CZ2021192A3 - Cylinder lock and key locking system, cylinder lock and key - Google Patents

Abstract

A cylinder lock and key stem locking system with at least one disc stop (3) with a central hole (20a) for the key stem (5). The stop (3) is rotatable around the longitudinal axis (O) and is provided with at least one coding projection (2000) and at least one coding cut-out (30) for the bolt (40). The stem (5) is formed by a longitudinal plate-like body with at least one coding surface (50) for interaction with the coding projection (2000) for turning the tumbler (3). At least one coding surface (50) is formed by a coding surface (50a) shifted in the direction (T) of the width of the shaft (5) at a distance (ΔT5) from the edge surface (523) of the shaft (5) and at least one coding cutout (30) is formed coding cutout (30a) shifted by an angle Δα3 compared to the position for cooperation with the coding surface (50) on the edge surface (523) of the stem (5). A cylinder lock with this locking system and a key for this locking system and this cylinder lock.

Description

Cylinder lock and key locking system, cylinder lock and key

Field of technology

The invention relates to a locking system of a cylinder lock and a key shaft, which includes at least one disk tumbler with a central hole for inserting and rotating the key shaft, wherein the disk tumbler is arranged to rotate around the longitudinal axis of the lock, and the disk tumbler is provided with at least one coding on the periphery of its central hole protrusion and on its outer circumference is provided with at least one coding cut-out for the lock, while the key shaft is formed by a longitudinal plate-like body, which is defined by a pair of opposite side surfaces defining the width of the shaft and a pair of opposite upper surfaces defining the height of the shaft, and the shaft is equipped with at least one coding surface , which is adapted to interact with at least one coding protrusion on the disk cylinder for a defined rotation of the disk cylinder around the longitudinal axis of the lock by at least one coding cut-out on the disk cylinder to the position against the lock.

The invention further relates to a cylinder lock with a locking system that includes at least one disk tumbler with a central hole for inserting and turning the key shaft, wherein the disk tumbler is arranged to rotate around the longitudinal axis of the lock and the disk tumbler is provided with at least one coding projection on the periphery of its central hole and on its outer circumference it is provided with at least one coding cut-out for the lock, while the coding projection is adapted for a defined rotation of the coding disc by the action of the coding surface on the key shaft around the longitudinal axis of the lock with at least one coding cut-out on the disc barrel to the position against the lock.

The invention also relates to a key for a locking system and for a lock, where the key contains a shaft which is formed by a longitudinal plate-like body, which is defined by a pair of opposite side surfaces defining the width of the shaft and a pair of opposite upper surfaces defining the height of the shaft, and the shaft is provided with at least one coding surface , which is adapted to interact with at least one coding protrusion on the disc cylinder for a defined rotation of the coding cylinder around the longitudinal axis of the lock and at least one coding cut-out on at least one disc cylinder to the position against the lock.

Current state of the art

From EP 989262, a cylinder lock and key combination, a key blank and the corresponding key are known. The cylinder lock contains a lock body in which the lock's rotating cylinder is rotatably mounted. The cylinder of the lock is equipped with a slot. A system of locking disks is placed inside the lock cylinder, each of which is equipped with at least one circumferential notch for determining the opening combination of the lock, and each of the disks is also equipped with a central hole for inserting a key. The lock also includes a locking rod to prevent rotation of the lock cylinder relative to the lock body in the locked position. At least one of the code lock disks is provided with a key hole in its central portion, in which the disk is provided with at least two separate inclined counteracting surfaces which are arranged on pitch diameters and are adapted to cooperate with combination surfaces on the key on the same pitch diameter. The key is basically rectangular in cross-section with at least one bevelled corner, on which the key is provided with beveled combination surfaces for the beveled counter-acting surface on the respective locking disc. These inclined combination surfaces on the key are arranged so that when the key is inserted into the lock and when the key is turned, they abut against the inclined counter-acting surfaces on the inner circumference of the respective locking disc and cause, when the key is turned further, each respective locking disc is rotated to the position in which the circumferential notches are of all the locking disks in the cover and create a common tunnel for the entry of the locking rod for turning the lock cylinder against the lock body, i.e. for unlocking the lock. The cooperating surfaces of each locking disk, the slanted coding surfaces of the key and the peripheral notches are thus arranged with each other to create the combinational values of the lock.

- 1 CZ 2021 - 192 A3

A certain disadvantage of this solution is the arrangement of inclined coding surfaces on the key and counteracting inclined surfaces on the inner circumference of the coding disks, which in practice limits the achievable number of combination possibilities of the lock, because when it is necessary to increase the combination possibilities of such a lock and key, it is very demanding and difficult, especially from the point of view laboriousness and accuracy of key production, to increase the number and slope of variously inclined individual cooperating surfaces on the key and on the inner diameter of the discs, following the position of the individual coding discs in the direction of the length of the lock and the position of the peripheral notches on the outer circumference of these coding discs. A possible simple increase in the number of coding discs is in turn disadvantageous due to an increase in the length of the lock, since the length of the lock should not exceed an acceptable limit.

