NO316181B1 - Cylinder lock and associated flat key - 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 key

The Sylmder lock is of a type in which control elements are equipped with control means which project into a key channel and which sense control tracks in a key which is pushed into the key channel, as at least on one side of the key channel, approximately parallel to this, it is arranged in the at least one control element with two control means which, with a first part, protrudes through a slot in the cylinder core and into the key channel and cooperates with the shallowest control grooves in the key which is pushed into the key channel and on the same side of the key channel is equipped with another control element with a control means which with a second part protrudes through another slot in the cylinder core, mn in the key channel and cooperates with the deep guide groove of the key which is mn pushed in the key channel, the first part being smaller than the second part, and at least one locking element is arranged which, by corresponding positioning of the control elements, can be brought into a free position for rotation of the cylinder core in relation to cylinder h unseen

On an associated flat key, guide grooves are arranged on the side surfaces with a varying distance from the back of the key, and possibly other guide elements are arranged, such as cuts in the key beard for pin holders, guide surfaces on the back of the key and longitudinal ribs and grooves in the key's insertion direction, as in at least three guide grooves are arranged on the smallest one of the two side surfaces, of which at least one is deeper than the other guide grooves, and the two shallowest guide grooves run roughly parallel to each other

The starting point for the present invention is a key and latch construction which is described in EP patent application no. 335 069

The purpose of the invention is to improve this known lock with regard to the number of vanations and locking security. The same must also be achieved when it comes to the design of the key. The lock according to the invention is characterized by the features that appear in patent claim 1 The key according to the invention is characterized by the features that appears from patent claim 6 Other preferred and advantageous features of the invention appear from the independent patent claims, the subsequent description and the drawings

In what follows, the invention will be described in more detail by means of an embodiment example

Fig 1 shows a locking cylinder, the cylinder housing is shown in longitudinal section and the rotatable cylinder core is shown in side projection and in a non-rotated position Fig 2 schematically shows a section along the line ll-ll, with only one half of the cylinder core and the cylinder housing shown, and with the key pushed Fig 3 is a section along the line lll-lll in fig 2 Fig 4 shows a longitudinal section through the cylinder housing, and fig 5 shows a partial t section of the cylinder housing seen from the right, the partial section corresponding to the section V-V in fig 4 Fig 6 is a side projection of a key, and fig 7 is a section along the line VII-VII in fig 6 Figs 8 and 9 show longitudinal sections and a side projection of the profile strip Figs 10 and 11 are projections showing a different design of the lock and which are similar to figs 1 and 2

In the cylinder housing 1, in a cylinder bore 2, is a cylinder core 3 which can be rotated in relation to the cylinder housing. Towards the outside, the cylinder core is closed by a bottom 4, while on the other end of the cylinder core there is a connecting part 5, not shown in detail

The cylinder housing 1 has six mutually parallel grooves 6, which are open towards

cylinder bore 2 In a longitudinal recess 7 in the cylinder core 3, a detent pusher 8 is displaceably arranged and holds a series of detent elements 9 that project outside the outer cylinder surface 2 of the cylinder core 3 and at a specific sliding position of the detent pusher 8 can be guided into the grooves 6 and thus enable turning of the cylinder core in the cylinder housing, or in the slide position shown to prevent rotation of the cylinder core by standing against the steps 34 between the grooves 6 The locking slide is actuated via a spring pin 10 On one end of the locking slide 8 a control slide 11 is arranged, which can is guided radially mn in the cylinder core. In the area 12, the control pusher 11 lies above a bearing surface 42 on the locking pusher 8. If the control pusher 11 is pressed into the cylinder core, a displacement of the locking pusher 8 takes place to the right, towards the spring of the spring pin 10, until the locking elements 9 have assumed a flush position in relation to to the tracks 6

Parallel to the key channel, not shown, displaceable locking pins are arranged in spacious bores 13, as can be seen more clearly from figs 2 and 3

Fig 2 shows a section along the line ll-ll, as only one half of the sylmder lock is shown. The other half is only schematically indicated, to make the drawing clear

