EP2096655A1 - Closing cylinder, key switch and method for actuating a key switch - Google Patents

Abstract

The cylinder (20) has a lock core (7) displaceably and rotatably held in a hollow profile-like lock unit (11) in form-fit manner in an initial position and actuating a switching mechanics. An end of a key channel (6) is associated to a front sided end (7b) of the core. A locking device (3) is movably retained in a feedthrough (12) by the lock body and in a feedthrough (5) by the core. The feedthrough (12) extends inclined to a longitudinal axis of the key channel. The feedthrough (5) is arranged in alignment to the feedthrough (12). The feedthroughs are associated to the end of the channel. An independent claim is also included for a method for actuating a key switch.

Description

The present invention relates to a lock cylinder, comprising a hollow profile-shaped lock body, a lockable in the lock body and rotatably held lock core, provided in the lock core key channel, wherein the beginning of the keyway is formed by an insertion opening in a first end face of the lock core and the End of the keyway is associated with the second front end of the lock core, having bores through the lock body and the lock core, which are distributed perpendicular to the longitudinal alignment of the lock body and the lock core, over the length of the lock core, extending at the bore ends of the bores each resiliently held Locking pins are provided, and comprising a resilient element having a locking device which fixes the lock core in the lock body in an initial position. Furthermore, the invention relates to a key switch, comprising a lock cylinder and a switching mechanism, wherein the lock cylinder has a lock body and a lock core, and a method for actuating a key switch.

At the human and machine operator interfaces, as e.g. electrical switches, access authorizations or restrictions may be required, which may be required e.g. be realized by a so-called key switch on a mechanical way. Only with the right key, the switching mechanism can be moved and, for example, a switching operation to be completed.

According to the known prior art key switches are used, which include a mechanical unit, which from a so-called lock core and a latter enclosing Lock body exists between which a positive connection can be lifted only with the appropriate key. To initiate a switching operation, the lock core is usually rotated in the enclosing lock body and takes with it a corresponding switching mechanism.

It is from the US Pat. No. 7,275,401 B1 a technical solution of a key switch, in which a first with the appropriate key axially displaceable in the lock body lock core releases the access by the displacement and then rotate together with the lock body. Such a key switch brings a variety of cost and operating advantages, especially in connection with hierarchical locking systems.

A serious disadvantage of the key switch of the latter solution, however, is the handling by an untrained operator, because the key must be pushed on for a full insertion into the keyway of the lock core together with the lock core a few millimeters, for example, about 2mm, to finally the enable desired rotary switching operation. For this purpose, overcoming the counterforce of a arranged between the front end of the lock core and the lock housing resilient element is required. This spring-elastic element, which can be referred to as a locking device, initially moves the lock core into a starting position due to its spring force. However, without a fixation of the lock core in this starting position, the lock core is already slightly displaced upon insertion of the key by the force with which the key is inserted into the keyway of the lock core, resulting in the clamping of the still unactuated locking pins and inhibiting further key insertion can. Furthermore, without a fixation of the lock core in the starting position, the lock core already during insertion of the key by the opposing force of the first locking pins - from the insertion counted starting from the key channel - slightly shifted, which can also lead to jamming of the still unactuated locking pins and inhibition of further Schlüsseleinschiebens.

Object of the present invention is to avoid the disadvantages of a lock cylinder or a key switch described above. In particular, the axial displacement of the lock core of the lock cylinder should be better controlled and simplified from the starting position to an end position. Furthermore, a method is to be provided that allows a controlled and simplified axial displacement of the lock core from the starting position to an end position.

These objects are achieved by a lock cylinder with the features according to independent claim 1, by a key switch with the features according to independent claim 10 and by a method for actuating a key switch with the features according to independent claim 11. Further features and details of the invention will become apparent from the dependent claims, the description and the drawings. Features and details that are described in connection with the lock cylinder are of course also in connection with the key switch and the method, and in each case vice versa.