ZCZ 2010-0879, CZ 2010-0843, CZ 2010-0880 and CZ 2010-0882 is a known cylindrical lock with a rotary key, where the lock contains a basic body with a cylindrical opening, in which a system of locking disks is arranged axially one behind the other, which are secured against spontaneous rotation. The locking disks are arranged either in a rotating housing placed in the cylindrical opening of the basic body of the lock. The locking discs are provided with a central hole and are provided in it on the pitch diameters with counter surfaces for coded contact with the coding surfaces, which are formed on the sides of the key on the corresponding pitch diameters of the side edges of the radial notches in the rotary key. The locking discs are provided on their outer circumference with notches for at least one lock and at least one guide element, which is adapted for comparing the tumblers to the desired rotation for removing the rotary key. The position of the deadbolt grooves is dependent on the respective coding function of the lock in relation to the position of the counter surface on the respective pitch diameter in the central hole of the respective coding disk and on the corresponding coding surface of the key on the side surface of the key body. The guide element of the key, which is adapted for guiding the central part of the key shaft inside the lock, also passes through the central hole in the pins. The key itself has a flat shape, the transverse profile of which is in the shape of the letter "X", or otherwise it is expressed in the form of a pair of letters "V" with their lower parts attached to each other, while the width of the key body increases from the center of the key body to the circumference of the key body. The side surfaces of the key body, after being defined by radial notches in the key body, are intended for cooperation with the counter-surfaces arranged on the inner circumference of the locking discs on a pitch diameter that corresponds to the depth of the radial notches in the key body. As shown in Fig. 1a and 1, which shows this state of the art, the mating surfaces P1, P2, ...., PX on the locking discs KUK together with the side coding surfaces KI, K2, ...., KX on the key KU and peripheral cut-outs VI and V2 on the KUK locking disks arranged with each other to create the combination values of the lock, while it is valid that the combination surfaces KI, K2, ...., KX on the KL key are always on the side wall BS of the body D of the KL key and positional angles and cutouts V on the outer circumference of the KUK locking discs are dependent not only on the position angles β _χ of the counter surfaces on the inner circumference of the KUK locking discs, but also on the corresponding pitch diameters R _x of the side edges of the respective combination surfaces K _x on the KL key (created using radial of notches in the key) and on the corresponding pitch diameters RU _X on the KUK locking discs.

The main disadvantage of this solution is the limited number of coding combinations due to the limited possible length of the lock, where the opposing surfaces P are arranged on the inner circumference of the locking discs, the coding surfaces K are always on the side surface of the KL key, or the side wall BS, the body D of the KL key, and the angular positions and circumferential notches V on the KUK locking disks are adapted to them, which in practice limits the number of lock combination options. Due to the need to increase the combination possibilities of such a lock and key, it is very demanding and difficult, especially from the point of view of labor and precision of production and also from the point of view of sufficient durability of the product, to increase the number of surfaces P and K in the available angular range of approx. % of the entire circumference of the locking discs, to increase the number pitch circles R _x and RU _X and to adequately create circumferential cutouts V in corresponding angular positions on the locking discs, etc. In order to achieve the required number of locking combinations, it is then necessary to produce a relatively large number of different locking discs with different protrusions and circumferential cutouts, which need to be assembled into locks with corresponding atom coding combinations to fit the key and radial notches into it. These disadvantages are manifested to a lesser extent in individual locking systems, but they are especially manifested in the so-called master and general key locking systems.

-2CZ 2021 - 192 A3

The aim of the invention is to eliminate or at least minimize the disadvantages of the current state of the art, in particular to enable the expansion of the number of coding combinations between the key and the locking discs, if possible even while reducing the manufacturing complexity of the lock or some of its components, both for individual locking systems and especially for locking systems master and master key.

The essence of the invention

The aim of the invention is achieved by a locking system of a cylinder lock and a key shaft, the essence of which is that at least one coding surface on the key shaft is formed by a shifted coding surface, which is located on the key shaft in the direction of the width of the shaft at a distance of ΔΤ5 from the edge surface of the key shaft to the depth of the material of the key shaft, while at least one coding cut-out of at least one disk tumbler is formed by a displaced coding cut-out, which is shifted on the outer circumference of the disk tumbler by an angle Δα ₃ compared to the position of the coding cut-out for cooperation with the coding surface situated on the peripheral surface of the key shaft.

The essence of the cylinder lock with this locking system is that the coding cut-out of at least one disk barrel is formed by a displaced coding cut-out, which is shifted on the outer circumference of the disk cylinder by an angle Δα ₃ compared to the position of the coding cut-out for cooperation with the coding surface on the marginal surface of the key shaft .

