DE1002787B - Automatic alarm device - Google Patents

Description

PATENT OFFICE

kl. 21 al 1/05

INTERNATIONAL KL.

H 041; G 08b

V 10069 VIII a / 21a ¹ REGISTRATION DAY: 24 JANUARY 1 9 5 6

NOTICE
THE REGISTRATION
AND ISSUE OF THE
EDITORIAL: FEBRUARY 21, 1957

The invention relates to an automatic alarm transmitter for certain signals, in particular for a SOS distant signal. Such facilities should, for. B. monitor the distress waves, whether under the from Recipient recorded characters an alarm signal 5 is located. Ideally, this consists of twelve characters of 4 seconds each with pauses of 1 second in between. The length of the characters may vary between 3.5 and 6 seconds and that of the pauses between 0.01 and 1.5 seconds. if three consecutive characters and the pauses in between meet these conditions, the device should trigger the alarm.

For this purpose, mainly relay arrangements have been used up to now. So is z. B. on a sequence of Signal receiving device responding to low-frequency pulses known with a tube circuit in which one tube to limit the minimum and the maximum duration of the pulses and a tube to limit the duration of the pulse pauses provided ao are. In the grid circles of these tubes there are time circles made up of i? C elements and in the anode circles Switching relays switched on, which operate a storage device in interaction with the timing circuits. As a storage device, a number of storage relays are provided in such a circuit that each time signals of the specified duration arrive with a subsequent pause of the specified duration Maximum duration of the successive memory relays to respond until either when a signal is received that does not meet the specified conditions, the initial state of the Circuit is restored or after the required number of correct signals have been received a switching process is triggered which, for example, causes an alarm signal generator to respond. Relay arrangements are, however, very susceptible to failure and can therefore be used for continuous, flawless monitoring not guarantee. Also, the safety regulations of various states recommend from the use of relays in distress systems is not possible at all. Furthermore, were with the known arrangements no precautions have been taken to rule out all possible errors with certainty.

An arrangement is also known in which a signal is triggered in such a way that a rectifier tube is interconnected with a relay and when an SOS distant signal is received or a sustained one Signal with the same time constant, the relay is activated. Here the DC current interrupted in case of incoming distant signal. This Morse pulse will then the cathode of the rectifier tube is cooled down to such an extent that the anode current stops flowing. That in the on-automatic Alarm giver

Applicant:

VEB Funkwerk Köpenick,
Berlin-Köpenick, Wendenschloßstr. 154-158

Jens Peter Rehahn, Berlin,
has been named as the inventor

The relay arranged in the circuit is demagnetized and thereby closes the alarm circuit. the However, the system cannot be coordinated nearly so precisely that it actually only works in the case of distress signals responds, so there will be very frequent false positives.

There has also been proposed a device operating with electronic relays in which an alarm is triggered when three consecutive characters have a length of α to b, e.g. B. 3.5 to 6 seconds and the pauses in between a length of c to d, z. B. 0.01 to 1.5 seconds. An electronic counting device is provided here, via which the alarm is triggered. At the entrance two electronic relays are with a delay of d seconds, one of which even an electronic relay with a delay of e - a - d takes seconds to respond, and the other at the fall is a pulse to a level of locking, provided they is not blocked by the activated relay with a response delay of e seconds, this impulse is passed on to a zero stage which, with each impulse, cancels any correct impulses previously registered by the counting stage, while the second relay at the input responds if there is a pause longer than d seconds take. Here there is an impulse directly or via the blocking level to the zero level. The relay with a delay of e seconds excites another electronic relay with a response delay of f = b - α seconds, which sends a pulse to the zero level directly or via the blocking level when it drops and, on the other hand, sends a pulse to the counter level when it drops.

Here, however, it is disadvantageous that the Delay time of the two input relays are heavily dependent on the level of interference when the

609 836/167

Interference voltage is no longer small compared to the required useful voltage. With the invention the object is achieved to avoid this disadvantage and the structure of the electronic alarm device further simplify.

According to the invention. an input stage is provided which only forwards characters to the downstream stages whose size is greater than the response wave of this input circuit. It controls an electronic relay with the response delay of d seconds and the response of another electronic relay with a delay of s seconds free, which is then brought by the relay with the delay of D seconds to respond. When it drops out, the relay sends a pulse to a counting stage with a delay of e seconds. Furthermore, a relay is energized with a delay of f seconds, which, like the relay with a delay of d seconds, activates an extinguishing stage when it drops out. Means are also provided which have the effect that the erase stage only passes the erase pulses on to the counting stage when the relay is in the rest position with the response delay of e seconds.