According to the invention, the objects are formed by a lock cylinder, comprising a hollow profile-shaped lock body, a lockable in the lock body and rotatably held lock core, provided in the lock core key channel, wherein the beginning of the keyway formed by an insertion opening in a first end face of the lock core is and the end of the keyway is associated with the second front end of the lock core, comprising bores through the lock body and the lock core, which is perpendicular to the longitudinal alignment of the lock body and the lock core, over the length of Distributed lock core, run, wherein at the bore ends of the bores each resiliently held locking pins are provided, comprising a resilient element having a locking device which fixes the lock core in the lock body in an initial position in which the locking device extending in an inclined to the longitudinal axis of the keyway first passage through the lock body and arranged in a flush with the first passage arranged second passage through the lock core movably, wherein the two bushings are associated with the end of the key channel, solved.

By such a lock cylinder, the axial displacement of the lock core of the lock cylinder from the initial position can be optimally controlled in an end position and thus simplified. By fixing the lock core in the lock body in a starting position, the key can be relatively easily inserted into the key channel of the lock core first. In this case, the key bit of the key when inserted into the keyway gradually forces the intended locking pins back. The beginning of the key channel is formed by an insertion opening in a first end face of the lock core. The key bit is inserted into the insertion opening. The keyway extends axially parallel or coaxially to the longitudinal axis of the lock core. The end of the key channel is assigned to the second front end of the lock core.

The lock cylinder has a plurality of holes, which extend through the lock body and the lock core, distributed over the length of the lock core. The holes are arranged perpendicular to the longitudinal direction of the lock body and the lock core. The bores are advantageously designed as so-called pin bores. At the bore ends of the bores each resiliently held locking pins are provided which fix the lock core within the lock body when not inserting a key and a rotation of the lock core about its longitudinal axis prevention. The holes are distributed over the length of the lock core. The locking pins are movably held within the bores. Via a resilient element, such as a coil spring, which is fixed to the bottom of a bore, a closing pin is acted upon by a spring force.

Core of the invention is the fixation of the lock core in the lock body by the special arrangement of the locking device. The locking device has a resilient element by which the locking device exerts a force on the lock core, so as to keep the lock core during insertion of the key in the starting position within the lock body. The locking device is preferably arranged in a first passage extending through the lock body inclined relative to the longitudinal axis of the keyway and movably held by the lock core in a second passage arranged in alignment with the first passage. The two bushings are located at the end of the keyway. That is, the end of the keyway faces the insertion opening for the key.

The locking device is effective as long as the key - recognizable to the operator - has not yet been inserted into the keyway as far as the stop. Shortly before the complete insertion of the key into the keyway, the force of the locking device on the key bit now acts in addition to the force that the last closing pin exerts on the key bit. That is, from a certain distance covered the key within the key channel, in addition to the force of the locking pins an additional force acts on the key bit, whereby the further introduction of the key is difficult. The locking device thus has two functions. For one, it blocks a movement of the lock core. Secondly, it complicates the complete introduction of the key into the key channel. This is given by the fact that the locking device not only in the first passage through the lock body, but also in the second feedthrough arranged in alignment with the first feedthrough is movably held by the lock core. The inclination of the bushings, ie the longitudinal axes of the bushings, to the longitudinal axis of the lock core can be different. Thus, the longitudinal axes of the bushings may for example be arranged at an angle between 45 ° and 135 ° to the longitudinal axis of the lock core and the keyway. However, particularly preferably, the longitudinal axes of the passages are perpendicular to the longitudinal axis of the lock core or the keyway.

