DE102008018297A1 - Locking cylinder i.e. double-cylinder lock, has coupling elements inlaying by force of spring impinged in coupling recess, from which elements elude in uncoupling position, and elements are retained in coupling position of slide - Google Patents

Abstract

The cylinder has a closing element (4) rotatably supported in housing (3). A driveshaft (6) is switchable between a rotatable uncoupled position and a torque proof coupling position to the closing element using a slide (8) that is movable from a magnetic actuation element (7) by magnetic force. A set of coupling elements (9) inlays by the force of a spring (10) that is impinged in a coupling recess (11), from which the coupling elements elude in the uncoupling position, and the coupling elements are retained in the coupling position of the slide.

Description

The The invention relates to a lock cylinder with a housing, a rotatably mounted in the housing closure member and with at least one drive shaft, which by means of one of a magnetic actuator by magnetic force displaceable slider between a rotatable uncoupled position and a rotationally fixed coupling position to the closing member is switchable.

Such a lock cylinder describes the DE 103 03 220 A2 , The lock cylinder has a drive shaft which carries a knob at each end. The drive shaft is rotatably mounted in a housing of the lock cylinder. In a housing recess is a closing member which can be coupled to the drive shaft by means of a coupling member. A slide having a magnet can be brought into a positive connection between the closing member and the drive shaft. For this purpose, a permanent magnet, which can be displaced in the axial direction of the drive shaft. A second magnet opposed thereto drives the coupling slider to the uncoupled position. While in the coupling position, the closing member is rotated at a rotation of the knob, it is not rotated in the uncoupled position or only with a small Mitschleppkraft.

Of the Invention is based on the object, the generic Lock cylinder with respect to the switching mechanism 'between To improve coupling position and uncoupled position.

Solved The object is achieved by the specified in the claims Invention, each claim being an independent solution represents the task and can be combined with any other claim.

First and foremost, one or more coupling members are provided. These coupling members are acted upon by a spring in coupling recesses. In the decoupled position, they can emerge from the coupling recesses, so that the torques transmitted to the closing member with the drive shaft are small and insufficient to close a lock with the closing member. In the coupling position, the coupling members are held positively by a slide. In the coupling position, the coupling members can not escape from the coupling recesses, so that in this position a rotationally fixed entrainment of the closing member is ensured by the drive shaft. In an alternative, it is provided that the magnetic actuator has a reversible in the axial direction of the drive shaft, poled in the radial direction switching magnet, which cooperates with two opposite polarity, diametrically to the axis of rotation of the switching magnet associated with the slider permanent magnet. The switching magnet can be turned against two stops. The switching magnet changes its direction of force with respect to the slider when it is rotated by 180 °. In an initial position of the switching magnet is in the immediate vicinity of a poled in the same direction permanent magnet of the slider. The slider is thus held either in the uncoupled or in the coupled position. In the decoupled position, the coupling members can escape in immersion clearances of the slide. This is done in the radial direction, based on the axis of rotation of the drive shaft. In the coupled position this is not possible. In this position, the slide between the coupling members, so that they are held positively in the coupling recesses. To shift the slider in the other operating position, the switching magnet is rotated by a drive motor. It is pivoted by more than 180 °, for example by 220 °. In a 180 ° rotation are opposite poles, so that the switching magnet unfolds a repulsive effect on the permanent magnet lying next to him and also on the magnet lying away him an attractive effect. Since the switching magnet is rotated when switching but beyond the 180 ° -Winkelstellung out in a tilted position, it is held by the stronger repulsive force in the tilted position against a stop. The freely displaceable with inoperative lock cylinder slide shifts due to the changed direction of force in the other operating position, in turn, the switching magnet is in attractive operative connection to the nearest him permanent magnet of the slide. This changes the position of the switching magnet. It pivots out of the tilted position so that its pole axis lies in the direction of the polar axis of the permanent magnet. The coupling recesses are preferably formed by V-shaped radial recesses of a ring inner wall of the closing member. A plurality of preferably eight coupling recesses are arranged in a uniform circumferential distribution about the axis of rotation of the closing member. In each case two mutually opposite coupling recesses obliquely cut tips of the coupling members are substantially a positive fit. The two ends of the coupling members facing away from the locking tips are acted upon by a spreading spring, so that the two coupling members are acted upon by a common helical gear compression spring in the coupling recesses. Between the two mutually facing ends of the coupling members of the coupling slide is displaceable in the radial direction to the axis of rotation. The Um switching magnet sits on a drive shaft of an electric motor, which is located in the drive shaft of the lock cylinder. The electric motor is preferably supported by two housing halves in the drive shaft. One of the two housing halves can form the stop against which a counter-stop of the drive shaft of the electric motor or of the switching magnet occurs when the latter is rotated.

