DE102022114503A1 - Key and locking device - Google Patents

Abstract

The present invention relates to a key (10) for a lock cylinder (52), wherein the key (10) has a key shaft (14), the key shaft (14) extending in a longitudinal direction (18) from a key head (12) to a Key tip (16) of the key (10), the key shaft (14) having two key broad side surfaces (24), the key (10) further having a cam (36) which protrudes from one of the key broad side surfaces (24), wherein the cam (36) is formed in one piece with the key shaft (14). The present invention further relates to a locking device (50) with such a key (10) and a lock cylinder (52).

Description

The present invention relates to a key for a lock cylinder, the key shaft extending in a longitudinal direction from a key head to a key tip of the key, the key shaft having two key broad side surfaces, the key further having a cam. The present invention further relates to a locking device with a key and a lock cylinder.

Such keys and locking cylinders are, for example, from the publication EP 1 593 800 B1 known.

The publication EP 1 593 800 B1 relates to a locking device consisting of a key and a locking cylinder, wherein a cylinder core mounted in a cylinder housing has a key channel for inserting the key shaft of the matching key, which key shaft is able to displace tumbler pins protruding into the key channel in such a way that the cylinder core is rotatable, the Key shaft has an insert piece which cooperates with a supplementary locking part mounted in a bore of the cylinder core, the insert piece having a shaft and a head, the shaft being inserted into an opening in the key shaft and the head interacting with a supplementary part.

The head of such an insert serves as a projection or cam, which is queried as a security feature in the cylinder core, for example by means of the associated additional locking part. Every time the key is used to open the corresponding lock cylinder, mechanical forces act on the insert. In other words, the insert is subjected to mechanical stress every time the key is used. After a certain number of uses of the key, the insert can become loose, which can cause the insert to fall out of the hole or at least make it more difficult to query the insert in the cylinder core.

Against this background, it is therefore an object of the present invention to provide an improved key and an improved locking device. In particular, it is an object of the present invention to provide a key with high mechanical stability and long durability. Furthermore, it is an object of the present invention to provide a key that is as simple and inexpensive to produce as possible.

According to a first aspect, a key for a locking device is provided, wherein the key has a key shaft, the key shaft extending in a longitudinal direction from a key head to a key tip of the key, the key shaft having two key broad side surfaces, the key further comprising a cam , which protrudes from one of the key broad side surfaces, the cam being formed in one piece with the key shaft.

The key shaft of the key extends between the key head and the key tip of the key. This extension defines a longitudinal direction of the key from key head to key tip. The key shaft can have a rectangular or substantially rectangular cross-sectional profile along the longitudinal direction. The two longer sides of this rectangle are called the key broadside surfaces. The two shorter sides of the rectangle in cross section are referred to below as the key narrow side surfaces. The two key broad side surfaces are thus arranged perpendicular to the longitudinal direction on opposite sides of the key shaft.

The key shaft has a length in the longitudinal direction. The length of the key shaft can be 20 mm to 70 mm, preferably 30 mm to 50 mm, in particular 43 mm. A first direction is perpendicular to the longitudinal direction and parallel to each key broadside surface. The first direction can also be called the key broadside direction or width direction. The key shaft has a width in the first direction. The width of the key shaft can be 4 mm to 20 mm, preferably 6 mm to 12 mm, in particular 8.9 mm. A second direction is perpendicular to the longitudinal direction and perpendicular to each key broadside surface. The second direction can also be called the key narrow side direction or the elevation direction. The key shaft has a height (also called thickness) in the second direction. The height of the key shaft can be 1 mm to 10 mm, preferably 2 mm to 5 mm, in particular 2.4 mm. The longitudinal direction, the first direction and the second direction are perpendicular to one another in pairs.

The cam is arranged on at least one of the key broad side surfaces. A cam can also be arranged on each key broad side surface, for example if the key is designed as a reversible key. The cam is a projection that protrudes from the key broadside surface in the second direction. In other words, the cam rises from the corresponding one the key broadside surface in the second direction.

Each key broadside surface can have a basic profile contour. The basic profile contour of each key broad side surface can have a plane, starting from the plane one or more recesses (such as holes, grooves, recesses, etc.) can be formed, which serve as security features of the key and can be queried in a locking cylinder. These recesses thus extend inwards from the plane in the second direction. The cam therefore protrudes particularly on the flat side, i.e. from the plane, of the basic profile contour in the second direction.

The cam is formed in one piece with the key shaft. In other words, the cam is integrally formed with the key shaft. To produce a key with a key shank and a cam that are integrally formed, for example, a die-casting process, an extrusion process or a machining process (e.g. a milling process) can be used.

The cam has a length in the longitudinal direction. The length can be 2 mm to 10 mm, preferably 4 mm to 8 mm, in particular 6.3 mm. The cam has a width in the first direction. The width can be 0.8 mm to 3 mm, preferably 1.2 mm to 2 mm, in particular 1.5 mm. The cam has a height in the second direction. The height can be 0.1 mm to 2 mm, preferably 0.2 mm to 1 mm, more preferably 0.3 mm to 0.7 mm, in particular 0.48 mm.

According to a second aspect, a locking device is provided with a key according to the first aspect and a lock cylinder, the lock cylinder having a housing and a cylinder core, the lock cylinder having one or more locking devices, each locking device being movable between a locking state and a release state and a rotational movement of the cylinder core relative to the housing blocks in the locked state and releases it in the released state, the cam being assigned to one of the locking devices.