The invention will be explained in more detail using the exemplary embodiment shown in the figures.

Fig. 1 shows a normal circuit diagram and Fig. 2 shows a block diagram.

The device essentially consists of a counting stage 6, 7, which is formed by the tubes Rö 9 and RölO , and several electronic relays 2, 3 and 4 that have already been proposed.

The mode of operation of these electronic relays is explained on the basis of the relay 4 formed by the first system of the tube Rö 7 and the tube Rö 8 with a response delay of 2.5 seconds. In contrast to the known flip-flop circuits, the cathodes of the tube Rö8 are not at the same potential. The cathode of the first system receives a positive bias voltage Uj ₁ , which is less than the operating voltage Uj, of the tube. As a result of the cathode elevation, a control voltage can be fed to the first system of the tube which is either positive or negative with respect to the cathode potential. In the idle state, the grid of the tube RO7 / 1 (first system) connected upstream of the arrangement via a resistor W38 is at cathode potential, ie the tube is open. Its internal resistance bridges a capacitor C 12 lying parallel to it between the resistor 38 and zero potential. Accordingly, if the resistors JV35 to W39 are correctly dimensioned, a low voltage compared to the voltage U _k is present on the grid of the first system of the tube egg. So the grid is biased negatively and the tube is locked. The voltage divider consisting of the anode resistor fF40 of the first system of the tube Rö8 and two further resistors W4: 3 and W 44, which is between the operating voltage Uj and the negative bias voltage U _g , is dimensioned so that when the first system of the tube Rö 8, that is to say when the anode current does not flow through the resistor W 40, the second system of the tube Rö8 is certain to receive such a grid bias voltage tapped between the resistors W 43 and W 44 that it is open. In the rest position, the first system of the tube tube 7 and the second system of the tube are. /? «? 8 opened and the first system of the tube Rö8 locked.

Is now the first system of the tube Rö7 locked, that the electronic relay is caused to respond, then the voltage across the capacitor C12 increases. Corresponding to the time constant of the i? C element formed by the resistor network and the capacitor, the voltage at the grid of the first system of the tube Rö8 rises so far that the anode current begins. As a result of the associated larger voltage drop across the resistor W4ß of the voltage divider W 40, W 43 and! W 44 drops the voltage on the grid of the second system of the tube Rö 8. As a result, the current flowing through the resistors W 41 and Wi2 in the anode circuit also becomes smaller, while the potential at the connection point of these two resistors and thus at the grid of the first system of the tube Rö 8 rises. This process continues regardless of the further charging of the capacitor C 12 until the grid current begins in the first system of the tube Rö8. As a result of the anode current then flowing through the resistor W4: 0 , the negative voltage on the grid of the second system of the tube Rö8 is so great that it is completely blocked. In working condition so the first system of Röhrei? OE7 and the second system of tube Rö8 are locked while the first system of the tube is open Rom. 8

Appropriate dimensioning of the resistors W38 and W39 ensures that the changeover from one state to the other takes place relatively quickly. The resulting voltage jumps are differentiated and used as switching pulses. If the first system of the tube Rö7 is opened again, the capacitor C 12 discharges via the anode-cathode path of this tube. As soon as the grid of the first system of the tube RÖ8 becomes negative with respect to the cathode, the two systems of the tube RÖ8 fall back into their rest position. This release time is short compared to the delay time.

The electronic relays 2 and 3, formed by the tubes Rö3 and i? Ö4 or the tubes Rö5 and the Röhrei? Ö6, work in basically the same way. The function of the capacitor C 12 and the resistors fF "38 to W 44 is carried out the capacitor C 7 and the resistors W16 to W 22 or the capacitor ClO and the resistors W 26 to 1 ^ 34 taken over.

The electronic relay 2 formed by the tubes RoZ and i? Ö4 with a response delay of 1.5 seconds has a special feature compared to the relay 4 in that a double triode Rö3 is connected upstream of the bistable circuit of the tube i? Ö4. This is necessary because, as will be explained later, this electronic relay controls compliance with the shortest pause time of 0.01 seconds. As a result, the capacitor C 7 must be able to discharge very quickly via the second system of the tube Rö3 .

