HU216494B - Electronic lock - Google Patents

Abstract

An electronic locking arrangement comprising a lock unit (17) and a key unit (19) is proposed. Each of the units has a control circuit (35, 41) and a transmitting and receiving circuit (33, 47, 39, 43) which transmit information signals inductively via coupling coils (21, 23) to the control circuit (35, 41) of the other particular unit. The transmitting and receiving circuit of the lock unit (17) has an amplitude modulator (33) and a frequency demodulator (47) for the transmission of the information signals, whilst the transmitting and receiving circuit of the key unit (19) comprises a frequency modulator (43) and an amplitude demodulator (39). In dependence on the information signals transmitted between the units (17, 19), the control circuit (35) of the lock unit (17) generates a control signal representing the locking state. The transmission of the information signals takes place via a single pair of coupling coils (21, 23) utilised in both transmission directions. The amplitude modulator (33) modulates the high-frequency signal of a free-running high-frequency oscillator (27), the frequency-determining circuit of which comprises the coupling coil (21) of the lock unit, whilst the amplitude demodulator (39) is connected to the coupling coil (23) of the key unit (19). The frequency modulator (43) is likewise connected to the coupling coil (23) of the key unit (19) and detunes the frequency-determining circuit of the high-frequency oscillator (27) in dependence on the information signal to be transmitted. The frequency demodulator (47) is also coupled to the high-frequency oscillator (27). The locking arrangement permits high locking security, along with a high data transmission rate, at a comparatively low outlay in terms of structural parts. <IMAGE>

Description

The scope of the description is 8 pages (including 2 tabs)

EN 216 494 Β (21, 23), the amplitude modulator (33) modulates a high-frequency signal of a preferably freewheeling high frequency oscillator (27), and the coupling coil (21) is part of the frequency-determining elements of the oscillator (27), and the amplitude modifier (39). ) the coupler unit (19) is coupled to the coupling coil (23), and the frequency modulator (43) is coupled to the coupling coil (23) of the key unit (19) and, as a function of the information signal, aligns the frequency range of the high frequency oscillator (27) and the frequency modulator (27). 47) connected to the high frequency oscillator (27).

Field of the Invention The present invention relates to an electronic locking device comprising a lock unit and a key unit, each having a control unit and a transmitter and receiver unit, which are provided with inductively coupling coils for the control unit of the other unit, wherein the first unit, in particular the transmitter and receiver unit of the lock unit, is the information. the amplitude modulator and the frequency modulator which transmit the signals, while the other unit, in particular the key unit, comprises a frequency modulator and an amplitude modulator, and wherein the lock unit control unit generates a closed signal control signal depending on the information signals transmitted between the units.

DE-A-35 17 858 discloses an electronic locking device having a lock unit comprising a mechanical lock and a key unit formed as a flat key, each unit comprising a control unit, a transmitter and a receiver, which can be connected to each other by means of coils for the transmission of information signals. . The high-frequency oscillator connected to the lock unit transfers the operating energy to the key unit through a first pair of coupling coils. The coding information stored in the key unit container is transmitted to the lock unit by a frequency modulated signal of the carrier signal generated by the high frequency oscillator of the key unit, comparing it with the encryption data stored in the lock unit storage to generate the control signal corresponding to the closed state. In order to program the coding information stored in the lock unit storage, the amplitude of the signal transmitted from the oscillator of the lock unit to the first coupling coil can be modulated. Accordingly, the key unit comprises an amplitude modulator which separates the encoded information.

In order to increase the security of the closure, it is necessary to transfer information signals in both directions between the lock unit and the key unit during each closing process. Meanwhile, the infoimation flow of each direction cannot affect each other. In order to minimize the mutual interaction of information transmitted between the lock unit and the key unit, DE-A-3244 566 discloses a solution in which the transmission times of each direction are shifted relative to each other in time and the axis of the coupling coil pairs relative to one another. Rotated 90 ° in space.

