EP4317633A1 - Lock cylinder with a cylinder core which can be locked against rotation - Google Patents

Abstract

The invention relates to a locking cylinder, in particular a locking cylinder with a locking system, with a cylinder core rotatably mounted in the cylinder housing, which can be rotated via a key or knob inserted into the cylinder core and can be coupled to a locking bit to trigger a locking process. In order to create a simplified system for locking a To create a locking cylinder, an electric motor (3) is arranged in the cylinder core, from which a tilting mechanism (6) can be driven, which has two stable end positions, and from which a spring-loaded pin (5 or 8) can be controlled, the tilting mechanism (6) is designed so that the stable end positions can bias the spring-loaded pin (5 or 8) in the tension and compression directions, with a spring-loaded pin (5) in one of the two end positions of the tilting spring mechanism blocking the rotation of the cylinder core by inserting its radially outer end into a recess (12) is immersed in the cylinder housing, while the other pin (8) in this end position of the tilting spring mechanism (6) radially decouples the locking bit (4) with its outer end.

Description

The invention relates to a locking cylinder, with a cylinder core rotatably mounted in the cylinder housing, which can be rotated via a key or knob inserted into the cylinder core and coupled to the locking bit to trigger a locking process.

The locking concepts for electronic locking cylinders are intended to offer ever greater security. With this functional principle, it doesn't matter whether it is an electronic knob cylinder or an electronic, key-based system. The core is locking to the cylinder housing and coupling to the locking bit/output. This offers greater security than just a locking system or just a coupling system. This mode of operation is known from DE 10 2007 053 741 A1 and the EP3 118 977 B1 , where magnets are used here.

The invention is based on the object of implementing a simplified system for locking a locking cylinder.

The problem is solved according to the invention by a locking cylinder with the features of claim 1,

According to the invention, a locking cylinder, in particular a locking cylinder with a locking system, is provided, with a cylinder core rotatably mounted in the cylinder housing, which can be rotated via a key or knob inserted into the cylinder core and can be coupled to a locking bit to trigger a locking process, and with an electric motor arranged in the cylinder core in which a tilting spring mechanism can be driven, which has two stable end positions, and from which a spring-loaded pin can be controlled, the tilting spring mechanism being designed in such a way that the stable end positions can bias the spring-loaded pins in the tension and compression directions, with a spring-loaded pin in the end position of the tilting spring mechanism blocks the rotation of the cylinder core by its radially outer end dipping into a recess in the cylinder housing, while the other pin in this end position of the tilting spring mechanism uses its outer end to radially decouple the locking bit.

Alternatively, two spring-loaded pins acting in radially opposite directions can be driven by the tilting spring mechanism at the same time, with one pin triggering the blocking of the cylinder housing in one end position of the tilting spring mechanism or unlocking it in the other end position, while the other pin couples the locking bit to the cylinder core and thus the Cylinder core rotation and locking bit movement are possible.

The functional principle of the locking cylinder, or the functional principle of the locking system for the locking cylinder, is based on a tilting spring mechanism with two stable end positions that is moved by an electronic drive, which in turn - according to one embodiment variant - controls two spring-loaded pins acting in opposite directions, with one pin having the locking function to the cylinder housing and a pin takes over the coupling to the lock bit/output. The cylinder housing and also the locking bit/output have corresponding recesses for locking/coupling.

The tilting spring mechanism is designed so that it can always be controlled by the drive and maintains its stable end positions, even if the locking bit is still engaged or the locking pin is not yet in its recess in the cylinder housing. The spring forces are designed accordingly.

The system is preferably bistable and the springs of the locking pins/coupling pins can withstand pressure and tension. The drive does not have to reach an end position, but could also continue driving; the stable end positions are maintained by the tilting spring mechanism. The system is energy efficient due to the small movement angle of the drive.

The advantage is that the locking and coupling function significantly increases the security of this locking system. Even if, for example, the locking pin cannot lock in the housing groove (because the position of the core has not been reached), the other pin disengages the locking bit.

Another advantage is that axial impacts caused by the radially arranged coupling/locking pins have little impact on the safety of the system. In addition, the drive can be equipped with a gear stage that counteracts manipulative rotational acceleration. The rotor is also designed so that its center of mass is at the pivot point of the motor axis. This should also make manipulations more difficult.

• Fig. 1 zeigt hier die Ausführung als Elektronik - Knaufzylinder.
• Fig. 2 ist der Schnitt A-A und zeigt das Kippsprungwerk in der sperrenden / ausgekuppelten Position.
• Fig. 3 ist der Schnitt B-B und zeigt das Kippsprungwerk ebenfalls in der sperrenden Position.
• Fig. 4 zeigt den Schnitt A-A, aber diesmal in entsperrter und kuppelnder Position des Kippsprungwerkes bzw. deren gefederte Stifte.
• Fig. 5 zeigt den Schnitt B-B in der entsperrten / kuppelnden Position.
• Fig. 6 zeigt die Lage des Motors im Zylinderkern.
• Fig. 7 zeigt einen Schnitt analog zu B-B, und
• Fig. 8 zeigt einen Schnitt analog zu A-A.

