FR2687426A1 - Cylinder with electromagnetic actuation for a lock - Google Patents

Abstract

The present invention relates to a cylinder for a lock, controlled electromagnetically by a key having a non-mechanical coding, which can be inserted into a slot (3) of its rotor (2) housed within a stator (1), the said cylinder being equipped with an element (11) for latching the rotor which can be actuated by an electromagnet (10) placed under the control of an electronic circuit comparing a code specific to the lock with the non-mechanical code of the key, when the latter is inserted into the slot of the rotor. According to the invention, the electromagnet (10) is housed within the thickness of the stator (1) and the associated latching element consists of a pivoting tumbler (11) carried by the rotor (2), the said tumbler being movable between a latching position in which it is engaged in a notch (14) of the stator (2) and an unlatching position in which it comes to be housed in an internal circumferential groove (28) of the stator (1) communicating with the notch of the latter.

Description

"Electromagnetically actuated cylinder for lock"
The present invention relates to a cylinder for a lock, electromagnetically controlled by a key having a nonmechanical coding, insertable in a slot of its rotor housed inside a stator, said cylinder being provided with a rotor locking member actuable by an electromagnet placed under the control of an electronic circuit comparing a code specific to the lock to the nonmechanical code of the key, when inserting the latter into the slot in the rotor.

 -In locks equipped with cylinders of this type, it is desirable that the electromagnet and the associated locking member are entirely concealed inside the cylinder to be as far as possible protected from burglary attempts, which is generally not the case in current locks.

 The present invention has set itself the aim of satisfying this objective from a miniaturized electromagnet and for this purpose proposes a cylinder for lock, of the type specified in the introduction, which is characterized in that said electromagnet is housed in the thickness of the stator and the associated locking member is constituted by a pivoting flake carried by the rotor, said flake, placed opposite the active end of the electromagnet, with its substantially orthogonal pivot axis to the axis of the rotor, being movable between a locking position in which is engaged in a notch of the stator and an unlocking position in which it is housed in an inner circumferential groove of the stator communicating with the notch of the latter.

 In a preferred embodiment of the present invention, the stator is made of a non-magnetic material while the pivoting flake is carried by a first magnetic part of the rotor, and the core of the electromagnet is in contact with a second magnetic part. of the rotor crossed, like the first, by the key insertion slot, the flake being positioned relative to the core of the electro-S; mant to come to be pressed against the active end of the latter in its unlocked position .

 Thus, using a magnetic blade key, a continuous magnetic circuit will be produced between the pivoting spangle and the electromagnet core, a circuit that the spangle will loop in its unlocked position. We can then reduce the power of the electromagnet which goes in the direction of finding an optimal miniaturization for the latter.

 Advantageously, the first magnetic part of the rotor is formed in the bottom of the cylinder, so that the pivoting straw is most difficult to access in the event of an attempt to break into the cylinder.

 Preferably, the rotor is formed by a stack of discs, two of them constituting said first and second magnetic parts of the rotor while the other discs are made of a non-magnetic material, the manufacture of the rotor being thus simplified.

 According to another advantageous characteristic of the invention, the magnetic disc carrying the straw is reduced in diameter compared to the other discs and is received in a non-magnetic peripheral ring having a cutout for the passage of the straw, the core of the electro- magnet bearing, on one side on this ring and, on the other on the second magnetic disc.

 This makes it possible to bring the pivoting straw as close as possible to the active end of the core of the electromagnet, to further reduce the power of the latter.

An embodiment of the electromagnetically actuated cylinder according to the present invention will now be described in more detail, but only by way of nonlimiting example, with reference to the accompanying drawings in which
- Figure 1 is a longitudinal sectional view of this cylinder in its locked state
- Figure 2 is a sectional view along line II-II of Figure i
- Figure 3 is an enlargement of a detail of Figure 1;
- Figure 4 is a partial sectional view along line IV
IV of Figure 3; and
- Figures 5 and 6 are views respectively similar to Figures 3 and 4, but showing the cylinder in its unlocked state.

