DK161775B - CYLINDERLASE DETERMINATION BODY - Google Patents

Description

DK 16 1775 B

i \

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a fastener for securing a lock cylinder in thin-walled doors, drawers or similar parts which must be lockable, especially in metal cabinets or boxes, where the lock cylinder housing or a sleeve accommodating the lock cylinder housing is passed through a recess and snap lock with the back of the part to be locked.

For fixing lock cylinder housings in thin-walled doors or the like, it is known to use a specially made steel spring which is bent into annular shape and inserted into a groove in the cylindrical part of the lock cylinder housing 10. The annular steel spring is formed with protruding springs which, when the lock cylinder housing is inserted through the recess in the part to be lockable, engage snap-locking with its rear. This known method of attachment is complicated, with the annular steel spring being an additional separate structural member 15 which is relatively complicated to manufacture. Furthermore, in order to secure this structural part, a ring groove must be formed in the lock cylinder housing, and in addition it must be secured against rotation in relation to the lock cylinder housing. Furthermore, the placement of the steel spring requires an additional mounting step.

The object of the invention is therefore to provide a fastening means which unnecessarily separates, i.e. separate structural members for obtaining the snap-locking engagement with the part to be lockable, while at the same time providing a more secure attachment to the part to be locked, and furthermore is inexpensive to manufacture.

This object is solved according to the invention in that the lock cylinder housing or a bushing which accommodates it has in a piece of resiliently resilient tongues formed therein, which at their free end has a radially inclined surface in a plane which cutting the longitudinal axis of the housing and the bushing respectively at an angle where the angle deviates from 90 ° and the intersection point of the longitudinal axis is displaced in its direction with respect to the inclined surfaces and the inclined surfaces are resiliently supported on the edge between the limiting surface of the recess and the back of the part to be locked. and runs in parallel therewith.

The advantage of this design is that no additional structural member is to be manufactured and / or mounted for securing the lock cylinder housing or bushing that accommodates it. The lock cylinder housing is simplified in that it does not have to be designed

DK 161775 B

2 a groove insertion of the spring. At the same time, the control measures have also been reduced. Furthermore, the solution chosen is cheap. The inclined surfaces are supported in a linear fashion on the corresponding opposite edges of the recess, thereby providing the locking effect.

The thickness of the end of the resilient tongues adjusts.

the necessary equalization of tolerances in the thickness of the structural parts to be locked. Thus, the inclined surface compensates partly tolerances with respect to the dimension of the recess through which the cylinder housing is inserted and partly tolerances with respect to the material thickness of the part to be locked.

Several tongues distributed over the circumference may be arranged, but preferably two such tongues are arranged. The protection against rotation of the lock cylinder housing or bushing which accommodates this in the recess in the structural part to be locked is obtained by a special shaping of this recess and the lock cylinder housing or bushing respectively. For this, the recess has a shape which differs from a circular shape, e.g. with flat sides. Further, additional recesses may be formed therefrom, such as e.g. The threads projecting radially outward from the corresponding flat-shaped area of the cylinder housing or bushing are passed through. In this way the tongues act as an extra protection against rotation.

The embodiment of the invention is suitable not only for use in metal cabinets or metal boxes, but also in thin-walled boxes or plastic cabinets. The design of the tongues and their inclined surfaces prevents damage to the plastic material and still ensures good retention. The known solutions with steel springs cannot be used here because of the cutting effect.

According to a preferred embodiment, the tongues, at their farthest from the rear of the part to be locked, are located at an integral end with the lock cylinder housing or bushing. In the case of lock cylinder housings mounted in axial direction and preferably by a bushing which accommodates the lock cylinder housing, according to a further embodiment of the invention, the circumferential surface of the lock cylinder housing or bushing may be disconnected such that the tongues are components of this disconnected circumferential surface. The inclined surfaces extend radially outward from the circumferential surface. However, the tongues extend substantially in the longitudinal axis of the locking cylinder housing and the bushing, respectively. Alternatively, for axial mounting, the tongues may be approximately radially inclined

DK 161775 B

3, the fastening end extending first radially outwardly beyond the circumferential surface of the locking cylinder housing or sleeve and then extending into one longitudinal axis, but in relation to this radially outwardly displaced tongue section, at which end the inclined surfaces are arranged.

