HU215769B - Safety lock and flat key fitting to it - Google Patents

Abstract

The invention relates to a cylinder lock and an associated key. The latter has the features that at least three control grooves are provided on at least one of the two side surfaces, at least one of the control grooves is designed to be deeper than the other control grooves, and the two shallow control grooves are provided such that they run approximately parallel to one another, characterised in that a further cutout (domed milled relief 22) for releasing the control slide 11 is provided on at least one of the flat sides, and in that, at least on a key front (key spine), there is arranged an oblique profiling which meshes with an analogous profiling of a profiled strip arranged in the cylinder lock. <IMAGE>

Description

The present invention relates to a cylinder lock and an associated flat wrench.

The cylinder lock is of a type provided with actuators having guides that extend into a keychain and contact the keyholes of a key inserted in the keychain and are arranged on at least one side of the keychain in parallel with at least one control member having two guides they extend through an opening in the cylinder core to the keyhole and are connected to the less deep control grooves of the key inserted in the keychain, and on the same side of the keyway is a control element having a second length extending into another keyhole through the other connected to a deeper control opening of the key, wherein the first length dimension is smaller than the second length dimension and at least one locking member is provided which is the appropriate position of the control means It is designed to allow rotation of the roll core in the cylinder housing.

The flat key of the present invention has guide grooves and, optionally, additional controls, such as front face edge, "beard" notches, rear edge guide faces and two longitudinal ribs and grooves, which are adjustable from the rear edge, at least one of the side surfaces has at least three guide grooves, and at least one of them is formed deeper than the other two control grooves, and the two less deep control grooves are arranged parallel to each other.

The invention is based on the key-lock arrangement disclosed in EP-OS 335 069.

SUMMARY OF THE INVENTION The object of the present invention is to provide a lock having more variations and greater locking safety than the known lock. The same objective is achieved by training the lock key.

SUMMARY OF THE INVENTION An object of the present invention is to provide a cylinder lock provided with actuators having guides that extend into a keychain and contact the keyholes of a key inserted in the keychain, and at least one side of the keychain arranged parallel to at least one keychain with a first length dimension extending through an opening in the cylinder core to the keyhole and connecting to a less deep control groove of the key inserted in the keychain, and on the same side of the keychain a control element with an additional control member extending through another opening in the core connected to a deeper control opening of the key inserted into the keyway, wherein the first length dimension is smaller than the second length dimension and at least one locking member is provided which controls in the appropriate position of the organs, the cylinder core is rotatable in the cylinder housing, wherein the locking member is formed as a slidable locking slider in the groove of the cylinder core, having locking members extending into a groove in the cylinder housing formed into which the closure members extend when the roll core is rotated, allowing further rotation.

The invention also includes a flat wrench which, on its side surfaces, has guide grooves at a distance varying from the rear edge and optionally additional controls such as the front edge of the key, "beard" cuts, rear edge controls and longitudinal ribs. having at least three guiding grooves on at least one of the two flat side surfaces, at least one of which is deeper than the other two guiding grooves, and the two less deep guiding grooves being arranged parallel to each other, wherein at least one flat side surface of the key a guide slot is provided for receiving the guide slide and at least one of the rear or front edge faces is provided with an inclined profile which fits in with a profile strip arranged in the cylinder lock.

The invention will now be described in more detail with reference to the drawings, in which an exemplary embodiment is provided. The attached drawings show

Fig. 1 is a perspective view of a lock cylinder with a cylindrical housing in longitudinal section and a rotatable cylindrical core in a non-rotated position;

Fig. 2 is a schematic sectional view taken along plane II-II in Fig. 1, with only one half of the roll core and cylinder housing depicted, the key being inserted;

Figure 3 is a sectional view taken along the plane III-III in Figure 2, a

Figure 4 is a longitudinal section of the cylinder housing, FIG

Figure 5 is a right, partly sectional view of the cylinder housing, a

Figure 6 is a side view of a key, a

Figure 7 is a sectional view taken along plane VII-VII in Figure 6, a

Figures 8 and 9 are a longitudinal section and a view of the profile strip, a

Figures 10 and 11 illustrate a further embodiment of the lock, similar to Figures 1 and 2.

In Figure 1, the cylindrical bore 2 of the cylinder housing 1 is provided with a roll core 3 which can be pivoted in the cylinder housing 1. Outwardly, the cylindrical core 3 is sealed with a disk 4, and at the other end of the cylindrical core 3 is a clutch 5, not described hereinbelow.

