CZ2003457A3 - Cylinder-type lock and key? - Google Patents

Abstract

In the present invention, there is disclosed a cylinder-type lock comprising a cylinder lock body (2), a cylinder (6), which can be rotated by the key (9), tumblers (4) and (15), first blocking pin (3) and blocking pins (14) and springs (8), in which cylinder-type lock at least in one, advantageously in the first hole (1) performed in the cylinder lock body (2) there is arranged the first blocking pin (3) contacting the tumbler (4) placed in the hole (5) of the cylinder (6), whereas the sum of length of the blocking pin (3) and tumbler (4) length is such that during overcoming the spring (8) resistance and during contact of the first blocking pin (3) with the hole (1) bottom, a frontal cone of the tumbler (4) reaches up to a key hole (7) in the cylinder (6) in such a way, that the width of the key hole (7) is restricted thereby at the spot of the tumbler (4) frontal cone. The key (9) has its own individual codes (10) at a level of its contact surfaces (11) interconnected by a path (12) and a leading surface (13) of the key (9) has a width that allows reciprocal movement of the key (9) to the key hole (7) along the frontal cone of the tumbler (4).

Description

Key operated cylinder lock with linearly generated codes

Technical field

The invention relates to the field of lock technology, in particular cylindrical lock inserts operated by flat keys, whose codes on the side surfaces form a series of dimples and the codes on the edges form a series of slots.

BACKGROUND OF THE INVENTION

Known and most widespread cylindrical lock cylinders are made up of a lock cylinder body, a key-rotated cylinder and tumblers, locking pins, possibly pedestals and springs. The cylinder is controlled by a flat key, whose codes are formed as a series of dimples on the side surfaces of the key or as a series of cutouts on the edges of the key, or as a combination of both. The disadvantage of such assembled cylindrical lock cylinders is that they are easily overcome by using the dynamic impact unlocking method. This method, known as the SG effect, consists in that a tool is first created in such a way that codes or cut-outs are created in the key blank or in a type-like key in the number of tumblers and at their pitch. The codes on the tool have the same shape and depth as the deepest for a given cylinder lock type. The tool thus adjusted is pushed into the cylinder as far as it will go, brought back by at least one code pitch and is pushed back to the stop by a direct blow to the tool. The inclined surface of the cut-outs or dents of the tool strikes the tumbler's front cones against the locking pins and against the springs. When the tumblers and locking pins are reversed, a gap is created between the tumblers and pins due to differentially distributed forces and different weights of the tumblers and pins, which allow the cylinder to rotate at the same time in the shear plane.

SUMMARY OF THE INVENTION

The known disadvantages of cylindrical lock cylinders are eliminated by a key-operated lock cylinder with linearly formed codes according to the invention, which consists of a lock cylinder body, a key-rotated cylinder, tumblers, locking pins and springs. The principle of the technical solution consists in that in at least one, preferably in the first opening formed in the body of the lock insert for the locking pin, there is a locking pin adjoining the tumbler located in the tumbler opening in the cylinder of the lock insert. When the key is inserted into the key hole in the cylinder to the position where the cylinder can be rotated, the spring resistance is overcome, the tumbler and the locking pin are pressed all the way. The locking pin rests on the bottom of the hole. The sum of the length of the locking pin and the length of the tumbler is such that the tapered front cone extends into the keyhole in the cylinder such that the transverse dimension of the keyhole is limited by at least 0.1 mm at the tumbler and

dimension. The key is formed in such a way that its individual codes are interconnected at the level of their bearing surfaces with a path which is preferably created by the same tool by which the individual codes are created by its linear displacement. The key can be inserted into the key hole because the leading surface of the key is smaller than the transverse dimension of the key hole, allowing the key to slide into the key hole along the taper of the tumbler. The path created between the codes at any of its points does not exceed the plane of the lead-in surface, so that it also does not prevent the insertion of the key.

Attempting to rotate the cylinder described by the SG effect will cause the following situation. If a tool of the same type is used to make the tool, the tool will not pass through the taper face of the tumbler into the key hole. The tool must therefore be further machined to a dimension allowing the key to pass into the key hole. This reduces the lead-in area for all tool codes and the SG effect cannot be achieved. If a tool of the same type with the codes already created should be used to produce the tool, so that the codes should be deepened to the deepest code, it cannot be done. This is prevented by the lack of material for creating the lead-in surface of the tool codes where they are created between the path key codes.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 shows a cylinder lock cylinder operated with a key with linearly generated codes, in the basic position, with the key inserted and the separation plane between the cylinder and the lock cylinder body released.