If the input stage 1, described later, emits a positive pulse when a character arrives, it only reaches the grid of the second system of the tube Rö 3 via the rectifier Gr 2 and the capacitor C 5, while it comes from the grid of the first system with the grid leakage resistor W9 is kept away by the oppositely polarized rectifier Gr 1. The second system of the tube Rö3, which has hitherto been blocked as a result of the negative grid bias voltage supplied via the resistor 1 ^ 15

is opened, the voltage at the anode drops as a result of the voltage drop across the resistors W 11 and W 12. This negative voltage surge reaches the grid of the first system of the tube Ro 3 via the capacitor C 3. This is blocked and the voltage at its anode rises, since there is no longer a voltage drop at the anode resistor ^ FlO. This positive voltage surge arrives via the capacitor C 6 to the grid of the opened second system with the grid leakage resistors W13 and W 14 and prevents the internal resistance from increasing, so that the capacitor C 7 can discharge very quickly. In the event of a kickback of the input stage 1, a negative pulse reaches the grid of the first system of the tube Rö3 via the rectifier Gr 1 and the capacitor C 4, while it is kept away from the second system of this tube by the rectifier Gr 2 . The previously open tube system is blocked, the anode voltage increases, so that a positive pulse reaches the grid of the blocked second tube system via the capacitor C 6 and opens it. The interaction between the two systems is the same as before, so that the capacitor C 7 can again discharge very quickly. The only difference compared to the first case is that the process does not begin with the second, but with the first system of the tube Rö3. The individual components are dimensioned in such a way that the tube relay changes immediately when an impulse arrives and returns to its rest position after 1.5 seconds. This is the opposite position as that of the electronic relays 3 and 4.

The relay 3 formed by the tubes Rö 5 and Rö 6 with a response delay of 2 seconds is controlled by two variables. When a character is received, the second system of tube 2 and thus also the second system of tube 5 is blocked. However, the relay only responds when the first system of tube 5 is blocked. This is done by responding to the electronic relay 2 with the tubes Rö3 and i? Ö4. Since the capacitor C 10 must be prevented from discharging earlier than the capacitor C 6 at the end of the character, otherwise the counting pulse emitted via the capacitor C17 will immediately be cleared via the capacitor C 8 and the tube Rö 7/2 to the counting stage would follow, a delay element with the resistor W23 and the capacitor C 9 is provided. The grid discharge resistors W22 and W23 are arranged as usual, as are the anode resistors 1 ^ 24 and W25. Preconditions for the response of the electronic relay are the input of a character and the response of the electronic relay 2.

The input stage 1, which consists of the first system of the tube Röl (Röl / 1) and the tube Rö2 , works basically on the same principle as the electronic relay, but it has some special features in terms of dimensioning. Its task is to respond only when a certain voltage value is exceeded and to switch immediately and to revert to the starting position when the voltage value is as constant as possible. The resistance W3 is therefore smaller than in stages 2, 3 and 4, and the return of the voltage from the anode of the second system of the tubes to the first system takes place directly from the anode and not via a voltage divider. Instead of the two resistors W 41 and W 42 of stage 4, only one resistor W 6 is provided. The resistors Wl, W 4, WS, Wl and WS as well as the capacitor C1 correspond in their mode of operation to the resistors W39, W 40, W43, W 44 and the capacitor C 12. The capacitor Cl is, however, much smaller, so that the delay time of this Level is only a few milliseconds. Instead of the resistors W36 and W37 , only one resistor W 2 is provided. The grid leakage resistance of the tube Rö 111 is designated by Wl. The capacitor C2 is used to steepen the edges of the pulses emitted during reversal. The task of the stage is to switch over only when a certain input voltage is reached and thus to set the following stages in function. Interferences with lower voltage are thus kept away and the delay times of the electronic relays remain constant, regardless of whether an interference level of a certain voltage was already present.

The counting stage 6, 7, consisting of the tubes Rö9 and i? Ö'10, has the task of giving the grid of the second system of the tube Röl, the so-called triggering stage 8, after receiving three successive correct characters, such a voltage that this system opens will. For this purpose, the counting stage is made up of two normal flip-flop circuits with resistors W 45 to W52 and £ F55 to JF 64. The resistors W 45 and W 47 or FF55 and WhI are each together exactly as large as the resistors W 53 and W 63, so that the symmetry of the structure is not affected by this. The arrangement of the two resistors is only made in order to be able to tap a voltage of a suitable magnitude for controlling the tripping stage 8 from the connection point via the resistors W 46 or / ^ 56. The capacitors C 15, C18, C21 and C23 are used in a known manner to increase the edge. The coupling of the tubes Rö 9 and RölO to the second system of the Röhrei? Ö7 takes place via the capacitors C 14, C 19 and the rectifiers Gr 3, "Gr 4. The rectifier ensures that only negative pulses reach the stages and the two stages are not coupled to one another via the grille.

