EP0330803A2 - Cylinder for a safety lock - Google Patents

Abstract

The rotary lock cylinder has a cylinder core (3) and a housing (1), hardened spring-loaded housing pins (4) and core pins (5) being mounted in radially extending bores. By means of a key to be inserted into the key channel (8), the tumbler pins (4, 5) are arranged so as to allow the rotation of the cylinder core (3). The cylinder core (3) has, in bores (10), pins (11) made of hardened steel which extend in the longitudinal direction of the cylinder core (3). The pins (11) are so arranged that, when a screw is screwed in, it is guided on the pins (11) and the core pins and housing pins (5, 4) are thereby pressed into the cylinder housing (1) to the extent of a spring block. When the screw is rotated further, the thread flights on the hardened tumbler pins (5) are peeled off. As a result of this measure, the screw has no hold in the cylinder and therefore cannot tear the cylinder or pull the core (3). <IMAGE>

Description

Rotary lock cylinders of this type are generally known and have proven themselves and have found widespread use. A break-in method has now become known in which a self-tapping and hardened steel screw with a diameter of approximately 4 mm and with a hexagon head is screwed into the cylinder core of such a rotary lock cylinder. With a pulling device, for example according to DE-OS 3 711 938, the screwed-in screw is pulled out of the cylinder housing together with the cylinder core and the now exposed driver is rotated with a screwdriver and the lock is thus opened. To prevent this break-in method, claws can be attached to the inner end of the cylinder core and the cylinder core can be coupled to the driver. However, it has been shown that as a result the extraordinarily high tensile force of the puller, such a cylinder core can be easily pulled out of the cylinder housing. It is much more effective to provide the cylinder core with a radially projecting shoulder at one end in a rotary lock cylinder made up of assembled cylinder parts and to insert this from behind into the housing opening. However, this is not possible with a double lock cylinder with a one-piece cylinder housing, since the cylinder core can only be inserted from the front.

The invention has for its object to provide a rotary lock cylinder of the type mentioned, in which the burglary method mentioned is ineffective and which is still functional and can be produced inexpensively. The object is achieved by the invention according to claim 1. With the rotary lock cylinder according to the invention, it is as possible possible to screw a hardened steel screw into the cylinder core. Here, however, the threaded part of the guided screw is sheared off by the pins and / or the core pins. If the pulling device is now pulled on the screw, there is no hold in the cylinder core and is pulled out of it, the cylinder core remaining in the housing. If the screw is screwed in too close to the core pins in the cylinder core, the tumbler pins in their holes are pushed radially outwards by the screw. However, this leads to a complete blocking of the rotary lock cylinder, since the Anchored outside core pins anchor the cylinder core in the cylinder housing. It is therefore essential that the pins are arranged in such a way that when a screw is screwed in, the screw is guided on these pins and the core and housing pins are thereby pressed onto the block in the cylinder housing. When the screw is turned further, the threaded cheese on the hardened tumbler pins is peeled off. As a result of this measure, the screw has no holding strength in the cylinder and therefore cannot tear the cylinder or pull the core.

If the rotary lock cylinder has several rows of tumblers, as is usually the case with rotary lock cylinders for flat keys, the pins extend in the longitudinal direction of the cylinder core, two or four pins being provided, depending on the arrangement of the tumbler rows. In a rotary lock cylinder for a so-called serrated key, the pins are preferably inserted into the cylinder core in such a way that they run perpendicular to the longitudinal axis of the cylinder core and parallel to the tumbler pins. Several pairs of pins are preferably arranged at a distance from one another. If the distances between the pairs of pins are different, the security is increased that when the screw is screwed in, its threaded part is sheared off by the pins. If there are only two pins, there is a risk that they will not damage the threaded part of the screw, but on the contrary give the screw additional hold. Of course, an attempted break-in also fails if the Screw is partially screwed into the housing while avoiding contact with the pins.

The development according to claims 5 to 9 reinforces the locking cylinder in the area of the web and at the same time prevents the web from being weakened with a drilling tool and being torn apart with the aforementioned break-in method of the double cylinder. If the double cylinder can be separated in the area of the faceplate screw, the pins anchored in the cylinder housing prevent the bridge of the cylinder part from shearing off on the long plate and the cylinder part from being pulled out of the door.

• Fig. 1 einen Querschnitt durch einen erfindungsgemässen Dreh­schliesszylinder,
• Fig. 2 eine Ansicht eines Zylinderkerns nach einer Variante,
• Fig. 3 einen Schnitt durch den Zylinderkern entlang der Linie III-III in Fig. 2,
• Fig. 4 einen Teilschnitt durch einen Doppelzylinder, und
• Fig. 5 einen Teilschnitt entlang der Linie V-V in Fig. 4.

Exemplary embodiments of the invention are explained in more detail below with reference to the drawing. Show it:

• 1 shows a cross section through a rotary lock cylinder according to the invention,
• 2 is a view of a cylinder core according to a variant,
• 3 shows a section through the cylinder core along the line III-III in FIG. 2,
• Fig. 4 is a partial section through a double cylinder, and
• 5 shows a partial section along the line VV in FIG. 4.