The operator sees at the time when an increased counterforce occurs that the key is not yet fully inserted in the keyway. The operator must exert increased force to fully insert the key into the keyway. When pushing back the spring-loaded last closing pin and spring-loaded locking device, the operator thus forcibly presses with a higher force, so that due to the lock core, which is released after unlocking the locking device and the repression of the last closing pin in its movement, automatically from the initial position axially is moved to an end position. Due to the increased application of force shortly before the key is fully inserted, the lock core is subconsciously moved axially. From a certain point, ie, after a certain successful repression of the locking device and the last locking pin, the force exerted by the locking device and the last locking pin on the key bit abruptly, so that due to the swing in the introduction of the key, this axially displaces the lock core from the released starting position into the end position. In the end position of the lock core can be rotated so as to actuate a connected switching mechanism.

Preference is given to a lock cylinder, in which the two passages are aligned with the bore associated with the end of the key channel, in which a spring-loaded Closing pin is provided, are arranged, wherein the spring force of the resilient element of the locking means of the force acting on the locking pin in this bore, counteracts. That is, the longitudinal axes of the passages through the lock body or the lock core advantageously extend coaxially to the longitudinal axis of the last hole. As a result, the key bit or the key tip is acted upon on two opposite sides in each case with a force. To insert the key, the key tip must move the locking device in the opposite direction as the last locking pin. The last intended locking pin and the locking device take the key tip, so to speak, in a pair of pliers.

Particularly preferred is a lock cylinder, wherein the first passage through the lock body forms the guide bore of the end of the lock core associated bore. This represents a particularly constructively simple solution. In the production of the bore, i. the pin bore, which serves to receive the last closing pin, a guide bore is first generated by the wall of the hollow profile-shaped lock body, to then generate the pin hole in the opposite wall of the lock body. The locking device is adapted to the size of the guide bore produced. Depending on the configuration of the blocking device, the size and shape of the second passage, i. the countersink in the lock core, the pilot hole, or not. Advantageously, the second passage in the lock core has smaller dimensions than the guide bore, i. the first passage through the lock body.

The locking device can be designed in various ways. In a first preferred embodiment, the locking device is formed by the resilient element of the locking device itself. That is, the free end of the resilient element is movably held in the two passages and immersed in the keyway of the lock core and thereby blocks rotation and axial displacement of the castle core. Upon insertion of a key into the keyway, the tip of the key pushes away the end of the resilient member, thereby releasing the movement of the lock core. The resilient element may for example be a leaf spring, a plate spring or an elastomeric spring.

In a further preferred embodiment of the lock cylinder, the locking device has a latching projection, which is spring-loaded by the resilient element of the locking device, wherein the latching projection has a curved or pointed end. The locking projection may be, for example, a locking pin. The latching projection is connected to the resilient element. This connection can be non-positive and / or cohesive. The curvature or the tapered end serves to ensure that the key tip can better engage the locking projection in order to push it back against the spring force of the resilient element.

A particularly preferred embodiment of the lock cylinder provides that the locking device comprises a ball which is spring-loaded by the resilient element of the locking device. The ball is movably mounted in the first passage of the lock body. On the one hand, the movement of the ball through the second passage in the lock core, ie the countersink, is limited. The limitation of the movement of the ball on the other side is made by the elastic element. The second passage in the lock core advantageously has slightly smaller dimensions than the ball, so that it can only partially submerge through the second passage. That is, a small portion of the ball is inserted due to the spring force of the resilient element in the keyway of the lock core to fix this in a starting position. Upon insertion of a key in the keyway, the ball is pushed back against the spring force of the resilient element by the key tip and the movement of the lock body released. The ball is not connected to the spring-elastic element and is acted upon only by this with a spring force. As a resilient element arranged around the lock body around leaf spring is particularly suitable. In particular, when using a ball as part of the locking device, it is advantageous if the first passage through the lock body has a larger diameter, as the second passage through the lock core.