The cylinder housing 1 has six parallel annular grooves 6 which open in the direction of the cylinder bore 2. A longitudinal groove 7 of the roll core 3 is provided with a locking slide 8 which carries a series of locking members 9 which extend over the outer surface of the roll core 3 and fit into the annular grooves 6 at the correct position of the locking slide 8. hengerház2

In the position shown, rotation of the cylinder core 3 is prevented because the locking elements 9 are caught in the ribs 34 between the annular grooves 6. The locking slide 8 is spring-loaded by a spring pin 10. At one end of the locking slide 8 is a guide slide 11 which can be inserted radially into the roll core 3. In the section 12 of the control slide 11, the control slide 11 lies above the rising surface 42 of the locking slide 8. When the guide slider 11 is pressed into the roll core 3, the locking slider 8 moves to the right against the spring of the spring pin 10 until the locking members 9 assume a position in the annular grooves 6.

In addition to the key groove (not shown), slidable pins 16 are arranged in well-formed bores 13, which are described in more detail with reference to Figures 2 and 3.

Figure 2 is a sectional view taken along plane II-II in Figure 1, with only one side of the cylinder lock shown. The other half is only schematically marked for better understanding of the drawing.

The key 14 is fully inserted into the corresponding key groove of the cylinder core 3, the key 14 having guide grooves 15, by means of which the locking pins 16 are adjusted to the proper offset position. The locking pins 16 have guide pins 17 in the direction of the keyway which are guided in the guide grooves 15 of the key 14 and each locking pin 16 is provided with a locking piece 18 on the other side which is located in the groove 19 when the locking slide 8 is in the position. The control slider All is in the zero position (in the unturned position of the cylinder core 3 in the cylinder housing 1) in the control opening 20 of the cylinder housing 1. As the roll core is rotated, the guide slide 11 is pushed inward in the direction of the arrow, which is made possible by the arcuate cut-outs of the key 14. The locking slide 8 is then moved to the right, which is possible because the locking pins 16, due to the corresponding key 14, are in a position which allows the locking projections 23 to penetrate the locking slide 8. Further, the locking elements 9 are placed in the correct position so that they fit into the annular groove 6 and allow the core 3 to rotate in the cylinder housing 1.

Figure 3 illustrates a section illustrating the interaction of the parts described above. The cross-section of the key 14 is incomplete in that only the guiding grooves 15 which illustrate the actual control function at the respective cross-sectional locations are indicated. Thus, the left side lacks the deeper groove and the right side lacks the two flatter grooves, which will be described later. The key 14 is pressed against the left and right by the two locking pins 16, in particular by the control pins 17. Both locking pins 16 can be displaced upwards in the holes 13. The stubs 18 extend as ribs along the stops 16 and are provided with cutouts 24 into which the locking projections 23 of the locking slide 8 can be inserted. If all locking pins 16 occupy this position on one side of the key 14, the associated locking slide 8 will be displaceable, so that the locking members 9 can rotate into their respective annular grooves 6 when rotating the roll core, thereby further rotating the roll core 3.

If an attempt is made with a non-locking key, at least one of the locking pins 16 will assume an incorrect position so that the locking pins 18 will collide with one or both of the locking projections 23 so that the locking slide cannot be pushed. The closures 9 then engage the annular grooves 6 against the surface 25 of the ribs 34 so that further rotation of the roll core is impossible.

As a further security and variation element, a profile strip 26 is arranged in the lock. This profile strip 26 is located along the keyway in a cavity 27 of the cylinder core 3 and can be displaced radially therein, that is, movable in and out of the key. The profile formation 28 contacts the corresponding profile 29 formed on the back edge (possibly front edge, "beard") of the key 14. Divided along the length of the profile strip 26 are a plurality of raised bumps 30 which are located in the moon-shaped recesses 31 when the key is in the zero position. In this case, the profile profile 28 of the profile 26 is unrelated to the profile 20 of the key 14. When the roll core 3 is rotated, the profile strip 26 is moved towards the rear of the key 14, whereby the profiles are interconnected. If the profiles do not match, the profile 26 will remain with part of its body in the portion 32, thereby causing the profile 26 to abut one of the abutment faces 33 of the ribs 34 between the annular grooves 6. Figures 8 and 9 show a sectional profile 26 in section and view from the keychain. The number of ribs shown is only one of many possible variations. Figure 3 shows the profile strip 26 in its upright position, which in practice is taken up after turning the roll core 3. The depth of the guide grooves 15 and the length of the control pins 17 are the same in the cases illustrated, but in practice, as will be illustrated with reference to Figures 6 and 7, different designs of these dimensions are advantageous.

