DE102013114423B4 - Lock cylinder with magnetic tumbler pin - Google Patents

Abstract

Locking device with a lock cylinder and a matching key with a cylinder core (4) which is mounted in a bearing cavity of a cylinder housing (1) so that it can rotate about an axis of rotation (D) and in whose key channel (5) which extends in the direction of the axis of rotation (D) one or more Coding recesses (8) and a shank (7) of the key (2) having at least one magnetic zone (6) can be inserted, the pole direction of the magnetic zone (6) running transversely to the plane of the broad side of the key, with at least one in a direction through the axis of rotation (D) first core (9) and housing bore (10) arranged in the radial plane (R) and in which a first core pin (11) and an associated housing pin (12) that can be displaced in a direction transverse to the direction of the axis of rotation (D) are mounted, with the first core pin (11) can be moved from a locked position to a release position by scanning a coding recess assigned to it, and with at least one second core bore (14) closed to the key channel (5) in which a magnetic, through magnetic interaction with the at least one magnetic zone (6) second core pin (13), which can be brought from a locked position to a release position, can be displaced in the direction of its polarization, characterized in that the core bore (14) supporting the magnetic core pin (13) is a blind bore having a bottom (16), wherein the bottom (16) separates the blind hole from the keyway (5).

Description

The invention relates to a locking device with a locking cylinder and a matching key with a cylinder core which is mounted in a bearing cavity of a cylinder housing so that it can rotate about an axis of rotation and in whose key channel extending in the direction of the axis of rotation one or more coding recesses and a shank of the key having at least one magnetic zone can be inserted with at least one first core and housing bore located in a radial plane running through the axis of rotation, in which a first core pin that can be displaced in a direction transverse to the direction of the axis of rotation or an associated housing pin are mounted, the first core pin being detected by scanning a associated coding recesses can be brought from a blocked position to a release position, and with at least one second core bore in which a magnetic second core pin that can be brought from a blocked position to a release position by magnetic interaction with the at least one magnetic zone can be displaced.

The US 4,398,404A discloses a locking device for a lock cylinder, wherein a tumbler element having two magnets interacts with a key shank having two magnets in such a way that the tumbler element is shifted from a locked position to a release position when the magnets of keys inserted in a key channel are correctly polarized.

The FR 975163 A discloses a lock cylinder with a key made of a ferromagnetic material, which can attract magnetic tumbler pins inserted in core bores of a cylinder core.

The DE 10 2006 059 599 A1 describes a lock cylinder with a cylinder core and a key inserted therein, which has a magnetic zone. A magnetic tumbler pin is located in a core bore.

The DE 30 16 393 A1 describes a lock cylinder in which the key has magnetic zones which can exert a torque on tumbler elements, which also have magnets, in order to bring the tumbler elements into a release position by turning them.

The DE 43 01 705 A1 describes a lock cylinder with core pins and housing pins and non-round core pins that are not rotatably mounted in core bores.

The DE 102 20 078 B3 describes a lock cylinder with a movement transmission member to displace a locking part.

The DE 963 123 B describes a lock cylinder with non-round core pins.

Lock cylinders with magnetic pins are also known from the DE 10 2006 059 599 A1 and DE 30 16 393 A1 . The magnetic pins interact with magnetic zones of the key shank and are brought from a locked position into a released position by magnetic attraction or magnetic repulsion. In addition to the magnetic tumbler pins, a locking cylinder also has core pins that mechanically scan coding recesses in the key.

Lock cylinders with tumbler pins arranged in different levels are also available from the DE 43 01 705 A1 and DE 10 220 078 B3 previously known.

Locking cylinders with spring-loaded tumbler pins with slanted faces are from the DE 698 18 428 T2 or DE 9 63 123 previously known.

The invention is based on the object of further developing a lock cylinder with both mechanical and magnetic tumbler pins in a way that is advantageous in terms of use and production technology.

The object is achieved by the invention specified in the claims.