A further preferred embodiment of the lock cylinder provides that a second spring-elastic element is provided by which the lock core can be acted upon by a spring force at its second front end. Thus, the lock core can be acted upon end face by another resilient element, such as a coil spring, with a force acting axially parallel or coaxial with the longitudinal axis of the lock core on this, so that this easily erschich the axial displacement of the lock core. This second spring-elastic element is mainly used to return the lock core from the end position to the starting position after a switching operation has been successfully carried out and the key has been removed from the keyway of the lock core. This second spring-elastic element alone can not hold the lock core in the starting position, since upon insertion of a key, the spring-elastic element would yield and thus the disadvantages of clamping the lock pins listed in the introduction would not be ruled out. In conjunction with the locking device, the front side arranged on the lock core second resilient element can advantageously influence the leadership of the lock core, in particular provide for its return to the starting position.

According to the second aspect of the invention, the objects are achieved by a key switch comprising a lock cylinder having a lock body and a lock core, and a switch mechanism in which the lock cylinder is designed according to the first aspect of the invention and the lock core of the lock cylinder for actuating the switching mechanism.

Such a key switch allows a simple controlled movement of the lock core of the lock cylinder from the starting position to an end position, so that a secure circuit of the switching mechanism can be done. The key switch allows in particular an automatic axial displacement of the lock core of the lock cylinder, which is required for the subsequent rotation of the lock core. Due to the necessary axial displacement of the lock core, the key switch is double secured. The key switch has a safe operation due to the special design of the lock cylinder. That is, jamming of the lock pins upon insertion of the key into the keyway and inhibition of further key insertion is prevented by the lock means initially fixing the lock core in a home position. Only with the complete insertion of the key in the key channel blocking is released. For this purpose, an increased force during insertion of the key is required. After overcoming the "power mountain" to unlock the locking device just before the key stop, the key is moved axially with the lock core by a few millimeters until the desired end position of the lock core is reached. Then the lock core can be rotated about its longitudinal axis, so as to actuate the switching mechanism of the key switch.

• ein Schlüssel wird durch die Einführöffnung des Schlosskerns in den Schlüsselkanal eingeführt und verdrängt während des Einführens die federnd gehaltenen Schließstifte;
• beim oder nach dem Erreichen des letzten Schließstiftes stößt die Schlüsselspitze gegen die federkraftbeaufschlagte Sperreinrichtung;
• zur weiteren Einführung des Schlüssels wird der Schlüssel mit einer erhöhten Einführkraft eingeführt, um neben dem letzten Schließstift auch die Sperreinrichtung zurückzudrängen;
• nach dem Erreichen der maximal möglichen Zurückdrängung der Sperreinrichtung wird der Schlüssel, durch die nachlassende Krafteinwirkung der Sperreinrichtung auf die Schlüsselspitze, vollständig eingeführt und der Schlosskern axial aus der Ausgangsstellung in eine Endstellung verschoben;
• nach der Erreichung der Endstellung wird der Schlüssel zusammen mit dem Schlosskern um die Längsachse des Schlosskerns gedreht und nimmt dabei eine verbundene Schaltmechanik mit bzw. betätigt nach einer bestimmbaren Drehung eine Schaltmechanik.

According to the last aspect of the invention, the objects are achieved by a method for actuating a key switch, comprising a hollow profile lock body, a lockable in the lock body and rotatably held lock core, provided in the lock core key channel, the beginning of the keyway through an insertion in a first front end of the lock core is formed and the end of the key channel associated with the second end face of the lock core is, comprising bores through the lock body and the lock core, which are distributed perpendicular to the longitudinal alignment of the lock body and the lock core, distributed over the length of the lock core, wherein at the bore ends of the bores each resiliently held locking pins are provided, having a spring-elastic element having Locking device which fixes the lock core in the lock body in a starting position, the method being characterized by the following steps:

• a key is inserted through the insertion of the lock core in the keyway and displaced during insertion, the resiliently held locking pins;
• during or after reaching the last locking pin, the key tip abuts against the spring-loaded locking device;
• for further insertion of the key, the key is inserted with an increased insertion force in order to force back the locking device in addition to the last locking pin;
• after reaching the maximum possible repression of the locking device of the key is completely introduced by the declining force of the locking device on the key tip, and the lock core axially displaced from the initial position to an end position;
• after reaching the end position of the key is rotated together with the lock core around the longitudinal axis of the lock core and takes a connected switching mechanism with or operated after a determinable rotation a switching mechanism.

