NO318803B1 - Keys and cylinder head - Google Patents

Abstract

The invention concerns a key for a cylinder lock, the flat sides of the key having longitudinal ribs and/or grooves running in the direction in which the key is inserted into the keyhole. The key is characterized in that at least one of the flat sides of the key also has at least one groove (18, 19, 20) which is shorter than the shaft (2) of the key and which is inclined at an angle to the direction (3) in which the key is inserted into the lock.

Description

The invention relates to a key for a cylinder lock as stated in the introduction in claim 1. The invention also relates to a cylinder lock for this key, as stated in the introduction in claim 9.

The invention is based on keys and cylinder locks which are known from AT 392 506, 347 285, 340 802 and 371 879. From the known technique in the area, further reference should be made to US 4 723 427, EP 159 494 and EP 237 172, All these known however, constructions can be improved at all given advantages in terms of safety and the number of variations available.

The known longitudinal profiling with longitudinal ribs and/or longitudinal grooves on the key flat sides can be retrofitted with relatively simple means. When it comes to variation figures, a large number of variation possibilities is sought, especially because the possibilities that are actually available when preparing locking systems with hierarchically designed locks and keys often have to be drastically reduced, even if a high variation figure is theoretically given.

The purpose of the present invention is to overcome the above-mentioned disadvantages, and to provide keys as well as locks which make it difficult to imitate keys for abuse, provide a large number of variation possibilities, and yet meet the necessary quality requirements in terms of construction and with regard to wear.

According to the invention, this purpose is achieved by the key having the characteristic features as stated in claim 1, and the cylinder lock having the characteristic features as stated in claim 9.

Advantageous embodiments of the key and the cylinder lock are indicated in the independent claims.

The invention shall be described in more detail in the following in connection with some design examples and with reference to the drawings, where fig. 1 is a side view of the key according to the invention, fig. 2 is a sectional view of a known profiling scheme, fig. 3 is a sectional view along the line III-III in fig. 1, fig. 4 and 5 are views of the cylinder core seen from the side and from above, fig. 6 is a plan view of a lock detail, fig. 7 is a view seen in the direction VII of fig. 6, fig. 8a, 8b and 8c are sectional views along the line VIII-VIII in fig. 6 for various design examples of this structural element, fig. 9 is a sectional view of a cylinder lock along the line IX-IX in fig. 4, as the cylinder housing is additionally arranged, fig. 10 is a side view of a further embodiment of a key according to the invention, fig. 11 is a sectional view along the line XI-XI in fig. 10, fig. 12 and 13 are sectional views along the line XII-XII in fig. 10, fig. 14 shows four variants a) to d) of the profile note in the key, fig. 15 is a sectional view of a further embodiment variant, fig. 16-19 show a locking element in plan which is coordinated with each other, fig. 20 is a side view of an embodiment of the key, fig. 21 - 27 show a further preferred design example in different views and sections, fig. 28 is a side view of a further developed small plate, fig. 29 is a sectional view along the line XXIX-XXIX in fig. 28 through the associated locking part, and fig. 30 shows a preferred key design.

Fig. 1 schematically shows a key according to the invention where the drawn variation elements can also describe an embodiment example for a practical embodiment. As usual, the flat key comprises the key handle 1 and the key shaft 2, which is essentially fully insertable in the insertion direction 3 into the key channel in an associated cylinder lock. The key shaft 2 comprises the key ring 4, the key tip 5 and the key chest 6. Dotted is the indented holding recess 7 which starts from the key chest, where the holding recesses can cooperate in a known manner with holding pins in the cylinder lock.

On the key flat side, two key grooves 8 and 11 are arranged as a component of the key length profiling, which extend in the direction of the key insertion direction 3 and thus run parallel to the key ridge 4.

Furthermore, further profile notches 18, 19 and 20 have been arranged which have a length which is less than the length of the key shaft 2, and which are arranged at an angle in relation to the key's insertion direction 3. A different profile notch 21 is drawn in at an angle as an example. At one and the same sensing point on the key, it can also e.g. be arranged two such crossing profile notches in order to be able to sense the same key within a locking system from different sensing elements in different locks.

Line 22 is the profile notch symmetry line for each profile notch. Corresponding to the design of the associated sensing element in the lock, the profile notch which is actually formed on the key can either be arranged above or below or on both sides of this profile notch symmetry line 22. In fig. 1, the profile grooves are formed on both sides of the profile groove symmetry line, which is only for example to be explained in more detail.

In fig. 1, only one key flat side is shown. The other key fiat side of the same key can similarly have longitudinal profile notes or profile ribs and which have profile grooves (18, 19 or 20), as the angular positions of the grooves can be arranged equal or opposite or in a different position.

