FR2890994A1 - ELECTROMECHANICAL LOCK WITH CONDITIONAL OPERATION - Google Patents

Abstract

The electromechanical lock, comprising a bolt actuating mechanism (12) and a catch plate (14) with a corresponding electromagnetic emitter (24) and receiver (26) and a feeder, has the emitter in the form of a directional infrared emitter in the catch plate, facing towards an infrared receiver in the lock mechanism. The feeder consists of an electromagnetic radio-frequency generator (32) designed to produce electromagnetic energy delivered remotely to the emitter, and an electro- magnetic radio-frequency receiver (40) that collects the electromechanical energy and is located in the catch plate.

Description

2890994 1

  The present invention relates to an electromechanical lock comprising a lock mechanism and a corresponding strike, said lock comprising an electromagnetic transmitter and receiver respectively installed in the lock mechanism and in the striker.

  The lock mechanism is usually enclosed in a housing, which is mounted in the edge of a leaf of a door. Said door makes it possible to close off an opening made in a wall and the opening defines an embrasure in which said door is housed in a closed position. The corresponding strike, is mounted in the recess and secured to the wall so that the housing can come opposite said keeper, when the door is precisely in the closed position.

  The lock mechanism comprises at least one bolt housed in the housing and intended to be driven projecting from the latter and said door, to be engaged in the keeper and thus maintain in a fixed position, the door in the doorway.

  In order to remotely control the closing of the doors, that is to say their holding in a fixed position in their embrasure, and the engagement of the bolt of the electromechanical lock in the corresponding strike, but only on condition that the door is well in the closed position, and the lock mechanism opposite the strike, it was imagined to equip the electromechanical lock of a transponder. Thus, by installing this transmitter / receiver, which automatically transmits a signal in response to a coded interrogation signal that it receives, in the latch or in the lock mechanism and by mounting the transmitter of the coded signal respectively, in the lock mechanism or in the striker, it is possible to condition the operation of the lock mechanism, the reception of the signal in response, the latter being possible only when the lock mechanism is located in the vicinity of the striker.

  Reference may also be made to document BE 1 013 197, which describes such a device.

  However, the low directivity of the transmitter of the coded signal, which is linked to the transponder itself, allows the lock mechanism to function when it is approaching the lock and not exclusively when it is exactly next to it.

  Also, a problem that arises and that the present invention aims to solve, is to provide an electromechanical lock, the lock mechanism of which allows the bolt to be engaged in the striker, io only when this mechanism is located exactly opposite of said keeper.

  In order to solve this problem, the present invention proposes an electromechanical lock comprising a lock mechanism and a corresponding strike, said lock mechanism being equipped with a bolt adapted to engage in said latch when said lock mechanism is worn opposite said striker so as to hold said lock mechanism in a fixed position relative to said striker, said electromechanical lock comprising an electromagnetic transmitter and receiver, one being housed in said lock mechanism, while the other is housed in said striker, said lock comprising supply means for supplying said transmitter so that said transmitter transmits a coded signal to said receiver, when said lock mechanism is carried opposite said striker, receiving said coded signal by said receiver allowing the engagement of said bolt in said striker; according to the invention, said electromagnetic emitter consists of a directional infrared emitter housed in said striker and directed towards said receiver which is housed in said lock mechanism, said receiver being an infrared receiver; and said supply means comprise an electromagnetic radio frequency generator housed in said lock mechanism, said electromagnetic radio frequency generator being for remotely powering said transmitter.

  Thus, a feature of the invention lies in the implementation of both a transmitter and an infrared receiver, and an electromagnetic radio frequency generator to power this infrared transmitter, and also in the installing the generator in the lock mechanism to power the infrared transmitter located in the lock, which itself will then transmit a coded signal to the infrared receiver located in the lock mechanism. In this way, the operating authorization of the lock mechanism, and the operation of the bolt in the striker, will be given only on the dual condition, firstly that the electromagnetic radiofrequency generator is located opposite the infrared generator housed him in the strike and, in order to supply energy, and secondly, that the same infrared generator is oriented directly in the alignment of the infrared receiver located opposite in the mechanism of lock. Thus, thanks to this dual alignment condition, for which the lock mechanism must be located exactly opposite the strike, and which corresponds to a situation in which the door on which is installed the lock mechanism, is in a shutter position of an opening, the bolt is actuated, certainly only inside the striker. Consequently, there is no need to provide an important functional clearance between the bolt and the striker in which it engages, which was the case of the devices according to the prior art, for which the detection of the relative position lock mechanism and strike was not very accurate.