The key 14 is fully offset in the associated key channel in the cylinder core. The key 14 has guide grooves 15, with which the corresponding sliding position of the locking pins 16, which are displaceably arranged in the bores 13, is determined. the other side each locking pin 16 has locking bolts 18 which run in recesses 19 when the locking pusher 8 is in the position shown

The control pusher 11 is in the zero position (non-rotated position of the cylinder core in the cylinder housing) in a control recess 20 in the cylinder housing 1 When the cylinder is turned, the control pusher 11 is pushed inwards in the direction of the arrow 21, which is made possible due to the skull cut-outs 22 in the key 14. This moves the locking pusher 8 to the right, the rest is possible because the locking pins 16, due to the correct key 14, take a position which enables the introduction of the locking forces 23 on the locking pusher 8. Thus, the locking elements 9 come to the position where they align with the grooves in the housing and enable turning of the cylinder core in the cylinder housing

Fig 3 shows a cross-section showing the interaction between the above-described parts. The cross-section of the key 14 is incomplete in that only the grooves 15 that actually effect steering and the location of the cross-section are shown. In the left half, the deep groove is thus missing, and in the right half are missing the two shallower grooves, which will be described in more detail below

The open-end wrench 14 is sensed from the left and right because of the two locking pins 16 and also the guide bolts 17. Both locking pins 16 can be shifted in height in the bores 13. The locking bolts 18 lie like knobs along the locking pins 16 and have protrusions 24 through which the locking springs 23 on the locking pusher 8 can be pushed. all the locking pins 16 on one side of the key occupy this correct position, the associated locking pusher 8 can be moved, so that the locking elements 9 can be inserted into the assigned grooves 6 when the cylinder core is turned, so that the cylinder core can be turned further

When the key is fake, at least one of the locking pins 16 is faulty, so that the locking bolt 18 is in contact with one locking projection 23 or both of these, so that the locking pusher 8 cannot be displaced. The locking elements 9 thus come into contact with the surfaces 25 on the steps 34 between the grooves 6, so that continued rotation of the cylinder core is effectively prevented

A profile strip 26 is arranged as a safety and vanation element. This profile ridge 26 lies along the key channel in a recess 27 in the cylinder core and is radially displaceable in this, i.e. in the direction from and towards the key. The profiling 28 senses an assigned profiling on the back of the key (respectively front side) 29 The profile horse 26 has along its length several run-on lugs 30, with which the profile strip lies in sickle-shaped recesses 31 when the key is in the zero position. Thus, the profile rings 28 and the profiles on the back side 29 of the key do not engage When turning the cylinder core, the profile horse 26 is displaced in the direction towards the rear of the key, so that the mutual profiles lie against each other When the profiles do not match, part of the profile horse 26 remains inside the slot 32, so that the strip comes into contact with one of the contact surfaces 33 on the steps between the nng grooves 6 Figs 8 and 9 show profile horse 26 in section and in side projection seen from the key channel, and will be understood without explanation The number of ribs shown is only one of many possible variants Fig 3 shows the profile horse 26 in the extended position, as it is in practice after turning the cylinder core The depth of the grooves 15 and the length dimension of the guide bolts 17 are drawn with the same dimensions In practice these dimensions are preferably different, as will be explained in connection with figs 6 and 7 Figs 4 and 5 show a central longitudinal section and an end projection of the cylinder housing 1 The control extension 20 serves to control the control pusher 11 The ring grooves 6 are separated by means of the steps 34 The steps 34 are interrupted by the grooves 35 and form the surfaces 25 which serve as stops for the locking elements 9. Three of the narrow grooves 6 have the sickle-shaped recesses 31 in which the pile lugs 30 run and which press the profile horse 26 inwards towards the back of the key. in the recess 27 in the cylinder core Fig 6 shows a key seen from the side, sl ik it can, for example, be introduced into a lock as shown in fig 1 -5 The key shaft has on the side shown 37 a skull extrusion 22 for inserting the control pusher 11 From the key tip 38, three control grooves run, corresponding to the control grooves described above 15 The two control grooves 39 run into each other parallel and are relatively shallow The third guide groove 40 is made deeper and can also cross the other two grooves 39 There are two types of locking pins 16, as shown in fig 3 One type of locking pin has a longer guide bolt 17, which is guided in the deep guide groove 40 The second locking pin type has two shorter guide bolts, which are guided in the two guide grooves 39 In Fig. 6, the position of the parallel, different guide bolts 17 on the locking pins is drawn as circles