The design of the profiling in the longitudinal direction of the key and analogously to this key channel in the lock takes place in a preferred way according to a profile system that is described in AT 340 802 and 371 879. In the following, this profile system will be explained in more detail in connection with fig. 2.

The profile system is based on a theoretical basic profile 23, which can be imagined as composed of rhomboid-shaped elements 24 arranged in a zigzag pattern. The spaces formed between the opposite elements 24 up to the enveloping plane 25 are either formed as grooves or remain as key material as ribs in order to achieve the necessary profiling and diversity. The longitudinal profile elements have reference numbers 8-17, with two consecutive ribs drawn in hatched with reference numbers 13 and 14. It is noteworthy that the ribs (e.g. 13 and/or 14) with this type of profiling remain within the enveloping plane 25. If a key is intended for all ribs, the key has a smooth surface, which should be avoided in practice.

When manufacturing such a key, it is naturally assumed that a key blank corresponds to the enveloping plane 25, and when key material is removed or retained at locations 8-17, either notches or ribs are arranged.

For the preparation of hierarchies in closed systems, a further system can also be used. As described and characterized in AT 371 879, the key and the associated key channel can preferably comprise an invariable basic profile within a locking system and a variable profile which together make up the total profile, as both the basic profile and the variable profile are arranged distributed over the key area that is effective for locking and opening. Here the profiles are arranged pushed into each other so that at least one profile element of the basic profile on each side of the key is arranged between two profile elements of the variable profile.

This profile system comes into use when preparing closing systems, especially when a large number of hierarchical steps must be taken into account. When preparing the individual profile in this closing system, e.g. the profile elements 8, 10 and 15 on the key are always arranged as ribs, so that the basic profile in this installation consists of the theoretical basic profile 23 and those on the added ribs 8,10 and 15. All other profile elements 9,11,12,13, 14, 16 and 17 are available for the variations to form the necessary closing differences.

With this profile system, it is of particular advantage that the basic profile in the entire facility cannot be recognized on a single key, so that imitation for misuse of a key is made difficult. Furthermore, the higher the hierarchy, the more complicated the key appears. This also makes it difficult to imitate master keys in a facility. Fig. 3 shows the cross-section of a key (analogous to this also the cross-section of an associated key channel), with a profile system schematically drawn in accordance with fig. 2, as the assumed actual profile design is drawn as an example with strong lines. The figure shows a section along the line III-III in fig. 1 and thus cuts through the further profile groove 18 which lies at an angle in relation to the key's longitudinal profile grooves. Similar elements have the same reference numbers in fig. 1 and 2.

As can be seen, the profile elements 12, 13 and 14 are arranged as ribs. All other profile elements and among them also the profile elements 9 and 10 are present as grooves which extend over the entire length of the key shaft.

The cross-section of the profile groove 18 which extends diagonally across the key is trough-shaped, as the profile groove in this design example is arranged on both sides of the profile groove symmetry line 22.

For the design of variations, it is equally possible to arrange the profile notch just above the profile notch symmetry line or below this symmetry line and Ia to be sensed by correspondingly designed sensing elements.

As can be seen from fig. 1, the profile groove 18 cuts into both the longitudinal groove 8 lying above it and the longitudinal groove 11 lying below it.

Figs 4 and 5 show a cylinder core seen from the side and from above, how it can be used in connection with the previously described keys. The cylinder core 26 occupies the continuous key channel 25. The core flange has the reference number 28 and goes outside the associated housing. The cylinder core end 29 lies in the interior of the lock and connects the turning movement of the cylinder core 26 in a manner not shown with a coupling on a closing nose which in turn activates the door lock. All these elements are known in the art.

The holes for the pin holders have reference number 30.

Roughly perpendicular to the key channel 27, the core recesses 31 are arranged until the key channel 27 tapers somewhat in the area 32. The recesses 33 which extend upwards appear in practice when using finger mills to shape the core recesses 31. When using other tools, this recess can also be omitted.

In the core recesses 31, the sensing elements are arranged in the form of small plates 34 as shown in fig. 6 - 8. On the key-side end, each small plate has a sensing end 35 and on the other side a locking extension 36.

As shown, the sensing end 35 is seen in the direction of arrow VII and in fig. 7 designed as an inclined projection, the slope being arranged in such a way that the sensing end 35 can be introduced into the adapted inclined profile groove (18, 19 or 20) with a suitable key. This design thus combines the manufacturing technical advantage of axis-parallel arranged core recesses 31 with the inclined sensing of the inclined profile grooves.

