DE2930038A1 - Remote control for electronic lock for machine - sends coded pulses to receiver that only excites unlocking solenoid when thyristors turn on in given sequence - Google Patents

Abstract

The electronic lock has a transmitter containing a crystal oscillator producing pulses and a modulator modulating the pulses. A receiver contains a detector that detects only the carrier-waves of the pulses from the transmitter. A detector at the receiver passes on only the received waves from the pulses. Thyristors are controlled by the decoder in a given sequence. A solenoid is only excited when the thyristors are turned on in a given sequence. The solenoid unlocks or locks the machine. The transmitter and receiver have aerials. The decoder contains filters each tuned to a different frequency.

Description

The invention relates to an electronic lock for remote

locking or remote unlocking of a remote location Machine using a radio wave.

A wide variety of electronic locks have been described and practically used. Usually there are those to be locked or unlocked Machines in a remote, inaccessible location. With part of the conventional Electronic locks are solenoids arranged in various ways. With others electronic locks are made a combination of a high frequency and several Low frequencies in various ways. These two types of conventional electronic However, locks have several disadvantages. In particular, it occurs due to Noises related to incorrect operation.

Furthermore, these conventional locks are constructed in a co-developed manner very prone to failure and expensive to manufacture.

It is therefore an object of the present invention to provide an electronic Create a lock that eliminates the disadvantages of traditional electronic locks avoids.

It is also an object of the invention to provide an electronic lock for Remote locking or unlocking of a remote location Machine to create, which is essentially not due to noise in its operating behavior can be affected and which on countless combinations of unlocking digits is adjustable and simple in its structure and ii essentially free from interference and is cheap to manufacture.

According to the invention, this object is achieved by an electronic lock for remote locking or unlocking of a machine solved which comprises a sending system and a receiving system. The broadcast system includes a Oscillator circuit for generating a large number of pulses. The transmitter includes furthermore a modulator circuit for modulating the frequency of the pulses. The receiving system comprises a detector circuit for receiving the modulated pulses and for detection of the transmitted waves according to the heterodyne system, so that only the carrier waves of the Pulses can be selected. Furthermore, a decoding circuit is provided which from the impulses now reproduces the received waves, as well as a multitude of Thyristors, which can be actuated by the output signals of the decoding circuit. A solenoid is only switched on when the thyristors are in a predetermined Order to be switched on. This locks the machine in question or unlocked.

According to the invention an electronic lock for remote locking or remote unlocking of a machine, which has a transmitting system and a receiving system includes. The transmission system comprises an oscillator circuit for generating pulses and a modulator circuit for modulating these pulses. The receiving system comprises a detector circuit, which from these pulses of the transmission system after the heterodyne principle only selects the carrier waves, as well as a decoding circuit to reproduce only the received waves from the detected pulses. A multitude of thyristors is switched on by the output signals of the decoding circuit, in a predetermined order, and a solenoid can only be actuated when the thyristors are turned on in the predetermined order.

This locks or unlocks the machine.

The selected combination of digits is preferably a combination transmitted by frequencies. The frequencies are through a multitude captured by filters. Preferably the decoding circuit comprises a plurality of NOR gates, and the inputs of the NOR gates are with selected combinations the filter connected. Monostable multivibrators are preferably equipped with individual, selected NOR gates of the plurality of NOR gates of the decoding circuit can be connected. The outputs of the NOR gates are connected to the control electrodes of thyristors or similar semiconductor switches connected. The solenoid to be actuated is in the main current path one of the thyristors. The thyristors are preferably connected in such a way that the current flowing through an ignited thyristor also through the previous ones Thyristors must flow, with the solenoid in the main circuit of the last thyristor lies. A switch can preferably be provided to extinguish the thyristors, which interrupts the current flowing through the thyristors, and this switch can be actuated by the output signal of the detector. It can be one act normally off (or on) switch.

In the following the invention is explained in more detail with reference to drawings; 1 shows a schematic representation of a transmitter system of an electronic Lock according to the present invention; Fig. 2 is a table of various combinations of unlocking numbers and frequencies of the electronic lock; Fig. 3 a schematic representation of the receiver system of the electronic according to the invention Lock; and FIG. 4 is a circuit diagram of the electronic circuit in the one according to the invention electronic lock from the decoder circuit to the solenoid.

The drawings show an embodiment of the invention electronic lock. This is to be described in the following under the assumption that the numbers 1, 3 and 5 are used as unlocking numbers.

Fig. 1 shows a transmitter system for transmitting an unlocking Signal wave for the electronic lock according to the invention with an oscillator 10, which includes a crystal oscillator or the like (not shown) and which Pulse signals are generated corresponding to the selected unlocking numbers when the severity of the sender assigned to the selected unlocking digits are to be switched on. In the embodiment shown, it is only necessary the switches of the unlocking digits 1, 3 and 5 in any, desired or to be switched on in a predetermined sequence. As shown in Fig. 2, each of the unlocking Digits can be represented by a combination of two different frequencies. For example, the unlocking digit is 1 through a combination of frequencies F1 and F2 shown. The pulses generated in the oscillator 10 pass through a Oscillator circuit 11, which pulses in the form of a combination of two different Frequencies generated according to the selected unlocking digits. The oscillator circuit 11 generates a pulse with a carrier frequency after reception of an impulse, namely in the form of the combination of frequencies, and the impulse the oscillator circuit 11 reaches a modulator circuit 12, which the carrier frequency of the pulse is modulated, and the frequency-modulated pulse is sent to an antenna 13 of the transmitter system, which the frequency-modulated pulse to the receiver system feeds.

