lack of the key 20 . The situation according to FIG. 8 thus results . When the cylinder core 14 continues to rotate in the direction of the arrow 52 , the helical compression spring 40 is “drawn” into the groove 46 . While the plate element 42 is in the first receiving bore 24 , the other end of the helical compression spring 40 is held on the base 44 of the third bore 36 . Due to the slowly running out of the outside 26 of the cylinder core 14 groove 46 , the helical compression spring 40 , ie the wire forming it finally gets into the narrow annular space 54 between the cylinder core 14 and the housing 12 . The thickness of the wire forming the helical compression spring 40 is selected such that wedging now occurs more between the cylinder core 14 and the housing 12 . In other words, the helical compression spring 40 or the wire forming it and the annular space 54 form a kind of interference fit. The result of this is that the cylinder core 14 is wedged, so to speak, and consequently can no longer be rotated, namely neither forwards nor backwards. The locking device 10 is thus rendered unusable.

The advantage of the locking device 10 according to the invention can be seen in particular in the fact that the locking device 10 is no longer usable at the moment when the helical compression spring 40 is "drawn" into the groove 46, even if only a small portion. Because even if the person manipulating the locking device 10 in the situation according to FIG. 9 recognizes that the wire 38 is immersed in the receiving bore 24 , the locking device 10 can no longer be used since the helical compression spring 40 can no longer be brought back into the receiving bore 36 leaves. If two third receptacle bores 36 with a wire 38 are arranged in the housing 12 with a small circumferential offset, it is almost impossible for the person manipulating the locking device 10 , when the cylinder core 14 rotates, both wires by manipulation tools or the like during rotation to keep the cylinder core 14 in the third receiving holes 36 . Because at this time to bewerkstel, the cylinder core 14 would slightly move back and forth who to what it can be very hard to appear at mutually rotated third mounting holes 36 to keep both wires in the third Aufnahmebohrun gen 36th

Claims (9)

1. Locking device with

• - a housing ( 12 ) which has a receiving space ( 16 ),
• a cylinder core ( 14 ) rotatably arranged in the receiving space ( 16 ) and having an insertion channel ( 18 ) for a key ( 20 ),
• - At least one first receiving bore ( 24 ) in the cylinder core ( 14 ) for a locking pin ( 30 ), the first receiving bore ( 24 ) to the housing ( 12 ) and the insertion channel ( 18 ) is open and
• - At least one second receiving bore ( 28 ) in the housing ( 12 ) for a locking pin ( 32 ), the second receiving bore ( 28 ) being open towards the receiving space ( 16 ) and in a first rotational position of the cylinder core ( 14 ) with its first receiving bore ( 24 ) is aligned,
• - At least one third receiving bore ( 36 ) which is open to the receiving space ( 16 ) and in a second rotary position different from the first rotational position is aligned with one of the first receiving bores ( 24 ) of the cylinder core ( 14 ), and
• - A in the third receiving bore ( 36 ) arranged clamping element ( 38 ), which is in the second rotational position when the key ( 20 ) is not in the cylinder core ( 14 ) in the third receiving bore ( 36 ) aligned with the first receiving bores ( 24 ) of the Reaches the cylinder core ( 14 ) and extends within the transition area between the two receiving bores ( 36 , 24 ),

characterized by

• - That the clamping element ( 38 ) is a wire which is rotatable when the cylinder core ( 14 ) is deformed into the space ( 54 ) between the cylinder core ( 14 ) and the housing ( 12 ) and for blocking the cylinder core ( 14 ) can be clamped between the latter and the housing ( 12 ).

2. Locking device according to claim 1, characterized in that the wire is a spring wire ( 40 ) which is biased in the direction of the cylinder core ( 14 ). 3. Locking device according to claim 1 or 2, characterized in that the wire has a widened head end ( 42 ) facing the cylinder core ( 14 ), on which the locking pin ( 30 ) in the third receiving bore ( 36 ) associated with the housing ( 12 ) of the first receiving bores ( 24 ) of the cylinder core ( 14 ) with the key ( 20 ) inserted therein and rotation of the cylinder core ( 14 ). 4. Locking device according to one of claims 1 to 3, characterized in that the wire is designed as a helical spring wire ( 40 ) of a helical compression spring. 5. Locking device according to one of claims 1 to 4, characterized in that starting from the third receiving bore ( 36 ) of the housing ( 12 ) facing the first receiving bore ( 24 ) of the cylinder core ( 14 ) a circumferentially in the opening direction of rotation of the cylinder core ( 14 ) extending inlet groove ( 46 ) is arranged, the depth of which decreases towards its end ( 50 ) facing away from the first receiving bore ( 24 ). 6. Locking device according to claim 5, characterized in that starting from the third receiving bore (36) of the housing (12) facing the first receiving bore (24) of the cylinder core (14) extending in the circumferential direction in the closing direction of the cylinder core (14) inlet groove ( 46 ) is arranged, the depth of which decreases towards its end ( 50 ) facing away from the first receiving bore ( 24 ). 7. Locking device according to claim 5 or 6, characterized in that each inlet groove ( 46 ) widens towards its end ( 48 ) facing the first receiving bore ( 24 ). 8. Locking device according to claim 7, characterized in that the widened end ( 48 ) of each inlet groove ( 46 ) is approximately 1/4 to 1/1 of the diameter of the first receiving bore ( 24 ). 9. Locking device according to one of claims 1 to 8, characterized in that the housing ( 12 ) has at least two third receiving bores ( 36 ) each with a wire, which are assigned to different first receiving bores ( 24 ) of the cylinder core ( 14 ), and that the at least two third receiving bores ( 36 ) are arranged offset with respect to one another in the direction of rotation of the cylinder core ( 14 ).