The essence of the key for this locking system and for this cylinder lock is that at least one coding surface on the key shank is formed by a displaced coding surface, which is situated on the key shank in the direction of the width of the shank at a distance ΔΤ5 from the edge surface of the key shank to the depth of the material of the key shaft, while this distance ΔΤ5 corresponds to the shifted position of the shifted coding cut-out on the respective disc cylinder.

The advantage of this solution is a fundamental increase in the number of locking, i.e., coding combinations, both for individual locking systems and for master and master key locking systems (SGHK). The invention makes it possible to use the dimension of the key shaft in the direction of the thickness of the shaft for further, space-dependent, distribution of the coding elements on the key and on the disc pins, which expands the possibilities of the mutual positions of the coding elements on the key and on the disc pins in the direction of the perimeter of the lock and key and makes it possible to expand the peripheral angle of the disk tumblers and the key, usable for the geometry of the locking system, for the combination of the mutual positions of the coding elements on the disk tumblers and on the key, etc. In essence, the invention adds another dimension to the existing systems with disk tumblers, in which it is possible to create a locking combination of disk tumblers and the key . At the same time, this places higher demands on the production of the key, but on the other hand, it simultaneously provides a higher degree of security for the lock and especially the key against unauthorized production and forgery, it provides an increase in the security of the lock and key while maintaining the structural simplicity of the disc tumbler system and the lock as such. Any increase in the requirements for the production of the key can be balanced when using this invention by using a pair of identical disk tumblers in one lock to create the locking code with the key, which are only mirror-inverted in relation to each other in the lock assembly, which allows it to be realized using a pair of factory-identical disc tumblers, which are only mirror-inverted in the lock assembly, two different locking codes, so that it is possible to produce for the lock and locking system according to the invention only half the number of disc tumblers with different shapes from each other while maintaining the number of different locking codes.

Clarification of drawings

The invention is schematically illustrated in the drawing, where Fig. 1 shows a cross-section of a key according to the state of the art, Fig. 1a the arrangement of the key and the disc tumbler according to the state of the art from Fig. 1, Fig. 1b the arrangement of the disc tumbler according to the state of the art from Fig. 2, Fig. 2 schematic arrangement of a locking system according to the invention comprising a lock and a key, Fig. 2a arrangement of one

-3 CZ 2021 - 192 A3 of a disc tumbler according to the invention, Fig. 2b arrangement of the basic body with inserted disc tumblers and spring discs, Fig. 2c layout of the exploded assembly of the basic body with disc tumblers and spring discs, Fig. 2d a slightly lower view of the arrangement according to Fig. 2c, Fig. 2e an example of the implementation of a spring disk, Fig. 3 a detail of the implementation of the coding system on the key according to the invention, Fig. 4 a cross-section of the key stem in the plane A-A from Fig. 3, Fig. 5 a longitudinal section of the plane in the direction of the height of the key by arrangement of a lock with an inserted key, Fig. 5a cross-section along plane A-A in Fig. 5, Fig. 6 cross-section of an alternative version of the key with an inclined, displaced coding surface and with coding surfaces also in the region of the grooves for the longitudinal guide element of the key in the lock, Figs. 7 to 7d examples of realization of disc tumblers with an offset coding cut-out and Fig. 7e and 7f use the disc tumblers with an offset coding cut-out according to Figs. 7 and 7a with a key according to the present invention.

Examples of implementation of the invention

The invention will be described on examples of the implementation of a locking system of a cylinder lock and key, where the lock contains a system of disc tumblers 3 arranged behind each other, also on an example of the implementation of a cylinder lock with this locking system and on examples of the implementation of a key K and disk tumblers 3 for this locking system and for this cylinder lock.

The lock includes a basic body 1, which is equipped at one end with a coupling S for connection with an unillustrated unlocking tooth. The basic body 1 is provided at its other end with a longitudinal cylindrical opening 10, in which an assembly of coding discs 3 is arranged rotatably around the longitudinal axis O of the lock.

In the illustrated embodiment, the coding disks 3 are separated from each other by springing disks 2, which are adapted to separate adjacent disk tumblers 3 and to elastically define the axial clearances in the direction of the longitudinal axis O of the lock within the disk tumbler system 3. For an improved definition of these axial clearances, on the basic body 1, a system of axial stops is created for a defined group of disk tumblers 3 and their assigned spring disks 2, when, for example, each trio of spring disks 2 and the disk tumbler 3 arranged between them is defined in the basic body 1 by the position of these axial stops so that the extreme spring discs 2 of this trio are defined by axial stops and the middle spring disc 2 is arranged as a so-called floating between a pair of so-called floating disc tumblers 3.