Of the Lock cylinder can have two drive shafts. A Drive shaft connected to a door inside knob can be permanently coupled with the closing member rotatably be. A second, with a door outside Rotary knob coupled drive shaft can over the previously be described clutch coupled to the closing member. But it is also possible that both drive shafts only in the coupled position transmit torque to the closing member can. It is considered particularly advantageous that All electrical lines within the drive shaft or firmly connected to the drive shaft knob. No safety-relevant electrical cables need it led out of the cylinder body or from the knob become. Furthermore, it is considered advantageous that the electric motor or the changeover solenoid can be turned to any operating position. There are no mechanical elements affecting the rotatability of the engine could block. Only the slide can in the decoupled position, but also in the coupling position, depending on Position of the coupling members to be motion blocked. Because the coupling members but subjected to force by the compression spring in the coupling recesses be, there is a constant tendency that the coupling members from the wall of the slide or out of the free spaces remove, so the displacement of the possibly blocked slide release. After release of the blocked slide he will then by the converted magnetic force direction in the other Shifted operational position. Due to the stop-limited tilting position the switching magnet remains the latter in the respective switched Position despite repulsive effect to the nearest Permanent magnets. The drive motor thus only needs either in the one or the other direction of rotation for pivoting the switching magnet to be energized, for example 210 °. In the dumped Storage position is no further fixation of the switching magnet required.

One Embodiment of the invention will be described below attached drawings explained. Show it:

1 a lock cylinder in a perspective view,

2 the lock cylinder in plan view,

3 a section along the line III-III in 2 .

4 a section along the line IV-IV in 3 .

5 the closing member 4 with coupling members arranged therein 9 , as well as slide 8th and drive motor 5 in a perspective view in the uncoupled position,

6 a rear, also perspective view according to arrow VI in 5 .

7 a representation according to 5 after turning the switching magnet 7 about 210 °,

8th an illustration of only the coupling members 9 as well as the slider 8th and the switching magnet 7 in the coupling position,

9 a representation according to 8th after turning the switching magnet by about 210 °,

10 a follow-up presentation to 9 with displaced in the uncoupled position slider 8th .

11 a representation according to 10 , but with a switching magnet twisted by about 210 ° 7 .

12 a section along the line XII-XII in 4 .

13 a section along the line XIII-XIII in 4 .

14 a section according to the line XIV-XIV in 4 with displaced in the coupling position coupling slide 8th .

15 a section along the line XV-XV in 4 .

16 a representation according to 14 with a slide displaced into the uncoupled position 8th .

17 a representation according to 15 in the decoupled position with out of the coupling recesses 11 herausverlagerten coupling members 9 , and

18 a representation according to 5 , but with illustrated half housing 16 for receiving the engine 5 ,

The illustrated in the drawings Lock cylinder is a double lock cylinder. On each side of the double lock cylinder is a knob 1 . 2 intended. The knob 1 is fixed to a drive shaft 6 ' connected, the knob 2 is fixed to a drive shaft 6 connected. The two drive shafts 6 . 6 ' are in bearing bores of a cylinder housing 3 stored. In the middle of the cylinder housing 3 a recess is provided in which a closing member 4 is mounted rotatably. With the closing element 4 a mortise lock of a door can be actuated.

In the embodiment, the drive shaft 6 ' with the closing member 4 can be brought into different working positions. In a coupling position, torques can be transmitted via the drive shaft 6 ' be transferred to the closing member. In a decoupled position, only small torques from the drive shaft 6 ' on the closing member 4 be transmitted.

In the drive shaft 6 ' is a drive motor 5 stored. For this purpose stuck in the drive shaft 6 ' two housing halves 16 that the engine 5 take up. With not shown electrical lines is the engine 5 connected to a control electronics, located in the knob 1 located. There can also be batteries. The control electronics may be connected to a transceiver to communicate with a transponder carrying a privacy secret.

The drive motor 5 drives a motor drive shaft, on which a stopper body 14 sitting. This stop body 14 acts with a counter-attack 15 together, so that the motor shaft of the electric motor 5 only by a limited angle of rotation can rotate. The angle of rotation is greater than 180 °, but less than 360 ° and is approximately in the range between 220 ° and 270 °.