EP-B-287,686 discloses a solution in which the frequency of the carrier signal carrying information transmitted from the key unit to the lock unit is selected differently from the frequency of the operating energy signal transmitted on the first coupling coil from the lock unit 15 to the key unit. Filters are provided by the filters on the receiving side for each signal to be disconnected.

EP-A-288 791 discloses bi-directional transmission of information signals between a lock unit and a key unit via a single coupling coil in a high frequency carrier modulated form, wherein both the lock unit and the key unit have a synchronously controlled switch that alternately interleaves the coupling coils with a modulator. or with a demodulator.

Finally, DE-C-3402737 discloses the transmission of information signals between a lock unit and a key unit through a single coupling coil. Here, the coupling coil of the lock unit is connected to the output of a high frequency oscillator, and the coupling coil of the key unit is connected to a damping circuit switchable by the control unit. The amplitude of the high-frequency current of the lock-side coupling coil inductively coupled to the key-side coupling coil varies depending on the attenuation of the key-side coupling coil. This amplitude change carries the coded information of the key unit. To synchronize the lock unit to the key unit, the high frequency generator also generates a periodic synchronization signal, which is transmitted in the form of a phase shift of the high frequency signal.

The above-described electronic locks require a considerable amount of construction effort, i.e. require multiple coupling pairs and a high frequency oscillator both in the lock unit and in the key unit, with the consequence that the power consumption increases and the data transfer rate decreases, which in turn reduces the closing safety or increase the shutter release time.

It is therefore an object of the present invention to provide an electronic locking device which has a relatively simple construction design, operates with a high degree of security and provides a short speaking time.

Starting from the locking mechanism shown in the introduction, the above task can be solved by an electronic locking device according to the invention, where the transmitting and receiving units of the high frequency oscillator, amplitude modulator, amplitude modulator, frequency modulator and frequency modulator for transmitting the information signals from the lock unit to the key unit and from the key unit to the lock unit. common coupling coils, the amplitude modulator modulates a high frequency signal of a preferably freewheeling high frequency oscillator, and the coupling coil is oscillary 1

HU 216 494 Β is a part of the key unit coupling coil, and the frequency modulator is coupled to the key unit coupling coil and sets the frequency range of the high frequency oscillator as a function of the information signal, and wherein the frequency modulator is connected to the high frequency oscillator.

A single high frequency oscillator and a single pair of coupling coils are sufficient for two-way transmission of information signals in a single locking mechanism. The data rate is primarily determined by the frequency of the high-frequency oscillator, which can be selected to be relatively high, for example 2 MHz or above. Since there is no need for a high-frequency oscillator in the key unit, the power consumption of the key unit is low. The current required for operation can be generated by rectifying the high frequency signals transmitted by the coupling coil. Bidirectional transmission of information may occur simultaneously or in time in each transmission direction. In the case of simultaneous transmission, an amplitude limiter is inserted in front of the frequency modulator, which keeps the amplitude modulation caused by the amplitude modulation from the frequency modulator. As a frequency modulator, any conventional frequency modulator switching is suitable, but pulse width modulators are particularly suitable for this purpose, converting the oscillator high frequency carrier signal into a pulse-width modulated pulse wave.

The locking mechanism preferably comprises a mechanically lockable cylinder lock which comprises a key unit integrated with a flat key. Conventional cylinder locks are standard in size, so the switching elements of the lock unit should be placed in a relatively small space. In a preferred embodiment of the invention, the amplitude of the high frequency oscillator output signal can be varied as a function of the amplitude of the oscillator operating voltage or current, and the amplitude modulator modulates the amplitude of the oscillator operating voltage or operating current, and the first circuit unit of the oscillator and coupling coil, the amplitude modulator and the control unit. defines a second circuit unit separated from the first circuit unit in space.

In this way, only a portion of the switching elements of the lock unit must be placed in the cylinder lock, while the other part, particularly the microprocessor control unit, may be placed outside the cylinder lock, for example inside or outside the lock housing. Since the amplitude modulator modulates the operating voltage or current of the oscillator, it is not necessary to conduct separate data transmission lines to the oscillator in addition to the supply lines required. This reduces the number of wires between the cylinder lock and the external circuit elements.