Figures 4 and 5 show a longitudinal section and a view of the cylinder housing 1 for better understanding. The control opening 20 serves to control the control slider all. The annular grooves 6 are separated by ribs 34. The ribs 34 are interrupted by the grooves 35 and form the surfaces 25, which optionally serve as a stop for the closures. Three of the annular grooves 6 have recesses 31 formed in the shape of an moon, in which the ridges 30 run, whereby the profile strip 26 is pressed inward against the backside of the key. The groove 36 allows the profile strip 26 to be inserted into the cavity 27 of the roll core 3 during installation.

Figure 6 illustrates a side view of a key, such as can be inserted into a lock shown in Figures 1-5. The key shank is provided with a recess 22 for receiving the guide slide 11 on the flat side 37 shown. From the tip 38 of the key, three guiding grooves start in accordance with the guiding grooves 15 described above. The two guide grooves 39 run parallel to each other and are formed at relatively shallow depths.

HU 215,769 Β

The third control groove 40 is deeper and thus intersects the other two control grooves 39. There are two types of stopcocks 16 as illustrated in Figure 3. One type of locking pin has a longer control pin 17, which is guided by the deeper control groove 40. The other type of stopcock is provided with two shorter control pins 17, which are guided by the two control grooves 39. In Figure 6, the parallel guide pins 17 of the locking pins are marked with circles.

Different key variations can be created by providing different running paths for the three control grooves 39 and 40.

Preferably, the key is formed as a reversible key, which means that the other flat side of the key is formed so that even when the key is rotated 180 °, it has the same image as shown in Figure 6.

The tip 38 of the key is shaped like a swallowtail. The lower control grooves 39 extend all the way to the two ends of the key, while the deeper control grooves 40 extend from the base of the dovetail cutout. This ensures that the control pins 17 of the locking pins 16, irrespective of their accidental resting position, enter the respective control pits.

On both key edges (on the backside of the key), the formed profile formation is symmetrical according to the principle of the reversible key, where the profile formation can be selected from many different profile variations.

The profile formation is preferably inclined, which makes the imitation significantly difficult.

Two transverse grooves 41 are formed near the tip 38 of the key, into which the spring cams arranged in the cylinder core 3 snap into place. The snap of these spring-loaded pins indicates that the key is fully inserted into the keyway.

Due to the arcuate shape of the cylindrical body slice of the cutouts 22 shown in Fig. 2, only a relatively thin rib is left here in the direction of the longitudinal center plane of the key. The depth of the cutout 22 corresponds to the required stroke of the control slide 11. However, the cut-out 22 may cover only a limited part of the key height, otherwise the key would be broken in that part. This key is an additional security feature. Preferably, the height 44 of the recess 22 is more than 50% of the height of the key shank 45.

At the apex 38 of the key is the base point 46 of the dovetail cutout 47 in the longitudinal axis of symmetry 48 of the key, from which the deeper guide groove 40 extends on each side of the key.

The two side panels 49 also guide the control pins 17 of the locking pins 16 into a symmetrical position from where the lower depth parallel control blades 39 start.

It may be added to the operation of the lock that the control slider 11 causes the slider 8 to be offset. All control sliders can be made of hardened steel or other hard metal for minimal wear. The shifting is facilitated by the oblique cut-outs of the closures 9 (see Fig. 1), which slide at the entry edges of the ribs 34 between the annular grooves 6. The wear of these oblique cuts can be effectively prevented. Fig. 10 shows a view of the lock according to the invention in an analogous manner to Fig. 1, where a modified embodiment of the lock pusher 8 is used. All. Fig. 3A is a sectional view of the corresponding side view.

The modified locking slide 50 is displaceable not in the axial direction but in the radial direction and is made in one piece with the control slide 51 having the same function as the control slide 11 described above. The locking slide 50 is either pushed into the cylinder core 3 along its entire length, or, if a suitable key is used, in the radial displacement, prevents the longitudinal protruding rib 52 from standing in front of a longitudinal groove of the cylinder housing 1 rotation. Preferably, the locking slide 50 may be entirely made of a hard metal to provide protection against drilling. Both extensions 53 serve to further guide the control slide. The dashed bores 54 open inwardly toward the material of the cylinder core and serve to receive compression springs so that the locking slide 50 is extended outwardly toward the cylinder housing.