  The detection accuracy obtained with the electromagnetic lock according to the invention is not only due to the aforementioned dual condition, but also to the directional infrared transmitter, which inherently transmits a coded signal in a determined direction according to a cone boundary around from this direction whose angle is less than 5.

  Moreover, and according to a particularly advantageous embodiment of the invention, said radio frequency electromagnetic generator being adapted to supply electromagnetic energy, said power supply means furthermore comprise an electromagnetic radio frequency receiver for collecting said electromagnetic energy. the electromagnetic energy, said radio frequency electromagnetic receiver being housed in said striker. Thus, the cores of two coils for example, one corresponding to the radio frequency electromagnetic generator and the other to the radio frequency electromagnetic receiver, are respectively installed in the lock mechanism and in the striker, so as to be in the extension. from each other with the thinnest air gap possible, when the lock mechanism is exactly opposite the strike. In this way, the energy transmitted remotely from the generator to the receiver is effected with good efficiency without great energy dissipation. It is therefore not necessary to provide a high-power electromagnetic generator.

  Advantageously, said radio frequency electromagnetic receiver is tuned to the frequency of the electromagnetic radiofrequency generator so as to be able to use this energy as efficiently as possible with the least possible loss. For this purpose, said radio frequency electromagnetic receiver is preferably coupled with a rectifier circuit for providing a directly usable rectified voltage.

  In addition, said directional infrared transmitter is mounted on an electronic circuit capable of being powered, precisely, voltage rectified by said rectifier. In this way, it is then the simple power control, which will allow to trigger the operation of the directional infrared transmitter.

  According to a preferred embodiment of the invention, said infrared transmitter and said infrared receiver respectively comprise an emitting diode and a receiving diode, which form a transmitter / receiver assembly at an extremely advantageous cost.

  Other features and advantages of the invention will appear on reading the following description of a particular embodiment of the invention, given by way of indication but not limitation, with reference to the accompanying drawings in which: Figure 1 is a schematic perspective view of an electromechanical lock according to the invention at a first angle of view of three-quarters right; - Figure 2 is a schematic perspective view of an electromechanical lock according to the invention at a second angle of view of left three-quarters; and Figure 3 is a schematic view of the electronic circuit of the electromechanical lock illustrated in Figures 1 and 2.

  Figures 1 and 2 show an electromechanical lock 10 according to the invention, consisting of a lock mechanism 12 and a keeper 14 arranged opposite. Furthermore, the lock mechanism 12 here has two superimposed bolts 16, 18 and the keeper 14, two superposed locking holes 20, 22 corresponding, in which are respectively engaged the two bolts 16, 18. Thus, the lock mechanism 12 which is installed in the thickness of a door not shown and along one of its edges, is here located opposite the striker 14, which is mounted in the frame of an opening not shown, that said door closes. The lock mechanism 12 and the striker 14 are then located in the extension of one another and in the same mean plane P, and thanks to the two superposed bolts 16, 18 respectively engaged in the two superimposed locking holes 20, 22, the lock mechanism 12 is blocked in translation with respect to the striker 14 in a direction perpendicular to the average plane P. The electromechanical lock 10 is electromechanical by nature, that is to say that the bolts 16, 18 are driven in translation by first electromagnetic means, housed in the lock mechanism 12 and which make it possible to control the actuation of the bolts 16, 18, by means of an electric control.

  Furthermore, and this is the object of the invention, the striker comprises a directional infrared transmitter 24 consisting of an emitter diode and adapted to emit a coded signal in the direction D towards the lock mechanism 12 while the lock mechanism 12 comprises him, an infrared receiver 26 consisting of a receiving diode and located opposite the directional infrared transmitter 24, and in the transmission direction D encoded signal. And moreover, the lock mechanism 12 includes an electromagnetic radiofrequency generator located in the vicinity of the infrared receiver 26 for remotely feeding the directional infrared transmitter 24.

  The electronic operation of the lock according to the invention will be detailed below with reference to FIG.

  3, the directional infrared transmitter 24 which is housed in the striker 14 and the infrared receiver 26 which is housed in the lock mechanism 12. In addition, the directional infrared transmitter 24 is controlled by a circuit infrared encoder 28, while the infrared receiver 26 is connected to an infrared decoder circuit 30.

  Furthermore, the lock mechanism 12 includes the radiofrequency electromagnetic generator 32 mentioned above, comprising at least a first coil 34 and a first capacitor 36, coupled to a generator circuit 38, while the striker 14 comprises an electromagnetic radio frequency receiver 40 comprising at least a second coil 42 and a second capacitor 44.

