RU2054109C1 - Device for contact-free energy and information receiving/transmission in systems requiring identification of users - Google Patents

Abstract

FIELD: energy and information receiving/transmission. SUBSTANCE: device has key 1, lock 2, two inductive coils 3, 14, two communication blocks 7, 16 of inductive channel, two communication blocks 10, 18 of optical channel, two capacities 4, 15, block 6 of energy monitoring, switch 8, magnet 11. EFFECT: highly efficient information and energy receiving/transmission. 5 dwg

Description

 The device relates to security systems, can be used in systems requiring user identification, and relates to electronic keys and locks with a non-contact way of transferring energy and information between them.

 Closest to the technical nature of the proposed device is a "Device for the non-contact connection of control and power currents between electronics with a closing (shut-off) cylinder and electronics in the key in an electronic-mechanical shut-off device" according to patent application DE N 3501482, cl. E 05 B 47/00, E 05 B 49/00, 1986.

 The known device contains an electronic key and a lock, between which, at a given relative position, inductive and optical communications occur. The electronic key contains an inductor, a communication unit of an inductive channel, a communication unit of an optical channel, a microprogram control unit. The inductor is connected to the communication unit of the inductive channel. The communication blocks of the inductive and optical channels of the key are connected to its microprogram control unit. The key is powered by the energy transmitted inductively. The electronic lock contains a power source, an inductor, an inductive channel communication unit, an optical channel communication unit, and a firmware control unit. The inductor is connected to the communication unit of the inductive channel. Communication blocks of the inductive and optical channels of the key are connected to the microprogram control unit. The firmware control unit has an output for connecting an external actuator and a communication channel with an external control device.

 The disadvantages of the known device include the fact that ferrite cores are used in the key and lock for inductive energy transfer, the cores protruding outward and can be easily damaged by external mechanical stress, which reduces the reliability of this device. This design is due to the need to supply a sufficiently large power to the key necessary to power its electronic circuit, and this does not allow the presence of large gaps between the ferrite cores of the key and the lock at the time of their interaction.

 In this key design, the operation of such a device can only be based on determining changes in the parameters in the inductive or optical channels. This is technically impossible without providing constant (or periodically appearing) power to at least part of the circuit. Thus, the lock of the known device constantly consumes the energy of the power source, which limits the possibility of using the device in systems for the protection of mobile objects with a limited energy resource, i.e. This device does not have such qualities as efficiency and reliability, which narrows the scope of its application.

 The problem to which the invention is directed is that the device possesses a combination of such technical characteristics as a high degree of secrecy, reliability, efficiency in terms of energy consumption, which would allow its use in security systems designed to protect a wide range of objects, as stationary and mobile.

 The technical result is the increased reliability of the key-lock system, which is achieved due to a significant increase in the maximum distance between them during interaction (up to 10-40 m) and the possibility of the key working through a dielectric partition, for example, a car glass or a special cover that closes the lock from external damage, transparent only in that part of the spectrum that is used in the optical communication channel, for example, in the infrared. In this case, the key and lock can be protected by dielectric housings and not have protruding parts, which increases its degree of protection against external mechanical damage. The technical results include the increased efficiency of the proposed device. This is achieved by introducing an additional communication channel that provides power to the electronic blocks of the lock, and then the key only when the key is brought to the lock. The introduction of this additional communication channel, in the absence or improper performance of which the key will not be recognized, essentially increases the degree of secrecy of the device.

 In FIG. 1 shows a functional diagram of a device; figure 2 an example of a specific implementation of the communication unit of the inductive channel of the key; figure 3 an example of a specific implementation of the communication unit of the inductive channel of the castle; figure 4 algorithm of operation of a specifically implemented key firmware control unit key; in FIG. 5 algorithm of operation of a specifically implemented lock microprogram control unit.

 The invention can be used in security systems for general purposes.

 The proposed device for contactless transmission of energy and information in systems requiring user identification contains electronic keys 1 and a lock 2. Electronic key 1 contains an inductance coil 3, an inductive channel coupling unit 7, an optical channel coupling unit 10, a microprogram control unit 9, a capacitance 4, energy storage 5, energy control unit 6, switch 8, magnet 11. An inductance coil 3 is connected in parallel to the capacitance 4, to the first and second inputs of the energy storage 5 and to the first and second outputs of block 7 communication inductive channel. The output of the energy storage device 5 is connected to the input of the energy monitoring unit 6 and the input of the switch 8, the output of which is connected to the power inputs of the inductive channel communication unit 7, the optical channel communication unit 10, and the microprogram control unit 9. The control input of the switch 8 is connected to the output of the power control unit 6. The terminal group of the inductive channel communication unit 7 is connected to the first terminal group of the microprogram control unit 9, the second terminal group of which is connected to the terminal group of the optical channel unit 10. The third group of terminals of the microprogram control unit 9 is the additional control inputs of the electronic key 1.