On the end of the motor shaft of the electric motor 5 there is a changeover magnet 7 , The axis of rotation of the motor shaft 5 runs coaxially to the drive shaft 6 ' , The polarity of the switching magnet 7 is directed in the radial direction.

The switching magnet 7 sits in an oval recess 17 a slider 8th , The slider 8th is in the area of the closing element 4 in the radial direction relative to the axis of rotation of the drive shaft 6 ' relocatable stored. Relative to the recess 17 owns the slider 8th two permanent magnets 12 . 12 ' in the opposite polarity, in diametrically opposed relation to the switching magnet 7 firmly with the slider 8th are connected. Is the polar direction of the switching magnet 7 in the direction of the polar axis of the two permanent magnets 12 . 12 ' , so is the switching magnet 7 with one of the permanent magnets 12 in attractive operative connection and with the respective other permanent magnet 12 ' in repulsive active connection. This has the consequence that the free inside the closing member 4 movable slides 8th moved to a position where the magnet attracting 12 the switching magnet 7 is closest.

Will the switching magnet 7 rotated by 180 °, so unfolds the moment the Umschaltmagneten 7 nearest permanent magnet 12 a repulsive effect. However, since the switching magnet is rotated by more than 180 ° to a stop position, it is (initially) acted upon against the stop due to the repulsive effect. The repulsive effect on the nearest permanent magnet 12 and then attracting effect on the distal permanent magnet 12 ' But then leads to a relocation of the slider 8th ,

The two previously discussed displacement positions of the slider 8th in each case an operating position is assigned. In a first displacement position, the slide can assume the decoupled operating position, in the second displacement position, the coupling position.

The slider has two opposite transverse to the polar axis of the permanent magnets 12 . 12 ' aligned immersion free spaces 13 , Relative to the middle between the two permanent magnets 12 . 12 ' are the two immersion free spaces 13 one of the two permanent magnets 12 ' adjacent.

Transverse to the direction of displacement of the permanent magnet and also in the radial direction with respect to the axis of rotation of the drive shaft 6 . 6 ' are in within the closing member 4 two coupling links 9 , The coupling members 9 have beveled coupling tips 9 ' that point away from each other. The coupling tips 9 ' have sloping flanks. The coupling tips 9 ' usually stuck in each coupling recesses 11 , where the two diametrically opposite peaks 9 ' in diametrically opposite coupling recesses 11 einliegen.

The closing element 4 has an annular section. In the inner wall of the ring are substantially V-shaped coupling recesses 11 , There are a total of eight arranged in a uniform circumferential distribution coupling recesses 11 intended.

The two coupling members 9 own blocking ends 9 '' which are spaced apart from each other. The distance between the two blocking ends 9 '' is greater than the width of the slider in the normal operating position 8th , One between the two blocking ends 9 '' the two coupling members 9 extending compression spring 10 acts on the coupling members 9 in the coupling recesses 11 ,

Is the coupling member 8th in the decoupled position, the two immersion clearances are aligned 13 with the blocking ends 9 '' the coupling members 9 , In this state, the drive shaft 6 ' turned, so is the closing member 4 initially dragged along. If the radially projecting projection of the closing member abuts 4 but on a resistance, so slide the beveled tips 9 ' the coupling members 9 on the inclined flanks of the coupling recesses 11 so that the coupling members 9 shift in the radial direction. Is the slide located 8th in the decoupled position, so can the blocking 9 '' into the immersion free spaces 13 dive in and between the coupling recesses 11 lying coupling projections of the closing member 4 run over. It is thus a free rotation in the decoupled position of the drive shaft 6 ' guaranteed. The tips 9 ' , So the oblique edges of the coupling members 9 , occur completely from the coupling recesses 11 out.

Will the slider 8th shifted into the coupling position, so the immersion free space shifts 13 from the escape position. Now, when applying a torque, the coupling members 9 displaced radially inward, then the blocking ends 9 '' to the side wall of the slider 8th before the tapered coupling ends 9 ' of the coupling member 9 the coupling recess 11 leave. In this coupled position are the coupling members 9 always in positive engagement with the coupling recesses 11 of the closing member 4 , There are high torques from the drive shaft 6 ' on the closing member 4 transferable.