Thus, the resilient tongues are arranged radially outside the circumferential surface of the lock cylinder housing or bushing respectively which accommodates this. The tongues are preferably arranged on the flat sides of the lock cylinder housing or bushing, respectively.

10 For an axial mount, the edges on which the sloping surfaces of the tongs are supported extend tangentially to a circle about the longitudinal axis and to a pivotal mount radially on the longitudinal axis.

Here, too, different modes of application of the resilient tongues are possible.

Thus, the tongues may be part of the lockably disconnected circumferential surface of the lock cylinder housing or bush. They then extend in the circumferential direction, i.e. over a circular arc about the longitudinal axis of the lock cylinder housing or bushing. The inclined surfaces are also disposed here at the end and also protrude beyond the circumferential surface of the cylinder housing or bushing, respectively. In addition, the tongues may also first extend radially outwardly from the circumferential surface of the lock cylinder housing or bush with an approximately radially extending portion and then transition into a substantially concentric tongue portion extending at the end of which the inclined surface is disposed.

For a pivot mounting, the tongues may also first extend with a relatively longitudinal axis but displaced relative to this lying portion from a radial surface of the locking cylinder housing or bushing, with which this or this abuts the front side of the part to be locked. , and then proceed to a tongue portion approximately concentric with the circumferential surface extending at the end of which the inclined surface is disposed.

The swivel assembly requires a different design of the recess into which the sleeve or lock cylinder housing is to be inserted.

For this purpose, the recess has sector sections for insertion and locking.

35 The locking is done in the same way as with a bayonet lock. To this end, a stop for complementary locking is placed next to the inclined surfaces of the tongues. This prevents a turning back in the opposite direction. The impact may be part of the tongue attachment end, i.e. a portion of the area thereof extending from the lock cylinder housing, respectively

DK 161775 B

4 the bushing. In order to achieve even greater security in the snap-locking, the inclined surfaces may be provided with a rifling or be stair- case. shaped.

In order to increase the elasticity of the resilient tongues, especially as a result of the material used for the barrel housing or the bushing, the tongue section, starting from its end connected to the barrel housing or bushing, may extend the waveform first towards the longitudinal axis and then in the direction away from it.

However, the tongue section may also, over its length beginning from its end connected to the locking cylinder housing or bushing, decrease first in its thickness perpendicular to the bending axis and then again increase in thickness in the direction towards the end provided with the inclined surfaces. Alternatively, at the fastening end, 15 weakening of the cross section of the tongs may be suitably formed. In the case where a bushing is used in which the locking cylinder housing is inserted, the tongues at their end formed with the inclined surfaces may be provided with inwardly projecting projections which cooperate with locking surfaces on the locking cylinder housing. A molding material, namely a metal alloy, can be used for the manufacture of the lock cylinder housing and the bushing and thus also of the resilient tongues formed therein.

This can, for example. be a zinc die cast material. Alternatively, it is also possible to use a resin mold suitable for injection molding, especially a resilient resin, e.g. provided with a metal-25 coating. These materials are usually relatively brittle. However, it has been found that in the design according to the invention there is no danger of fracture, and thus a material can be selected which would not normally be selected for the production of resilient tongues.

In order to facilitate the manufacture of the resilient tongs, in the case of a material as described above, the lock cylinder housing according to the invention in the region of the tongues may have through-openings for a movable mold tool part. This is especially true in the case where the tongues extend radially from the circumferential surface of the lock cylinder housing 35 or the sleeve.

According to a substantial feature of the invention, it is further proposed that the movement of the resilient tongues be restricted during locking. This results in only deformation of the 'resilient tongues within the elastic deformability'

DK 161775 B

5 area.

The restriction is preferably effected by an appropriate dimensioning of the free slot between the circumferential surface of the locking cylinder housing or sleeve and the side facing the flat of this tongue. Thus, when the limit values are reached, the tongue leans against the circumferential surface.