 The electronic lock 2 contains a power source 12, a magnetically controlled contact 13, an inductor 14, a capacitance 15, an inductive channel communication unit 16, a firmware control unit 17, an optical channel communication unit 18. The output of the power source 12 is connected to the first output of the magnetically controlled contact 13, the second output of which is connected to the power inputs: inductive channel communication unit 16, firmware control unit 17, optical channel communication unit 18. The inductor 14 is connected in parallel to the capacitance 15 and to the first and second terminals of the inductive channel coupling unit 16, another group of terminals of which is connected to the first group of terminals of the microprogram control unit 17. The second group of terminals of the block 17 is connected to the group of terminals of the communication unit 18 of the optical channel. The third output of the microprogram control unit 17 is the output of the electronic lock 2, and the fourth group of outputs of the microprogram control unit 17 is connected to the communication channel with an external control device. Given the relative position of the electronic key 1 and the lock 2, non-contact electromagnetic coupling between the inductors 3 and 14, the optical coupling between the optical link coupling blocks 10 and 18, and the magnetic coupling between the magnet 11 and the magnetically controlled contact 13 become possible.

 The device operates as follows. When holding the key 1 to the lock 2, the magnetic field of the magnet 11 installed in the key includes a magnetically controlled contact 13 installed in the lock, and the supply voltage from the lock power supply 12 is supplied to all lock blocks. The microprogram control unit (BMU) 17 includes a power generator 24 located in the inductive channel communication unit 16 and awaits the receipt of a code message from the key. The inductive channel communication unit 16, using the oscillatory circuit formed by the inductor 14 and the capacitance 15, provides the creation of an electromagnetic field of the desired intensity and frequency at the location of the key 1. Due to the electromagnetic coupling between the lock inductance coil 14 and the key inductance coil 3 in the key oscillatory circuit formed by an inductor 3 and a capacitance 4 induces an induction emf. This voltage is supplied to the energy storage device 5. When the key is placed in a predetermined position relative to the lock, a connection also occurs between the communication blocks 10 and 18 of the optical channel of the key and the lock, respectively.

 The energy storage device 5 located in the key stores energy from the oscillating circuit 3, 4. The energy control unit 6 monitors the amount of energy stored, and when it reaches a predetermined value, using the switch 8, connects the output of the energy storage device 5 to the power inputs of units 7 , 9 and 10 keys.

 From this moment in time, the exchange of information between the key and the lock via the optical and inductive communication channels begins using the corresponding communication blocks 10 and 7 of the key and the blocks 18 and 16 of the lock. Management of the exchange of information on these channels is performed by the key firmware control unit 9 and the lock unit 17. The interaction of the BMU 9 and 17 with the corresponding communication units of the inductive and optical channel is carried out via communication lines connecting the corresponding blocks with the groups of conclusions 1 and 2 of the corresponding BMU. The maximum exchange duration is determined by the energy storage of the energy storage.

 If the key and the lock have recognized each other, BMU 17 sets the corresponding signal on the third output, which is used to control the external actuator of the lock (for example, to open the door), before transmitting the encoded information about the code of the key attached to the lock to the external control device (computer) if necessary. An external control device connected to BMU 17 through a communication channel connected to the fourth group of BMU outputs can register the key number and the time of its presentation and enable or disable the appearance of the signal on the third output of BMU 17. The key codes that have the right to open this lock can be either recorded in a read-only memory (ROM) BMU 17 lock, or transferred to it from an external control device.

 On this, the exchange of information between the key and the lock can be completed. However, if it is necessary to have an increased level of secrecy and dedicated key groups (privileged) that allow their users to change the operation mode of the security system, then before giving a signal to identify their “own” key, additional information exchange between the key is provided for keys with dedicated codes 1 and lock 2. The lock on one of the communication channels transmits information about the lock code, which is recorded in the key memory BMU, to the key. If the key identifies this code as authorized, then it sends one second informational packet to the lock through one of the communication channels, in which it informs its additional identifier and transmits the state of the auxiliary control units connected to the third group of outputs BMU 9 of key 1. Keys with built-in additional control elements only privileged users of the security system, such as the security chief, etc. have the use of additional controls is perceived by BMU 17 of castle 2 as a command: for example, " arm "," disarm ", switch to" confirmation of access rights "," block the operation of all other keys ", etc. Since no additional exchange of information is usually carried out in the usual case, this information is much more difficult to “fake”. If additional information does not match, the lock BMU can send an alarm to the control device and block the door opening.

 The device stops working when the key is deleted. In this case, the magnetically controlled contact 13 is opened and the supply voltage is removed from the key blocks. If this happens before BMU 17 performs all the necessary operations, then the signal at the third output of BMU 17 will not appear and the protected object will remain blocked (for example, the door will not open).

 The energy control unit 6 can be made on the basis of a standard Schmidt trigger, switched on in such a way that it is triggered when the input voltage, which is also the supply voltage, is reached.

