DE1292043B - Signaling system - Google Patents

Description

The invention relates to a signaling system with a large number of detectors arranged in one or more loops, for which the operational readiness is monitored with the aid of a test current flowing between the transmitter and receiver.

Especially with fire alarm and room protection systems are qualified Message lines required, via which messages are only transmitted in rare exceptional cases will. Usually they lie fallow, and by operating themselves they can therefore do not recognize disturbances. Even so, they must be used properly in the event of an alarm and work reliably. So it is to be taken care that each one a message transmission impairing or even dangerous malfunction is recognized and reported immediately. Such line monitoring has hitherto mostly been carried out by means of a constant Direct current that flows in the idle state via the signal line and a certain Has quiescent current strength. In the previous systems, this then meant a weakening of the current or power amplification an alarm message, during power failure »wire break« and on considerably above the signaling current that normally occurs even with current amplification Display lying current value »line short circuit«. The evaluation devices of this quiescent current monitored Lines must therefore have four different amperage criteria clearly from one another can distinguish. However, this requires a relatively good reporting line and a constant voltage source, as every change in the line condition or the supply voltage such as B. a current leakage as a result of line damage or voltage changes due to aging of the voltage sources of one of the four current criteria to be distinguished lead to another and thus the target state, falsify the idle state, for example, into an alarm or other error message can.

There are also known signaling systems in which the lines are star-shaped are laid and in which these lines are monitored by a test facility, which is automatically transferred to the disturbed star line in the event of a fault on one of the star lines is connected. To connect this test device to the one to be checked However, the line is still an additional control device in the known signaling system necessary. The test device is only switched on when a the star lines is disturbed. In many cases this will and can only then be determined when, for example, an alarm message is currently being transmitted target. However, it is precisely this message that cannot be transmitted in good time.

The invention is based on the object of monitoring this known quiescent current Reporting devices to eliminate their own deficiencies and ensure secure transmission and Recognition possibility for the four possible criteria of a reporting device create, especially when amplifiers or others are in the message line Consumers are looped in. This is constantly on their part Operational readiness monitored by means of a test current between the transmitter and receiver Message line achieved in that, according to the invention, with each message loop to be monitored a test device is permanently connected and a switch controlled by a clock control means which change the current amplitude in a rapidly repeating sequence operate in such a way that if the line is not disturbed, depending on the position an alarm button at least two consecutive times in their amplitude different current values and in the event of a faulty line (line break, short circuit) Current values of the same amplitudes flow over the signal line, which in the receiver by means of Switching means for displaying the operating or malfunction status of the message line can be evaluated.

Instead of the previously necessary four different electricity or The signaling device according to the invention now only needs voltage values distinguish between two current values. This makes the for a unique Separation of the current values available safety margin significantly increased and thus the security against malfunctions of the entire reporting device significantly improves, as both for line monitoring and for the messages »Quiet« or »Alarm« Elements of digital circuit technology can be used. In a further embodiment According to the invention, a timer arranged in the transmitter switches a load resistor to the signal line fed by a direct current source. Also is by one If the alarm line is not disturbed, the order of the two consecutive, different current values interchangeable with one another, with synchronization means ensure that the sequence is recognizable. It is still advantageous as soon as several transmitters and receivers connected to one another via the same message line messages assigned to them are timed by means of a time division multiplex method to be transmitted one after the other, especially if to detect interference Transmit encrypted messages from a sending station to a receiving station and in this control a comparison device, which in the event of a faulty The transmission of a message detects the »disturbance« intervention and a »disturbance« alarm transmitter actuated. In addition, a selection device can be provided in the encoder, which a Encoder selects one of several equivalent, encrypted messages, so that interference in such a reporting device without being displayed, are practically excluded.