A locking device according to the invention can have the following advantageous design features. The second core hole supporting the magnetic core pin is a blind hole closed to the key channel. The bottom of the second core hole is therefore permeable to the magnetic field of the magnetic core pin or the magnetic zone of the key shank. The bottom of the blind hole forms a thin layer of material that separates the core hole from the keyway. Furthermore, a spring element can be provided, with which the magnetic core pin is loaded in the direction of its blocking position. In the locked position, a locking section adjoining the end face of the magnetic tumbler pin protrudes into a housing opening. The oblique end face then lies completely in the housing opening. The magnetic core pin is acted upon by a magnetic attraction through the magnetic zone of the key shank against the restoring force of the spring element in the direction of its release position. The magnetic force is stronger than the spring force, so the core pin through magnetic Attraction against the restoring force of the spring element can be brought into the release position. Provision can also be made for the magnetic core pin to interact with a second housing pin which is acted upon by a prestressed spring element in the direction of its blocking position and which can be brought into a release position by magnetic repulsion of the magnetic core pin by the magnetic zone against the restoring force of the spring element. While in the variant described above the two magnets, which form the magnetic zone on the one hand and the magnetization of the core pin on the other, must have the same polarity, the magnets in this exemplary embodiment must have opposite polarity so that the second core pin can be brought into its release position. Here, too, the magnetic force must be greater than the force of a return spring. In this variant, the restoring spring acts on a second housing pin which lies in a housing opening. The end face of the second housing pin is acted upon by the end face of the magnetic pin. The axis along which the magnetic tumbler pin can move has an obtuse angle to the axis of the second housing pin when the locking device is in the locked position. While the axis of the magnetic core pin lies in the secant plane, the axis of the housing pin interacting with the magnetic pin lies in a radial plane. The axis of movement of the second housing pin thus passes through the axis of rotation of the cylinder core. The magnetic core pin may have a reduced-diameter portion. This reduced-diameter section can point in the direction of the keyway and can have a permanent magnet. The permanent magnet can be stuck in an opening of the core pin with a pole direction directed in the axial direction of the magnetic core pin. The magnetic zone of the key shank is formed by a permanent magnet whose pole direction runs transversely to the plane of the broad side of the key, i.e. it lies in the plane normal. The magnetic core pin is arranged non-rotatably in its bearing bore. The bearing bore has a non-circular cross-section. A cross-section edge initially runs over more than 180 degrees on a circular arc line. The edge of the cross-section forms a bulge with the formation of kinks. The bulge forms a longitudinal recess which, while forming an edge, merges into a wall section of the second core bore running on an inner surface of a circular cylinder. The core pin has a cross-section which also has an edge section which extends over more than 180 degrees and runs on a circular arc line. A projection which forms a longitudinal rib protrudes from this edge section. The longitudinal rib lies in the longitudinal recess in the wall of the core hole. It is of particular advantage if the longitudinal rib is flanked on both sides by bulges. The bulges then face the above-mentioned edges, so that a rounded flank faces an edge. This prevents the core pin from tilting in the core pin hole. The bulges extend in the radially inward direction of an imaginary circle in which the edge section extending over more than 180° runs. A second housing pin cooperating with the magnetic pin can have a circular intermediate surface and lie rotatably in its associated housing bore. A locking device according to the invention may have a plurality of magnetic pins. Each magnetic pin interacts with a magnetic zone assigned to the key shank. In particular, it is provided that the locking device has at least one magnetic pin, which is brought into a release position by magnetic repulsion from the magnetic zone, and has at least one further magnetic pin, which can be brought into its release position by magnetic attraction through the magnetic zone of the key shank. The housing opening, into which the magnetic pin enters in its locked position or in which a second housing pin cooperating with the magnetic pin is located, can be formed by an insert plate. If the lock cylinder has a number of magnetic pins, the insert plate forms a number of openings. The openings can be implemented as through holes in the insert plate. The insert plate is preferably inserted in a recess in the wall of the bearing cavity of the cylinder housing, in which the cylinder core is rotatably mounted. The insert plate can be pushed into the recess from the end face of the cylinder housing. The longitudinal edge sides of the recess or the longitudinal edge sides of the insert plate, which extend in the axial direction of the cylinder housing, can extend in the transverse direction in the radial direction, so that a dovetail-like structure is formed overall, so that the insert plate is restrained in the radial direction. The bottoms of the second housing openings are formed by the bottoms of the recess.