The cylinder core has a substantially cylindrical shape. According to this cylindrical shape, a radial direction and an axial direction are defined. The key channel has an opening at an axial end of the cylinder core through which the key can be inserted or inserted into the key channel. The key is inserted into the key channel of the cylinder core in one insertion direction and removed from the key channel of the cylinder core in the opposite direction to the insertion direction. The insertion direction corresponds to the axial direction.

When the key is inserted into the key channel along the axial direction, the cam of the key is sensed with the associated locking device. The cam interacts with the associated locking device in such a way that the locking device cannot block a rotational movement when the key is fully inserted. In other words, the locking device is in the released state when the key is fully inserted.

However, if the key is not fully inserted or if an incorrect key is used, in particular a key without a cam or without a matching cam, the locking device can enter the locking state.

For example, the locking device can be designed in such a way that the locking device has the locking state as its basic state, i.e. in the state without an inserted key, and can only be transferred to the unlocking state by completely inserting the correct key, i.e. the key with the appropriate cam. In other words, the rotational movement is only released when the key with the appropriate cam has been fully inserted.

Alternatively, the locking lock can also be designed in such a way that the locking lock initially releases the rotational movement and only changes to the locking state after the cylinder core has rotated through a certain angle, for example 135° or 225°, unless the key has the appropriate cam. In other words, the locking protection has the release state as the basic state. When using a key with a suitable cam, the locking device remains in the released state even when the cylinder core is rotated. If, on the other hand, a key is used that does not have a suitable cam, the locking device is put into the locked state after the cylinder core has been rotated through a certain angle. In this case, the wrong key can no longer be removed.

Due to the one-piece design of the cam with the key shaft, the key has a high level of mechanical stability in the area of the cam. This prevents the position of the cam from changing, the cam from deforming or the cam from falling off the key shaft after a large number of uses of the key.

The task set at the beginning is thus completely solved.

In a first embodiment of the first or second aspect, the cam extends in the longitudinal direction.

The cam is preferably elongated. In particular, the length of the cam can be greater than the width of the cam.

In a further embodiment of the first or second aspect, the cam has a length in the longitudinal direction, the length of the cam being 5-25%, preferably 8-20%, more preferably 10-15%, in particular 12%, of the length of the key shaft amounts.

The cam therefore only extends in the longitudinal direction over a relatively small area of the key's broad side surface.

In a further embodiment of the first or second aspect, a transition of the cam to the key broad side surface is smooth.

The term “smooth” means that the transition is continuous or continuous and has no edge or kink. In other words, the slope or gradient of the key broad side surface and the slope or gradient of the cam at the transition are the same. This further improves the mechanical stability of the key in the area of the cam. Furthermore, the cam cannot be curved too much in the transition areas. For example, a radius of curvature in these areas can be greater than 0.1mm. This also further improves the mechanical stability.

In a further embodiment of the first or second aspect, the cam has a head region.

Preferably, the head area extends in the longitudinal direction. The head area of the cam is the area of the cam with the greatest height. The head area is in particular the area that is used for querying in the lock cylinder. The head area can in particular be designed such that a cam control pin of the associated locking device rests against the head area when the key is fully inserted into the locking cylinder and is arranged in a release position. The head area has a length in the longitudinal direction. The length of the head area can be 1 mm to 9 mm, preferably 3 mm to 7 mm, in particular 5.1 mm. The head area has a width in the first direction. The width of the head area can be 0.5 mm to 2 mm, preferably 8 mm to 1.5 mm, in particular 1.1 mm.

In a further embodiment of the first or second aspect, the head region is flat in the longitudinal direction.

In other words, the height of the cam remains the same or essentially the same along the longitudinal direction in the head area.

In a further embodiment of the first or second aspect, the head region is convexly shaped in a first direction that runs perpendicular to the longitudinal direction and parallel to the key broad side surfaces.

In particular, the cam can be rounded in the head area. The curvature of the head region in the first direction can have a radius of curvature of 1 mm to 5 mm, preferably 2 mm to 3 mm, in particular 2.4 mm.

In a further embodiment of the first or second aspect, the cam has a transition region on the key head side and a transition region on the key tip side, the head region being arranged in the longitudinal direction between the transition region on the key head side and the key tip side, in particular wherein the transition region on the key head side and the key tip side are designed in such a way that the cam has a smooth transition to the key broad side surface in the longitudinal direction.

The key tip-side transition area is arranged between the head area and the key broad side surface. The key tip-side transition area describes the transition of the cam to the key broad side surface on the side of the cam facing the key tip. The key head-side transition region is also arranged between the head region and the key broad side surface. The key head-side transition area describes the transition of the cam to the key broad side surface on the side of the cam facing the key head. The transition area on the key head side and the key tip side are designed such that the cam has a smooth transition to the key broad side surface in the longitudinal direction. For example, the key tip-side and the key head-side transition region can each have a convex section and a concave section. The convex section adjoins the head area. The concave section adjoins the key broad side surface. The transition between convex and concave Section can run parallel to the second direction or inclined to the second direction. The transition from the concave area to the key broad side surface is preferably smooth. Preferably, the convex and concave sections have the same radius of curvature. Preferably, the transition region on the key head side is longer in the longitudinal direction than the transition region on the key tip side.

In particular, the transition area on the key tip side can have a length. The length of the transition region on the key tip side can be 0.2 mm to 1.5 mm, preferably 0.3 mm to 1 mm, in particular 0.4 mm. The transition between the convex and the concave section of the key tip-side transition region is preferably inclined with respect to the second direction. The inclination can be 5° to 45°, preferably 12° to 30°, in particular 20°. The radii of curvature of the convex and concave section of the key tip-side transition region are preferably the same and amount to 0.1 mm to 0.75 mm, preferably 0.15 mm to 0.5 mm, in particular 0.2 mm.