In fig. 7, a profile rib symmetry line 37 is drawn and with respect to this profile rib symmetry line, it is possible with three different designs of the sensing end as shown in fig. 8a - 8c. The sensing end 35 is arranged either above or below or on both sides of this profile rib symmetry line 37. The production in fig. 8 shows only the section surface along the line VIII-VIII in fig. 7 and not the other edges of this body. The locking extension 36 has a round wedge-shaped course and engages in the zero position of the cylinder core according to fig. 9 into a locking recess 38 in the cylinder housing 39. As shown with the help of this fig. 9 can easily be seen, the key 40 can be pushed unhindered into the key channel 27 as the small plate 34 has sufficient room for avoidance into the locking recess 38. When turning the cylinder core 26, the locking continuation runs up the walls of the locking recess 38, and the small plate 34 is pushed inwards towards the key channel 27. When the key is correctly designed and has the correct profile groove 18, the sensing end 35 fits into the profile groove 18 and the small plate lies completely inside the cylinder core 26 so that the rotation of the cylinder core is enabled. In the case of a false key, the sensing end 35 hits the key material and the locking extension 36 does not release the locking recess 38, so that a rotation of the cylinder core is prevented.

When it comes to variation numbers, it can be established that at each of the obliquely arranged profile notes, four variation possibilities can also be provided. In fig. 8, three of these possibilities are shown, and the fourth variation consists in the fact that the small plate is without sensing end 35, so that there is also no inclined profile groove adapted to the key. The small plate 34 thereby prevents an impact of the housing pin 41 into the core recess 31 when this is rotated past the housing pin 41. The core pin has reference number 47. The arrangement of the inclined profile notches does not affect the variation numbers with respect to the longitudinal profile elements. The variations of the slanted profile notes thus come to full effect. If the slanted profile notes are only arranged on one key side, this increases the number of profile elements available for variation by six. Five longitudinal profile elements on each key side provide 1024 variation possibilities. Three additional slanted profile notes together with the longitudinal profile elements provide approximately 64,000 variation options.

Alternatives to the examples shown are possible in a variety of ways within the scope of the invention. On the key, the slanted profile notes can also be arranged crossed over each other, with one of the two notes being sensed in the core. That way, the same key can lock in different cores.

The profile grooves 18, 19, 20 are preferably brought up to the center line of the key profile cross-section or somewhat shallower in order to avoid breaking through the key wall. Fig. 10 is a side view of a second embodiment of the key according to the invention. The slanted profile notes 18,19,20 are, compared to the embodiment in fig. 1, advanced more to the key tip and partially overlap. Profile grooves 18 and 20 are narrower, while profile groove 19, on the other hand, has twice the width (see also fig. 14). Fig. 11 is a sectional view along the line XI-XI and is self-explanatory. The cut edges with the longitudinal profile notches 8, 11 are not drawn in this section to make the preparation easier. Fig. 12, 13 are representations analogous to fig. 2 and 3. Shown are all profile possibilities and the possible cross-sectional shapes for the inclined profile groove 42, 43 on the left or right key side. It is possible to arrange both profile notes 42, 43 on both sides of a key. For sensing of such a key at all sensing points, the corresponding small plates must of course be arranged on both sides of the key channel.

The individual longitudinal profile elements are shown in fig. 12, 13 with such a dimension that is advantageous in practice. A possible rib 44 is shown with hatching. At reference number 45, there are two ribs arranged next to each other which in this area complete the key up to the wrapping end 46.

Fig. 14 schematically shows the four variation options A) - D) for the cross-section of the inclined profile grooves 18, 19 or 20. The profile groove 19 in fig. 10 corresponds to variant B). The profile notes 18 and 20 which are also drawn on fig. 10 corresponds to either variant A) or variant D). The variant marked with C) is a variant where there is no inclined profile groove, and the small plate 34 therefore does not need a sensing end 35 either.

The angle between the profile notches 18, 19, 20 and the key's insertion direction can be chosen arbitrarily and is in the embodiment in fig. 10 about 15°.

A further embodiment of the key according to the invention and the associated lock is shown in fig. 15 - 20.

Fig. 15 shows the end side of the cylinder housing 39 with the notched cylinder core 26. A key 52 is pushed into the key channel which, in the release position, presses the cam pin 47 downwards. The core pin 47 is inserted into the core pin bore 51.

In this embodiment, the small plate 48 is biased in the direction towards the locking recess 38 by means of a spring 50. The small plate 48 has a tongue 53 projecting downwards which the pressure spring 50 engages. For guiding the tongue 53 and receiving the spring 50, a recess 49 is arranged in the housing.