• 1 in einer perspektivischen Darstellung ein erstes Ausführungsbeispiel der Erfindung in Form eines Doppelschließzylinders,
• 2 einen passenden Schlüssel,
• 3 einen Schnitt gemäß der Linie III - III in 1 durch den Schließzylinder zur Verdeutlichung eines mechanischen Zuhaltungsstiftpaares 11, 12 und eines magnetischen Zuhaltungsstiftes 13,
• 4 vergrößert den Abschnitt IV in 3 bei nicht eingestecktem Schlüssel,
• 5 eine Darstellung gemäß 3 jedoch mit eingestecktem passenden Schlüssel,
• 6 den vergrößerten Ausschnitt VI in 6,
• 7 eine Darstellung gemäß 6 jedoch mit einem nicht schließenden Schlüssel,
• 8 einen Schnitt gemäß der Linie VIII - VIII in 5,
• 9 eine Darstellung gemäß 4 eines zweiten Ausführungsbeispiels,
• 10 eine Darstellung gemäß 6 des zweiten Ausführungsbeispiels,
• 11 eine Darstellung gemäß 7 des zweiten Ausführungsbeispiels,
• 12 eine perspektivische Darstellung eines dritten Ausführungsbeispiels der Erfindung, wobei die Wandung der Lagerhöhlung, in der der Zylinderkern 4 angeordnet ist, aufgebrochen dargestellt ist,
• 13 eine Seitenansicht auf den in der 12 dargestellten Schließzylinder,
• 14 den Schnitt gemäß der Linie XIV - XIV in 13 und
• 15 den Schnitt gemäß der Linie XV - XV in 13.

Exemplary embodiments of the invention are explained below with reference to the accompanying drawings. Show it:

• 1 in a perspective view a first embodiment of the invention in the form of a double lock cylinder,
• 2 a suitable key
• 3 a cut according to the line III - III in 1 through the lock cylinder to illustrate a pair of mechanical tumbler pins 11, 12 and a magnetic tumbler pin 13,
• 4 enlarges section IV in 3 if the key is not inserted,
• 5 a representation according to 3 but with a suitable key inserted,
• 6 the enlarged section VI in 6 ,
• 7 a representation according to 6 but with a non-locking key,
• 8th a cut according to the line VIII - VIII in 5 ,
• 9 a representation according to 4 a second embodiment,
• 10 a representation according to 6 of the second embodiment,
• 11 a representation according to 7 of the second embodiment,
• 12 a perspective view of a third embodiment of the invention, wherein the wall of the bearing cavity in which the cylinder core 4 is arranged is shown broken away,
• 13 a side view of the in the 12 shown lock cylinder,
• 14 the cut according to the line XIV - XIV in 13 and
• 15 the cut according to the line XV - XV in 13 .

The drawings show a lock cylinder which has a housing 1 . The housing 1 has a flange section in which a plurality of housing bores 10 are arranged. In each of the housing bores 10 there is a housing pin 12 which is supported against the bottom of the housing bore 10 with a compression spring 29 .

The cylinder housing 1 has a bearing section which forms a circular-cylindrical bearing cavity 3 in which a cylinder core 4 is arranged. The cylinder core is coupled to a locking element with which a lock can be actuated.

The cylinder core 4 can be rotated about an axis of rotation D. The axis of rotation D is the center axis of the bearing cavity 3.

The cylinder core 4 has a key channel 5 running in the direction of the axis of rotation D, which has coding ribs protruding into the channel. A key 2 has a key shank 7 which has coding recesses 8 . With these coding recesses 8, core pins 11 arranged in core bores 9 of cylinder core 4, each having an individual length, can be brought into a release position in which the parting surface between core pin 11 and associated housing pin 12 is aligned with the parting line between cylinder core 4 and bearing cavity 3, so that the Cylinder core 4 can be rotated. the key shank 7 also has grooves running in the longitudinal direction, into which the ribs of the wall of the key channel 5 can engage.