First, a key is inserted through the insertion of the lock core in the keyway and displaced during insertion, the resiliently held locking pins. The lock core is positively held displaceable and rotatable in a lock body. During insertion of the key in the keyway of the lock core of the lock core is held in its initial position, ie can not be moved or twisted. This is done by the Locking device. To further introduce the key, the key is inserted with an increased insertion force to unlock the locking device in addition to the last locking pin. After reaching the last closing pin, ie the closing pin, which is located furthest away from the insertion opening of the lock core in a hole in the lock core, the key meets two resistors. The first resistance is applied by the last locking pin, which must be pushed back by the key tip against the spring force of the resilient element in the last hole in this. The second resistor is generated by the blocking device. To unlock the locking device, it must also be displaced by the key tip of the key from the key channel.

After reaching the maximum possible repression of the locking device of the key is completely introduced by the declining force of the locking device on the key tip and the lock core axially displaced from the starting position to an end position. Maximum possible repression of the locking device according to the invention means a displacement of the locking device until it no longer protrudes into the keyway. If the last locking pin and the locking device have been removed from the keyway, the movement of the lock core is released, so that it can be moved from the starting position. Due to the increased force acting on the key during insertion of the same, an axial displacement of the lock core takes place together with the key until the lock core has reached an end position.

After reaching the end position of the key is rotated together with the lock core around the longitudinal axis of the lock core and takes a connected switching mechanism with or operated after a determinable rotation a switching mechanism of the key switch.

By the locking device, which makes it difficult to insert the key in addition to the last locking pin at the end of the key channel, the operator of the key when applying the locking device has to apply a higher force for the introduction of the key. The essence of the invention is that shortly before the complete insertion of the key, the operator is forced to insert the key with a larger force, with the effect that from the time of maximum possible repression of the locking device, the blocking force of the locking element abruptly decreases and the lock core with the Key "automatically" is moved to the end position. That is, by overcoming the two locking forces of the last locking pin and the locking device, and thereby the greater applied force, the operator unconsciously pushes the lock core from the starting position to the end position.

Preferred is a method in which the key tip of the key pushes back the locking device and the last locking pin synchronously. As a result, after overcoming the blocking force of the locking device no further force of displacement of the lock core oppose more and the movement is continued with momentum to the limit of the axial displacement of the lock core.

The distance that the lock core must cover between the starting position and the end position can be variably determined. However, a method is preferred in which the lock core is axially displaced by 1 to 5 mm, in particular by 2 to 3 mm, after unlocking the locking device and the last locking pin. Such a long shift is sufficient for the additional safety function of the key switch. Only after covering this distance, the lock core and the key can be rotated about the longitudinal axis of the lock core to operate the switching mechanism.

Preferably, a key switch according to the second aspect of the invention is provided for carrying out the method.

FIG 1

einen Schließzylinder eines Schlüsselschalters mit eingeführtem Schlüssel.

The invention will now be explained in more detail with reference to a non-exclusive embodiment, with reference to the accompanying drawings. It shows:

FIG. 1

a lock cylinder of a key switch with inserted key.

The FIG. 1 shows a lock cylinder 1 of a key switch with inserted key 8. The lock cylinder 1 has a locking device 3, which comprises a ball 1 and a resilient element 3a. The ball 1 is acted upon by the resilient element 3a with a force. The ball 1 is movably held in the first passage 12 by the lock body 11. The resilient element 3a presses the ball 1 in the second passage 5 of the lock core 7. In this case, the second passage 5 through the lock core 7 has a smaller diameter than the ball 1. However, due to the spring force of the spring-elastic element 3a acting on it, the ball 1 projects into the keyway 6 and thereby prevents a rotation or displacement of the lock core 7 in the lock body 11 of the lock cylinder 20. In this way, the locking device 3 holds the lock core 7 in one starting position. That is, with an introduction of a key 8 in the keyway 6 of the lock core 7, the lock core 7 due to the locking device 3 initially can not be moved from the starting position. Further, the lock core 7 is fixed in the lock body 11 by the lock pins 10, 10a, which are movably held in the bores 4, 4a, respectively, by a spring element 13.