In order to obtain a secure snap-locking action, the angle of the inclined surface is dimensioned in such a way that a blocking effect is obtained between the edge and the inclined surface. The angle of the inclined plane in relation to the longitudinal axis is between 85 ° and 50 °.

In the drawing, preferred embodiments of the invention are illustrated. In the drawing:

FIG. 1 is a view of the lock cylinder housing according to the invention with lock cylinder; FIG. 2 is a side view of the embodiment of FIG. 1; FIG. 3 is a plan view of the embodiment of FIG. 1 with the lock cylinder housing in the locked position; FIG. 4 shows a recess in a door section; FIG. 5 shows a section through a bushing with resilient tongues as a component of the circumferential surface; FIG. 6 is a view of the embodiment of FIG. 5; FIG. 7 is a side view of a lock cylinder housing with in the circumferential direction of the cylinder housing, i.e.

25 is a concentric spring tongue extending concentrically with the longitudinal axis; FIG. 8 shows the embodiment of FIG. 7 is a rear view of the lock cylinder housing; FIG. 9 is a view similar to that of FIG. 7 and 8 show suitable recesses in the structural part to be locked, fig. 10 is an alternative embodiment of the embodiment of FIG. 1-3, wherein the resilient tongues have a wavy extending section and only the housing itself is shown; FIG. 11 is a side view of a further embodiment in which the tongues project from a radial surface of the lock cylinder housing and extend in its circumferential direction; FIG. 12 shows the embodiment of FIG. 11 is a rear view of the lock cylinder housing,

DK 1617 7 5 B

6 FIG. 13 shows a recess in a door section for the embodiment according to FIG. 11 and 12, FIG. 14 is a side view of a lock cylinder housing having concentric 5 longitudinally extending tongues constituting components of the circumferential surface; and FIG. 15 is a section along line A-A of FIG. 14th

The FIG. 1-3, the lock cylinder housing 1 has integrally formed tongues 2,3. The tongues 2,3 are resiliently shaped 10 and extend with their fastening end 19 from the end of the lock cylinder housing 16 end of the lock cylinder housing 1.

In the embodiment of FIG. 1-3, the lock cylinder housing 1 in the region of the resilient tongues 2,3 is formed with flat 15 sides 29. The lock cylinder housing 1 is accommodated in a recess, e.g. in a door 12, which here constitutes the component to be locked. When operating the key 32, the bolt 33 is turned in behind a fixed edge of the fixed structural member and locks the structural member 12 relative to this stationary member.

The resilient tongues 2, 3, with their fastening end, first extend approximately radially from the circumferential surface 20, i.e. in FIG.

1-3 from the flat sides 20 which are portions of the circumferential surface 20 of the lock cylinder housing 1, from which the resilient tongues 2,3 extend approximately in the same direction as the longitudinal axis x-x of the lock cylinder housing, but radially displaced relative thereto. The resilient tongues are provided at their free end with inclined faces 4 and 5. The inclined faces 4 extend in such a way that they intersect the longitudinal axis xx of the locking cylinder housing at a point S which is displaced axially forwardly from the inclined faces 4,5. direction toward the keyhole inlet port 16.

30 Between the underside 28 of the tongue and the circumferential surface 20 or the flat sides 29 of the lock cylinder housing 1, a slot 9 and 10, respectively, are provided. The gap 9 and 10, respectively, are dimensioned in such a way that no unacceptable deformations of the tongs 2,3 can occur.

Further, the lock cylinder housing 1 is provided with a flange 11, 35 having a radial surface 22. The lock cylinder housing 1 is in mounted condition with this radial surface 22 against the front face 15 of the structural part 12 to be locked. The resilient tongues 2,3 are supported with their inclined faces 4,5 on the edges 6,7, which are part of additional recesses 31.

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7

The auxiliary recesses 31 belong to the recess 8 for insertion of the lock cylinder housing 1. The edges 6,7 constitute the boundary edges between the auxiliary recess 31 and the back 14 of the structural part 12 to be locked. In an axial mount used in the embodiment of FIG. 1-3 or 5 and 6, the edges of the 6.7 tangent all extend to a circle about the axis x-x. The auxiliary recesses 31 in FIG. 4 permits penetration of the resilient tongues 2,3 and is used together with the corresponding faces of the recess 8 of the lock cylinder housing 1 to secure the lock cylinder housing against 10 turns.