The core bores 9 are in a row one behind the other and in a common radial plane R. The radial plane R is characterized in that the axis of rotation D runs in it. The radial plane R runs through the center plane of the key channel 5, which coincides with the center plane of the key shank 7 when the key shank 7 has been inserted into the key channel 5.

A magnetic pin 13 is mounted in a second core bore 14 . The magnetic pin 13 can be displaced in the direction of an axis A. The axis A is the center axis of the core bore 14 which receives the magnetic tumbler pin 13. The displacement axis of the magnetic tumbler pin 13 lies in a secant plane S. The secant plane S does not run through the axis of rotation D, but intersects the radial plane R, in which the mechanical tumbler pins 11, 12 can move, at a distance from the axis of rotation D. Preferably lies the point of intersection between the secant plane S and the radial plane R offset by about half the radius of the cylinder core 4 to the axis of rotation D, the offset being directed in the direction away from the mechanical tumbler pins 11,12.

The offset can be in a range between ¼ of the radius of the cylinder core 4 and ¾ of the radius of the cylinder core 4.

The magnetic zone 6 in the key shank 7 is formed by a permanent magnet 6 which lies in an opening in the key shank with its polar axis in the direction of the surface normal of the broad side of the key.

The core hole 14, in which the magnetic tumbler pin 13 is located, is a blind hole. The blind hole has a closed bottom 16 so that the core hole 14 is spatially separated from the keyway 5 . The magnetic field lines of the magnet 6 and a magnet 22, which is assigned to the tumbler pin 13, penetrate the bottom 16 of the core bore 14.

The core pin 13 has a reduced-diameter section which is inserted into a reduced-diameter section of the core bore 14 . The face of the reduced diameter section has an opening in which the perma nentmagnet 22 is inserted, which is polarized in the direction of the axis A of the magnetic tumbler pin 13.

One end of a helical compression spring is supported on a step between a section of the core bore 14 with a larger diameter and a section with a smaller diameter. The other end of the compression coil spring acts on a step formed by a larger-diameter portion of the magnetic pin 13 . The area of the magnetic core pin 13 with the larger diameter has a non-circular cross-section and an end face 15 which runs obliquely. The inclined surface of the end face 15 can be a plane. However, the sloping end face 15 can also be slightly curved.

Blocking sections 18 , 18 ′, which are formed by the peripheral wall of the core pin 13 , directly adjoin the end face 15 .

When the cylinder core 4 is in the locked position, the opening of the core bore 14 is opposite a housing opening 19 . The blocking section 18, 18' engages in the blocking position of the magnetic tumbler pin 13 in the housing bore 19, one of the two blocking sections 18, 18' being formed by a step.

The 8th shows a cross section through the core bore 14 and the magnetic tumbler pin 13 located therein. The core bore 14 has a non-round cross section, so that the core pin 13 cannot rotate in the core bore 14. The core hole 14 has a cross-section with a cross-sectional edge portion 28 that runs on a circular arc line. The core bore 14 forms a longitudinal recess 26 in an angular range. The longitudinal recess 26 merges into the circular arc line 28 with the formation of two edges 27 .

The magnetic core pin 13 has a longitudinal rib 24 which dips into the longitudinal recess 26 . The longitudinal rib 24 is flanked by two bulges 25 , each of the bulges 25 facing an edge 27 . The longitudinal rib 24 merges into the recess 25 without any kinks. The recess 25 forms a groove which runs parallel to the longitudinal rib 24 and has a concavely rounded bottom which merges into a convexly rounded longitudinal rib 24 . As a result of this configuration, an edge 27 is opposite a rounded surface of the magnetic tumbler pin 13 that is free of kinks. The core pin 13 has a cross section with an edge portion 23 running on a circular arc line. The recesses 25 extend radially inward with respect to this circular arc line. The longitudinal rib 24 extends radially outward with respect to this circular arc line.