In this embodiment of the lock cylinder 20, the first passage 12 simultaneously represents the guide bore 2 of the bores 4, 4 a through the lock body 11 the force exerted by the resilient element 3a of the locking device 3 on the ball 1, the spring force of the spring element 13, which is arranged in the last hole 4a, counteracts. Upon insertion of the key 8 in the keyway 6 of the lock core 7, the key tip 9 and the key bit gradually displaces all existing locking pins 10. Just before the key 8 is fully inserted into the keyway 6, meets the key tip 9 of the key 8 the ball 1 of the locking device 3 and the last locking pin 10a. These counteract the insertion of the key 8 due to the spring forces acting on them. The operator of the key 8, when reaching the ball 1 and the last closing pin 10 a, must exert a higher force than before in order to fully insert the key 8 into the key channel 6.

The locking device 3 realizes a starting position of the lock core 7, which the operator, as it were unconsciously overcomes with the complete insertion of the key 8. The blocking by the locking device 3 is effective, as long as the key 8 - recognizable to the operator - is not yet inserted to the stop and leads in overcoming their "power mountain" just before the key stop to an unconscious pushing the key 8 and the lock core. 7 by a few millimeters to the desired end position of the lock core 7.

The guided in the second implementation 5 of the lock core 7 ball 1 of the locking device 3 acts near the rear end, ie the second end 7b of the lock core 7 with a force component in the direction of the longitudinal axis 14 of the lock core 7 on this and resiliently stops the key eighth just before its complete insertion. The blocking effect is canceled with the further insertion of the key 8 and thus synchronously with the displacement of the last locking pin 10a. On the "descent" after overcoming the blocking power mountain is now the displacement of the lock core 7 no more force and the movement is continued "with momentum" until the limitation of the axial displacement of the lock core 7.

This effect will be after FIG. 1 by the placement of the loaded with the leaf spring 3 ball 1 in the guide bore 2, which corresponds to the first passage 12, the last closing pin bore 4a achieved. About the second implementation 12 or the so-called countersink 5 on the keyway 6 inhibits the ball 1, the displacement of the lock core 7 with respect to the forces acting against the key insertion forces of the locking pins 10, 10 a matched force.

When inserting the key 8 from about 5mm before the key start the ball 1 raised from the top 9 of the key 8. From then on, the last locking pin 10a continues to dip into its bore 4a and can no longer tilt. At some point, the locking force or locking force of the locking device 3 "abruptly" back and the lock core 7 is "automatically" moved to its end stop.

Claims (14)