  Of course, here is meant by coil, a core, for example ferrite, around which is wound a wire, which through the passage of an electric current generates a magnetic field. Such a coil is characterized by its inductance L. In addition, a capacitor consists of two opposite conductive surfaces separated by an insulator, and is characterized by its capacitance C. In addition, the radio frequency electromagnetic receiver 40 is coupled to a rectifier bridge 46 itself coupled to the infrared encoder circuit 28.

  When the aforementioned door is in a closed position and the lock mechanism 12 illustrated in FIGS. 1 and 2 is disposed opposite the striker 14, the first coil 34 of the radio frequency electromagnetic generator 32 is then located opposite the second coil 42 of the radio frequency electromagnetic receiver 40. Advantageously, the cores of the two coils 34, 42 are then oriented in the extension of one another with a relatively narrow air gap, of the order of one centimeter. In addition and in this same position, the directional infrared transmitter 24 and situated opposite the infrared receiver 26, so that the infrared receiver 26 can receive a coded signal emanating from the infrared transmitter 24.

  Thus, when the lock mechanism 12 is properly fitted opposite the striker 14, without the bolts still being engaged in the striker 14, and when the generator circuit 38 supplies the electromagnetic radiofrequency generator 32, an alternating current is then generated in the radiofrequency electromagnetic receiver 40. This alternating current is tuned in frequency by the second capacitor 44 and is rectified by the rectifier bridge 46 to supply the infrared encoder circuit 28 with DC power which can then generate and transmit a coded signal to the directional infrared transmitter 24.

  Obviously, the infrared receiver 26 which is located opposite the directional infrared transmitter 24 is adapted to receive said coded signal that the infrared decoder circuit 30 can then decode. If the decoded signal conforms to a predetermined pre-recorded signal, the superposed bolts 16, 18 can then be translated into the locking holes 20, 22.

  In this way, on the one hand, there is no need to provide a particular independent power supply for the infrared encoder circuit 28, since it is powered remotely by means of the radio frequency electromagnetic generator 32 and the corresponding radio frequency electromagnetic receiver. On the other hand, the lock mechanism 12 will allow the actuation of the bolts 16, 18 only insofar as it is located exactly opposite the striker 14, and this, thanks to the dual condition of the relative position of two coils 34, 42 and more, the relative position of the directional infrared transmitter 24 and the infrared receiver 26. Indeed, thanks to the high directivity of the infrared radiation, the transmission of the coded signal can be done only in a relative position of the transmitter and receiver, determined only offering a possibility of a small deviation from the direction D of the order of a millimeter, for example. io

Claims (6)

  An electromechanical lock (10) comprising a lock mechanism (12) and a corresponding strike (14), said lock mechanism being equipped with a bolt (16, 18) adapted to engage said keeper (14). when said lock mechanism (12) is carried facing said striker (14) so as to maintain in said fixed position said lock mechanism with respect to said striker, said electromechanical lock (10) comprising a transmitter (24) and a electromagnetic receiver (26), one being housed in said lock mechanism (12), while the other is housed in said striker (14), said lock comprising supply means (38) for feeding said transmitter (24) so that said transmitter transmits a coded signal to said receiver (26), when said lock mechanism (12) is carried facing said latch (14), receiving said coded signal by said receiver (26) authorizing the engagement of said bolt (16 , 18) in said striker (14); characterized in that said electromagnetic transmitter is constituted by a directional infrared transmitter (24) housed in said keeper (14) and facing said receiver (26) which is housed in said lock mechanism (12), said electromagnetic receiver (26) ) being an infrared receiver; and in that said power supply means comprises an electromagnetic radio frequency generator (32), housed in said lock mechanism (12), said radio frequency electromagnetic generator (32) being for remotely powering said transmitter (24).   2. An electromagnetic lock according to claim 1, characterized in that, said radio frequency electromagnetic generator (32) being adapted to supply electromagnetic energy, said power supply means further comprise an electromagnetic radio frequency receiver (40) for collecting said electromagnetic energy, said radio frequency electromagnetic receiver (40) being housed in said striker (14).   3. Electromagnetic lock according to claim 2, characterized in that said radio frequency electromagnetic receiver (40) is tuned to the frequency of the radio frequency electromagnetic generator (32).   An electromagnetic lock according to claim 2 or 3, characterized in that said radio frequency electromagnetic receiver (40) is coupled with a rectifier circuit (46) for providing a rectified voltage.   5. An electromagnetic lock according to claim 4, characterized in that said directional infrared transmitter (24) is mounted on an electronic circuit (28) capable of being supplied with voltage rectified by said rectifier circuit (46).   6. Electromagnetic lock according to any one of claims 1 to 5, characterized in that said infrared transmitter (24) and said infrared receiver (26) respectively comprise an emitting diode and a receiving diode.