By means of different progressions of the three guide tracks 39 and 40, different key vanes are formed

Preferably, the key is a reversible key, the other side of the key being designed in such a way that it looks the same as shown in Fig. 6 after a 180° turn

The key tip 38 is designed in a dovetail shape. The shallow grooves 39 extend to both tip areas of the key, while the deep guide groove 40 begins in the middle of the bottom of the dovetail-shaped recess. Thus, it is achieved that the guide bolts 17 on the locking pins are inserted into the correct guide grooves regardless of their random position

The profiling on both key edges is here carried out symmetrically to form a turning key, as the profiling is one of many possible profile extension habits. The profiling is preferably sharp, which significantly complicates imitation

In the vicinity of the key tip 38, two transverse grooves 41 are arranged, which form insertion grooves for a spring element which is arranged in the cylinder core. With the help of this spring element, the user of the key receives a noticeable signal that the key has been completely inserted into the key channel

The dome milling 22 extends with its cylindrical surface-shaped bottom to near the longitudinal middle plane of the key, so that only a relatively thin step remains between these bottoms. The depth of each dome milling corresponds to the necessary movement of the control pusher 11. The dome milling should, however, only project in a limited part of the height of the key shaft, as the key may otherwise break at this point This is another safety feature of the key Preferably the height 44 of the cap strap is more than 50% of the key shaft height 45

On the key tip 38, the bottom 46 of the dovetail-shaped recess 47 lies in the longitudinal plane of symmetry 48 of the key shaft, and the one deep groove 40 (on both sides of the key) has its starting point in this plane

The two flanks 49 lead the guide bolts 17 on the locking pins to a symmetrical position, from which the parallel, shallower guide grooves 39 extend

When it comes to the operation of the lock, it should be noted that the control pusher 11 causes displacement of the locking pusher 8. The control pusher 11 can consist of hardened metal, so that only little wear occurs. The displacement is promoted due to the chamfers on the locking elements 9 (see fig. 1), which slide along the inlet edges of the steps 34 between the grooves 6 Effective wear is prevented on these bevels Fig 10 shows the lock according to the invention in a similar projection to Fig 1, using a different design of the locking slide 8, with reference to figure 50

Fig 11 shows a corresponding section seen from the side

The locking slide 50 is displaceable, not in an axial direction but in a radial direction, and is one with the control slide 51, which in terms of function corresponds to the above-described control slide 11. The locking slide 50 is, along its entire length, either m-shifted in a longitudinal recess 7 in the cylinder core 3 or is prevented from radial displacement by using a false key, so that the elongate projection 52 protrudes mn in an axial, longitudinal groove in the cylinder housing and thus prevents rotation of the cylinder core The locking slide 50 can preferably be made entirely of hard metal, so that it also a boring obstacle The two extensions 53 serve for further control of the control slide The bores 54, which are shown with dashed lines, are open downwards towards the material in the cylinder core, and contain compression springs, so that the locking slide 50 is biased outwards in the direction of the cylinder housing

The operation of this locking pusher can be seen in fig 11. A position is shown in which a correct key is inserted and turned somewhat, so that the locking pusher 50 is inserted into the cylinder core in its entire length. The steps 34 in the annular grooves in the inner surface of the cylinder housing are interrupted by an axial groove 55, so that space is formed for the introduction of the projection 52 on the locking pusher 50 The pushed-in position of the locking pusher 50 is made possible by all the locking pins 16 taking the correct position, as described above, and that the key exhibits the correct skull milling 22

When the cylinder core is turned to the zero position, the compression spring 56 can push the detent pusher outwards in the direction of the arrow 57. The projection 52 thus enters the axial groove 55, and the steps 34 which are located between the nng grooves 6 can prevent rotation of the cylinder core. or is not sufficiently deep, or when at least one of the locking pins 16 takes an incorrect position

Claims (10)