The inclined faces 4.5 of the resilient tongues 2,3 extend, as is the case e.g. seen in FIG. 1, in a mounted position parallel to the edges 6.7 and the boundary surfaces 18, respectively. Since the material used for the lock cylinder housing 1 is generally not in good deformation properties, the resilient tongues 2,3 in the bending axis direction yy beginning at the attachment end 19 are first formed with decreasing thickness perpendicular to the bending axis yy and then in the direction toward their free end, i.e. in the direction towards the inclined surfaces 4.5 formed with increasing thickness. The thickness of the resilient 20 tongues in the region of the inclined surfaces 4,5 is dimensioned in such a way that sufficient tolerance equalization can be obtained for the usually occurring varying thicknesses of the structural members 12 to be locked so that a secure locking is achieved. . The inclined angle is dimensioned in such a way that between the edge 25 6 and 7 respectively, and the corresponding inclined surface 4 and 5 respectively in the mounted position, as shown in FIG. 3, an automatic block is obtained, i.e. that the resilient tongues 2,3 can not avoid radially inwardly, thereby enabling the locking cylinder housing to be pulled out. The angle is thus selected in such a way as to obtain a blocking effect independently of the material used. It is also possible to increase the locking effect by e.g. the oblique surfaces 4,5 are formed stair-shaped, so that a snap-locking action is obtained from staircase to staircase. Hereby, a surface engagement is also obtained between the back side 14 of the structural part 12 to be locked and the inclined surface 4 and 5 respectively. This effect can also be achieved by means of a rifling of the inclined surfaces. Usually, a line contact between the edges 6 and 7, respectively, and the associated inclined faces 4 and 5 of the tongues 2 and 3, respectively, is sufficient.

The mounting is done in a way that the lock cylinder housing 1 with

DK 161775 B

8 the bolt 3 is first passed through the recess 8 and after being placed in the correct position, i.e. in a position where the longitudinal axis x-x extends approximately perpendicular to the plane of the door 12, is pushed further through the aperture 8 until the radial surface 22 abuts the front face 15 of the structural member 12 to be locked. During the insertion j, the tongues 2,3 with their outer surface first slide on the bounding surfaces 18 of the edges 6 of the extra recess 31 and deform j radially inwards in the direction of the longitudinal axis x-x. When the locking cylinder housing 1j with its radial surface 22 is contacted with the front face 15, the tongues spring 2.3 radially outwardly and their inclined faces 4,5 lie against the edges 6,7.

If the lock cylinder housing 1 is to be removed from the door 12, the resilient resilient tongues 2,3 must simply be pressed slightly radially inwardly against the longitudinal axis xx of the lock cylinder housing 1. The gap 9,10 is dimensioned in such a way as to avoid overloading. of the tongues 2,3, so that the resilient resilience of the tongues 2,3 even with brittle material is not impaired.

In FIG. 5 and 6, there is shown a bushing 17 which serves to receive a locking cylinder housing 1. Thus, in this embodiment, the locking cylinder 1 can be locked not directly but only over the bushing 17 to the structural part 1. Unlike the resilient tongues 2,3 according to FIG. . 1-3 are the resilient tongues of the embodiment of FIG. 5 and 6 are components of the circumferential surface 20 of the bushing 17. The resilient tongues are connected at their furthest from the end 25 of the radial surface 22 to the circumferential surface 20, i.e. that their attachment end 19 is a component of the circumferential surface 20. Hereby, between the circumferential surface 20 and the resilient tongues 2,3, a U-shaped feed opening 27 is formed for carrying a movable mold tool part. The resilient tongues 2,3 extend with their tongue portions 21 in the longitudinal axis xx, and their inclined faces are also arranged in such a way that they protrude from the circumferential surface 20 and are disposed with such inclination that they cut the longitudinal axis xx in a point located in front of the inclined faces 4,5 in the direction of the key entry opening. The tongue section 21 is adapted in cross-section 35 to the circumferential surface of the sleeve 20. Furthermore, the resilient tongues 2,3 have approximately in the region of the inclined surfaces 4.5 radially inward projections 26 which engage in appropriate recesses in the lock cylinder housing.