At the in the 5 until 7 illustrated first exemplary embodiment, the magnetic tumbler pin 13 is pushed by the spring 17 into the 4 acted upon shown locking position, in which the locking portion 18, 18 'rests in the housing bore. Here, the housing bore 19 runs in the direction of the eccentric axis A. To a certain extent, it is aligned with the core bore 14.

If a suitable key is inserted into the keyway 5 so that the magnetic zone 6 is opposite the permanent magnet 22 with the correct polarity, the core pin 13 is removed from the in 4 locked position shown in the in 6 shown release position drawn, the spring 17 is tensioned. If the key is pulled out of the key channel 5 again, the magnetic tumbler pin 13 is pushed into the in 4 shown blocking position brought.

If a key with a magnetic zone 6 that has the wrong polarization is inserted into key channel 5, the result is in 7 shown operating position. The magnetic tumbler pin 13 is held in the locked position by the spring 17 and possibly by the force of the repelling magnets 6, 22.

That in the 9 until 11 The illustrated embodiment also has a magnetic core pin 13. However, a housing pin 20 is inserted in the housing opening 19. A helical compression spring 21 acts between the housing pin 20 and the bottom 19' of the housing opening 19, which acts on the housing pin 20 from the opening 19 in the radially inward direction. The axis B, in which the housing pin 20 can move, intersects the axis of rotation D of the cylinder core 4. The axis B is thus a radial line. The housing pin 20 has a circular cross section. It is rotationally symmetrical and lies rotatably in the housing bore 19, which has a circular cross section.

The magnetic tumbler pin 13 is not cushioned in this embodiment. It is displaced completely into the core bore 14 by the force of the spring which acts on the housing pin 20 and is supported on the bottom 16 of the core bore 14 in the process. The housing pin 20 protrudes into the core bore 14 in some areas in order to block the rotation of the cylinder core 4 . He is supported on the sloping end face 15 of the core pin 13 from. From the 10 it can be seen that the displacement axis A of the core pin 13 and the displacement axis B of the housing pin 20 assigned to it intersect at an angle between 30 degrees and 50 degrees.

Is based on the in 9 If a correct key is inserted in the locking position shown in the key channel 5, the permanent magnet 6 of the key shank 7 must be opposite the permanent magnet 22 with the polarity opposite to it in order to develop a repelling effect through the partition 16 between the key channel 5 and the core bore 14. The core pin 13 is pushed into the in 10 brought released position shown in which the housing pin 22 is completely displaced into its housing 19, wherein the compression spring 21 acting on it is tensioned. In this position, the cylinder core can be rotated. The 11 shows the effect of a non-locking key inserted in the key channel 5. The magnets 6, 22 are now poled in the same direction, so that they attract each other. The core pin 13 remains in its locked position, in which the housing pin 20 partially enters the core bore 14 .

The 12 until 15 show a second embodiment of the invention. The double lock cylinder shown there has a cylinder housing 1 with a bearing cavity for mounting a cylinder core 4. The cylinder core 4 has a plurality of core bores 14 running essentially parallel to one another and arranged one behind the other in the axial direction, in each of which a magnetic tumbler pin 13 is inserted, as has been described above . The lock cylinder has at least one magnetic core pin 13 which can be brought into its release position by a repelling magnetic effect in relation to the magnetic zone 6 . This magnetic pin 13 is in the 14 shown and corresponds in terms of its design and functioning to that in FIGS 9 until 11 magnetic pen shown.

The lock cylinder also has at least one magnetic tumbler pin 13 which can be brought into its release position by magnetic attraction through the magnetic zone 6 . He is in the 15 shown and corresponds to the structure and function of the magnetic pen that the 4 until 6 show.