In particular, the transition area on the key head side can have a length. The length of the transition region on the key head side can be 0.2 mm to 1.5 mm, preferably 0.4 mm to 1.2 mm, in particular 0.8 mm. The transition between the convex and the concave section of the key head-side transition region is preferably parallel to the second direction. The radii of curvature of the convex and concave section of the key head-side transition region are preferably the same and are 0.1 mm to 0.75 mm, preferably 0.2 mm to 0.6 mm, in particular 0.4 mm.

In a further embodiment of the first or second aspect, the cam has two lateral transition regions in the first direction, the head region being arranged in the first direction between the two lateral transition regions, in particular wherein the two lateral transition regions are designed such that the cam in the first direction has a smooth transition to the key broad side surface.

The lateral transition areas describe the transition of the cam to the key broadside surface on both sides of the cam in the first direction. The lateral transition areas are designed such that the cam has a smooth transition to the key broad side surface on both sides in the first direction. For example, the lateral transition areas can be straight. In other words, the lateral transition regions can have a constant inclination relative to the second direction. The inclination relative to the second direction can be 0° to 45°, preferably 20° to 35°. In particular, the inclinations of the two lateral transition areas can be different. For example, one side transition area can be inclined by 20° and the other can be inclined by 35°.

In a further embodiment of the first or second aspect, the cam is arranged in the longitudinal direction on the key broad side surface in the middle or on the key head side.

This distances the cam from the tip of the key. In particular, the cam is arranged closer to the key head than to the key tip. The distance to the key tip in the longitudinal direction can be 10 mm to 30 mm, preferably 15 mm to 25 mm, in particular 22 mm.

In a further embodiment of the first or second aspect, the key shaft has a key stop, with the cam being arranged in the longitudinal direction on or near the key stop.

The key stop forms a stop for the lock cylinder. In particular, the key shaft can only be inserted or inserted into the key channel of the cylinder core up to the key stop. The key stop thus defines an insertion area of the key in the longitudinal direction. The insertion area is the area of the key shaft that is located in the key channel when the key is fully inserted into the key channel. Preferably, the cam extends in the longitudinal direction from the key stop towards the key tip. In particular, an end of the cam on the key head side can be arranged closer, for example by 0.5 mm, to the key head than the key stop. In other words, the cam can extend further towards the key head than the insertion area of the key.

In a further embodiment of the first or second aspect, the cam is arranged at a distance from the lateral edges of the key shaft in the first direction.

In other words, the cam is at a distance from the narrow sides of the key shaft. In particular, the cam can be arranged centrally or offset from the center in the first direction with respect to the key shaft.

In a further embodiment of the first or second aspect, the key broad side surface has a plurality of longitudinal grooves, each longitudinal groove running parallel to the longitudinal direction (16), the cam being arranged on an elevation between two of the plurality of longitudinal grooves.

The longitudinal grooves form recesses in the basic profile contour of the key broad side surfaces in the second direction. The basic profile contour then has an elevation between two longitudinal grooves. The elevation is preferably flat in the longitudinal direction. The elevation only rises up to a maximum of the level of the basic profile contour of the key broad side surface. The cam is arranged on such a survey. The cam thus increases the elevation in the second direction beyond the key broad side surfaces (in particular beyond the plane of the basic profile contour of the key broad side surfaces). In other words, the cam sits on such an elevation. The elevation has a width in the first direction. The width of the elevation can be 1.5 mm to 8 mm, preferably 2 mm to 5 mm, in particular 3.11 mm. The elevation extends to the tip of the key. In the area in which the cam is not arranged, the elevation can have a convex shape in the longitudinal direction. The longitudinal grooves can be correspondingly concavely curved. The radius of curvature of the curvature of the elevation can be 1 mm to 5 mm, preferably 2 mm to 3 mm, in particular 2.4 mm. Preferably, the curvature of the result in the first direction has the same radius of curvature as the curvature of the head region of the cam. In particular, the centers of curvature of these two curvatures can be offset from one another in the first direction. The offset can be, for example, 0.1 to 0.5 mm, preferably 0.2 mm to 0.3 mm, in particular 0.25 mm.

In a further embodiment of the first or second aspect, a transition from the cam to the elevation is smooth.

In other words, the transition from the cam to the elevation is continuous and has no edge or kink. In other words, the cam and the bump at the transition have the same pitch or inclination. In particular, the concave areas of the transition area on the key head side and the key tip side enable a smooth transition in the longitudinal direction to the flat area of the elevation. On the sides in the first direction, the elevation slopes down, preferably straight, into the two longitudinal grooves. The elevation has a slope or slope on each side. At the transition, the gradient or inclination corresponds to the gradient or inclination of the corresponding lateral transition area. In this way the mechanical stability is further improved.

In a further embodiment of the second aspect, the locking device has a cam control pin, wherein the cam control pin is mounted in the cylinder core so that it can move in the radial direction, wherein the cam control pin is movable in the radial direction between a locking position and a release position, the cam control pin being inserted by inserting the key can be moved from the locking position to the release position by the cam.

The cylinder core preferably has a radial bore which extends to the key channel. The cam control pin is arranged in the radial bore and is mounted movably therein in the radial direction between the locking position and the release position. When the cam control pin is located in the release position, the lockout safety is in the release state. When the cam control pin is located in the locking position, the locking safety can be moved to the locking state.

In a further embodiment of the second aspect, the locking device has a housing pin, wherein the housing pin is mounted in the housing so as to be movable in the radial direction, the housing pin being biased inwards in the radial direction, wherein when the cam control pin and the housing pin are arranged radially aligned are, the cam control pin and the housing pin cooperate in such a way that the housing pin blocks the rotational movement of the cylinder core relative to the housing in the locking position of the cam control pin and releases it in the release position of the cam control pin, in particular wherein the locking device is in the locking state when the housing pin blocks the rotational movement of the cylinder core locked against the housing.