The mounting is done by first inserting the bush 17

DK 161775 B

9, the recess 8, under which the resilient tongues 2,3 over the inclined surfaces 4,5 at their outer surface are pressed inwards and then abut against the edges 6,7. Then, the lock cylinder housing 9 is inserted into the central bore of the sleeve 17 until the projections 26 on the resilient tongues 2,3 5 snap into the corresponding recesses in the circumferential surface of the lock cylinder housing. The resilient tongues 2,3 together with the projections 26 ensure that the resilient tongues cannot escape inward. The lock cylinder housing may further be formed with radially outwardly extending tongues projecting radially out of the central bore of bush 17 and 10 abut against the radial surface 22 so as to provide a further axial locking of the lock cylinder housing in the central bore 17.

The FIG. 5 and 6, an additional bushing 17 can also be transferred to the lock cylinder housing 1 itself.

In FIG. 7 and 8 there is shown an embodiment for mounting by turning about the longitudinal axis x-x of the cylinder housing 1. In the example shown, only the cylinder housing 1 itself is seen without a bolt. It also substantially corresponds to the bushing 17. For the mounting by rotation, a change in the recess 8 in the structural part to be locked, namely the door 12, 20 is necessary. Such an altered recess is shown in FIG. 9. With regard to the design of the resilient tongues 2,3, reference is made to FIG. 7 and 8.

The resilient tongues 2 and 3 also extend here with their fastening end 19 radially from the circumferential surface 25 of the lock cylinder housing 1. The tongue section 21 extends substantially concentrically with the circumferential surface 20.

The tongues 2,3 are arranged in such a way that a gap 35 is formed between these and the radial surface 22 of the locking cylinder housing 1. The resilient tongues 2,3 have a length starting from the tongue section 21 30 beginning at the attachment end 19 and in the direction towards the sliding surface 34 of the radial surface 22, ie the gap 35 narrows in its width. The inclined face 4 and 5, respectively, form from this sliding surface 34. The inclined face 4 and 5 respectively extend substantially radially and are supported on the associated edges 35 and 6 and 7 respectively in the recess 8. The lock cylinder housing is further provided with a stop 25. which cooperates with a corresponding impact surface 38 in the recess. The impact surface 38 and the edges 6 and 7, respectively, extend radially on the longitudinal axis x-x. The abutment 25 also exits from the circumferential surface 20, but is led all the way to it

DK 161775 B

Further, the radial surface 22. Further, the resilient tongues 2,3 in the direction towards their attachment end 19 are formed with notches favoring a resilient movement in the axial direction, i.e. in the axial direction x-x. The recess 8 in the structural part 12 to be locked 5 has an insertion section 23. This insertion section 23 is dimensioned in such a way that the resilient tongues 2,3 together with the corresponding stop 25 can be inserted into the recess. Then the locking cylinder 1 is rotated in a counterclockwise direction. Thereby, the locking section 36 of the structural member 12 and then the impacting section 37 move 10 into the gap 35 between the radial surface 22 of the locking cylinder housing 1 and springing tongues 2,3.

The resilient tongs 2,3, first, with their open surfaces 34 abut the edge formed between the abutment 39 and the back side of the structural member 12, and at the further turning movement 15 the resilient tongue 2,3 moves away from the radial surface 22 This pivotal movement can occur until the abutment 25 with its abutment surface 38 comes into abutment against the abutment 39 in the latching sector 36. At the same time, the resilient tongues 2,3 can then return to their initial position, where the oblique surface 4 and 5 can come 20 to abutment against edge 6.7. The lock cylinder housing is then secured both in the circumferential direction and in the axial direction. As an additional fuse, the impact sector 37 located in the gap 35 between the radial surface 22 and the resilient tongues 2,3 serves.

In the embodiment shown in FIG. 10, only the lock cylinder housing 1 can be seen without the associated internal structural parts.