Unlike those in the 1 until 11 illustrated embodiments are in the in the 12 until 15 embodiment shown, the housing openings 19 are formed by an insert plate 30 . It is a curved plate made of hard plastic or metal, which lies in a pocket 31 in the wall of the bearing cavity 3. The wall of the insert plate 30 pointing towards the axis of rotation runs in cross-section on an arc of a circle and forms a partial section of the bearing surface for bearing the cylinder core 4 . The side of the insert plate 30 opposite this side lies against the bottom of the recess 31 . The insert plate 30 has a large number of through bores either for the entry of the blocking section of a tumbler pin 13 which can be brought into the release position by magnetic attraction or for receiving a housing pin 20 which is acted upon by a spring element 21 in the blocking direction, the spring element 21 being on the bottom of the recess 31 supports.

The long sides of the insert plate 30 or of the recess 31, which extend in the axial direction of the cylinder core 4, have a plane of extension which is a radial plane. For this reason, the two longitudinal edge sides of the insert plate 30 and the recess 31 extend in the shape of a dovetail. As a result, the insert plate 30 is tied up in the recess 31 .

The insert plate 30 can be pushed into the recess 31 from the front face. This can be done when the cylinder core 4 is assembled.

• Eine Schließvorrichtung, die dadurch gekennzeichnet ist, dass die Achse Ader zweiten Kernbohrung 14 in einer quer zur Radialebene R verlaufenden und gegenüber der Drehachse D versetzten Sekantenebene S angeordnet ist, wobei der einen unrunden Querschnitt aufweisende und undrehbar in der ihm zugeordneten Kernbohrung 14 einliegende magnetische Kernstift 13 eine schräg zu seiner Achse A verlaufende Stirnfläche 15 aufweist.

The above statements serve to explain the inventions covered by the application as a whole, which further develop the state of the art at least through the following combinations of features, namely:

• A locking device which is characterized in that the axis A of the second core bore 14 is arranged in a secant plane S running transversely to the radial plane R and offset relative to the axis of rotation D, the magnetic core pin having a non-circular cross-section and lying non-rotatably in the core bore 14 assigned to it 13 has an end face 15 running obliquely to its axis A.

A locking device which is characterized in that the core bore 14 supporting the magnetic core pin 13 is a blind bore closed to the key channel 5 .

A locking device characterized in that the secant plane S is offset in the direction away from the first core pins 11 from the axis of rotation D, in particular by approximately ¼ to ¾ of the radius of the cylinder core 4, preferably by half the radius of the cylinder core 4.

A locking device which is characterized by a spring element 17 with which the magnetic core pin 13 is acted upon in the direction of its locked position, the magnetic core pin 13 being able to be brought into the release position by magnetic attraction through the magnetic zone 6 against the restoring force of the spring element 17 and a to the end face 15 adjacent Sperrab Section 18, 18' of the magnetic core pin 13 protrudes into a housing opening 19 in the locked position.

A locking device which is characterized in that the magnetic core pin 17 interacts with a second housing pin 20 which is spring-loaded in the direction of its locking position and which can be brought into a release position by magnetic repulsion of the magnetic core pin 13 by the magnetic zone 6 against the restoring force of a spring element 21.

A locking device characterized in that the second housing pin 20 cooperating with the magnetic core pin 13 is supported in a second housing bore 19 which extends in a radial direction with respect to the axis of rotation D such that the axis A of the core bore supporting the magnetic core pin and the axis B of the second housing bore 19 extend at an obtuse angle to one another.

A locking device which is characterized in that the magnetic core pin 13 has a diameter-reduced section pointing towards the key channel 5, in which a permanent magnet 22 polarized in the axial direction of the magnetic core pin is inserted, which is polarized with a pole arranged in the key shank 7 transversely to the broad side plane of the key, the Magnet zone 6 forming permanent magnet interacts.

A locking device which is characterized in that in particular a section of the magnetic core pin 13 has a cross-sectional edge 23 extending over more than 180 degrees and running on a circular arc line, from which a longitudinal rib 24 protrudes.

A locking device characterized in that the longitudinal rib 24 is flanked by bulges 25 on both sides.

A locking device which is characterized in that the second core bore 14 has a longitudinal recess 26 in which the longitudinal rib 24 lies, the longitudinal recess 24 merging into a wall section 28 of the second core bore 14 running on an inner surface of a circular cylinder, forming an edge 27.