The tube egg 9 is also via the capacitor Cl! controlled by the second system of the tube Rö6. The capacitor CIl assigned to this system serves to increase the edge of the switching pulses. The tube RÖ7 / 2, stage 5 only amplifies positive impulses (i.e. emits negative impulses) and only when the tube Rö6 is in the rest position, because otherwise the operating point is too far in the negative. The stages 6 and 7 or the tubes Rö9 and i? ÖlO are also coupled to one another via the capacitor C 20. Cathode capacitors are designated by C16 and C 22. The counter stage works as follows:

In the idle state, the first two systems of the tubes Rö9 and RölO are blocked and the second systems are open. At the connection points of the resistors W 45 and W 47 or PF55 and W57, there is a voltage that is also effective on the grid of the second system of the tube Röl via the resistors WQo and W 56, which are used to decouple the two flip-flop circuits and is below the cathode potential, so that the trigger level 8 is blocked. It is only opened when the first two systems of the tubes Rö9 and RölO are open, as only then does the grille min-

at least has cathode potential. C 24 is located on the grid of this tube and causes a slight delay in triggering, which is required in the case of error case III described later.

If a negative counting pulse arrives at the tube 6 of the relay 3 on the input of a correct character via the capacitor C17 from the tube Rö 6 of the relay 3, the bistable system formed by this tube changes over in a manner known per se, that is, the left system is opened and the right one is locked. Here, a positive pulse is applied to the tube Rö 10 via the capacitor C 20, but this does not affect the bistable system. The first system of the tube Rö9 and the second system of the tube are open, so that the release stage remains blocked. If a second negative counting pulse now reaches the tube i? Ö9j via the capacitor C 17, the bistable system strikes back into its starting position. At the same time, a pulse in turn to the tube Ro is given 10, which, however, this time negative, so that the bistable system formed by this tube also turns. After the second character, the second system of tube Rö9 and the first system of the tube are open Ro thus 10th Trigger level 9 still cannot respond. Upon receipt of a third correct character, the tube Rö 9 turns over again and gives a positive pulse to the tube Rö 10, which does not affect it. The first systems of both tubes are now open, so that the grid of the second system of the tube Röl reaches cathode potential. The trigger level 8 then responds.

However, it is not sufficient that the alarm is triggered only after three correct characters have been received; it must also be ensured that the counting stage is switched back to the starting position if there are incorrect characters or pauses in between. This object is achieved in that when a wrong character is received, the second system of the Röhrei? Ö "7 (stage 5) via the capacitors c 14, cl5 and the rectifiers Gr3, Gri emits an extinguishing pulse to both tubes, whereby the first two systems of the Tubes Rö 9 and Rö 10 are locked and the counting stage is returned to the starting position.

The mode of operation of the entire circuit will be explained in more detail using the possible operating cases.

1. Operation case:

A character is longer than 3.5 and shorter than 6 seconds, the pause is longer than 0.01 and shorter than 1.5 seconds. For the sake of simplicity, assume a character duration of 4 and a pause duration of 1 second assumed.

At the beginning of the symbol, the input stage with the tubes Rö 111 and Rö 2 switches to the working position as soon as the response threshold is exceeded. The resulting voltage jump is differentiated and given as a pulse to the electronic relay 2, which changes immediately and returns to the rest position after 1.5 seconds have elapsed. The impulse given to the second system of the tube Rö 7 (stage 5) via the capacitor C 8 is negative and therefore has no effect.

At the same time, the first system of the RoS tube is blocked, while the second system had already been blocked by the reversal of the entrance step. The electronic relay 3 (Rö 5 and Rö 6) changes over after 2 seconds. After a further 0.5 seconds, the symbol ends, whereby the electronic relay 2 changes over and relay 3 returns to the rest position. Here, a negative pulse is sent from the anode of the second system of the tube 6 via the capacitor C 17 to tube 9 and switches it over.

After a pause of 1 second, the same process is repeated, the tube Rö 9 (stage 6) returns to its starting position and sends a negative pulse to the bistable circuit 7, which causes the tube Rö 10 to flip over. After the completion of three characters, as already described, Röl / 2 is energized and triggers z. B. off the alarm via a relay.

2. Fault I:

A character is greater than 1.5 and less than 3.5 seconds. The process is the same as in case 1, up to the turning of the tube i? Ö4. Since the character ends before the tube overturns, the counting stage is not influenced from there. A upon termination of the character at the Röhrei? E4 emerging positive pulse is applied to the second system of tube Ro 7 (canceller 5) and, since the tube Ro is 6 (electronic relay 3) in the starting position, amplified and connected as a negative pulse the tubes Rö 9 and Rö 10 return to their original position.