The housing preferably has a radial bore which extends radially outwards from the cylinder core. The housing pin is arranged in the radial bore and is mounted movably therein in the radial direction. In particular, the housing pin is biased inwards in the radial direction by means of a spring element. When the cam control pin and the housing pin are not radially aligned, the lockout safety is in the release state. When the cam control pin and the housing pin are disposed in radial alignment, the cam control pin and the housing pin can cooperate to transition the locking mechanism between the release state and the locking state. For this purpose, the housing pin is designed in such a way that it fits into the radial bore of the cylinder core, in which the cam control pin is arranged, can be inserted if the cam control pin and the housing pin are arranged radially aligned. If the housing pin partially extends into the radial bore of the cylinder core, the rotational movement of the cylinder core relative to the housing is blocked. The locking device is then in the locking state. When the cam control pin is disposed in the locking position (i.e., when the cam control pin is not offset radially outward by the mating cam), the locking safety is moved to the locking state or the locking safety remains in the locking state when the cam control pin and the housing pin are arranged radially aligned are. When the cam control pin is disposed in the release position (i.e. when the cam control pin is offset radially outward by the mating cam), the locking safety is moved to the release state or the locking safety remains in the release state when the cam control pin and the housing pin are arranged radially aligned . The movement of the locking device from the locked state to the released state or the holding of the locking device in the released state is carried out by the cam, which presses the cam control pin into the release position and holds it there. The cam prevents the housing pin from penetrating the radial bore of the cylinder core. The movement of the locking device from the release state to the locked state or the holding of the locking device in the locked state is carried out by the pretensioning force, which presses the housing pin radially inwards. The preload force causes the housing pin to be pressed radially inwards into the radial bore of the cylinder core.

In a further embodiment of the second aspect, the key channel has a longitudinal groove which is assigned to the cam, the longitudinal groove extending at least as far as the cam control pin.

In particular, the longitudinal groove extends at least from the opening of the key channel at the axial end of the cylinder core to the cam control pin. In particular, the length of the longitudinal groove in the axial direction of the cylinder core can be as long as the length of the cam in the longitudinal direction of the key. The longitudinal groove preferably extends to the radial bore for the cam control pin. In the locking position, the cam control pin is partially arranged in the longitudinal groove, in particular with its radially inner end. The radially inner end can be rounded. When the key is inserted, the cam is moved in the longitudinal groove up to the hole and the cam control pin arranged therein. When the key is fully inserted, the cam control pin is pushed radially outwards from the longitudinal groove by means of the cam. In the release position, the cam control pin is therefore not arranged in the longitudinal groove.

In a further embodiment of the second aspect, a cross-sectional contour of the longitudinal groove is designed to be complementary to a peripheral surface of the cam.

In this way, a circumferential surface contour of the cam, in particular a size of the cam, can also be queried. The outer cross-sectional contour can then serve as a further security feature, which can be queried using the key channel.

It is understood that the features mentioned above and those to be explained below can be used not only in the combination specified in each case, but also in other combinations or alone, without departing from the scope of the present invention.

• 1 eine isometrische Ansicht einer Ausführungsform eines Schlüssels;
• 2 eine Draufsicht des Schlüssels aus 1;
• 3 eine Seitenansicht des Schlüssels aus 1;
• 4 eine Vergrößerung des durch IV gekennzeichneten Bereichs aus 3;
• 5 eine Querschnittansicht entlang einer Linie V-V in 2;
• 6 eine isometrische Ansicht einer Ausführungsform einer Schließvorrichtung;
• 7 eine isometrische Ansicht der Schließvorrichtung aus 6 mit vollständig eingeführtem Schlüssel;
• 8 eine isometrische Ansicht der Anordnung eines Nockenkontrollstifts an dem Schlüssel in 7;
• 9 eine Draufsicht in axialer Richtung auf einen Zylinderkern eines Schließzylinders der Schließvorrichtung aus 6;
• 10 eine Draufsicht in axialer Richtung auf einen Zylinderkern eines Schließzylinders der Schließvorrichtung aus 6 mit eingeführtem Schlüssel;
• 11 eine Längsschnittansicht der Schließvorrichtung aus 6 mit vollständig eingeführtem Schlüssel;
• 12 eine Längsschnittansicht der Schließvorrichtung aus 6 mit teilweise eingeführtem Schlüssel;
• 13 eine Querschnittansicht der Schließvorrichtung aus 6 in radialer Richtung mit vollständig eingeführtem Schlüssel;
• 14 eine Querschnittansicht der Schließvorrichtung aus 6 mit teilweise eingeführtem Schlüssel;
• 15 eine Querschnittansicht der Schließvorrichtung aus 6 mit verdrehtem Zylinderkern im Sperrzustand; und
• 16 eine Querschnittansicht der Schließvorrichtung aus 6 mit verdrehtem Zylinderkern im Freigabezustand.