It is further preferred that the frequency modulator also forms part of the second external circuit unit. To accomplish this, the elements of the high-frequency oscillator must be appropriately dimensioned, such as the amplitude of the operating voltage or, in particular, the operating current at the high frequency oscillator pulsating with the instantaneous frequency of the high frequency vibration, and the frequency modulator starts to pulse the operating voltage or the operating current amplitude.

The high-frequency oscillator, which is preferably a capacitance tri-pole capacitor formed by capacitive three-point switching, is connected to an operating voltage connector impedance, and the amplitude modulator modulates the current flowing through this serial circuit or the voltage on the serial circuit. The impedance outputs a signal corresponding to the current frequency of the oscillator and directs it to the frequency modulator. The impedance resistance may also be preferred, but preferably inductance is used to avoid actual losses. The three-point oscillators have the advantage that they are very simple and the current of the oscillator amplifier, such as a transistor, flows through the coupling coil. In addition, in such oscillators, the operating voltage can be varied within very wide limits and still vibrate at very low voltages.

The amplitude modulator is connected in series with the high-frequency oscillator operating voltage connectors, and is configured as a variable network resistor network in steps with the control unit. In the simplest case, the resistance network is a single resistor with which the switch controlled by the control unit is connected in parallel.

Preferably, the key unit coupling coil forms part of a vibrating circuit tuned to the high frequency oscillator carrier frequency, so that a sufficiently high output voltage can be generated for the key control unit. Preferably, the rectifier used for generating the operating voltage from the high frequency signal is a diode voltage doubler, which can be used to further increase the voltage.

In a further preferred embodiment of the invention, the frequency modulator of the key unit is coupled to a vibrating circuit, a damping resistor network of variable value with a key unit control unit.

High shutter safety and high operational security can be achieved if the lock unit control unit periodically sends a trigger signal, after which the key unit outputs a response signal, and the lock unit control unit transmits coding data after receiving the response signal, after which the key unit also sends encrypted data.

The lock security is also enhanced if the key unit sends a data block containing both the currently encoded data and the coded data generated by the key unit, and the lock unit control unit evaluates the encoded data transmitted in the data block to generate the control signal. For example, the key unit may transmit encrypted data stored in its container, but it is also possible to retrieve encoded data from the lock unit after re-encoding or mixing according to an algorithm. Since the previously transmitted coded data of the lock unit and the coded data specific to the key return to the lock unit, which evaluates them, very good closing security can be achieved.

EN 216 494 Β

When the coded data of the lock unit and the key unit match, the lock signal corresponding to the closed state in the lock unit can be routed to an external operation monitoring unit, for example an alarm center, but can also be used for additional mechanical blocking of the cylinder lock, for example by proper control of an electromagnetic locking unit.

The invention will now be described in more detail by way of example with reference to the accompanying drawings, in which:

Figure 1 is a schematic side view of an electronic cylinder lock, a

Figure 2 is a front view of the cylinder lock of Figure 1;

Figure 3 is a schematic side view of the electronic flat key for the cylinder lock of Figure 1, a

Fig. 4 is a block diagram of an electronic locking device according to the invention;

Fig. 5 is a schematic schematic diagram of an exemplary embodiment of the electronic locking device of Fig. 4.

The cylinder lock shown in Figures 1 and 2 has a conventional cylinder closure 1 and a rotatable conventional roller cylinder 3 which can be locked by a pair of shutter flaps 5 arranged one behind the other. In the case of the pulled out key 7 (Fig. 3), the lock pins 5 are fixed to the cylinder lock housing 1 by the cylinder 3. The stem 9 of the key 7, which is inserted into the key hole 11 of the cylinder body 3, engages the lock pins 5 relative to the shell of the cylinder body 3 so that the cylinder body 3 can be rotated relative to the cylinder lock 1.