The resilient tongues 2,3 also extend radially here from the circumferential surface 20. of the locking cylinder housing 1. 1 to 3, the resilient tongues 2,3 are here formed waveform, i.e. that the tongue section 21 from the attachment end 19 30 first extends inwardly towards the longitudinal axis x-x and then again away from it. This also favors the deformation of the resilient tongues 2,3. Here, too, the resilient tongues 2,3 are formed with inclined faces 4.5 at their free ends. The oblique surfaces 4,5 change into a bead which serves to limit the radially inward movement of the tongues 2,3 as the bead comes into contact with the circumferential surface 20. A lock cylinder housing 1 in this embodiment or a sleeve 17 in this embodiment also serves as the embodiment of FIG. 1-3 for axial mounting.

A further embodiment of mounting by rotation is

DK 161775B

11 shown in FIG. 11 and 12. The corresponding recess 8 is shown in FIG.

13. The lock cylinder housing 1 is provided with resilient tongues 2,3 which extend concentrically with the longitudinal axis x-x of the lock cylinder housing 1. The resilient tongues 2,3 extend in the axial direction from the radial surface 22 of the locking cylinder housing and then extend from the attachment end 19, they are connected in one piece with the radial surface 22 in the circumferential direction. The resilient tongues are spaced apart from the circumferential surface 20. The resilient tongues have at their free end a sliding surface 34 which extends in the direction towards the radial surface 22 and ends in the inclined surfaces 4,5. The inclined faces 4 and 5, respectively, are arranged such that they intersect the longitudinal axis xx and that the intersection point S is offset in the direction away from the radial surface 22. This is a difference from the previously described embodiments, where the intersection point S in the direction of key insertion The ring opening 16 (Fig. 1) lies in front of the inclined faces 4,5. Seen in the direction from the key entry opening 16, the intersection point S in this case lies behind the inclined faces 4,5. Between the free end of the tongue 2,3 and the radial surface 22 is a gap.

The recess 8 has an insertion sector 23 which substantially corresponds to the sector 23 'over which the tongues extend. The locking cylinder housing 1 is mounted by placing the locking cylinder housing in such a way that the tongues 2,3 can be inserted into the feed area 23. Then the locking housing 36 is rotated in such a way that the locking sector 36 can enter the gap between the resilient tongues 2,3 and radial surface 22. This is facilitated by giving the idle surfaces 34 abutting the edge of the back side 14, thereby moving the resilient tongues 2,3 in the axial direction away from the radial surface 22. When the end position is reached, i.e. when the abutment surface 38, which is a component of the fastening end 19 of the resilient tongues 2,3, during rotation 30 comes into contact with the associated counterface 39, the resilient tongues 2,3 may also spring back in the direction towards the radial surface 22 and come for abutment against the associated edges 6.7 of the bolt sectors 36.

FIG. 14 and 15 show a further variant. Here, it is essentially a similar design to that in connection with FIG. 5 and 6, but in this case the resilient tongue extends in the circumferential direction of the circumferential surface 20, i.e. concentric with the longitudinal axis x-x. Here, the resilient tongues 2,3 are also constituents of the circumferential surface 20 and are provided with suitable axial inlet surfaces. The difference from the embodiment according to i 5 12

DK 16177 5 B

FIG. 5.6 is that the axial suspension acts in the circumferential direction and not in the axial direction.

i 1 ° 15 20 25 30 35

Claims (13)