Embodiments of the invention are shown in the drawing and are explained in more detail in the following description. Show it:

• 1 an isometric view of an embodiment of a key;
• 2 a top view of the key 1 ;
• 3 a side view of the key 1 ;
• 4 an enlargement of the area marked by IV 3 ;
• 5 a cross-sectional view along a line VV in 2 ;
• 6 an isometric view of an embodiment of a locking device;
• 7 an isometric view of the locking device 6 with key fully inserted;
• 8th an isometric view of the arrangement of a cam control pin on the key in 7 ;
• 9 a top view in the axial direction of a cylinder core of a locking cylinder of the locking device 6 ;
• 10 a top view in the axial direction of a cylinder core of a locking cylinder of the locking device 6 with key inserted;
• 11 a longitudinal sectional view of the locking device 6 with key fully inserted;
• 12 a longitudinal sectional view of the locking device 6 with key partially inserted;
• 13 a cross-sectional view of the locking device 6 in the radial direction with the key fully inserted;
• 14 a cross-sectional view of the locking device 6 with key partially inserted;
• 15 a cross-sectional view of the locking device 6 with twisted cylinder core in locked state; and
• 16 a cross-sectional view of the locking device 6 with twisted cylinder core in release state.

The 1 until 3 show an embodiment of a key 10. The key 10 has a key head 12, which is also called a key head. The key head 12 is used to manually grip the key 10. A key shaft 14 extends from the key head 12. Various security features are arranged on the key shaft 14, which are queried when the key 10 is inserted into a corresponding locking device. If the query is positive, the locking device can be moved from a locked state to a released state.

The key shaft 14 extends along a longitudinal direction 18 from the key head 12 to a key tip 16 of the key 10. The key shaft 14 has a rectangular or substantially rectangular cross-sectional profile. The two longer sides of this rectangle are referred to as key broad side surfaces 24. The two shorter sides of the rectangle in cross section are referred to below as key narrow side surfaces 26. The key broad side surfaces 24 and the key narrow side surfaces 26 are each arranged opposite to one another.

A first direction 20 runs perpendicular to the longitudinal direction 18 and parallel to each key broad side surface 24. A second direction 22 runs perpendicular to the longitudinal direction 18 and perpendicular to each key broad side surface 24. The longitudinal direction 18, the first direction 20 and the second direction 22 are perpendicular in pairs each other. The directions 18, 20, 22 thus form a Cartesian coordinate system.

The key shaft 14 has a length L1 in the longitudinal direction 18. The length L1 can be 20 mm to 70 mm, preferably 30 mm to 50 mm, in particular 43 mm. The key shaft 14 has a width B1 in the first direction 20. The width B1 can be 4 mm to 20 mm, preferably 6 mm to 12 mm, in particular 8.9 mm. The key shaft 14 has a height H1 in the second direction 22. The height H1 can be 1 mm to 10 mm, preferably 2 mm to 5 mm, in particular 2.4 mm.

Each key broadside surface can have a basic profile contour. The basic profile contour of each key broad side surface can have a plane, one or more recesses (such as bores, grooves, recesses, etc.) being formed starting from the plane. In particular, each key broad side surface can have a plurality of longitudinal grooves 28. In the embodiment shown, the key broad side surface 24 has two longitudinal grooves 28. An elevation 30 is arranged between the two longitudinal grooves 28. The elevation 30 also extends in the longitudinal direction 18. In particular, the longitudinal grooves 28 and the elevation 30 can extend up to the key tip 16. The elevation 30 becomes wider towards the longitudinal grooves 28.

The key shaft 14 can also have a key bit 32 which is formed on a key narrow side surface 26.

The key shaft 14 can also have a key stop 34. The key stop 34 serves as a stop for a lock cylinder when the key 10 is inserted into the lock cylinder. In other words, the key can only be inserted into the lock cylinder from the key tip 16 to the key stop 34. The key stop 34 thus defines an insertion area of the key shaft 14 in the longitudinal direction 18, which can be inserted into the lock cylinder. The security features of the key 10 to be queried are arranged in this insertion area.

The key 10 also has a cam 36. The cam is arranged on one of the key broad side surfaces 24. The key 10 can also have a cam 36 on each key broad side surface 24 and/or have several cams on a key broad side surface 24.

The cam 36 projects in the second direction 22 from the key broad side surface 24. The cam 36 is formed in one piece with the key shaft 14. In other words, the cam is integrally formed with the key shaft 14. The transitions of the cam to the key broad side surface 24 are smooth in the longitudinal direction 18 and in the first direction 20.

The cam 36 is arranged in the longitudinal direction 18 on the key broad side surface 24 in the middle or on the key head side. The cam 36 is spaced from the key tip 16. In particular, the cam 36 can be arranged closer to the key head 12 than to the key tip 16. Alternatively, the cam 36 can also be equally spaced from the key tip 16 and the key head 12. The distance to the key tip 16 in the longitudinal direction 18 can be, for example, 10 mm to 30 mm, preferably 15 mm to 25 mm, in particular 22 mm.

The cam 36 is arranged in the longitudinal direction 18 on the key stop 34. The cam 36 extends in the longitudinal direction 18 from the key stop 34 towards the key tip 16. An end of the cam 36 on the key head side is arranged closer (for example by 0.5 mm) to the key head 12 than the key stop 34.

The cam 36 is arranged at a distance from the lateral edges of the key shaft 14 in the first direction 20. The cam 36 is therefore at a distance from the narrow side surfaces in the first direction. In particular, the cam 36 can be arranged on the elevation 30.

In the 4 and 5 the arrangement and design of the cam 36 is shown in detail.

The cam 36 has a length L2 in the longitudinal direction 18. The length L2 can be 2 mm to 10 mm, preferably 4 mm to 8 mm, in particular 6.3 mm. The cam 36 has a width B2 in the first direction 20. The width B2 can be 0.8 mm to 3 mm, preferably 1.2 mm to 2 mm, in particular 1.5 mm. The cam 36 has a height H2 in the second direction 22. The height H2 can be 0.1 mm to 2 mm, preferably 0.2 mm to 1 mm, more preferably 0.3 mm to 0.7 mm, in particular 0.48 mm.