 The switch 8 can be performed on a transistor, the collector of which is connected to the output of the energy storage device 5, the base to the output of the energy control unit 6, and the emitter to the power inputs of the key blocks 7, 9 and 10.

 The inductive channel communication unit 7 can be made according to the circuit shown in FIG. 2, where the threshold element 20, made, for example, on the basis of the comparator, has a response threshold equal to half the supply voltage and is used to determine the moment of occurrence of the zero phase signal from the power generator 24 of the lock. The output of the threshold element 20, the positive voltage drop at which signals the zero phase of the input signal from the power generator 24, is supplied to the first group of terminals BMU 9 of the key. This signal is also used when transmitting information through an inductive communication channel from the lock to the key by frequency or phase modulation of the signal of the power generator 24.

 To modulate the quality factor of the 3-4 key oscillation circuit, a photoresistor optocoupler controlled by transistor 22, for example, can be used. To limit the currents through the base of the transistor and the optocoupler LED, the resistor 23 and resistor 21 are used in the circuit in figure 2.

 The communication blocks 10 and 18 of the optical communication channel can be implemented according to standard schemes used in the organization of fiber optic communication lines. Each of them includes a receiver and an optical signal transmitter.

 As the magnet 11, a barium ferrite magnet can be used.

 The inductive channel communication unit 16 can be performed, for example, according to the functional diagram shown in FIG. 3. The power generator 24 is made according to a circuit comprising a serially connected master oscillator and a power amplifier. The frequency of the generator is determined by the oscillatory circuit located in it. Parallel to the capacitance of the oscillating circuit, an additional capacitance 30 can be connected using the switch 29, controlled by a logical signal from the lock BMU 17. When an additional capacitance is connected, the generation frequency of the master oscillator and, accordingly, the frequency of the “power” signal are changed. Changing this frequency serves to transmit information from the lock to the key. The threshold element 25 may be performed based on a comparator. It has a response threshold equal to half the supply voltage, and a positive voltage drop at its output occurs at a time when the voltage phase from the output of the power generator 24 is zero. Its output is connected to BMU 17 and serves to synchronize the reception and transmission of information through optical and inductive communication channels.

 The voltage drops across the resistor 28, inversely proportional to the quality factor of the oscillatory circuit of the key (elements 3 and 4 in figure 1).

 Block 27 comprises a rectifier with a low pass filter.

 Block 26 contains a series-connected AC voltage amplifier and a threshold element with a response threshold equal to half the supply voltage. Its output is connected to BMU 17.

 The microprogram control units 9 and 17 can be performed according to schemes containing read-only memory (ROM), random access memory (RAM), logic elements and a clock. The operation algorithm of a specifically implemented BMU 9 is shown in FIG. 4, and the operation algorithm of a specifically implemented BMU 17 in FIG. 5.

Claims (1)

 1. DEVICE FOR NON-CONTACT TRANSMISSION OF ENERGY AND INFORMATION IN SYSTEMS REQUIRING USER IDENTIFICATION, consisting of an electronic key and a lock, the electronic key comprising an inductor connected to an inductive channel communication unit, an optical control unit communication unit, an optical unit communication unit, an optical unit communication unit, an optical unit communication unit, an optical unit communication unit communication channel of the inductive channel is connected to the first group of terminals of the microprogram control unit, the second group of terminals of which is connected to the group of terminals of the communication unit of the optical the analogue, and the electronic lock contains a power source, an inductor connected to the communication unit of the inductive channel, the communication unit of the optical channel, the firmware control unit, and the terminal group of the communication channel of the inductive channel is connected to the first terminal group of the firmware control terminal, the second terminal group of which is connected to a group of terminals of the optical channel communication unit, the third output of the microprogram control unit is the first output of the electronic lock, the fourth group of outputs of the micro unit program control is the second output of the electronic lock, and the key and lock inductance coils, as well as the communication blocks of the optical channel of the key and lock, are installed with the possibility of interaction with each other for a given location of the key and lock, characterized in that the capacitor and energy storage are additionally introduced into the electronic key , an energy control unit, a switch and a magnet, the capacitance being connected in parallel to the inductor to the first and second inputs of the energy storage device, to the first and second terminals of the unit and inductive channel, the output of the energy storage device is connected to the input of the energy control unit and the input of the switch, the control input of which is connected to the output of the energy control unit, the output of the switch is connected to the power inputs of the inductive channel communication unit, optical channel communication unit, firmware control unit, the third group of outputs which is the additional control inputs of the electronic key, and a capacitance and a magnetically controlled contact are additionally introduced into the electronic lock, and the capacitance is parallel to It is connected to the inductance coil and the first and second conclusions of the inductive channel communication unit, the output of the power source is connected to the first output of the magnetically controlled contact, the second output of which is connected to the power inputs of the microprogram control unit, the inductive channel communication unit, the optical channel communication unit, the magnet and the magnetically controlled contact installed with the ability to interact with a given location of the key and lock.

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