All. In FIG. 4A, the mode of operation of the locking slide 50 is shown. The figure illustrates a state where the corresponding key is inserted into the lock and is already slightly turned so that the locking slide 50 is pushed into the roll core along its entire length. The ribs 34 of the annular grooves are interrupted by an axial groove 55 on the inner surface of the cylinder housing, thereby providing adequate protrusion for the protruding rib 52 of the locking slide 50. The depressed position of the locking pusher 50 is illustrated by the fact that each locking pin 16 takes up the correct position, as described above, and the key has corresponding recesses 22.

When the roll core returns to the zero position, the compression springs 56 push the locking slide 50 outward in the direction of arrow 57. The rib 52 thus extends into the axial groove 55 and the ribs 34 between the annular grooves 6 can prevent rotation of the roll core. This obstruction occurs either when there is no etch 22 or if it is not deep enough, or if one of the locking pins 16 is in an incorrect position.

Claims (10)

PATENT CLAIMS Cylinder lock having control means with actuating means extending into a key channel and contacting the control sockets of a key inserted in the key channel and having at least one control element having two control means arranged on at least one side of the key socket, they extend through one opening of the roll core to the keyway and engage the less deep control grooves of the key inserted into the keyway, and on the same side of the keyway there is arranged a control element having a second length dimension through another opening of the key4 EN 215 769 Β and is connected to the deeper control opening of the key inserted into the keyway, the first length being smaller than the second length, and at least one locking member arranged to allow the control members to rotate in the cylinder lock characterized in that the locking member is formed as a displaceable locking slider (8) in the groove of the roll core (3), which has locking elements (9) which extend into a groove (35) of the roll housing (1) (1) are formed by annular grooves (6) open in the direction of the roll core (3), into which the locking elements (9) extend when the roll core (3) is turned. Cylinder lock according to Claim 1, characterized in that a control slide (11) is arranged in the cylinder core (3) which is slidably inserted into the cylinder core (3) through the control opening (20) of the cylinder housing (1) and a section (12). ) has an inclined contact surface (42) for displacing the locking slide (8) and one end of the guide slide (11) extends into the key cut-out (22). Cylinder lock according to Claim 1, characterized in that the cylinder core (3) is provided with a locking slide (50) which is integrally formed with the control slider (51) and is radially inserted into a groove (7) of the cylinder core (3). formed, and one end of the guide slide (51) is also retractable into a key cutout (22), and the locking slide (50) extends into an axial groove (55) of the housing (1) and is spring-pressed when rotating the roll core (3). it has a protruding rib (52) which allows it to be rotated radially so as to allow further rotation of the roll core (3). Cylinder lock according to Claim 1 or 3, characterized in that the cylinder core (3) is guided by the recesses (31) of the cylinder lock (1) along the key hole and on the rear edge (or front edge, "beard") of the key. a sliding profile strip (26) having a profile formation (28) adapted to the formed profile. Cylinder lock according to Claim 4, characterized in that the profile formation (28) is inclined with respect to the central plane of the profile strip (26). 6. Flat wrench having on its lateral surfaces, at a distance from the rear edge, guiding grooves and, where appropriate, additional guides, such as the front edge of the key, "beard" cuts, guides and grooves in the rear edge and longitudinal direction of key penetration, at least one of the two flat side surfaces having at least three guide grooves and at least one of them being formed deeper than the other two control grooves and the two less deep control grooves arranged parallel to each other, characterized in that at least one flat side surface of the key 11) is provided with a recess (22) suitable for receiving and at least one of the rear or front edges having an inclined profile (28) which fits into a profile (26) arranged in the cylinder lock. A flat key according to claim 6, characterized in that a cut-out (22) is formed on both flat side faces of the key to a depth approximating the center plane of the key, wherein a tapered portion of key material remains between the bottom faces of the cutouts. Flat key according to claim 6 or 7, characterized in that the height of the cutout (44) is more than 50% of the height of the key shank (45). 9. A 6-8. Flat key according to any one of claims 1 to 4, characterized in that the key tip (38) has a dovetail cut-out (47) in a manner known per se and that the starting point of each guide groove (39,40) is symmetrical to the longitudinal axis of symmetry (48). 10. A 6-9. Flat key according to any one of claims 1 to 3, characterized in that the key is designed as a reversible key.