Lock cylinder (20), comprising a hollow profile-shaped lock body (11), a lockable in the lock body (11) and rotatably held lock core (7), one in the lock core (7) provided key channel (6), wherein the beginning of the key channel ( 6) is formed by an insertion opening in a first front end (7a) of the lock core (7) and the end of the keyway (6) is associated with the second end face (7b) of the lock core (7), comprising bores (4) through the Lock body (11) and the lock core (7), which are distributed perpendicular to the longitudinal alignment of the lock body (11) and the lock core (7), over the length of the lock core (7) extend, wherein at the bore ends of the bores (4, 4a ) each resiliently held closing pins (10, 10 a) are provided, comprising a resilient element (3 a) having locking means (3), the lock core (7) in the lock body (11) in a Ausgangsstel fixed, characterized in that the locking device (3) in a tilted to the longitudinal axis of the keyway (6) extending first passage (12) through the lock body (11) and in a flush with the first passage (12) arranged second passage ( 5) is movably held by the lock core (7), wherein the two passages (12, 5) are associated with the end of the key channel (6). Locking cylinder (20) according to claim 1, characterized in that the two passages (12, 5) are arranged in alignment with the end of the keyway (6) associated bore (4a) in which a spring-loaded closing pin (10a) is provided, wherein the spring force of the resilient element (3a) of the locking device (3) counteracts the force acting on the locking pin (10) in this bore (4a). Lock cylinder (20) according to claim 1 or 2, characterized in that the first passage (12) through the Lock body (11) the guide bore (2) of the end of the lock core (7) associated bore (4a). Lock cylinder (20) according to one of claims 1 to 3, characterized in that the locking device (3) by the resilient element (3a) of the locking device (3) is formed. Locking cylinder (20) according to one of claims 1 to 3, characterized in that the locking device (3) has a latching projection which is spring-loaded by the resilient element (3a) of the locking device (3), wherein the latching projection is a curved or pointed end having. Locking cylinder (20) according to one of claims 1 to 3, characterized in that the locking device (3) has a ball (1) which is spring-loaded by the resilient element (3a) of the locking device (3). Lock cylinder (20) according to one of claims 1 to 6, characterized in that the first passage (12) through the lock body (11) has a larger diameter than the second passage (5) through the lock core (7). Lock cylinder (20) according to one of claims 1 to 7, characterized in that a second resilient element is provided, through which the lock core (7) at its second end face (7b) can be acted upon by a spring force. Lock cylinder (20) according to one of claims 1 to 8, characterized in that the resilient element (3a) is a leaf spring. Key switch, comprising a lock cylinder (20) having a lock body (11) and a lock core (7) has, and a switching mechanism, characterized in that the lock cylinder (20) is designed according to one of claims 1 to 9, wherein the lock core (7) is designed for actuating the switching mechanism. A method for actuating a key switch, comprising a hollow profile-shaped lock body (11), a lockable in the lock body (11) and rotatably held lock core (7), in the lock core (7) provided key channel (6), wherein the beginning of the key channel (6) is formed by an insertion opening in a first end face (7a) of the lock core (7) and the end of the keyway is associated with the second end face (7b) of the lock core (7), comprising bores (4, 4a) through the Lock body (11) and the lock core (7), which are distributed perpendicular to the longitudinal alignment of the lock body (113) and the lock core (7) over the length of the lock core (7) extend, wherein at the bore ends of the bores (4, 4a ) each resiliently held locking pins (10, 10 a) are provided, comprising a resilient element (3 a) having locking means (3), the lock core (7) in the Schlosskö Fixed body (11) in a starting position, characterized by the following steps: - A key (8) is inserted through the insertion opening of the lock core (7) in the keyway (6) and displaced during insertion, the resiliently held locking pins (10, 10 a); - When or after reaching the last locking pin (10 a), the key tip (9) abuts against the spring-loaded locking device (3); - For further introduction of the key (8) of the key (8) is introduced with an increased insertion force, in addition to the last locking pin (10 a) and the locking device (3) to push back; - After reaching the maximum possible repression of the locking device (3) of the key (8) is completely introduced by the declining force of the locking device (3) on the key tip (9) and the lock core (7) axially displaced from the initial position to an end position; - After reaching the end position of the key (8) is rotated together with the lock core (7) about the longitudinal axis (14) of the lock core (7) and thereby takes a connected switching mechanism or operated after a definable rotation a switching mechanism. A method according to claim 11, characterized in that the key tip (9) of the key (8) pushes back the locking device (3) and the last locking pin (10a) synchronously. A method according to claim 11 or 12, characterized in that the lock core (7) by unlocking the locking device (3) and the last closing pin (10a) by 1 to 5mm, in particular by 2 to 3mm, axially displaced. Method according to one of claims 11 to 13, characterized in that for carrying out the method, a key switch according to claim 10 is provided.

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