In the shown embodiment, the axial stops on the base body 1 are represented by the side walls 110 of the through windows 11 in the base body L

In a non-illustrated embodiment, the disk tumblers 3 are axially separated from each other by flat disk inserts without springing capabilities, or the disk tumblers 3 are axially separated from each other by separating cups, or the disk tumblers 3 are axially separated from each other by other suitable axial separation means, including a suitable system of axial stops arranged on the inner wall of the basic body 1 either for each disc tumbler 3 separately, or arranged on the inner wall of the basic body 1 always for a defined group of disc tumblers 3.

In an embodiment not shown, the disk tumblers 3 are arranged so that they abut each other axially, i.e. in the direction of the longitudinal axis O of the lock, i.e. there is no axial separation means between them.

The disc tumblers 3 and any axial separation means, in the illustrated example these axial separation means are represented by spring disks 2, are provided with a central through hole 20a. which in the direction of the longitudinal axis O of the lock, i.e. in the direction of the length of the lock, creates a key cavity 21 of the lock, in which, in the illustrated embodiment of the lock, a guide element 6 is arranged longitudinally for guiding the central part of the key shaft 5 in the lock. The guide element 6 is rotatable

-4CZ 2021 - 192 A3 around its longitudinal axis, which coincides with the longitudinal axis O of the lock and is adapted both for the longitudinal guidance of the shaft 5 of the key and for the support of the shaft of the key 5 when rotating the shaft of the key 5 around the longitudinal axis O of the lock and around the longitudinal axis 51 of the shaft 5. The customs entrance to the key cavity 21 is covered by a front shield 7 with a key hole 70, the shape of which copies the shape of the basic envelope of the cross section of the shaft 5 of the key.

An example of the realization of an axially separating means in the form of a spring disk 2 is shown in Fig. 2e and 2f. In this exemplary embodiment, the spring disk 2 is formed as a flat disk with a central through hole 20a. while this flat disc is bent in its central part into an arc of radius RO. while the depth hj of this deflection is greater than or equal to the minimum required axial distance of the two adjacent disk tumblers 3 of the lock assembly. In the embodiment shown, the spring disk 2 is provided with an upper end 2a with a pair of flat protrusions 2al for axial securing by seating on the side walls 110 of the through windows 11 in the base body L. At its opposite end, the flat disk is provided with a guide protrusion 2b 1 with a groove 2b2 for the bolt 40 of the lock , whereby the guide projection 2b 1 passes, for example, through the longitudinal cut-out 12 in the base body 1. The stem 5 of the key has a basically flat shape with a cross-section in the shape of the letter "X" or also in the shape of a pair of letters "V" attached to each other by their lower parts, where with the direction from the center S of the shaft 5 of the key to the circumference of the shaft 5 of the key, the width T of the shaft 5 of the key increases.

The disc tumbler 3 is provided with a system of coding protrusions 2000 on the periphery 200 of its central hole 20a for contact with the coding surfaces 50 on the key K. The coding protrusions 2000 in the central hole 20a of the disc tumbler 3 are formed at the corresponding pitch radii Rp, Ri, R ₂ , etc. from the center S of symmetry of the respective disk cylinder 3 and are equipped with radially laid coding surfaces 2001 or 2002. The longitudinal axis O of the lock passes through the center S of symmetry of the respective disk cylinder 3.

The pitch radii Rp, Ri, R ₂ to R _x of the disc cylinder 3 correspond to the pitch radii Po. Pi, P2 to Ρχ, or the depth of the radial notches, to create the radially located coding surfaces 50 on the rotary key K, which will be described in more detail in the following text.

In the illustrated embodiment, the disk tumblers 3 in the central opening 20a are provided with coding protrusions 2000 at three pitch radii Rp, Ri, R ₂ , which are intended for cooperation with the coding surfaces 50 on the shaft 5 of the rotary key at three corresponding radii Po, Pi, U In the non-illustrated embodiment, the number of mutually corresponding radii _Rx and Px is different, e.g. 4 or 2, etc.

The disc tumblers 3 are provided on their outer circumference with at least one coding cut-out 30 for at least one bolt 40 of the lock coupled to the not shown bolt of the lock. The disk tumblers 3 are further provided on their outer perimeter with at least one guide notch 31 for at least one control rod 4 of the lock, which is adapted in a known manner for aligning the disk tumblers 3 to the desired rotation for removing the shaft 5 of the rotary key from the lock. The control rod 4 and the lock 40 are arranged parallel to the longitudinal axis O of the lock.