The invention will be explained in more detail below with reference to the drawings. This shows:

• Fig. 1 shows here the version as an electronic knob cylinder.
• Fig. 2 is the section AA and shows the tilting spring mechanism in the locking / disengaged position.
• Fig. 3 The section is BB and shows the tilting spring mechanism also in the locking position.
• Fig. 4 shows section AA, but this time in the unlocked and coupling position of the tilting spring mechanism or its spring-loaded pins.
• Fig. 5 shows the cut BB in the unlocked/clutching position.
• Fig. 6 shows the position of the engine in the cylinder core.
• Fig. 7 shows a section analogous to BB, and
• Fig. 8 shows a section analogous to AA.

Fig. 1 shows here the version as an electronic knob cylinder.

The profile cylinder 1 with cylinder core, which contains the mechanics and electronics, is operated with a knob 2.

In Fig. 2 is the cut AA in Figure 1 and shows the tilting spring mechanism in the locking/disengaged position.

An electric motor 3 ( Figure 6 ) with actuator 11 moves the slider 6 of the tilting jump mechanism. The slide is mounted on tips on one side (towards the locking bit) with a solid pin 9 and on the other side by a spring-loaded pin combination 7. This pin combination prevents the compression spring from buckling.

The left pin 5 is connected to the slide 6 of the tilting spring mechanism via a tension/compression spring. The lock bit 4 has one or more recesses for coupling with the right pin 8 ( Figure 3 ). The Figure 2 shows the tilting jump mechanism as a section from above. The offset of the two pins 5 and 8 can be clearly seen here. Pin 8 couples into the locking bit 4, and pin 5 locks via grooves 12 in the cylinder housing. If the cylinder core is still loaded with forces (locking cam is still in engagement with pin 8), then the slide 6 can still be moved into the locking position, the locking pin 5 engages in a housing groove 12 and when the load is removed from the locking cam, it is decoupled the pin 8.

Fig. 4 shows section AA, but this time in the unlocked and coupling position of the tilting spring mechanism or its spring-loaded pins.

Fig. 5 shows the cut BB in the unlocked/clutching position.

The spring ends 10 are clamped in the grooves of the slide 6 and the grooves of the locking pin 5 and pin 8.

Fig. 7 shows a modified version in a section analogous to BB, in which the The locking pin, i.e. pin 5, was removed from the tilting spring with a spring. This means that the cylinder core rotates freely. It is coupled with the pin 8 in the locking bit 4.

Fig. 8 shows a section analogous to AA. This system locks with the pin 5 in a housing groove 12. The locking bit is firmly connected to the cylinder core 2 with a fixed pin 13 and therefore always rotates with the cylinder core.

List of reference symbols:

1 -

Profile cylinder housing

2 -

Cylinder core

3 -

engine

4 -

Lock bit that is coupled with pin (8).

5 -

Locking pin that blocks core rotation and engages in the grooves (12).

6 -

Slider of the tilting jump mechanism

7 -

Pin - spring combination of the tilting spring mechanism

8th -

Dome pin

9 -

Counter bearing of the tilting jump mechanism

10 -

Springs from locking pin (5) and coupling pin (8)

11 -

Actuator that switches the tilting jump mechanism

12 -

Recesses in the cylinder housing for the locking pin (5)

13 -

Locking pin lock bit

Claims (7)

Locking cylinder, in particular locking cylinder with a locking system, with a cylinder core rotatably mounted in the cylinder housing, which can be rotated via a key or knob inserted into the cylinder core and can be coupled to a locking bit to trigger a locking process,
characterized by an electric motor (3) arranged in the cylinder core, from which a tilting jump mechanism (6) can be driven, which has two stable end positions, and from which a spring-loaded pin (5 or 8) can be controlled, the tilting jump mechanism (6) being designed in this way that the stable end positions can preload the spring-loaded pin (5 or 8) in the pulling and pushing directions, with a spring-loaded pin (5) in one of the two end positions of the tilting spring mechanism blocking the rotation of the cylinder core by inserting its radially outer end into a recess (12). in the cylinder housing, while the other pin (8) in this end position of the tilting spring mechanism (6) radially decouples the locking bit (4) with its outer end. Lock cylinder according to claim 1,
characterized,
that two spring-loaded pins (5 and 8) acting in radially opposite directions can be driven by the tilting spring mechanism (6), with one pin (5) triggering the blocking of the cylinder housing in one end position of the tilting spring mechanism or unlocking it in the other end position, while the other Pin (8) couples the locking bit to the cylinder core and thus enables the cylinder core to rotate and the locking bit to be driven. Lock cylinder according to claim 1 or 2,
characterized,
that the locking cylinder is part of a mechatronic locking system. Lock cylinder according to one of claims 1 to 3,
characterized,
that the forces of the tilting spring mechanism (6) with the connected tension compression springs (10) of the coupling or locking pin are designed in such a way that the slide (6) is moved into the respective position at any time by the motor (3) with actuator (11). other end position can be brought. Lock cylinder according to one of claims 1 to 4,
characterized,
that the center of mass of the actuator (11) is arranged near the center of the axis of the motor. Lock cylinder according to one of claims 1 to 5,
characterized,
that the motor (3) is arranged in the axial direction of the cylinder core. Lock cylinder according to one of claims 1 to 6,
characterized,
that the slide (6) of the tilting spring mechanism with its coupling/uncoupling and locking/unlocking elements is arranged to act radially.

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