1 Cylinder lock, in that control elements are equipped with control elements that project into a key channel and sense control tracks on a key (14) that is pushed into the key channel, and in that at least one control element with two control elements is arranged at least on one side of the key channel and parallel to this, which control means with a first part in the longitudinal direction protrudes through a slot in the cylinder core (3), to the key channel, and cooperates with shallow control grooves (39) in the key (14) which is pushed into the key channel, as on the same on the side of the key channel, another control element is arranged with a control member which with a second part in the longitudinal direction projects through another slot in the cylinder core, to the key channel, to cooperate with a deep control groove (40) in the key (14) which is pushed into the key channel, in that the first part in the longitudinal direction is smaller than the second part in the longitudinal direction, and in that there is arranged at least one lock (8) which in the corresponding position of the steering element e can be brought to a neutral position for rotation of the cylinder core (3) in relation to the cylinder housing (1), characterized in that the detent is a detent pusher (8) which is displaceable in a recess in the cylinder core (3), and which exhibits the detent element (9) which, in the non-rotated position of the cylinder core, projects into a groove (35) in the cylinder housing (1) , and that the cylinder housing (1) has grooves (6) that are open to the cylinder core, and in which the locking elements (9) are guided during rotation of the cylinder core, so that continued rotation is possible 2 Cylinder lock as stated in claim 1, characterized in that a guide pusher (11) is arranged in the cylinder core (3) which is arranged for displacement through a guide extension (20) in the housing in the cylinder core and has an inclined contact surface 12, with which the locking pusher (8) can be moved, so that a end of the control pusher (11) is fed into a recess (cap milling 22) in the key 3 Cylinder lock as stated in claim 1, characterized in that there is arranged in the cylinder core (3) a locking pusher (50) which is made in one with a control pusher (51) and is radially displaceable in a recess (7) in the cylinder core (3), with one end of the control pusher ( 51) can engage in a recess (cap milling 22) in the key, and the locking pusher (50) has a projection (52) that engages in an axial groove (55) in the cylinder housing and when the cylinder core is turned can be pushed out radially against a spring force and thus enable continued rotation of the cylinder core (3) 4 Cylinder lock as stated in claim 1 or 3, characterized in that a profile strip (26) is arranged in the cylinder core (3) along the key channel which is displaceable in a radial direction, the radial displacement being controlled by a recess (31) in the cylinder housing, and the strip (26) has a profiling (28) which cooperates with a corresponding profiling on the edge of the key (29) 5 Cylinder lock as stated in claim 4, characterized in that the profiling (28) is arranged at an angle in relation to the longitudinal middle plane of the profile horse (26) 6 Flat key for freeing a guide pusher (11) in a cylmder core (3), with the key on the side faces showing guide grooves (39) with varying distances from the back of the key and possibly other control elements, such as cuts in the key's beard for staple holders, guide surfaces on the back of the key and longitudinal ribs and grooves in the key's insertion direction, with at least three guide grooves arranged on at least one of the two side surfaces (37), of which at least one guide groove (39) is designed deeper than the other guide grooves, and the two the shallow guide grooves (39) are arranged continuously approximately parallel to each other, characterized in that at least one of the flat side surfaces (37) is provided with a hood milling (22) for freeing the control pusher (11), and that at least one of the key edges (29) is provided with a notched profiling ( 28) which cooperates with an analogous profiling on a profile strip (26) which is arranged in the cylinder core (3) 7 Open-end wrench as stated in claim 6, characterized in that the hood milling (22) is arranged on both flat side surfaces (37) of the key, and has a depth that reaches close to the longitudinal center plane of the key, so that only a thin step is arranged in the area where the hood millings are closest to each other of key materia let 8 Flat spanner as specified in claim 6 or 7, characterized in that the height (44) of the skull milling (22) constitutes more than 50% of the key shaft height (45) 9 Open-end wrench as specified in one of claims 6-8, characterized in that the key tip in a manner known per se exhibits a dovetail-shaped recess (47), and that the starting point of all the guide grooves (39, 40) is arranged symmetrically about the longitudinal symmetry plane (48) 10 Open-end wrench as specified in one of claims 6-9, characterized in that the key is designed as a reversible key