Each coding cut-out 30 is arranged on the circumference of the disc cylinder 3 in such an angular position that corresponds to the angular coding function specified by the mutual angular position of the respective coding surface 2002 on the respective pitch radii Ro, Ri, R ₂ to R _x on the circumference of the central hole 20a in the disc cylinder 3 and the respective coding surfaces 50 on the corresponding pitch radius Po. Pi, P2 to Ρχ on shaft 5 keys. Coding cut-outs 30 on the outer circumference of each of the disk tumblers 3 then, with their angular positions and in cooperation with the angular positions and the size of the coding surfaces 2001 or 2002 on the inner circumference of this disk tumbler 3, determine the locking code of the respective disk tumbler 3 and in cooperation with the other disk tumblers 3 and the coding surfaces 50 on the corresponding pitch radii Po, Pi, P2 to Ρχ on the shaft 5 of the keys then determine the locking code of the entire lock.

In order to achieve the necessary or desired complexity of the locking code of the entire lock, a certain number of disk tumblers 3 along the longitudinal axis O, i.e. along the length of the lock, is needed.

-5CZ 2021 - 192 A3

The key cavity 21 is arranged longitudinally around the longitudinal axis O of the lock and is adapted for the longitudinal insertion of the shaft 5 of the key and for the rotation of the shaft 5 of the key about its longitudinal axis 51, which in this arrangement, when the shaft 5 is inserted in the lock, merges with the longitudinal axis O the castle. When rotating the shaft 5 of the key in the key cavity 21, there is an interaction between the shaft 5 of the key, or by its coding surfaces 50 described below, and coding surfaces 2002 on the protrusions 2000 on the central opening 20a of the disc tumblers 3.

The shaft 5 of the key contains a longitudinal plate-like body, which is defined in the direction of its length d by the front end 53, by which the shaft 5 is inserted into the lock, and by the rear end 54, on which the holder of the shaft 5, not shown, is usually placed. At its front end 53, there is a longitudinal the plate-like body of the stem 5 is provided with an oblique narrowing to facilitate the insertion of the stem 5 into the lock.

In the direction T of the thickness of the stem 5, the longitudinal plate-like body is defined by a pair of opposite side surfaces 52 of the stem 5, which are provided with edge surfaces 523 situated in the part of the side surfaces 52 connected to the upper surfaces 55 of the stem 5. In the illustrated embodiment, the side surfaces 52 of the stem 5 are keys in the central part of the width of the stem 5 further provided with longitudinal grooves 520 and/or longitudinal recesses 521 and/or longitudinal protrusions 522. which are usually intended for the longitudinal guidance of the stem 5 of the key, to ensure the necessary shape strength of the stem 5 of the key and, if necessary, are also adapted for extension of the coding functions of the lock by coding between the sides 52 of the shaft 5 of the key and the front shield 7 and/or between the sides 52 of the shaft 5 of the key and the inner walls of the guide element 6.

In the direction V of the height of the shaft 5, the longitudinal plate-like body of the shaft 5 is defined by the upper surfaces 55, which at their side ends connect to the side surfaces 52 of the shaft 5 and at their front and rear ends connect to the front end 53 of the shaft 5 and the rear end 54 of the shaft 5.

In the illustrated embodiment, the shaft 5 from the direction against the upper surfaces 55, i.e. in the direction against the height V of the shaft 5, is provided with a system of radial notches 550 running perpendicular to the length of the shaft 5, which also pass through the edge surfaces 523 in the side surfaces 52 of the shaft 5. Radial through the notches 550, part of the material of the shaft 5 is thus removed, while the parts of the edge surfaces 523 of the shaft 5 left on the shaft 5 contain at least one coding surface 50 for cooperation with the coding surfaces 2002 or 2001 on the protrusions 2000 on the inner circumference of the central hole 20a of the disk cylinder 3. The position of the radial of the notches 550 on the shaft 5 in the direction d of the length of the shaft 5 and the depth H of the radial notches 550 (or pitch radii Po, Pi, P2 to P _x edges on the shaft 5 of the key) determine the position and size of the coding surfaces 50 on the edge surfaces 523 of the shaft 5 , which are adapted to work with the corresponding coding protrusions 2000. or with their coding surfaces 2001 or 2002. on the inner circumference of the hole 20a of the respective disc tumbler 3. The position and size of the coding surfaces 50 on the edge surfaces 523 of the stem 5 corresponds to the position of the respective disc tumbler 3 in the direction of the longitudinal axis O, i.e. in the direction of the length of the lock, further also the position of the coding protrusion 2000, or its coding surfaces 2001 or 2002, in the through hole 20a of the disc cylinder 3, the pitch radius Ro, Ri, R2 to R _x of the respective coding protrusion 2000, respectively. its contact edges 2001. the size of the coding protrusion 2000. or its coding surface 2001 or 2002 and the angular position of the coding cut-outs 30 on the outer circumference of the disk tumbler 3 etc. to jointly create the locking code of the lock between the shaft 5 of the key and all the disk tumblers 3 of the lock, i.e. the locking system of the lock.