A locking device which is characterized by a plurality of magnetic core pins 13, wherein at least one magnetic core pin 13 can be brought into the release position by magnetic attraction through the magnetic zone 6 against the restoring force of the spring element 17 and at least one further magnetic core pin 13 with a pointing towards its blocked position spring-loaded second housing pin 20 which can be brought into the release position by magnetic repulsion of the magnetic core pin 13 by the magnetic zone 6 against the restoring force of a spring element 21 .

A locking device, which is characterized in that one or more second housing bores 19, in particular as through bores, are formed by an insert plate 30 which is arranged in a pocket 31 in the wall of the bearing cavity 3.

Reference List

1

lock cylinder housing

2

Key

3

bearing cavity

4

cylinder core

5

key channel

6

magnetic zone

7

shaft

8th

coding recess

9

core drilling

10

housing bore

11

core pin

12

housing pin

13

magnetic tumbler pin

14

core drilling

15

face

16

Floor

17

spring element

18

lockdown section

18'

lockdown section

19

case opening

19'

caseback

20

housing pin

21

spring element

22

permanent magnet

23

edge

24

longitudinal rib

25

bulge

26

longitudinal recess

27

edge

28

wall section

29

Feather

30

insert plate

31

recess

A

axis

B

axis

D

axis of rotation

R

radial plane

S

secant level

Claims (11)

