DE29618653U1 - Pin tumbler in a rotary lock cylinder - Google Patents

Abstract

This invention concerns a pin tumbler consisting of housing pin (5, 20, 25), a core pin (6) and a compression spring (7) which is seated in the housing (3) of the rotating lock cylinder (1), against the force of which the pin tumbler (4) releases the cylinder core (2) with the rotational movement of the key introduced into the key channel (15). The housing pin (5, 20, 25) has a recess around its circumference directly behind the face (11) which abuts the core pin (6), in such a way that an edge (16) with an acute angled cross section is formed. The housing pin (5) locks securely even with a small progressive step of for instance 0.5 mm.

Description

Patent attorneys

Dr. Loesenbeck (1980) .: ^# * .:.\. ^: * .\' ^:: ., ^:

Dipl.-lng. Stracke &igr;

Dipl.-lng. Loesenbeck

JöilenbeckerStr, .164-33613 Bielefeld MGi27/e _P Poetfach 101882 · 33518 Bielefeld

Ernst Keller 8805 Richterswil

Pin locking in a rotary lock cylinder

The invention relates to a pin tumbler in a rotary locking cylinder for a security lock, with a housing pin and a core pin and a compression spring mounted in the housing of the rotary locking cylinder, against the force of which the tumbler can be arranged by means of a radial displacement to release the cylinder core from rotating with a key that is inserted into the key channel.

Tumblers of this type have long been known in numerous designs in high-quality rotary lock cylinders. Such a tumbler in a rotary lock cylinder is known, for example, from the applicant's EP-A-O 646 689. To release the cylinder core from rotation, these tumblers are lifted and positioned using a key that is inserted into the keyway, with the surfaces of the housing pin and the core pin that are in contact with one another lying on the shear line of the rotary lock cylinder. The housing pin is also called the counter bolt.

Tumblers can lock positively or negatively. With a negative locking, the housing pin locks by engaging in the hole in the cylinder core. With a positive locking, however, the core pin engages in the hole in the housing and thus locks the rotary lock cylinder. Such an engagement takes place in one or more increments. In order to increase the combinatorics and thus the number of locking variants,

Very small step increments are used, with the smallest permissible step increments being in the range of 0.35 to 0.5 mm.

If a locking system is only set up with positive locks, it is possible to identify a master key from several individual keys lying next to each other, which should not be possible from a security point of view. However, if positive and negative are combined, the locks are completely concealed, so that a master key cannot be identified even by a specialist. This type of concealment significantly increases the security value of a locking system.

When setting up a high-quality locking system, it is therefore very important that the division into main groups, groups and individual locks is calculated using positive and negative locking.

The small step changes mentioned above cause few problems with precisely manufactured locking cylinders with small core and housing play and positive locking. However, if a negative locking with only one step change comes into effect, the locking cylinder can be pushed through easily with an individual key that does not belong to this group and can therefore be opened with this unauthorized key. A step change of 0.5 mm is therefore not enough to lock the cylinder core. When pushed through, material from the cylinder core is pushed away and the cylinder core is damaged. The rotary locking cylinder with the damaged cylinder core can now be opened easily at any time with the unauthorized individual key. In some cases, the housing pin is lifted out of the hole without significantly damaging the cylinder core. To prevent this, a step change of at least 0.9 mm was previously necessary for a secure negative locking.

The invention is based on the object of creating a locking device of the type mentioned, which avoids the disadvantages mentioned.

and which offers a high level of safety even with a step change of less than 1 mm and negative locking.

The task is solved in a pin tumbler of the type in that the housing pin is recessed on its circumference immediately behind its front side that rests on the core pin, in such a way that an edge with an acute-angled cross-section is formed. The invention has the effect that with a small step change and negative locking, the housing pin tilts when force is applied in the housing bore and the edge digs into the cylinder core. The digging in prevents the housing pin from being lifted out of the bore. Tests have shown that the housing pin cannot be pushed away even if the key is turned with around 12 N until it breaks. The greater the torque, the more the housing pin digs into the cylinder core on its inner edge. In a rotary lock cylinder with tumblers according to the invention, negative locking with a step change significantly smaller than 1 mm is therefore also possible and withstands an unauthorized attempt to unlock it.

Further advantageous features emerge from the dependent patent claims, the following description and the drawings.

An embodiment of the invention is explained in more detail below with reference to the drawing.

Figure 1 shows a section through part of a rotary locking cylinder with a locking mechanism according to the invention,

Figure 2 shows schematically the position of the inventive locking device according to Figure 1 exerting a torque on the cylinder core,

Figure 3 shows a housing pin in a greatly enlarged view,

9 9 ··

Figures 4 and 5 show a view and a section of a variant of a housing pin of the tumbler according to the invention, and

Figure 6 shows another embodiment of a housing pin.

Figure 1 shows a known rotary locking cylinder 4 with a cylinder core 2, also called rotor, and a housing 3, also called stator.

A tumbler 4 is mounted in radial bores 8 and 9 of the cylinder core 2 and the housing 3, respectively, which has a core pin 6 and a housing pin 5. The tip 6a of the key pin 6 engages in a key channel 15 and rests against further core pins 6' and ^6'11 . The core pins 6' and 6'' belong to tumblers which can be constructed in the same way as the tumbler 4, but are mounted transversely to it in the locking cylinder 4.