1. Fastener for securing a lock cylinder in thin-walled doors, drawers or similar parts which must be lockable, especially in metal cabinets or boxes, wherein the lock cylinder housing or a bushing accommodating the lock cylinder housing is passed through a recess and snap-locking engaging means. with the rear of the part to be locked, characterized in that the locking cylinder housing (1) or a bushing (17) which accommodates this has in a thus formed 10 resilient resilient tongues (2,3) which have at their free end a surface (4,5) extending inclined in a radial direction in a plane intersecting the longitudinal axis (xx) of the housing (1) and of the sleeve (17), respectively, at an angle (a) where the angle differs from 90 ° and the point of intersection (S) with the longitudinal axis (xx) is displaced in its direction relative to the inclined surfaces (4,5) and the inclined surfaces are resiliently supported on the edge (6,7) between the limiting surface (18) of the recess (8) and the rear (14). ) of the part (12) to be locked , and runs parallel to it. Fastener according to claim 1, characterized in that the tongues (2,3) at their furthest from the rear (14) of the part (12) to be locked, located end (19) are connected in one piece to the lock cylinder housing ( 1) or the bush (17). Fastener according to claim 1 for mounting in the longitudinal axis direction, characterized in that the tongues (2,3) are parts 25 of the suitably interrupted circumferential surface (20) of the lock cylinder housing (1) or the bushing (17) and have a longitudinal axis ( (xx) extending but radially outwardly relative to said tongue portion (21), at which end the inclined surfaces (4,5) are disposed and the inclined surfaces (4,5) project radially beyond the circumferential surface (20) ( Fig. 5.6). Fastener according to claim 1 for mounting in the longitudinal axis, characterized in that the tongues (2, 3) with an approximately radially extending fastening end (19) first extend radially outwardly beyond the circumferential surface of the lock cylinder housing (1) or bush (17). 20) and then passes into a longitudinal axis (xx) extending but in relation to the longitudinal axis (xx) radially outwardly displaced tongue portion (21), at which end the inclined faces (4,5) are arranged (Fig. 3 , 10). Fastening means for mounting by rotation about the longitudinal axis, characterized in that the tongues (2,3) are parts of the suitably disconnected circumferential surface of the locking cylinder housing (1) or the bushing (17) and has a tongue section extending in the circumferential direction (21). , at whose end the inclined surface (4,5) is arranged and the inclined surfaces (4,5) project radially outwardly past the circumferential surface (20). j i 6. Mounting means for mounting by rotation about the longitudinal axis, characterized in that the tongues (2,3) first extend radially outwardly from the circumferential surface (20) of the lock cylinder housing (1) or the bushing with an approximately radially extending part (19). j (17) and then passes into an approximately concentric tongue portion (21) extending concentrically with the circumferential surface (20), at which end the inclined surfaces (4,5) are arranged (Fig. 7,8). Fastener according to claim 1 for mounting by rotation about the longitudinal axis, characterized in that the tongues (2,3) first extend with an approximately 15 longitudinal axis (xx) but displaced relative to the longitudinal axis (xx). radial surface (22) of the lock cylinder housing (1) or bush (17), with which this (1) or this (17) abuts the front side (15) of the part (12) to be locked, and then enters a approximately 20 tongue portions (21) extending concentrically with the circumferential surface (20), on which end the inclined surface (4,5) is arranged (Fig. 11,12). Fastener according to any one of claims 6-8, characterized in that a stop (25) for complementary locking is arranged on the inclined surfaces (4,5) 25 of the tongs (2,3) (Fig. 7,8 ). Fastener according to any one of claims 1 or 3-7, characterized in that the tongue portion (21) extending over its length starting from its end (19) connected with the lock cylinder housing (1) or the bush (17) first enters the towards the longitudinal axis (xx) and then in the direction away from it (Fig. 10). Fastener according to any one of claims 1 or 3-7, characterized in that the tongue section (21) starting from its end connected to the lock cylinder housing (1) or the bush (17) 35. first decreases in its thickness perpendicular to the bending axis and then again increases in thickness in the direction towards the end provided with the inclined surfaces (4,5). Fastener according to claims 1,3 and 5 with a bushing surrounding the lock cylinder housing, characterized in that DK 161775 B ice tongues (2,3) have at their free end inwardly projecting projections (26) which cooperate with corresponding locking surfaces of lock cylinder housing (1) («g. 5). Fastener according to claim 1, characterized in that the resilient movement of the tongues (2,3) is restricted during locking and the restriction is effected by an appropriate dimensioning of the free slot (9, 10) between the circumferential surface (20) and the facing face (28) of the tongues (2,3). Fastener according to claim 1, characterized in that the edges (6,7) and thus the limiting surfaces (18) of the recess (8), on which the inclined surfaces (4,5) of the tongs (2,3) are supported, fitting in the longitudinal axis (xx) extends tangentially to a circle about the longitudinal axis (xx) or to a fitting by rotation about the longitudinal axis (xx) extending radially relative to it.