If a torque is transmitted in the coupling position, then the locking ends 9 '' on the side wall of the slider 8th at. They exert a frictional force on the slider 8th out. This causes the slider 8th is inhibited. The slider is also motion inhibited when the blocking ends 9 '' in the immersion areas 13 einliegen. Nevertheless, can be in these motion-inhibited positions of the slider 8th the switching magnet 7 relocate. Its movement position but remains due to the repulsive magnetic force on the held in the tilt position switching magnet 7 saved. The electric motor must be energized to switch so only for a short time.

Is the movement inhibition of the slider 8th lifted, it leads to the permanent magnets 12 . 12 ' acting magnetic force to an instantaneous, but time-delayed displacement of the slider 8th in the other operating position.

All disclosed features are essential to the invention (in itself). In the disclosure of the application is hereby also the disclosure content of the attached / attached priority documents (Copy of the advance notice) fully included, too for the purpose, features of these documents in claims present Registration with.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 10303220 A2 [0002]

Claims (12)

Lock cylinder with a housing ( 3 ), one in the housing ( 3 ) rotatably mounted closing member ( 4 ) and at least one drive shaft ( 6 . 6 ' ) by means of one of a magnetic actuator ( 7 ) by magnetic force displaceable slide ( 8th ) between a rotatable decoupled position and a rotationally fixed coupling position to the closing member ( 4 ) is switchable, characterized by one or more coupling members ( 9 ), which by the force of a spring ( 10 ) acted in coupling recesses ( 11 ) einliegen, from which they can dodge in the uncoupled position and in which they in the coupling position of the slide ( 8th ) are held. Lock cylinder with a housing ( 3 ), one in the housing ( 3 ) rotatably mounted closing member ( 4 ) and at least one drive shaft ( 6 . 6 ' ) by means of one of a magnetic actuator ( 7 ) by magnetic force displaceable slide ( 8th ) between a rotatable uncoupled position and a rotationally fixed coupling position to the closing member ( 4 ) is switchable, characterized in that the magnetic actuator ( 7 ) one in the axial direction of the drive shaft ( 6 . 6 ' ) rotatable, radially poled switching magnet ( 7 ), with two opposite polarity, diametrically, with respect to the axis of rotation of the switching magnet ( 7 ), the slider ( 8th ) associated permanent magnet ( 12 . 12 ' ) cooperates. Lock cylinder according to one or more of the preceding claims or in particular according thereto, characterized in that the slide between two in the direction away from each other federbe aufschlagten coupling members ( 9 ) is arranged. Locking cylinder according to one or more of the preceding claims or in particular according thereto, characterized in that the slide a immersion space ( 13 ) into which at least one coupling member ( 9 ) can dip in the decoupled position. Locking cylinder according to one or more of the preceding claims or in particular according thereto, characterized in that the switching magnet ( 7 ) of a particular in the drive shaft ( 6 ' ) arranged engine ( 5 ) is rotary drivable. Locking cylinder according to one or more of the preceding claims or in particular according thereto, characterized in that the switching magnet ( 7 ) stop limited by a pivoting angle of more than 180 °, but less than 360 ° pivot. Lock cylinder according to one or more of the preceding claims or in particular according thereto, characterized in that the slide in its respective, the decoupled position or the coupling position, associated operating position by the magnetic attraction between Umschaltmagnet ( 7 ) and Gleichgepoltem drive magnet ( 12 ) is held. Lock cylinder according to one or more of the preceding claims or in particular according thereto, characterized in that the switching magnet rotated by at least 180 ° after switching over 7 ) according to the then repellent effect to the nearest drive magnet ( 12 ) is kept limited in stroke in a slight tilting position. Lock cylinder according to one or more of the preceding claims or in particular according thereto, characterized in that the drive motor ( 5 ) of two housing halves ( 16 ) held in the drive shaft ( 6 ) lies. Lock cylinder according to one or more of the preceding claims or in particular according thereto, characterized in that the drive shaft ( 6 . 6 ' ) with a knob ( 1 . 2 ), in which a battery or an electronic control device and in particular a transmitter / receiver device is located. Lock cylinder according to one or more of the preceding claims or in particular according thereto, characterized in that the coupling recesses ( 11 ) substantially V-shaped radial recesses of an inner wall of a ring portion of the closing member ( 4 ) are. Locking cylinder according to one or more of the preceding claims or in particular according thereto, characterized by a multiplicity of coupling recesses arranged in uniform angular distribution (US Pat. 11 ).