FIG. 2 shows a key operated cylinder lock cylinder with linearly formed codes, with the key partially inserted, with the lead-in surface of the key passing along the front cone of the tumbler. The separation plane between the cylinder and the lock cylinder body is blocked

FIG. 3 shows a key operated cylinder lock key with linearly generated codes

Exemplary embodiment

An embodiment of the invention can be seen from Figs. 1 to 3. The cylinder 6 is operated by a flat key 9 with linearly formed codes 10, on the side surface of the key 9. The codes 10 are formed as dimples by the same rotary machining tool as tracks 12 connecting the bearing surfaces. 11, the code 10. This removes the inner conical faces of the codes 10 shown in FIG. 1 and FIG. 3 by a broken line. The running surface 13 of the functional side of the key 9 has a smaller dimension than the narrower transverse dimension of the key hole 7, allowing the key 9 to slide into the key hole along the front cone of the tumbler 4. The track 12 does not extend beyond the plane of the leading surface 13 at any of its points, so that it also does not prevent the key 9 from being inserted into the key hole along the front cone of the tumbler 4.

Along the entire working path of the key 9, from the first code 10 to the end of the lead-in surface 13, the dimension of the key 9 is reduced compared to the transverse dimension of the key hole 7. Shown in thinner solid line in Fig. 3.

In the first opening 1 formed in the lock cylinder body 2, there is a spring-loaded locking pin 3. In other openings formed in one plane in the lock cylinder body 2, the spring-loaded locking pins 14 are located. The tumbler 4 is located in the other holes formed in the same plane in the cylinder 6, in the same number and at the same spacing as the locking pins 14. The sum of the length of the locking pin 3 and the length of the tumbler 4 is such that into the key hole 7 in the cylinder 6 such that the transverse dimension of the key hole 7 is limited by 0.3 mm at the tumbler 4 by its front cone. At least by this value, the dimension of the key 9, in this case its thickness, is reduced in its functional path from the first code W to the end of the lead-in surface.

13.

Fig. 2 shows the insertion of the key 9 into the key hole 7 in the cylinder 6 in a position where the lead-in surface 13, by being dimensionally adapted, allows a tight sliding movement of the key 9 into the key hole 7. The spring resistance 8 is overcome and a locking pin 3 to the bottom of the first opening 7. Upon further sliding of the key 9, the tumblers 15 are pushed against the locking pins 14 and the springs 8 until the codes 10 are aligned against the tumbler 4 and the corresponding tumblers 15 and all tumblers touch the bearing surfaces 11. The contact surface between tumbler 4 and locking pin 3 and tactile the surfaces between the tumblers 15 and the locking pins 14 at this time coincide with the dividing plane between the lock cylinder body 2 and the cylinder 6 can be rotated. This is illustrated in Fig. 1.

When attempting to rotate the cylinder 6 described by the SG method, the effect occurs as follows. If a tool of the same type of key of the same size as the key hole 7 is used to make the tool, the tool will not pass into the key hole 7 through the taper of the tumbler 4. The tool must therefore be further machined to a dimension permitting this passage. This reduces the lead-in surfaces for all tool codes, and the SG effect can no longer be achieved. If a tool of the same type with the codes already created should be used to produce the tool, so that the codes should be deepened to the deepest code, it cannot be done - keys of the same type no longer have material to create the tooling faces which could bounce the tumblers in a stroke.

Claims (1)

Key operated cylinder with linearly formed codes consisting of a cylinder body, a key-operated cylinder, tumblers, locking pins and springs, characterized in that at least one, preferably a first opening (1) formed in the cylinder body (2), a locking pin (3) adjoining the tumbler (4) is disposed in the bore (5) of the cylinder (6), the sum of the length of the locking pin (3) and the tumbler length (4) being such that (8) and when the locking pin (3) contacts the bottom of the bore (1), the tapered front taper (4) engages the keyhole (7) in the cylinder (6) so that the transverse dimension of the keyhole (7) is at the front The taper of the tumbler (4) is thereby limited by at least 0.1 mm and at most by one half of its own dimension and the key (9) is formed such that its individual codes (10) are at the level of their bearing surfaces (11) between The keyway (9) has a dimension allowing the key (9) to slide into the keyhole (7) along the front cone of the tumbler (4) and the track (12) does not exceed at any of its points the plane of the leading surface (13).