Locking device with a lock cylinder and a matching key with a cylinder core (4) which is mounted in a bearing cavity of a cylinder housing (1) so that it can rotate about an axis of rotation (D) and in whose key channel (5) which extends in the direction of the axis of rotation (D) one or more Coding recesses (8) and a shank (7) of the key (2) having at least one magnetic zone (6) can be inserted, the pole direction of the magnetic zone (6) running transversely to the plane of the broad side of the key, with at least one in a direction through the axis of rotation (D) first core (9) and housing bore (10) arranged in the radial plane (R) and in which a first core pin (11) and an associated housing pin (12) that can be displaced in a direction transverse to the direction of the axis of rotation (D) are mounted, with the first core pin (11) can be moved from a locked position to a release position by scanning a coding recess assigned to it, and with at least one second core bore (14) closed to the key channel (5) in which a magnetic, through magnetic interaction with the at least one magnetic zone (6) the second core pin (13), which can be brought from a blocking position to a release position, can be displaced in the direction of its polarization, characterized in that the core bore (14) supporting the magnetic core pin (13) is a blind bore having a bottom (16), wherein the bottom (16) separates the blind hole from the keyway (5). locking device claim 1 , characterized in that the axis (A) of the second core bore (14) is arranged in a secant plane (S) running transversely to the radial plane (R) and offset relative to the axis of rotation (D), wherein the magnetic core pin (13) located in its associated core bore (14) has an end face running obliquely to its axis (A). locking device claim 2 characterized in that the secant plane (S) in the direction away from the first core pins (11) from the axis of rotation (D) in particular by about ¼ to ¾ of the radius of the cylinder core (4), preferably by half the radius of the cylinder core (4) is offset. Locking device according to one of the preceding claims, characterized by a spring element (17) with which the magnetic core pin (13) is acted upon in the direction of its blocking position, the magnetic core pin (13) being counteracted by a magnetic attraction through the magnetic zone (6) against the restoring force of the spring element (17) can be brought into the release position and a blocking section (18, 18') of the magnetic core pin (13) adjoining the end face (15) projects into a housing opening (19) in the blocking position. Locking device with a lock cylinder and a matching key with a cylinder core (4) which is mounted in a bearing cavity of a cylinder housing (1) so that it can rotate about an axis of rotation (D) and in whose key channel (5) which extends in the direction of the axis of rotation (D) one or more Coding recesses (8) and a shank (7) of the key (2) having at least one magnetic zone (6) can be inserted, with at least one first core (9) and Housing bore (10) in which a first core pin (11) that can be displaced in a direction transverse to the direction of the axis of rotation (D) or an associated housing pin (12) are mounted, with the first core pin (11) being detected by scanning a coding recess assigned to it from a blocking position can be brought into a release position, and with at least one second core bore (14) in which a magnetic second core pin (13), which can be brought from a blocked position into a release position by magnetic interaction with the at least one magnetic zone (6), can be displaced, characterized in that the magnetic core pin (17) interacts with a second housing pin (20) which is spring-loaded in the direction of its blocking position and which, by magnetic repulsion of the magnetic core pin (13) by the magnetic zone (6) against the restoring force of a spring element (21), in a release position can be brought. locking device claim 5 , characterized in that the second housing pin (20) cooperating with the magnetic core pin (13) is mounted in a second housing bore (19) which extends in a radial direction in relation to the axis of rotation (D), so that the axis (A) the core hole supporting the magnetic core pin and the axis (B) of the second Housing bore (19) run at an obtuse angle to each other. Locking device according to one of the preceding claims, characterized in that the magnetic core pin (13) has a reduced-diameter section pointing towards the key channel (5), in which a permanent magnet (22) polarized in the axial direction of the magnetic core pin is inserted, which is connected to a (7) arranged transversely to the plane of the broadside of the key, poled and forming the magnetic zone (6), interacts. Locking device with a lock cylinder and a matching key with a cylinder core (4) which is mounted in a bearing cavity of a cylinder housing (1) so that it can rotate about an axis of rotation (D) and in whose key channel (5) which extends in the direction of the axis of rotation (D) one or more Coding recesses (8) and a shank (7) of the key (2) having at least one magnetic zone (6) can be inserted, with at least one first core (9) and Housing bore (10) in which a first core pin (11) that can be displaced in a direction transverse to the direction of the axis of rotation (D) or an associated housing pin (12) are mounted, with the first core pin (11) being detected by scanning a coding recess assigned to it from a blocking position can be brought into a release position, and with at least one second core bore (14) in which a magnetic second core pin (13), which can be brought from a blocked position into a release position by magnetic interaction with the at least one magnetic zone (6), can be displaced, characterized in that a section of the magnetic core pin (13) has a cross-sectional edge (23) extending over more than 180 degrees and running on a circular arc line, from which a longitudinal rib (24) protrudes, which is flanked on both sides by bulges (25), the second core bore (14) having a longitudinal recess (26) in which the longitudinal rib (24) lies. locking device claim 8 , characterized in that the longitudinal recess (24), forming an edge (27), merges into a wall section (28) of the second core bore (14) running on an inner surface of a circular cylinder. Locking device with a lock cylinder and a matching key with a cylinder core (4) which is mounted in a bearing cavity of a cylinder housing (1) so that it can rotate about an axis of rotation (D) and in whose key channel (5) which extends in the direction of the axis of rotation (D) one or more Coding recesses (8) and a shank (7) of the key (2) having at least one magnetic zone (6) can be inserted, with at least one first core (9) and Housing bore (10) in which a first core pin (11) that can be displaced in a direction transverse to the direction of the axis of rotation (D) or an associated housing pin (12) are mounted, with the first core pin (11) being detected by scanning a coding recess assigned to it from a blocking position can be brought into a release position, and with at least one second core bore (14) in which a magnetic second core pin (13), which can be brought from a blocked position into a release position by magnetic interaction with the at least one magnetic zone (6), can be displaced, characterized by several magnetic core pins (13), at least one magnetic core pin (13) being able to be brought into the release position by magnetic attraction through the magnetic zone (6) against the restoring force of a spring element (17) and at least one further magnetic core pin (13) with a second housing pin (20) which is spring-loaded in the direction of its blocking position and which can be brought into the release position by magnetic repulsion of the magnetic core pin (13) by the magnetic zone (6) against the restoring force of a spring element (21). Locking device according to one of Claims 5 , 6 or 10 , characterized in that one or more second housing bores (19), in particular as through bores of an insert plate (30) are formed, which is arranged in a pocket (31) of the wall of the bearing cavity (3).

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