The rotary lock cylinder shown in Fig. 1 is a double cylinder with two cylinder housings 1, which are connected to each other by means of a web 2 made of hardened steel. However, the rotary lock cylinder can also be a simple cylinder. In the cylinder housing 1, a cylinder core 3 is rotatably mounted in a known manner, which has a key channel 8, in which a key, not shown here, is used to actuate the lock. The tumbler rows of core pins 5, housing pins 4, springs 6 and chamber walls 7 are arranged with the key. The core pins 5 are made of hardened steel, while the housing pins 4 can be made of brass. The rotary lock cylinder shown has a so-called Euro profile, but other profiles are also possible here.

The cylinder core 3 has four blind bores 10 which are open to the rear and which run parallel to its axis of rotation and are inserted into the pins 11 made of hardened steel with a fixed fit. The pins 11 have a diameter of approximately 2 mm and extend approximately over the entire length of the cylinder core 3. It is essential that, in the arrangement shown in FIG. 1, the two lower pins 11 are at a distance from one another which is smaller than approximately 3 , 2 mm and preferably less than 3.0 mm. The distance B between said pins 11 and the closest core pins 5 is preferably less than about 0.6 mm. With this arrangement, when a screw is screwed into the cylinder core 3, the threaded part on the latter by the pins 11 guiding the screw and / or the radially outward position pushed core pins 5 sheared, so that the cylinder core 3 can not be pulled out of the cylinder housing 1 even when the screw is well seated.

Depending on the number and arrangement of the tumbler rows, two pins 11 may suffice, but generally no more than four pins 11 are required.

If, as shown in FIGS. 2 and 3, the rotor has only one tumbler row in a cylinder core 12 with a profiled key channel 13, then, as shown in FIG. 2, a plurality of pins 20-24 can also be used, which are perpendicular to the axis of rotation of the cylinder core 12 extend. The pins 20 to 24 are inserted with a tight fit in bores 15-19 arranged in pairs which, as shown in FIG. 2, are each arranged between two bores 14 for the tumbler pins. It is also important here that the distances between two associated pins 20 to 24 are less than about 3.2 mm. The distances may be the same or, as shown in FIG. 2, distances D and E may be different.

In the double cylinder 40 shown in FIGS. 4 and 5, hardened steel pins 32 are additionally used in bores 31 of a web 30, which prevent the web 30 made of brass from shearing off. The pins 32 extend inside into the cylinder housing and on the end face up to close to the outer surface of the cylinder core. There is one on both sides Threaded bore 34 or the driver 33 each arranged at least one steel pin 32.

The above information thus results in rotary lock cylinders which, despite the considerably higher locking security, are only marginally more expensive than the conventional rotary lock cylinders, so that rotary lock cylinders according to the invention were created which not only take account of the safety requirements in an outstanding manner, but are also inexpensive due to their simple design and are reliable.

As is easily understood, details can be modified in different ways in adaptations to other cylinder types. In particular, the diameter of the pins 11 and 20 to 24 can also be greater than 2 mm, depending on the size of the rotary lock cylinder.

Claims (9)

1. Rotary lock cylinder for a security lock, spring-loaded pin tumblers 4, 5, 6) are mounted in bores running radially to a cylinder core (3, 12) and a cylinder housing (1), which are inserted by a key into the key channel (8) for the release of expansion of the cylinder core (3, 12) can be set, characterized in that at least two hardened steel pins (11; 20-24) are inserted in the cylinder core and arranged in such a way that they have a steel screw with a diameter of at least to be screwed into the cylinder core to pull it out leads about 3 mm and this is processed on the circumference by the steel pins (11; 20-24) and / or by pin tumblers (4, 5, 6) pressed radially outwards. 2. Rotary lock cylinder according to claim 1, characterized in that hardened steel pins (11) are used in the cylinder core (3), which extend approximately in the longitudinal direction of the cylinder core (3) and which are at a distance (A) from one another which is not greater than approximately Is 3 mm. 3. Rotary lock cylinder according to claim 2, characterized in that the pins (11) are arranged to the left and right of the key channel (8) and that the distance (B) of these pins (11) to the closest core pins (5) is selected so that that a screw with a diameter of about 4 mm, which is screwed into the key channel (8) between the pins (11), pushes the core pins (5) radially outward into the closed position. 4. Rotary lock cylinder according to claim 2 or 3, characterized in that the distance (B) between the pins (11) and the closest core pins (5) is not greater than about 0.6 mm. 5. Rotary lock cylinder according to claim 1, characterized in that the pins (20-24) run approximately perpendicular to the longitudinal direction of the cylinder core (3) in this, and that several pairs of such pins are arranged one behind the other seen in the longitudinal direction of the cylinder core. 6. Rotary lock cylinder according to claim 5, characterized in that the distances (D, E) between the pin pairs are different. 7. Rotary lock cylinder according to one of claims 1 to 6, wherein this is a double cylinder with a web connecting the two cylinder halves (30), characterized thereby characterized in that hardened steel pins (32) are used in bores (31) of the web (30), which extend into the cylinder housing (1). 8. Rotary lock cylinder according to claim 7, characterized in that the steel pins (32) run perpendicular to the longitudinal direction of the rotary lock cylinder in the web (30). 9. Rotary lock cylinder according to claim 8, characterized in that at least one steel pin (32) is arranged on both sides of the threaded bore (34) for the faceplate screw.

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