The cam 36 extends in the longitudinal direction 18. The cam 36 can be elongated. In particular, the length L2 of the cam 36 can be greater than the width B2 of the cam 36.

The cam has a head region 38, a transition region 40 on the key tip side, a transition region 42 on the key head side and two lateral transition regions 44, 46.

The head region 38 is arranged in the longitudinal direction 18 between the transition region 40 on the key tip side and the transition region 42 on the key head side. The head region 38 is arranged in the first direction 20 between the two lateral transition regions 44, 46. The transition areas 40-46 describe the transitions of the cam 36 from the head area 38 to the key broad side surface 24 in the longitudinal direction 18 and the first direction 20. The transition areas 40-46 are in particular designed so that the cam 36 in the longitudinal direction 18 and in the First direction 20 (i.e. on all sides of the cam 36) has smooth transitions to the key broad side surface 24.

The head area 38 has a length in the longitudinal direction 18. The length of the head region 38 can be 1 mm to 9 mm, preferably 3 mm to 7 mm, in particular 5.1 mm. The head area 38 has a width in the first direction 20. The width of the head area 38 can be 0.5 mm to 2 mm, preferably 8 mm to 1.5 mm, in particular 1.1 mm. The head area 38 is flat in the longitudinal direction 18. The head region 38 is convex in the first direction 20, in particular rounded. The curvature of the head region 38 in the first direction 20 can have a radius of curvature of 1 mm to 5 mm, preferably 2 mm to 3 mm, in particular 2.4 mm.

The key tip-side transition region 40 has a convex and a concave section in the longitudinal direction 18. The convex section borders the head area 38. The concave section borders on the key broad side surface 24. The transition from the concave area to the key broad side surface 24 is smooth. The transition from the convex section to the head region 38 is also preferably smooth. The transition between the convex and the concave section of the key tip-side transition region 40 is preferably inclined with respect to the second direction 20. The inclination can be 5° to 45°, preferably 12° to 30°, in particular 20°. The radii of curvature of the convex and concave section of the key tip-side transition region are preferably the same and amount to 0.1 mm to 0.75 mm, preferably 0.15 mm to 0.5 mm, in particular 0.2 mm.

The key head-side transition region 42 has a convex and a concave section in the longitudinal direction 18. The convex section borders the head area 38. The concave section borders on the key broad side surface 24. The transition from the concave area to the key broad side surface 24 is smooth. The transition from the convex section to the head region 38 is also preferably smooth. The transition between the convex and the concave section of the key head-side transition region 42 is preferably parallel to the second Direction. The radii of curvature of the convex and concave section of the key head-side transition region 42 are preferably the same and are 0.1 mm to 0.75 mm, preferably 0.2 mm to 0.6 mm, in particular 0.4 mm.

The lateral transition areas 44, 46 are designed such that the cam 36 has a smooth transition to the key broad side surface 24 in the first direction 20 on both sides. The lateral transition areas 44, 46 are straight, i.e. without any curvature. In other words, the lateral transition regions 44, 46 have a constant inclination relative to the second direction 22. The inclination relative to the second direction can be 0° to 45°, preferably 20° to 35°. In particular, the first lateral transition region 44 can have an inclination of 20° relative to the second direction 22 and the second lateral transition region 46 can have an inclination of 35° relative to the second direction 22.

In the area in the longitudinal direction 18 between the cam 36 and the key tip 16, the elevation 30 has a convex shape in the first direction 20 and a flat shape in the longitudinal direction 18. The two longitudinal grooves 28 on the two sides of the elevation 30 have a concave course in the first direction 20. The radius of curvature of the curvature of the elevation 30 can be 1 mm to 5 mm, preferably 2 mm to 3 mm, in particular 2.4 mm. Preferably, the curvature of the result 30 in the first direction has the same radius of curvature as the curvature of the head portion 38 of the cam 36. As in 5 shown, the curvature of the elevation 30 runs around a center of curvature Z1 and the curvature of the head region 38 runs around a center of curvature Z2. The centers of curvature Z1 and Z2 are offset from one another in the second direction corresponding to the height H2 of the cam 36. The centers of curvature Z1 and Z2 can also be offset from one another in the first direction 20. The offset in the first direction can be, for example, 0.1 to 0.5 mm, preferably 0.2 mm to 0.3 mm, in particular 0.25 mm.

The cam 36 and the elevation 30 are formed at the transitions in the longitudinal direction 18 and the first direction 20 so that these transitions are smooth. In other words, the cam 36 and the elevation 30 have the same pitch or inclination at the transitions. In particular, the concave areas of the transition area 40, 42 on the key head side and the key tip side enable a smooth transition in the longitudinal direction 18 to the flat area of the elevation 30. On the sides of the cam 36 in the first direction 20, the elevation 30 drops straight into the two longitudinal grooves . The elevation has a slope or slope on each of these sides. At the transition, the slope or inclination corresponds to the slope or inclination of the corresponding lateral transition area 44, 46.

6 shows an embodiment of a locking device 50. The locking device has the key 10, as described above in connection with 1 until 5 was described. Furthermore, the locking device 50 has a locking cylinder 52. In the first embodiment shown, the lock cylinder 52 is a profile cylinder. However, it can also be a different shape, for example a round cylinder or oval cylinder.

The lock cylinder 52 has a housing 54, a cylinder core 56 and a locking lug 58. The cylinder core 52 has a substantially cylindrical shape. According to this cylindrical shape, a radial direction, an axial direction and a circumferential direction are defined. The housing 54 has a cylindrical bore. The cylindrical bore extends from a first end to a second end of the housing 54. The cylinder core 56 is arranged in the cylindrical bore and is rotatably mounted in the circumferential direction. The cylinder core 56 is mounted in the housing 54, for example by means of a locking ring. The housing 54 also has a recess for the locking lug 58. The locking lug 58 is coupled to the cylinder core 56 and can be rotated together with it. The housing 54 is provided, for example, with a mounting hole 60 or threaded hole in order to be able to screw the lock cylinder 52 into a door.