 The electromagnetically actuated cylinder of Figure 1 is shown in the mounting position on a door lock S. In a manner known per se, it comprises a stator 1 enveloping a rotor 2 provided with a slot 3 for inserting the actuation key of the cylinder, coded electronically or magnetically. The stator-rotor assembly 1.2 is retained on a horizontal axis X, inside a cap 4 housed in an outer protective casing 5 of the cylinder. It will be noted here that the rotor 2 is formed by a horizontal stacking of discs.

 Figure i also shows the traditional bit 6 of the cylinder, carried by a rear section of the rotor 2 penetrating into the lock S. In the front part of the cylinder, the front walls of the cap 4 and of the casing 5, pierced with coaxial openings 7,8 for insertion of the key into the slot 3 of the rotor, delimit a space housing a device 9 for reading the code of the key.

 As in all electromagnetically actuated cylinders, the reading device 9 picks up the code of the key inserted in the cylinder and transmits it electrically to a control circuit, not shown, incorporated in the lock or a housing independent of it. In the event of coincidence with a code specific to the lock it has in memory, this control circuit activates an electromagnet 10 which then releases a locking member il from the rotor 2 of the cylinder.

 According to the present invention, the locking member 11 is constituted by a pivoting flake made of a highly magnetic material, carried by a disc 12, reduced in diameter, of the rotor 2, located in the bottom of the cap 4. As shown in the FIG. 2, the straw 11 is articulated around an axis Y substantially perpendicular to the axis X of the rotor, inside a recess 13 of the disc 12, open on the rear face and the edge of the latter, this recess 13 covering substantially half the thickness of the disk 12. The straw 11 extends beyond the peripheral surface of the rotor 2 and, in its locking position of the latter, illustrated by FIGS. 1 and 3, it penetrates with minimal play in an internal notch 14 of the stator 1. At the rear, this notch 14 is delimited by an inclined surface which, with a chamfer of the disc 15 of the rotor 2, located on the back of the disc 12, defines a surface d support 16 against which the straw 11 is pushed back into the locked position by a small wire spring 17.

 The disc 12, reduced in diameter, is made of a magnetic material. I1 is surrounded by a non-magnetic circular ring 18 freely carrying on the internal surface of the stator 1. The ring 18 covers the entire thickness of the edge of the disc 12 and is cut at 19 for the passage of the straw 11.

 The rotor 2 comprises a second magnetic disk 20 axially distant from the first 12 and placed between the latter and the front wall 7 of the cover 3, not far from this wall. The other discs, such as 21, of the rotor 2, are in turn made of a non-magnetic material, like the stator 1, the cap 3 and the casing 4 of the cylinder.

 The discs 21 and the ring 18 are preferably made of a plastic material called "Delrin", while the stator 1 is made of brass. The discs 12 and 20 are moreover preferably made of a sintered metal or a magnetic carbide and the flake 11 is preferably made of magnetic steel.

 As can also be seen in FIGS. 2 and 3, the electromagnet 10 is in turn fixed in a housing 22 formed in the upper part of the stator 1, and emerging at the rear on the notch 14 of the latter. Its core 23 is constituted by a small flat magnetic bar oriented in the direction of the axis X and carried on the top of the rotor 2, only by two small tabs 24,25. The front tab 25 of the core 23 is in contact with the magnetic disc 20 of the rotor and its rear tab 24, with the non-magnetic ring 18 of the disc 12. The tabs 24, 25 are made integrally with the core 23.

 As can be seen in FIG. 3, the core 23 of the electromagnet 10 extends at the rear to penetrate into the opening 14 of the stator 2 until it extends very slightly beyond the plane P from the vertical bottom of the recess 13 of the disc 12 of the rotor 2.