In addition to the mechanical locking locks 5, the cylinder lock housing 1 also has an electromagnetically actuated locking device 13, which, for example, locks the cylinder body 3 by preloading the locking pin 15, for example. However, the excitation pulse eliminates the interlock for the duration of the pulse. The locking mechanism 13 is controlled by the switching arrangement of the lock unit 17, depending on the encoded information generated by the key arrangement of the key unit 19 for the key 7 inserted into the key slot 11, and transmitted by an inductive coupler 21,23. The switching arrangement of the key unit 19, as shown in Figure 4, is located in the grip portion 25 of the key 7. The lock-side coupling coil 21 is fixed in the cylinder lock housing 1, for example, secured at the input of the all-key slot, while the key-side coupling coil 23 is positioned at the appropriate position of the stem 9, near the gripping part 25.

The coupling coil 21 forms part of a frequency-determining circuit of a high-frequency oscillator 27, such as an LC-oscillator circuit, not stabilized by a quartz crystal, for example, where the oscillator receives a supply voltage from the circuit unit 31 further away from the cylinder lock. The high frequency oscillator 27 is dimensioned such that the signal amplitude of the coupling coil 21 varies with the supply voltage of the conductor 29. The supply voltage is obtained, for example, from an amplitude modulator 33 as amplifier, whereby the high frequency magnetic field generated by the coupling coil 21 is modulated in an amplitude according to the information data provided by the control unit 35.

In the case of a plug-in key 7, the coupling coil 23 is inductively coupled to the high-frequency magnetic field of the coupling coil 21. The amplitude modulator 39 coupled to the coupling coil 23 through an input circuit 37 detaches information from the carrier signal of the high frequency oscillator 27 and transmits it to the key-side control unit 41.

On the other hand, the control unit 41 provides information for transmission to the switching arrangement of the lock unit 17. The information data is preferably provided to a frequency modulator 43, which is a pulse width modulator, which controls the impedance connected to the coil 23 in the input circuit 37 and thus the attenuation of the coupling coil 23. By coupling the coupling coil 23 with the frequency-determining loop of the high-frequency oscillator 27, the frequency-determining circuit is tuned to the pulse-width modulated signals of the frequency modulator 43, which leads to pulsation of the current flowing through the line 29 at the rate of frequency modulation. In the circuit unit 31, the frequency modulator 47 connects to the line 29 via a pulse-forming stage formed by an amplitude-limiting amplifier, separating the frequency-modulated information data from the high-frequency oscillator carrier signal 27 and forwarding it to the control unit 35 for further processing. The control unit 35 compares the predetermined encoded data with the encoded data from the key unit 19 and, if matched, receives a predetermined duration signal from the amplifier 49 to the conductor 51. The rectifier 53, which is connected to the input circuit 37, generates a working DC voltage from the high-frequency voltage induced in the coupling coil 23 for the circuits of the key unit 19.

As shown in FIGS. 1 and 2, a cylinder plate 55 is provided in the cylinder lock housing 1, which essentially comprises only the high frequency oscillator 27 and the coupling coil 21. Further circuit elements of the lock unit 17 are located in the outer circuit unit 31, which connects to the mounting plate 55 only through a small number of wires.

The information data transmitted between the lock unit 17 and the key unit 19 includes synchronizing data and encrypted data. Preferably, pulses modulated on the carrier signal of the high frequency oscillator 27 are transmitted in both directions alternately. The switching arrangement works as follows:

The coupling coil 21 generates a continuous high frequency magnetic field which is modulated in amplitude by the periodically generated start signal of the control unit. When the key 7 is inserted into the key slot 11, the magnetic field induces an alternating voltage in the coupling coil 23, from which the diode rectifier 53 connected to the input circuit 37 generates an operating DC voltage for the circuit of the key unit 19. After receiving a start signal, the control unit 41 generates a response signal to which the control unit 35 responds by transmitting encoded data. The control unit 41, after receiving the encoded signals, sends a data block which, in addition to the received encoded data, also contains encrypted data generated by the key-side, preferably the encoded data received. The control unit 35 compares the key1

EN 216 494 Β the coded data originally transmitted and decrypts the key-coded data. In the case of matching data, it generates a unlock signal.