Further details of the invention emerge from two exemplary embodiments selected from the variety of possible embodiments and represented by their circuit arrangements. It shows F i g. 1 a simple, basic reporting device, the reporting line of which is not protected against interference, FIG. 2 a reporting device with a reporting line also protected against interference, and FIG. 3 with the secured reporting line according to F i g. 2 possible pulse diagrams D 5 to D 14. By inserting a switch 100 (FIG. 1), a synchronous motor 101 is connected to the AC mains voltage and, at the same time, the other switching elements of the signaling device are connected to the battery 102. The synchronous motor 101 in the receiver E1 drives the cam roller 103 shown in its development, which in turn actuates relays 1, 3_, 4_ and _5 with its cams via contacts 104 to 107. The rotation time t of the cam roller is, for example, 60 ursec. If, after a time t1 of, for example, 10 ursec, the switch 104 is closed for a time t2 of, for example, 40 msec and a test voltage is applied to the line L 1, different currents, their temporal progression and their strength from the status of the message line, flow over this line L 1 and depend on the position of an alarm button 108 in the transmitter G1. The different current values are shown in four diagrams D 1 to D 4 .

If the line L 1 is not disturbed, a relay 2 picks up immediately via its winding 2A, since a capacitor 109 initially bridges the winding 2B of the relay 2_, which has the same dimensions but is looped into the line in the opposite direction. If the alarm button 108 is not pressed, the relay 2_ with its contact 21 connects the resistor 110 to the line L 1, and a large current immediately flows, as shown in diagram D 1. After a time t 3 «t2) of, for example, 20 msec, the capacitor 109 is charged, so that the current now flows through the winding 2B, the effects of these two windings 2A and 2B cancel each other out and the contact 21 drops. A considerably smaller current now flows through line L 1, which can also be seen from diagram D 1.

If, on the other hand, the alarm button 108 is pressed, a very small current initially flows (diagram D 2), since the relay 2_ responds again immediately via its winding 2A, but its contact 21 does not switch on the resistor 110 because the alarm button 108 is pressed. Only after the capacitor 109 has been charged after the time t3 does a current flow through the winding 2B, as a result of which the contact 21 returns to its rest position and thus switches on the resistor 110 , so that now, as can be seen from the diagram D 2, a high Electricity flows. If there is a short circuit along the line L 1, a constantly high current flows, as shown in diagram D 3, while in the event of a line interruption the current fails, as shown in diagram D 4.

Since the relay 1 responds only to the high current values, the time sequence is stored by the relays 3_ or 4_, depending on whether a current curve according to diagram D 1 or D 2 is present. Via the contacts 105 or 106 actuated by the cam roller 103 and the relay contacts 11 or 12, the relay 3_ responds in the case of a current sequence according to diagram D 1 or the relay 4 in the case of a current sequence according to diagram D 2. Both relays hold themselves via their contacts 31 and 41, respectively. After the roller contact 104 has been switched off after the time t2, the relay 5 finally responds via the roller contact 107. With its contact 51 it interrupts the self-holding circuit of the storage relays 3_ and 4, which, however, drop out with a time delay; In addition, the relay 5 applies voltage to the contacts 32, 42 and 32, 43 of the relays 3_ and 4 with its contact 52. Depending on which of the four current sequences according to the diagrams D 1 to D 4 was switched during the last handling, the contacts 32, 42, 43 have turned over or have not changed their position.

In the case of the current sequence in diagram D 1, the relay _9, which is also drop-delayed for the time (t 1-I- t 2) of 50 msec, for example, responds. Its delay is chosen so that it is tightened for the entire next roller revolution, so that if the line L 1 is intact and there is no alarm transmission via its contact 91, a lamp 111, which means "rest", lights up and thus indicates the operational readiness of the signaling device. If, on the other hand, the alarm button 108 is pressed, a current sequence according to diagram D 2 is transmitted instead, and the relay 4 responds, and thus its contacts 42 and 43 change their position, so that the relay ¢ responds and communicates via its contact 61 also holds itself. The contact 62 causes an alarm clock 112 to respond, and at the same time a lamp 113 lights up, which means "alarm". In the case of a current sequence according to diagram D 3, the contacts 32 and 43 turn over and cause the relay 8_ to respond, which is held by its self-holding contact 81. With its contact 82 it switches on an alarm clock 116 and the lamp 117, whereby "short circuit" is reported. If neither relay 3_ nor relay 4 picks up, so that their contacts 32 and 42 remain idle, relay 7_ is excited, which also maintains itself via its contact 71 and switches on an alarm clock 114 and lamp 115 via contact 72 , which indicates "broken wire" After taking note of one of these four message states, each of the stored messages can be deleted by pressing a rest key 118; At the same time, relays _6, _7, _8 also drop out, since their self-holding circuits are interrupted.