 The coil 26 isolated from the electromagnet 10, connected to the latter's control circuit, is itself formed around the core 23, between its tabs 24.25.

 The key, associated with the cylinder which has just been described, comprises a blade 27 (FIG. 5) made of a magnetic metal. In addition to its electronic or magnetic coding, the key has a conventional mechanical coding.

 Once it has been engaged in the slot 3 of the rotor 2 of the cylinder, as in FIG. 5, the key releases conventional mechanical locking flakes, not shown, acting between the rotor 2 and the stator 1 of the cylinder.

 Simultaneously and as seen in FIG. 5, the key, by its blade 27, makes a magnetic connection between the pivoting flake 11 and the core 23 of the electromagnet 10 through the discs 12 and 20. A coincidence having been established between the non-mechanical code of the key and the code specific to the lock, the control circuit of the electromagnet 10 sends, to the coil 26 of the latter, a current pulse which consequently causes a call for the pivoting straw 11, bringing it into contact with the core 23 of the electromagnet 10, the straw thus looping the above-mentioned magnetic circuit.

 The pivoting straw i1 is also extracted from the notch 14 which communicates with an inner circumferential groove 28 of the stator 2.

As shown in Figure 5, the free end of the straw 11, pressed against the core in a substantially vertical position, engages in this groove. As a result, the rotor is unlocked and can be rotated under the action of the key to actuate the bit 4 moving in translation the deadbolt of the lock.

 As soon as the current pulse is interrupted, the flake 11 is returned by the spring 17 against the surface 16 of the notch 14 and, being retained between the inner flanks of the latter, it immobilizes the rotor 2 in rotation to place the cylinder in its locking state.

 It is finally interesting to note that the straw i1 is incrochetable, since its access is impossible without damaging the cylinder. In addition, the discs 12 and 20, which are made of metal, constitute an additional anti-drilling defense.

Claims (5)

 1. Cylinder for lock, electromagnetically controlled by a key having a non-mechanical coding, insertable into a slot (3) of its rotor (2) housed inside a stator (1), said cylinder being provided with a locking member (11) of the rotor actuated by an electromagnet (10) placed under the control of an electronic circuit comparing a code specific to the lock to the nonmechanical code of the key, when the latter is inserted in the slot of the rotor, characterized in that the electromagnet (10) is housed in the thickness of the stator (1) and the associated locking member is constituted by a pivoting flake (11) carried by the rotor (2) , said flake, placed opposite the active end of the electromagnet (10), with its pivot axis (Y) substantially orthogonal to the axis of the rotor (X), being movable between a locking position in which is engaged in a notch (14) of the stator (2) and an unlocking position in which it is housed in a circumferential groove (28) inside the stator (1) communicating with the notch of the latter.  2. Cylinder according to claim 1, characterized in that the stator (1) being made of a non-magnetic material, the pivoting flake (11) is carried by a first magnetic part (12) of the rotor (2), and the core (23 ) of the electromagnet (10) is in contact with a second magnetic part (20) of the rotor (1) crossed, like the first, by the slot (3) for inserting the key, the flake (11 ) being positioned relative to the core of the electromagnet in order to be pressed against the active end of the latter in its unlocked position, said cylinder being controlled using a magnetic blade key.  3. Cylinder according to claim 2, characterized in that the first magnetic part (12) of the rotor (2) is formed in the bottom of the cylinder.  4. Cylinder according to claim 2 or 3, characterized in that the rotor (2) is formed by a stack of discs, two of them (12,20) constituting said first and second magnetic parts of the rotor (2) while that the other discs are made of a non-magnetic material.  5. Cylinder according to claim 4, characterized in that the magnetic disc (12) carrying the flake (11) is reduced in diameter compared to the other discs and is received in a non-magnetic peripheral ring (18) having a cutout (19) for the passage of the straw (11), the core of the electromagnet (10) bearing, on one side on this ring (18) and, on the other on the second magnetic disc (20).