FIG. 5 is a circuit diagram of a particular embodiment of a solution as shown in the general block diagram of FIG. Elements with the same function have the same designations as in 1-4. ábráknál; in the detailed description, reference is made to these figures.

The high frequency oscillator 27 located in the cylinder closure 1 is designed as a Colpitts oscillator, i.e. a capacitive three-point oscillator. The coupling coil 21 is connected in parallel to the serial coupling of two capacitors 57, 59 and forms a vibrating circuit (carrier frequency) defining the frequency (carrier frequency) of the high frequency oscillator 27 in the collector circuit of the transistor 61 operating in the emitter circuit. Connecting the oscillating circuit 63 farther from transistor 61 is coupled to the base of transistor 61 via coupler capacitor 65 to provide positive feedback. The common connection point of the two capacitors 57, 59 is connected to the emitter of the transistor 61. The connection 63 is also the power connection of the high frequency oscillator 27. The resistance coupled between the coupling 63 and the base, together with the resistor 69, determines the operating point of the transistor 61.

The amplitude modulator 33 comprises a resistor network 71 coupled between the operating voltage source 70 and the high frequency oscillator voltage source 27, and a parallel electronic switch 73 controlled by the control unit 35. The resistor network 71 is dimensioned so that the voltage at the connection 63 is sufficient for the high frequency oscillator 27. When the switch 73 shortens the resistance network 71, the supply voltage of the high frequency oscillator 27 increases and the high frequency oscillator 27 produces a stronger magnetic field through the coupling coil 21.

Between the resistor 69 coupled to the emitter and the ground point there is an inductance of 7 5, which also flows through the oscillating frequency of the high frequency oscillator 27. The threshold switching with the Schmitt trigger 77 in the pulse 45 stage generates a pulse signal on the inductor 75 from the pulse current, the instantaneous pulse width of which corresponds to the frequency of the high frequency oscillator 27. On the one hand, the pulse signal is synchronized with the control unit 35 and on the other hand with the frequency modulator 47 formed as the pulse width demodulator, which is implemented with a phase control circuit (PPL) in the illustrated embodiment. The frequency modulator 47 has led to its input 79, generating an output signal corresponding to the frequency difference or variation as a function of the reference frequency of the high frequency oscillator 27, which is transmitted to the control unit 35 via an amplifier 81.

In the insertion position of the key 7, the coupling coil 23 is coupled to the coupling coil 23 by means of an inductively coupled coil 21 which, together with the coupling coil 23, forms a oscillating circuit tuned to the carrier frequency of the high frequency oscillator 27. A voltage doubler 85 is formed from the diodes 87, 89 and capacitors 91, 93 for the oscillating circuit. The oscillating circuit provides for the amplification of the alternating voltage induced in the coupling coil 23, and the voltage doubling switch 85 rectifies and doubles this voltage. The voltage doubler 85 provides the supply voltage for the circuit elements of the key unit 19, in particular the control unit 41.

The capacitor capacitors 91, 93 of the voltage doubler 85 also form a voltage divider to which the amplitude modulator 39 is connected. The amplitude modulator 39 may have a conventional configuration and may include, for example, a rectifier and an associated amplifier. The frequency modulator 43 comprises a damping resistor network 95 and a switching electronic control switch 97 controlled by the control unit 41, which is inserted between the parallel oscillating circuit 23 and the ground potential. At the closed position of the switch 97, the frequency modulator 43 attenuates the parallel oscillation circuit, which reduces the effect of the coupling coil 23 on the coupling coil 21, thereby changing the oscillation frequency of the high frequency oscillator 27. In addition to the closed switch 97, the resonance circuit of the input circuit 37 absorbs more energy from the alternating magnetic field of the high-frequency oscillator 21 than the open switch 97. This energy is not available for the high frequency oscillator 27, thereby increasing the vibration frequency of the high frequency oscillator 27. In addition, the resonant circuit of the input circuit 37 is coupled through a resistor 99 to the clock input of the control unit 41 and provides synchronization of the control unit 41. For both control units 35, 41, a clock signal derived from the frequency of the high frequency oscillator 27 is provided, which enables bit coding of the information signals of the control unit 35, 41 in a synchronous manner with the oscillator frequency. The data transmission is thus not precisely timed, so the width of the data pulses determined by the control unit 35, 41 is determined by the number of specific oscillator periods of oscillator. Thus, no fixed reference frequency is required in the key-side circuit.

