RU2067653C1 - Locking mechanism of a code lock - Google Patents

Abstract

FIELD: lock production. SUBSTANCE: locking mechanism includes casing. Control heads installed on pivots and rigidly secured code disks are placed along the casing circuit. The mechanism has central control head put on spring-loaded central member. The latter has a step for interacting with locking members of code disks. Step cylindrical surface of the central member and pivot surface of each code disk placed in front of them on the side of the step are teethed for engaging each other. EFFECT: higher reliability. 1 dwg

Description

 The invention relates to locking mechanisms for locks having code disks, mating their locking elements with a bolt or a bolt drive.

 There is a known mechanism for locking a code lock containing code disks, on the axes of which control heads are installed for setting a code, in which the lockable elements mate with the lockable elements of the lock cover when it is opened (A. p. 1227786, MKI E 05 V 37/12). This castle has reduced privacy. There is always the possibility of selecting a code by “probing” each locking element, since each locking element of the code disk rotates around its axis in contact with the surface of the lid, the locking elements of which are interfaced with the locking elements of the code disks.

 Known lock containing code disks on the axes with locking elements and a stepped roller, which can serve as a lock bolt or as a drive bolt. This castle has increased secrecy, in contrast to the above, but still it is lowered, because code disks and a stepped roller occupy any position and it is possible to select a code by "probing". In addition, when opening and closing the lock, it is necessary to “knock down” the code of each locking element, which introduces inconvenience. This locking mechanism of the lock is the prototype of the proposed.

 The proposed locking mechanism does not have these drawbacks. This is achieved by the fact that the axis of the code disk from the side of the step of the roller is made with a gear surface mating with the external gear surface of the step of the roller.

 Indeed, having additionally performed on the axis of the code disk a gear surface that engages with the external gear surface of the roller step, we obtain a mechanism in which all code disks are connected by gear transmission when lowering the roller step to the locking elements and when one of them rotates, all code disks rotate . This excludes the possibility of selecting the code by “probing”, and when the stepped roller is set to its initial state, the code fails when the stepped roller or one of the code disks rotates.

 The drawing shows the design of the proposed mechanism.

 Code disks 1 have locking elements 2, conjugated with the outer surface of the step 3 of the roller 4, which has at its end an engagement element 5 with a lock bolt, or a bolt control mechanism. The roller has a rotary element 6. On the outer surface of the steps of the roller is made of the gear surface 7, which is associated with the gear surface of the axis 8 of the code disks. The roller is spring loaded 9.

 The proposed mechanism works as follows.

 Conditionally, we believe that the lock has a closed state, i.e. the locking elements 2 of the code disks 1 occupy an arbitrary position relative to the step 3 of the roller 4. The step 3 is in the upper position due to the spring 9. To open the lock, it is necessary to move the step 3 and the roller 4 by a distance equal to the thickness of the gear part 8 of the axis of the code disk plus the thickness of the code disk . It is easy to go down the gear part of the axis of the step 3, but if the code disks are not installed so that the locking elements 2 of the code disks are mated with the outer gear surface 7 of the step 3, the roller 4 does not connect to the bolt by the engagement element 5 and cannot open the lock. When rotating the code disk, to select the position of the locking element 2 of the code disks, all the disks rotate if the step 3 is engaged with them and the relative position of the locking elements is preserved, i.e. "probing" is excluded. In order to open the lock, it is necessary to set the step 3 to the upper position, when it does not engage with the gear part of the axes of the code disks and rotates freely. In this position, set the code discs in a certain position, when the locking elements are consistent with the surface 7 of the step 3, click on the rotary element 6, the step passes through the threaded parts of the axes of the code discs and falls to the stop, limited only by the size of the compressed spring 9. Roller 4 using the element gear 5 comes into contact with the crossbar and when turning the roller 4, the crossbar occupies the position the lock is open. After this release the rotary element 6, the roller 4 and the step 3 occupy the upper position. They knock down the code of any code disk or several, enter step 3 with the gear parts of the code disks, and slightly rotate the rotary element or any code disk, all code disks rotate and the code is knocked down.

 Thus, from the description and the drawing we see that the selection of the code by “probing” is excluded and if the code disks have fixed positions, then all the positions of the code will have to be passed, i.e. iterate over all the code combinations. In addition, it is easy to knock down the code of all code disks here.

Claims (1)

 A locking mechanism of a code lock, comprising a housing in which circumferentially mounted control heads and rigidly fixed code disks with locking elements and a central control head mounted on a spring-loaded central element having a step interacting with locking elements of the code disks, characterized in that the cylindrical step surface of the central element and the axis surface of each code disc located in front of it from the step side are toothed for I'm gearing with each other.