The housing 54 and the cylinder core 56 can basically have a large number of holes in which locking devices, in particular pin tumblers, are guided in order to query various security features of the key 10.

The cylinder core 56 has a key channel 62. The key channel 62 has an opening at an axial end of the cylinder core 56 through which the key can be inserted or inserted into the key channel 62. The key channel 62 extends in the axial direction. The key 10 is introduced into this key channel 62. After the key 10 has been fully inserted and all security features of the key 10 have been queried positively, all locking devices are moved into a position that allows the cylinder core 56 to be rotated relative to the housing 54. This is called the release state. If the key 10 is not fully inserted into the key channel 86 or is completely pulled out of this, rotating the cylinder core 56 relative to the housing 54 is not possible. This is called a lockout state.

Only the locking device associated with the cam 36, which interacts with the cam 36, will be explained below.

In 7 the lock cylinder 52 is shown without the housing 54. The lock cylinder has a locking device 64. The locking device 64 is assigned to the cam 36. The locking device 66 interacts with the cam 36 in such a way that by completely inserting the key 10, the locking device 64 can be moved into the release state by the cam 36 or is held in this state.

The locking device 64 has a cam control pin 66. The cam control pin can also be called the core pin. The cam control pin 66 is arranged in a radial bore 68 of the cylinder core. The radial bore extends in the radial direction from a radially outer edge of the cylinder core 56 to the key channel 62. The cam control pin 66 is mounted in the radial bore 68 so that it can move in the radial direction. A radially inner end of the cam control pin 66 is rounded. When inserting the key 10, the cam 36 and the cam control pin 66 work together in such a way that the cam control pin 66 is pressed radially outward. The arrangement of the cam control pin 66 on the cam 36 with the key 10 fully inserted is in 8th shown.

In 9 the cylinder core 56 is shown without a key 10. In 10 the cylinder core 56 is shown with the key 10 inserted. The key channel 62 of the cylinder core 56 has a longitudinal groove 70. The longitudinal groove 70 extends in the axial direction up to the radial bore 68. The longitudinal groove 70 is assigned to the cam 36. In particular, a cross-sectional contour of the longitudinal groove 70 is designed to be complementary to a peripheral surface of the cam 36. The longitudinal groove 70 extends in the axial direction from the opening of the key channel 62 at the axial end of the cylinder core 56 to the radial bore 68, i.e. up to the cam control pin 66. This causes the cam 36 to be in the longitudinal groove 70 when the key 10 is inserted up to the cam control pin 66.

In connection with the 11 until 16 The interaction of the locking device 64 with the cam 36 will be explained below.

The cam control pin 66 is movable in the radial bore 68 in the radial direction between a locking position 78 and a release position 74. In the locking position 78, the cam control pin 66 is arranged further inward in the radial direction than in the release position 74. In the locking position 78, the cam control pin 66 partially extends, in particular with its radially inner end, into the longitudinal groove 70. In the release position 74, it extends the cam control pin 66 does not fit into the longitudinal groove 70.

The locking device 64 can furthermore have a housing pin 80 and a spring element 82 in the housing 54. The housing pin 80 is radially movable and biased in the radial direction via the spring element 82. When the cam control pin 66 and the housing pin 80 are arranged in radial alignment, the cam control pin 66 and the housing pin 80 can cooperate to transfer the locking device 64 between the release state 72 and the locking state 76. In the illustrated embodiment (see 15 ), the lock cylinder 52 is constructed in such a way that the housing pin 80 and the cam control pin 66 are arranged in alignment when the cylinder core 56 is turned by a certain angle after the key 10 has been fully inserted (for example by 135 ° in one or by 225 ° in the other Direction) was rotated. Alternatively, the lock cylinder 52 can also be constructed in such a way that the housing pin 80 and the cam control pin 66 are arranged in alignment without the cylinder core 56 being rotated.

The locking safety device 66 is in the locking state 76 when the cam control pin 66 is arranged in the locking position 78 and the housing pin 80 and the cam control pin 66 are arranged in alignment. In the locked state 76, the housing pin 80 extends from the housing 54 into the radial bore 68 and thereby blocks rotation of the cylinder core 56.

The lockout safety is in the release state 72 when the cam control pin 66 is located in the release position 74 or when the housing pin 80 and the cam control pin 66 are disposed out of alignment. In the release position 74, the housing pin does not extend into the radial bore 68 and the cam control pin 66 only extends maximally to the radially outer edge of the cylinder core 56, whereby rotation of the cylinder core 56 is enabled.

When the key 10 is inserted into the locking channel 62, the cam is guided in the longitudinal groove 70 up to the radial bore 68. By fully inserting the key 10, the cam control pin 66 is pushed into position by the cam 36 radial direction pressed out of the longitudinal groove 70. This moves the cam control pin 66 to the release position 74. The cam control pin 66 is therefore arranged in the release position 74 when the key is fully inserted. This is in the 11 and 13 shown.

When the key is removed from the locking cylinder, the cam control pin is pressed back into the locking position 78 via the preload force of the spring element. If the key 10 is therefore only partially or not inserted at all into the key channel 62, the cam control pin 66 is arranged in the locking position 78. This is in the 12 and 14 shown.

In the 15 and 16 A state is shown in which a key is inserted into the lock cylinder 52 and the cylinder core 56 is rotated by a certain angle so that the housing pin 80 and the cam control pin 66 are arranged in alignment.