The tumbler 4 and the other tumblers not shown here are arranged by inserting the shaft of a key not shown here into the channel 6. The tumblers 4 are raised radially outwards in the direction of the line 15 against the reaction force of a compression spring 7 until the cambered surface 12 of the core pins 6 have reached the shear line 10 between the housing 3 and the cylinder core 2. The core pin 6 and the housing pin 5 complement each other in length. The housing pins 5 are therefore of different lengths, with the shortest housing pin 5 having a length of approximately 0.65 mm. Such a housing pin 5 never locks negatively.

In the arrangement according to Figure 1, the housing pin 5 locks negatively, i.e. it engages with the length of a step S of, for example, 0.5 mm in the bore 8 of the cylinder core 2. The front side 11 of the housing pin 5 is pressed against the front surface 12 of the core pin 6 by the pressure of the spring 7.

As shown in particular in Figure 3, the housing pin 5 is provided with a recess 13 immediately behind its front face, which extends around the entire circumference of the housing pin 5. This recess 13 means that the housing pin 15 has a comparatively sharp front edge 16. Behind this edge 16, the diameter decreases continuously along a conical surface 14 to an inclined shoulder 17. The angle β between the surface 14 and the shoulder 17 is approximately 105°. The angle α between the front face 11 and the conical surface 14 is less than 90° and preferably greater than 60°. The preferred angle α is between 85° and 65° and is preferably approximately 75°. The diameter A of the housing pin 5 is slightly smaller than the diameter of the bore 9 and is, for example, 2.97 mm. The length B of the housing pin varies, but is at least about 0.65 mm. The distance C between the front surface 11 and the shoulder 17 is slightly larger than a step S and is here about 0.75 mm. As can be seen, the recess 13 is not very deep and in no way weakens the housing pin 5.

If the cylinder core 2 is now turned clockwise in the direction of arrow 18, the housing pin 5 tilts as shown in Figure 2 and the comparatively sharp edge 16 digs into the cylinder core 2 at the point marked P. If the torque is increased, the housing pin 5 is not lifted out of the bore 8, but rather digs further into the cylinder core 2, which is made of comparatively soft material, with increasing force and thus cannot be pushed radially outwards. By tilting the housing pin 5, the distance between the edge 16 attached to the bore 8 and the shear line 10 is increased. The distance between the shear line 10 and the point P is thus significantly greater than the step S. The correspondingly large material thickness makes it difficult to push away the material of the cylinder core 2 lying above the point P and thus to remove the lock. This is not possible even with a force of around 12 N, which is usually enough to break a key. The housing pin is made of

hard material, in particular hardened steel, and is not significantly weakened at its inner end by the recess 13.

The recess 13 can also be designed differently and the surface 14 does not necessarily have to be conical. What is important, however, is that the edge 16 is comparatively sharp and can dig into the cylinder core as explained above and thus fix itself in the bore 8. The recess 13 can be produced cost-effectively by undercutting or undercutting.

Above the conical surface 14, the housing pin 5 has a cylindrical wall 19, with which the housing pin 5 is guided in the bore 9 of the housing 3 so that it can move radially. It is not necessary for all the locking mechanisms of a rotary lock cylinder to be designed as explained above. Preferably, however, all the housing pins 5 that engage in the cylinder core and lock negatively are provided with a recess 13. The shorter housing pins 5 with a length of approximately 0.65 mm can be designed as usual.

Figures 4 and 5 show a housing pin 20 according to a variant, which is provided with the recess 13 explained above. The housing pin 20 consists of a hardened body 23, into which a softer part 24 is inserted, which, as can be seen, has a protruding conical projection 24a. The compression spring 7 can be attached to this projection 24a in a simple manner by pressing the conical end 24a together like a rivet after the compression spring 7 has been placed. The compression spring 7 and the housing pin 20 then form a unit, which makes assembly much easier.

Figure 6 shows another version of a housing pin 25. This is again provided with a recess 13. The fastening of the compression spring 7 to the housing pin 1.5 is carried out here by means of a groove 17, into which end turns 28 of the compression spring 7 are clipped. The compression spring 7 is, as can be seen, double-conical, so that it essentially corresponds to the wire diameter.

can be compressed. The compression spring with the housing pin 25 can thus be accommodated in a comparatively short bore 9 of the housing 3.

Claims (7)

♦ · Pet Claims 1. Pin tumbler in a rotary lock cylinder (1) for a security lock, with a housing pin (5, 20, 25) and a core pin (6) and a compression spring (7) mounted in the housing (3) of the rotary lock cylinder (1), against the force of which the pin tumbler (7) is to be arranged by means of a radial displacement in order to release the cylinder core (2) from rotation using a key to be inserted into the key channel (15), characterized in that the housing pin (5, 20, 25) is recessed on its circumference immediately behind its end face (11) resting on the core pin (6), such that an edge (16) with an acute-angled cross-section is formed. 2. Pin tumbler according to claim 1, characterized in that the recessed surface (14) is a conical surface. 3. Pin tumbler according to claim 1 or 2, characterized in that the housing pin (5, 20, 25) has a comparatively sharp edge (16) at its inner end. 4. Pin tumbler according to one of claims 1 to 3, characterized in that the compression spring (7) is firmly connected to the housing pin (20, 25). 5. Pin tumbler according to one of claims 1 to 4, characterized in that the housing pin (5) is undercut or underturned on its circumference. 6. Pin tumbler according to one of claims 1 to 5, characterized in that the housing pin (5) is recessed behind its front face (11) such that the edge angle (α) of the front face is 85° to 65°, preferably approximately 75°. 7. Pin tumbler according to one of claims 4 to 6, characterized in that the compression spring (7) is attached to a soft projection (24a) of the housing pin (5).