Of course, on the side of the circuit unit 31, the frequency modulation can be implemented differently. For example, the frequency modulation in the control unit 35 can be implemented directly by frequency measurement as a function of the output signal of the pulse-forming stage 45.

Claims (12)

An electronic locking device comprising a locking unit (17) and a key unit (19), each having a control unit (35,41) and a transmitter and receiver unit having inductively coupled coils (21) for transmitting information to the control unit (35,41) of the other unit. , 23) are provided where 21 the transmitting and receiving unit of the first unit, in particular the lock unit, comprises an amplitude modulator (33) and a frequency demodulator (47) for transmitting the information signals, while the second unit, in particular the key unit (19) comprises a frequency modulator (43) and amplitude demodulator (39) and wherein, depending on the information signals transmitted between the units, the control unit (35) of the lock unit (17) generates a control signal specific to the closed state, characterized in that the information signals from the lock unit (17) to the key unit (19) and transmitting and receiving units having high frequency oscillators (21, 23) for transmitting to a lock unit (17) a high frequency oscillator (27), an amplitude modulator (33), an amplitude demodulator (39), a frequency modulator (43) and a frequency demodulator (47); 33) Output of a preferably freewheeling high frequency oscillator (27) the amplifier demodulator (39) is connected to the coupling coil (23) of the key unit (19) and the frequency modulator (43) to the coupling coil (19) of the key unit (19). 23), and wherein the frequency demodulator (47) is connected to the high frequency oscillator (27). Locking device according to claim 1, characterized in that the oscillator (27) and the coupling coil (21) are a first circuit unit, and the amplitude modulator (33) and the control unit (35) are a second circuit unit spaced from the first circuit unit. (31). The locking device according to claim 1, characterized in that the frequency demodulator (47) is also part of the second circuit unit (31). 4. A locking device according to any one of claims 1 to 5, characterized in that the frequency modulator (43) is designed as a pulse width modulator. The locking device according to claim 1, characterized in that the operating voltage terminals of the high-frequency oscillator (27) are connected in series with impedance (75) and the frequency demodulator (47) is also connected to the impedance (75). A lock according to claim 5, characterized in that the high-frequency oscillator (27) is designed as a capacitive three-point oscillator. Locking device according to Claim 5 or 6, characterized in that the impedance (75) is designed as an inductance, and the frequency demodulator (47) is connected to the inductance via a pulse shaping stage (45), preferably a Schmitttrigger (77). 8. Figures 5-7. A locking device according to any one of claims 1 to 6, characterized in that the amplitude modulator (33) comprises a resistor network (71) connected in series with the operating voltage connectors of the high-frequency oscillator (27) with the control unit (35). 9. A locking device according to any one of claims 1 to 4, characterized in that the coupling coil (23) of the key unit (19) forms part of a vibrating circuit (23, 83). The locking device according to claim 9, characterized in that a diode voltage doubler (85) for operating voltage is connected to the oscillating circuit (23, 83). Locking device according to Claim 9 or 10, characterized in that the frequency modulator (43) is provided as a damping resistor network (95) with a step-change value connected to the oscillating circuit (23, 83) by the control unit (41) of the key unit (19). formed. 12. A locking device according to any one of claims 1 to 4, characterized in that at least the coupling coil (21) of the locking unit (17) and the cylinder lock actuated by the key (7) form a structural unit, the key unit (19) and the key (7) which also includes an operating voltage rectifier (53) connected to the coupling coil (23).