In the variant shown in fig. 15, the small plate 48 with its sensing end 54 rests against the key material, so that the lock cannot be blocked. A blocking is only possible when a correct key is inserted which has the profile notch that corresponds to the sensing end's 54 profile notch.

Fig. 16-19 shows a variant of the small plate 48 in elevation which is coordinated with each other. At 17 is a sectional view along the line XVII-XVII in fig. 16.

The sensing end 54 of the small plate 48 shows slanted profiling which is arranged complementary to a corresponding profiling of slanted profile notes on the associated key.

Just as an example, two grooves 55, 56 and three ribs 57, 58 and 59 are provided. This inclined profiling can preferably be done in the same or similar way as the longitudinal grooves and longitudinal ribs on the key flat sides, as both the basic profile and the variable profile as previously described is arranged distributed over the key area which is effective for blocking and opening, and these profiles are pushed into each other. The blocking continuation has reference number 60 in these figures.

Fig. 20 is a side view of an embodiment of a key 52, how it can be used in connection with the lock in fig. 15-19. On the key flat side, in addition to the longitudinal grooves and longitudinal ribs, inclined profile groove groups 61, 62, 63 are arranged in three places which can be sensed by correspondingly designed small plates 48 in the lock.

Here, the profile notes assume an angle of approximately 45° in relation to the key's insertion direction, which is only shown as an example.

In the previously described design examples, several small plates are arranged in the lock on at least one side of the key channel, e.g. three small plates 54 in fig. 16 -19 corresponding to the three inclined profile groove groups 61, 62 and 63 in fig. 20.

In the preferred embodiment of fig. 21 - 27, two inclined profile groove groups 64, 65 are arranged on a key flat side (fig. 26) which together are sensed by a single small plate 66, as shown in fig. 21 - 23. The small plate 66 comprises at the sensing end 67 in two groups all inclined profile ribs 68 which are necessary for sensing the key's two profile groove groups 64 and 65 according to fig. 6. Along the locking continuation 69, a construction rib 70 extends to one side of the small plate 66.

Fig. 24 is an incomplete side view of a cylinder core 71 with the recess 72 which has occupied the small plate 66. Fig. 25 is a sectional view along the line 25 - 25 in fig. 24. The contact rib 70 of the small plate 66 (fig. 21, 22) prevents, in cooperation with the edge 73, too long penetration of the small plate 66 into the cylinder core, when it is displaced within the recess.

With regard to the above embodiment of the previously described embodiment examples, the function will be clear. When all the slanted ribs 68 of the small plate 66 agree with the slanted profile grooves on the key's two profile groove groups 64, 65 according to fig. 6, the small plate 66 can be pushed into the cylinder core 71 so far that the locking extension 69 releases the corresponding groove in the cylinder housing and the cylinder core 71 can be turned. This results in a function position which is shown analogously in fig. 9. If the key does not match the lock, the locking extension 69 remains at least in sections in engagement with the cylinder housing's associated locking recess and the lock is blocked. Fig. 27 is a sectional view along the line XXVII-XXVII in fig. 26 and shows that the millings for forming the inclined profile groove 74 are circular arc-shaped and do not cut the key spine 75, so that the key spine 75 also remains smooth on its edges, which facilitates the insertion of the key and avoids sharp points. Fig. 28 shows a further development of the small plate in fig. 21 - 23. In the central area with reduced cross-sectional dimensions, a pusher 76 is arranged whose two legs 77, 78 are somewhat shorter than the width of the small plate 66 with which the sensing end 67 with the inclined ribs 68 engages in the key's inclined profile notches.

In the case of a regulatedly designed "correct" key, the pusher 76 abuts with its sensing end against the flat side 79 of the key in such a way that its abutting end 82 uncovers the recess 83 as much as possible and guides the housing pins arranged in this plane of rotation over the recess 83. In the case of a fake key, as on the key flat side 79 instead of slanted profile grooves and ribs has a continuous large longitudinal groove, the pusher 76 with its sensing end 81 is inserted into this groove in the key, so that the housing pin 84 springs into the recess 83 by turning the cylinder core 85 and catches the cylinder core. This "negative" control increases security against unauthorized imitation of the key and disconnection of the control of the inclined profile elements by arrangement of a simple wide longitudinal groove in the key.

To fig. 29, it should also be noted that the pusher 76 has no abutment rib 70. Of the housing pin 84, any one that cooperates with the core pins in a known manner is preferred.

The recess 83 is somewhat extended (extension 86) for receiving the housing pin 84. On the other side, a running surface 87 (shown in dashed lines) may be arranged to enable the core to be turned back.