At least one coding surface 50 on the shaft 5 is formed on the displaced surface 5230, and forms a displaced coding surface 50a, which is situated on the key shaft 5 at a distance from the edge surface 523 on the shaft 5 in the direction T of the width of the shaft 5 at a distance ΔΤ5. This displaced surface 5230 is thus located in the direction T of the width of the stem 5 from the edge surface 523 on the stem 5 in the direction T of the width of the stem 5 to the depth of the material of the stem 5 in the direction T of the width of the stem 5. In angular terms, the displaced surface 5230 with respect to the edge surface 523 on shaft 5 angularly rotated about the center S of the shaft 5 of the key by an angle Δα-, as shown in Fig. 3, 4 and 5a. The displaced surface 5230 is created in the form of a recess, e.g. by milling, etc., from the side wall (edge surface 523) in the direction of the thickness T of the stem 5 to the necessary material depth ΔΤ5 corresponding to the angular rotation Δα-,

-6CZ 2021 - 192 A3

This displaced coding surface 50a on the displaced surface 5230 corresponds to at least one coding surface 2001 or 2002 on the coding projection 2000 in the central opening 20a of the disc tumbler 3 and at the same time at least one coding cut-out 30 on the outer circumference of the respective disc tumbler 3 displaced on the outer circumference of the disc tumbler 3 o the angle Acts compared to the position in which this coding cut-out 30 would be if it corresponded to the coding surface 50 located on the marginal surface 523 of the shaft 5 of the key. The coding cut-out moved in this way is thus shifted on the outer circumference of the disk tumbler by an angle Acts compared to the position of the coding cut-out for cooperation with the coding surface situated on the marginal surface of the key shaft. In this way, at least one displaced coding cut-out 30a is formed on the locking disc 3. The angular displacement Acu of the displaced coding cutout 30a ie can also be expressed as a tangential displacement ΔΤ3 of the displaced coding cutout 30a in the tangential direction to the circumference of the disc cylinder 3, while the size of this tangential displacement ΔΤ3 of the displaced coding cutout 30a corresponds to the distance ΔΤ5 of the distance of the displaced coding surface 50a on the shaft 5 of the key from the edge surface 523 of the shaft 5 in the direction T of the width of the shaft 5.

Fig. 6 shows an alternative embodiment of the key according to Fig. 4, where the key stem 5 in the longitudinal grooves 520 for the longitudinal conductor 6 of the key is provided with at least one additional recess 520a for extended coding also between the stem 5 of the key and the longitudinal conductor 6 of the key. In this alternative embodiment, at least one coding surface 50 on the shaft 5 is formed on a displaced surface 5230. and thus forms a displaced coding surface 50a, which is located on the shaft 5 of the key at a distance from the edge surface 523 on the shaft 5 in the direction T of the width of the shaft 5, here at a distance of ΔΤ5. This displaced surface 5230 is thus located in the direction T of the width of the stem 5 from the edge surface 523 on the stem 5 in the direction T of the width of the stem 5 to the depth of the material of the stem 5 in the direction T of the width of the stem 5. In angular terms, the displaced surface 5230 with respect to the edge surface 523 on shaft 5 angularly rotated around the center S of the shaft 5 of the key by an angle Δθ5. At the same time, the displaced surface 5230 is created in the form of a recess, e.g. by milling, etc., from the side wall (edge surface 523) in the direction of the thickness T of the stem 5 to the necessary material depth ΔΤ5 corresponding to the angular rotation Aag.

According to the embodiment in Figs. 2 and 3, the stem 5 is provided with at least two differently displaced surfaces 5230, 5231, while at least one displaced coding surface 50a is formed on at least one of them with a functional connection to the displaced coding cut-out 30a on the outer circumference of the respective disc cylinder 3. The amount of displacement AT of each displaced coding surface 50a relative to the side surface 523 of the key shaft 5 is either the same or different, or it is the same for a part of the displaced surfaces 5230, 5231 and different for a part of the displaced surfaces 5230, 5231.

For the practical use of the solution according to the present invention in the form of a dimensionally standardized locking insert, the distances ΔΤ5 and ΔΤ3 preferably have a value from 0.01 mm to 3 mm and the angles Aas and Δευ preferably have a value from 0.01° to 15°.

Figures 7 to 7d show a system of three different disc tumblers 3 for the locking system and lock according to the present invention. The disk tumbler 3 contains a central opening 20a, which is axially symmetrical along two mutually perpendicular axes, which are, for example, the horizontal axis X and the perpendicular vertical axis Y. On the circumference of the central opening 20a, coding protrusions 2000 are formed at pitch radii Rp, Ri, R2, whose front surfaces 2001 or 2002 are intended for cooperation with the coding surfaces 50 on the stem 5 of the rotary key at the corresponding radii Po. Ρι, Β

The disk tumblers 3 in Fig. 7 to 7c are provided on their outer perimeter with a pair of coding cut-outs 30 for the latch 40 of the lock. According to the known state of the art in Figs. 1 to 1b, these coding cutouts 30 are arranged on the outer circumference of the disk cylinder 3 also axially symmetrically according to one of the mutually perpendicular axes. This state of the art from Figs. 1 to 1b is transferred to the embodiment of this invention in Figs. 7 to 7c and shown by means of the first coding cut-out 30 shown by a solid line and by means of a virtual cut-out 30b indicated by a dashed line symmetrically arranged axially according to the vertical axis Y. At the same time, the disc tumbler 3 is provided with a shifted coding cut-out 30a. which is shifted on the outer circumference of the disk tumbler 3 by an angle Δα;.