3. Fault II:

A character is less than 1.5 seconds. At the beginning of the sign, as already described, an impulse at level 2. However, since the character ends before the delay time of 1.5 seconds has expired is, neither counting nor deletion can take place. In this case, there will be no deletion, to avoid short clutter characters within the normal pause between characters Prevent alarm triggering.

4. Fault III:

A character is longer than 6 seconds. The process is initially the same as in case 1. After switching over the electronic relay 3 (Rö6) , the first system of the tube egg? Ö7 is blocked, whereby the tube egg? Ö8 changes over after the delay time of 2.5 seconds (relay 4). . At the end of the symbol, the procedure is as in 1, then the tube Rö8 goes back to its starting position as the last step. The resulting positive impulse arrives via the capacitor C 13 to the second system of the tube egg 7, which acts as quenching stage 5, and is amplified since the tube egg 6 is already in the rest position again.

It then switches the tubes Rö9 and RölO back to their starting position as a negative impulse.

5. Fault IV:

* A pause is shorter than 0.01 second. In the case of breaks that are shorter than 0.01 seconds, the Entrance stage does not return to the starting position. So the following character is added to the first and results in a character that lasts longer than 6 seconds. The process then takes place as with Case 4.

g ₅ 6. Fault case V:

A pause is longer than 1.5 seconds. In the case of breaks that last longer than 1.5 seconds, goes after the cessation of the previous sign the tube egg? ö4 back to the rest position, since their Delay time is 1.5 seconds. Since each

but the input stage is in its rest position, the second system of the tube remains open Rom 5, and the Röhrei? OE6 is not switched. At the beginning of a new character, the tube beats Rö4. um, the resulting positive impulse brings the tubes Rö 9 and i? ÖlO back to their starting position via RÖ7 / 2.

Claims (6)

PATENT CLAIMS: 10 1. Automatic alarm device, especially for an SOS distant signal, which triggers an alarm via an electronic counting stage when three consecutive characters with a character duration of α to b, z. B. 3.5 to 6 seconds and an intervening pause from c to d, z. B. Enter 0.01 to 1.5 seconds duration using electronic, built in the manner of asymmetrical bistable circuits relay with a response delay of d, e - a - d, and f - b ■ - α seconds and a quenching stage that the Counting stage switches back to the initial position for each character that does not meet the above conditions, characterized in that an input stage (1) is provided which only forwards characters to the downstream device whose size is above the response threshold and the electronic relay (2) controlled with the response delay of d seconds and the response of the electronic relay (3) with the delay of s seconds releases, which is then controlled by the electronic relay (2) with the delay of d seconds and at a fall of pulses to the counter stage (6, 7) releases and the electronic relay (4) is energized with a delay of / seconds, which when it drops out just like the electronic relay (4) the extinguishing stage (5) is actuated with a delay of d seconds, and means are provided which ensure that the extinguishing stage (5) only passes the extinguishing pulses to the counting stage {6, 7) when the electronic relay ( 3) is in the rest position with a response delay of e seconds. 2. Alarm device according to claim 1, characterized in that the counting stage (6, 7) from bistable tube circuits. 3. Alarm device according to claim 1 and 2, characterized in that the counting stage (6, 7) is an amplifier tube is connected downstream, via which the alarm is triggered and whose grid with the grids of the first two tubes of the bistable Circuits of the counting stage are connected and only then receives such a voltage that Anode current flows when the two grids of the aforementioned first tubes reach their highest potential to have. 4. Alarm device according to claim 1 to 3, characterized in that the input stage (1) according to Kind of an unbalanced bistable circuit is constructed. 5. Alarm device according to claim 1 to 4, characterized in that the bistable circuit of the electronic relay (3) with a delay of e seconds two electron tubes are connected, one of which when a character arrives through the input stage (1) and the other after the delay time is blocked by the upstream electronic relay ■ (2) with a delay of d seconds, and that the arrangement is made so that the electronic relay (3) is only excited when both systems are blocked. 6. Alarm device according to claim 1 to 5, characterized in that the extinguishing pulses reach the grid of one of the counting stages (6, 7) upstream of the extinguishing stage (5) forming amplifier tube which is sent to the last tube of the electronic relay (3) with the delay of e seconds is coupled in such a way that the position of its working point makes it possible to pass on the pulses only when the electronic relay (3) is in the idle state with a delay of e seconds. 1 sheet of drawings © 6Ό9 856/167 2.57