Fig. 30 shows the cross-section of a part of the key 88 along an inclined profile groove 89.1 the area at the deepest cut is a longitudinal rib 90 so that the stability of the key is increased.

Claims (15)

1. Key for a cylinder lock which on the key flat sides has longitudinal ribs and/or longitudinal grooves that extend in the key's insertion direction in the key channel, where at least one further profile groove (18, 19, 20, 74, 89) is additionally arranged on at least one key flat side which has a length that is smaller than the length of the key blade (2), characterized in that the profile notch (18,19,20, 74, 89) has a straight shape over its entire length, and is arranged at an angle in relation to the insertion direction (3), and cuts at least one longitudinal groove (8,11). 2. Key according to claim 1, characterized in that the slanted profile groove (74) extends arcuately in depth and ends in the associated key flat side, so that the edges of the key ridge (75) have a smooth course. 3. Key according to one of claims 1 - 2, characterized in that the longitudinal grooves (8-17) and the profile grooves (18,19,20,74) are arranged on both key flat sides. 4. Key according to one of claims 1-3, characterized in that a longitudinal rib (90) is arranged in the area of the deepest cut of the slanted profile notches (89) on the flat side of the key. 5. Key according to one of claims 1-4, characterized in that the key has profile grooves (21) which have different angular positions in relation to the key's insertion direction (3). 6. Key according to one of claims 1-5, characterized in that it for locking systems, for designing the longitudinal profiling in a manner known per se, comprises an invariable basic profile and a variable profile within a locking system which together make up the total profile, and then well the basic profile as the variable profile is arranged distributed over the key area which is effective for locking or opening, and the profiles are arranged pushed into each other so that on each side of the key there is arranged at least one profile element of the basic profile or the variable profile between two profile elements of the variable profile or the basic profile. 7. Key according to one of claims 1 - 6, characterized in that at several, preferably two or three sensing locations on the key flat side of the key (52), profile groove groups (61-65) are arranged at an angle in relation to the key's insertion direction. 8. Key according to claim 7, characterized in that the profile groove groups (61, 62, 63) each form a profiling whereby an invariable base profile and a variable profile are arranged in a manner known per se within a closing system which together make up the overall profile, and both the basic profile and the variable profile are arranged distributed over the key area which is effective for blocking or opening, and the profiles are arranged pushed into each other so that at least one profile element of the basic profile is arranged respectively. the variable profile between two profile elements of the variable profile or the basic profile. 9. Cylinder lock for flat keys according to one of claims 1-8, where sensing elements are arranged which sense the key flat sides with a sensing end, and lie with locking extensions in the cylinder core's zero position opposite locking recesses in the cylinder housing, and when the cylinder core is turned with the correct key lies within the cylinder core, and remains with false keys in the locking recess and thus prevents turning, characterized in that the sensing elements are small plates (34, 48, 66) which extend along the key's insertion direction, and that the sensing ends (35) of these small plates are arranged at an angle in relation to the key's insertion direction corresponds to the angle of the profile notch on the associated key (40). 10. Cylinder lock according to claim 9, characterized in that the sensing end (35) of the small plate (34) is arranged opposite or below or on both sides of a profile rib symmetry line (37) in the small plate, or the sensing end (35) is omitted completely so that each small plate has four variation possibilities . 11. Cylinder lock according to claim 10, characterized in that the small plate or small plates (48) have profile grooves (55, 56) and profile ribs (57, 58, 59) at an angle in relation to the key's insertion direction and analogously to the profile groove group's (61,62,63) profiling. 12. Cylinder lock according to one of claims 9-11, characterized in that the small plate is resiliently biased in the direction towards the locking recess (38) of the cylinder housing (39). 13. Cylinder lock according to claim 12, characterized in that the small plate has a tongue (53) for abutment against a pressure spring (50) which is supported on the cylinder core (26). 14. Cylinder lock according to claim 9, characterized in that on at least one side of the key channel in the cylinder core (71) in a recess (72) a single small plate (66) is arranged which at the sensing end (67) has two groups of inclined profile ribs (68) . 15. Cylinder lock according to claim 14, characterized in that the small plate (66) has a pusher (76) which is displaceable in relation to the small plate and which has a length which in the direction of displacement is smaller than the width of the small plate, the pusher (76) with a proper key abuts against the flat side of the key (79) with its sensing end (81), and covers with its running end (82) the recess (83) up to the cylinder housing, and is inserted with a false key with its sensing end into a groove in the key and releases the recess (83) with its running end (82) so that a spring-biased housing pin (84) can enter the recess (83) and thus block the cylinder core (85).