-7 CZ 2021 - 192 A3 is not displaced by the tangential displacement ΔΤ3, compared to the position of the virtual cut-out 30b. i.e. relative to the position known from the state of the art and marked in Fig. 7 to 7c by a pair of angles 03. The size of the displacement angle Acts of the displaced coding cut-out 30a corresponds to the size of the displacement angle Acg of the displaced coding surface 50a on the shaft 5 of the key from the edge surface 523 of the shaft 5 in the direction T of the width (thickness) of the shaft 5, i.e. that the size of the tangential displacement ΔΤ3 of the displaced coding cutout 30a corresponds to the distance ΔΤ5 of the distance of the displaced coding surface 50a on the shaft 5 of the key from the edge surface 523 of the shaft 5 in the direction T of the width of the shaft 5.

Figures 7 and 7 show one and the same disc tumbler 3, which is adapted to perform the function of two locking codes, simply by mirror rotation of this disc tumbler 3 around the vertical axis Y and inserting the thus rotated disc tumbler 3 into the assembly of disc tumblers 3 of the locking system and the lock according to the present invention. In order to fulfill two different locking codes in the system and lock according to the present invention, it is thus sufficient to produce one disc tumbler 3, while a pair of offset coding surfaces 50a is correspondingly formed on the key shaft 5.

An equivalent embodiment of one and the same disk tumbler 3 with the first coding cut-out 30, the virtual cut-out 30b and the displaced coding cut-out 30a according to Fig. 7 and 7a is also shown in Fig. 7b and 7c with a different location of the cut-outs 30, 30a and 30b. Even this embodiment of the disc tumbler 3 makes it possible to realize two locking codes in the system and lock according to the present invention using one disc tumbler 3 by simply rotating the disc tumbler 3 around the vertical axis Y and inserting the thus rotated disc tumbler 3 into the assembly of the disc tumblers 3 of the locking system and lock according to this of the invention, while a pair of displaced coding surfaces 50a is correspondingly formed on the shaft 5 of the key.

Fig. 7d shows a completely symmetrical disk tumbler 3 with the coding cut-out 30 and without the displaced coding cut-out 30a.

Fig. 7e and 7f show the cooperation of the disk tumbler 3 from Figs. 7 and 7a with the shaft 5 of the key, where the disk tumbler 3 from fig. 7 in the position as drawn in Fig. 7 and behind it is arranged the disk tumbler 3 of Fig. 7a in the position as drawn in Fig. 7a. In Fig. 7e and 7f, it can be seen that the disk tumbler 3 located here on the left interacts with its coding surface 2001 with the coding surface 50 on the side 523 of the key shaft 5, and by this interaction the coding cut-out 30 is turned into a position suitable for the entry of the lock 4. Opposite the disc tumbler 3 located on the right in Fig. 7e interacts with its opposite coding surface 2002 with the displaced coding surface 50a in the recess in the side 523 of the key shaft 5, and by this interaction the displaced coding cut-out 30a is rotated into a position suitable for the entry of the lock 4, in which the coding cut-out 30a of the right disk tumbler 3 is shifted, overlapping with the coding cut-out 30 of the left disk tumbler 3. The disk tumbler 3 on the right is formed by the identical and only mirror-inverted disk tumbler 3 on the left.

The invention is not limited to only the embodiments explicitly described or shown here, but is applicable to any lock with disc tumblers.

Industrial applicability

The invention can be used in locking systems of cylinder locks with disc tumblers, in cylinder locks with disc tumblers and also in keys for these locks. The invention is applicable in safe locks, lock inserts and other types of locks with disc tumblers.