In 15 The example shows the case in which the key is either not fully inserted or a key is used that does not have a suitable cam. The cam control pin 66 is then not moved to the release position 74, but is arranged in the locking position 78. The housing pin 80 is partially pressed into the radial bore 68 by the biasing force of the spring element 82 and thereby blocks the rotational movement of the cylinder core 56 relative to the housing 54. Accordingly, the locking device 64 is in the locked state 76.

In 16 The case in which the key is fully inserted and the key also has the appropriate cam 36 is shown as an example. The cam control pin 66 is thus moved into the release position 74 by the cam. The housing pin 80 is therefore not arranged in the radial bore 68 and therefore does not block the rotational movement of the cylinder core 56 relative to the housing 54. Accordingly, the locking device 64 is in the release state 72.

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 1593800 B1 [0002, 0003]

Claims (19)

Key (10) for a lock cylinder (52), the key (10) having a key shaft (14), the key shaft (14) extending in a longitudinal direction (18) from a key head (12) to a key tip (16) of the Key (10), the key shaft (14) having two key broad side surfaces (24), the key (10) further having a cam (36) which protrudes from one of the key broad side surfaces (24), characterized in that the cam (36) is formed in one piece with the key shaft (14). key (10). Claim 1 , wherein the cam (36) extends in the longitudinal direction (18). key (10). Claim 1 or 2 , wherein the cam (36) has a length (L2) in the longitudinal direction (18), the length (L2) of the cam (36) being 5-25%, preferably 8-20%, more preferably 10-15%, in particular 12%, the length (L1) of the key shaft (14). Key (10) to one of the Claims 1 until 3 , whereby a transition of the cam (36) to the key broad side surface (24) is smooth. Key (10) to one of the Claims 1 until 4 , wherein the cam (36) has a head region (38). key (10). Claim 5 , wherein the head area (38) is flat in the longitudinal direction (18). key (10). Claim 5 or 6 , wherein the head region (38) is convexly shaped in a first direction (20), which runs perpendicular to the longitudinal direction (18) and parallel to the key broad side surfaces (24). Key (10) to one of the Claims 5 until 7 , wherein the cam (36) has a transition region (42) on the key head side and a transition region (40) on the key tip side, the head region (38) being arranged in the longitudinal direction (18) between the transition region (40, 42) on the key head side and the key tip side, in particular wherein the transition region (40, 42) on the key head side and the key tip side are designed such that the cam (36) has a smooth transition to the key broad side surface (24) in the longitudinal direction (18). Key (10) to one of the Claims 5 until 8th , wherein the cam (36) has two lateral transition regions (44, 46), the head region (38) being arranged in the first direction (20) between the two lateral transition regions (44, 46), in particular wherein the two lateral transition regions ( 44, 46) are designed such that the cam (36) has a smooth transition to the key broad side surface (24) in the first direction (20). Key (10) to one of the Claims 1 until 9 , wherein the cam (36) is arranged in the longitudinal direction (18) on the key broad side surface (24) in the middle or on the key head side. Key (10) to one of the Claims 1 until 10 , wherein the key shaft (14) has a key stop (34), the cam (36) being arranged on the key stop (34) in the longitudinal direction (18). Key (10) to one of the Claims 1 until 11 , wherein the cam (36) is arranged at a distance from the lateral edges of the key shaft (14) in the first direction (20). Key (10) to one of the Claims 1 until 12 , wherein the key broad side surface (24) has a plurality of longitudinal grooves (28), each longitudinal groove (28) running parallel to the longitudinal direction (16), the cam (36) being on an elevation (30) between two of the plurality of longitudinal grooves ( 28) is arranged. key (10). Claim 13 , whereby a transition from the cam (36) to the elevation (30) is smooth. Locking device (50) with a key (10) according to one of the Claims 1 until 14 and a lock cylinder (52), the lock cylinder (52) having a housing (54) and a cylinder core (56), the lock cylinder (52) having one or more locking devices (64), each locking device (64) between a locking state (76) and a release state (72) is movable and a rotational movement of the cylinder core (56) relative to the housing (54) blocks in the locking state and releases it in the release state, the cam (36) being assigned to one of the locking devices (64). Locking device after Claim 15 , wherein the locking device (64) has a cam control pin (66), the cam control pin (66) being mounted in the cylinder core (56) so that it can move in the radial direction, the cam control pin (66) in the radial direction between a locking position (78) and a release position (74), the cam control pin (66) being movable from the locking position (78) into the release position (74) by inserting the key (10) through the cam (36). Locking device after Claim 15 or 16 , wherein the locking device (64) has a housing pin (80), the housing pin (80) being mounted in the housing (54) so that it can move in the radial direction, the housing pin (80) being biased inwards in the radial direction, wherein, if the cam control pin (66) and the housing pin (80) are arranged radially aligned, the cam control pin (66) and the housing pin (80) cooperate in such a way that the housing pin (80) controls the rotational movement of the cylinder core (56) relative to the housing (54). in the locking position (78) of the cam control pin (66) and releases it in the release position (74) of the cam control pin (66), in particular wherein the locking device (64) is in the locking state (76) when the housing pin (80) stops the rotary movement of the Cylinder core (56) blocks relative to the housing (54). Locking device according to one of the Claims 15 until 17 , wherein the key channel (86) has a longitudinal groove (70) which is assigned to the cam (36), in particular wherein the longitudinal groove (70) extends to the cam control pin (66). Locking device according to 18, wherein a cross-sectional contour of the longitudinal groove (70) is designed to be complementary to a peripheral surface of the cam (36).

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