When the frequency-modulated pulse from the receiver system shown in FIG is received, the pulse first reaches an antenna 14 of the receiver system and then to a detector circuit 15, and this generates a Beat with the oscillator output and the received, frequency-modulated pulse according to the type of heterodyne system, and then the pulse is passed to a decoding circuit 16.

The decoding circuit 16 comprises a plurality of filters 17 for the Frequencies F1 .... F7 and a larger number of NOR gates 18, which selectively be switched on, depending on the actuation of the filters 17. For example the unlocking digit 1 passes through the filter 17, which corresponds to the frequencies F1 and F4 are assigned, and the output signals of these filters go to the NOR gates 18, which are assigned to these filters 17. These NOR gates 18 produce negative ones theoretical output signals.

The negative theoretical outputs of the NOR gates 18 are driving one of a plurality of monostable multivibrators 19, which the mentioned NOR gates 18 are assigned. The output signal of the driven, monostable Multivabrators 19 gets to a thyristor 20 (from a large number of thyristors), which is assigned to the driven, monostable multivibrator. This will the thyristor 20 switched on.

In the described embodiment, the unlocking digit 1, 3 and 5 are sent and received in this order, and the thyristors 20 are switched on in this order, and as soon as all three thyristors 20 are turned on, the electric current flows through the solenoid 21, which in turn a device 22 locked or unlocked.

The three thyristors 20 are designed such that when applied with the output signals of the monostable multivibrators 19 in a different than the predetermined or desired order an electric Current cannot flow through the solenoid 21, so that the electronic lock the machine 22 does not lock or unlock.

If the sending system has erroneous signals or signals in one of supplies the recipient system with an order deviating from the predetermined order, so the reset switch 23 is actuated and this causes the transmission system, repeat the signal transmission in the predetermined or correct order. In the described structure of the electronic lock according to the invention are the respective unlocking digits by a combination of two different ones Frequencies can be displayed, and the electronic lock is only operated when that The receiving system receives the pulses in the same order as the sending system which transmits impulses. Therefore, erroneous operation of the electronic Lock excluded, even if there is a high noise level. Since the unlocking digits can be combined in any way, one thus inventively a completely theft-proof electronic lock.

In addition, the electronic lock according to the invention is in his Structure extremely simple and it shows a precise operating behavior. It is with minor Costs compared to conventional electronic locks. It is Can be used as a control lock on various machines and in motor starters. That Electronic lock according to the invention can also be activated by acoustic waves operated instead of radio waves. The electronic lock according to the invention can thus be used within a wide area: 2. The inventive Electronic lock offers various excellent advantages and has one considerable practical value.

Claims (7)

Electronic lock P a t e n t a n 5 p r U c h e Öl Electronic Lock for remote locking or unlocking of a machine, marked by a transmission system (10-13) which has an oscillator circuit (10) for generating of pulses and a modulator circuit (12) for modulating the pulses, and a receiving system (14-22) comprising a detector circuit which only Carrier waves of the impulses of the transmission system selects according to the heterodyne principle, as well as a decoding circuit (16) for reproducing only the received waves from the detected ones Pulses, as well as a large number of thyristors (20), which by the output signal the decoding circuit (16) can be switched on in a predetermined order, and a solenoid (21) which can only be excited when the thyristors (20) in are switched on in the predetermined sequence, whereby the machine (22) is locked or is unlocked. 2. Electronic lock according to claim 1, characterized in that that the oscillator circuit (10) comprises a crystal oscillator and that the transmission system (10-13) comprises a transmitting antenna (13) which receives the modulated pulse of the modulation circuit (12) receives and transmits to the receiving system (14-22). 3. Electronic lock according to claim 2, characterized in that that the receiving system (14-22) has a receiving antenna (14) for receiving the modulated Includes pulses from the transmitting antenna (13). 4. Electronic lock according to one of claims 1 to 3, thereby characterized in that the decoding circuit comprises a plurality of filters (17), each of which is assigned to a separate frequency from a multitude of frequencies is, as well as a larger number of NOR elements (18), which can be switched on individually when assigned filters or combinations of filters are activated. 5. Electronic lock according to claim 4, characterized by monostable Multivibrators (19) between the NOR elements (18) and the thyristors (20), wherein the monostable multivibrators (19) by the output signals of selected ones NOR members (18) can be actuated. 6. Electronic lock according to one of claims 1 to 5, characterized characterized in that the thyristors (20) are connected in such a way that upon ignition the same in an order deviating from the predetermined order Solenoid (21) is not energized. 7. Electronic lock according to one of claims 1 to 6, thereby characterized in that the receiving system has a Reset switch (23) which is actuated when the thyristors (20) in one of the predetermined Sequence deviating sequence are ignited, so that hereby the transmission system is caused to repeat the sending process.