Claims (12)

PATENT CLAIMS 1. A cylinder lock and key stem locking system comprising at least one disc tumbler (3) with a central opening (20a) for inserting and rotating the key stem (5), wherein the disc tumbler (3) is rotatably arranged around a longitudinal axis (O) of the lock and disc tumbler (3) is provided with at least one coding protrusion (2000) on the circumference of its central opening (20a) and on its outer circumference is provided with at least one coding cut-out (30) for the lock (40), while the stem (5) of the key is formed by a longitudinal plate-like body, which is defined by a pair of opposite side surfaces (52) defining the width (T) of the stem (5) and a pair of opposite upper surfaces (55) defining the height (V) of the stem (5), and the stem (5) is equipped with at least by one coding surface (50) which is adapted to interact with at least one coding projection (2000) on the disk cylinder for a defined rotation of the disk cylinder (3) around the longitudinal axis (O) of the lock by at least one coding cut-out (30) on the disk cylinder (3) ) to the position against the end ohm (40), characterized by the fact that at least one coding surface (50) on the shaft (5) of the key is formed by a shifted coding surface (50a), which is located on the shaft (5) of the key in the direction (T) of the width of the shaft (5) ) at a distance (ΔΤ5) from the edge surface (523) of the key stem (5) to the depth of the material of the key stem (5), while at least one coding cut-out (30) of at least one disc cylinder (3) is formed by a displaced coding cut-out (30a), which is shifted on the outer circumference of the disc cylinder (3) by an angle (Δα ₃ ) compared to the position of the coding cut-out (30) for cooperation with the coding surface (50) situated on the edge surface (523) of the key shaft (5). 2. The locking system according to claim 1, characterized in that the stem (5) is provided with at least two displaced surfaces (5230, 5231), and at least one displaced coding surface (50a) is formed on each of them. 3. The locking system according to any one of claims 1 or 2, characterized in that the distance (ΔΤ5) has a value from 0.01 mm to 3 mm and the angle (Δα ₃ ) has a value from 0.01° to 15°. 4. A locking system according to any one of claims 1 to 3, characterized in that at least two disc tumblers (3) are the same in the set of disc tumblers (3) and are arranged mirror-inverted to each other. 5. A locking system according to any one of claims 1 to 4, characterized in that one axially springing disc (2) is arranged between each adjacent disk tumblers (3) adapted to define the axial play of the disk tumblers (3). 6. A cylinder lock with a locking system, which includes at least one disk tumbler (3) with a central opening (20a) for inserting and rotating the shaft (5) of the key, wherein the disk tumbler (3) is arranged to rotate around the longitudinal axis (O) of the lock and the disc tumbler (3) is provided with at least one coding protrusion (2000) on the circumference of its central opening (20a) and on its outer circumference is provided with at least one coding cut-out (30) for the latch (40), while the coding protrusion (2000) is adapted for a defined rotation of the coding disc (3) by the action of the coding surface (50) on the shaft (5) of the key around the longitudinal axis (O) of the lock by at least one coding cut-out (30) on the disk cylinder (3) into a position against the lock (40), characterized in that the coding cut-out (30) of at least one disk tumbler (3) is formed by a displaced coding cut-out (30a), which is shifted on the outer circumference of the disk tumbler (3) by an angle (Δα ₃ ) compared to the coding cut-out (30) for cooperation with coding surface (50) on the edge surface (523 ) of the shaft (5) of the key. 7. A cylinder lock according to claim 6, characterized in that at least two disk tumblers (3) are the same in the set of disk tumblers (3) and are arranged mirror-inverted to each other. 8. A cylinder lock according to any one of claims 6 or 7, characterized in that between each adjacent disk tumblers (3) one axially adjusting disk (2) adapted to define the axial clearance of the disk tumblers (3) is arranged. -9 CZ 2021 - 192 A3 9. A key for a locking system and for a cylinder lock, where the key contains a stem (5) which is formed by a longitudinal plate-like body, which is defined by a pair of opposite side surfaces (52) defining the width (T) of the stem (5) and a pair of opposite upper surfaces (55) defining the height (V) of the shaft (5) and the shaft (5) is provided with at least one coding surface (50) which is adapted to interact with at least one coding protrusion (2000) on the disc cylinder (3) for a defined rotation of the coding tumbler (3) around the longitudinal axis (O) of the lock and by at least one coding cut-out (30) on at least one disk tumbler (3) into the position against the lock (40), characterized by the fact that at least one coding surface (50) on the stem ( 5) of the key consists of a displaced coding surface (50a), which is located on the shaft (5) of the key in the direction (T) of the width of the shaft (5) at a distance (ΔΤ5) from the edge surface (523) of the shaft (5) of the key to the depth of the material shaft (5) of the key, while this distance (ΔΤ5) corresponds to the shifted position of the shifted code of the cut-out (30a) on the respective disc cylinder (3). 10. The key according to claim 9, characterized in that the shaft (5) is provided with at least two offset surfaces (5230, 5231), each of which has at least one offset coding surface (50a). 11. A key according to claim 9 or 10, characterized in that the amount of displacement ΔΤ5 of each displaced surface (5230, 5231) and each displaced coding surface (50a) relative to the side surface (523) on the shaft (5) is the same or different or is the same for part of the shifted surfaces (5230, 5231) and shifted coding surfaces (50a) and is different for part. 12. The key according to any one of claims 9 to 11, characterized in that the amount of displacement (ΔΤ5) has a value from 0.01 mm to 3 mm.