In Fig. 2 shows a block diagram of a reporting device for a reporting line L2 protected against interference by encrypted current sequences, as can be used, for example, for police emergency calls. In addition to the message line L2, this reporting device also consists of a transmitter G2 with an alarm contact 132 and a receiver E2. A clock generator 129 in the generator G2 generates the in FIG. 3 time cycle shown under D 5. With this timing a stepping mechanism 130 is controlled, which in the selected exemplary embodiment has six outputs which successively receive a potential dependent on the selected coding, as shown in FIG. 3 is shown under D 6 to D 11. Each of these pulse diagrams D 6 to D 11 is applied to one of the six outputs of the step switch mechanism 130 . As soon as the stepping mechanism switches on the last output with its sixth step, it acts back on the clock generator 129 in order to shorten this last pulse in favor of the currentless intermediate time (see FIG. 3, D 5, last pulse). This shortened pulse compared to the other pulses results in the synchronization between transmitter G2 and receiver E2.

Each of the outputs of the stepping mechanism 130 acts on a gate in a coder 131. At the output of this coder, a time sequence of currentless and current-carrying steps arises, which is dependent on the position of the alarm contact 132 and the code established by routing in the coder 131. The encoder enables several equivalent codes to be defined, from which a code switch 119 can be used to select. A change from one code to the other can only take place at the end of a cycle, which is why the code switch 119 is connected to the last output of the stepping mechanism 130. One of the signal sequences possible at the output of the encoder 131 is shown in FIG. 3 shown under D 12. In this signal sequence, provided that the alarm contact 132 is closed, the currentless state is assigned to diagram D 6, the current-carrying state to diagram D 7, the currentless state to diagram D 8 again, and so on. The output signal (FIG. 3, D 12) of the encoder 131 resulting in this way is fed to a message converter 120 and there converted into the actual transmission code, which is shown in FIG. 3 is shown under D 13. The “de-energized” state at the input of the signal converter 120 results in the sequence “energized - de-energized” at the output, while the energized state at the output results in the sequence “de-energized - energized” (FIG. 3, D 13).

This output signal of the message converter 120 reaches the message line L 2 to the receiver E2, the input of which is a message receiver 121. His job between a balanced line and an unbalanced receiving circuit - to separate and disturbances on the signal line, namely »wire break« or »short circuit«, to be determined immediately. When a line fault is identified, for example, begins a lamp 128 to flicker while the input signal is not disturbed. that of the diagram D 13 of FIG. 3 corresponds to that shown in FIG. 3 shown under D 12 Diagram is fed back and in this form from the message receiver to a decoder 124 is passed on. In addition, the notification receiver 121 gives the input signal to a clock 122 in order to synchronize it with each transmitted edge. In this way, the clock 122 runs synchronously with the clock 129 of the encoder G2 and, like the latter, generates an output signal. according to diagram D 5 in F i g. 3. This signal D 5 is fed to a synchronization part 125, which is the end of each cycle is determined, which is indicated by the shortened sixth pulse is. The synchronizing mechanism 125 gives a synchronization pulse at the end of each such cycle, as shown in diagram D 14 of FIG. 3, to a stepping mechanism 123 and sets it back to its original position each time. Is controlled however, this stepping mechanism 123 directly from the clock generator 122. The output pulses this stepping mechanism 123 in the receiver E2 correspond to those of the stepping mechanism 130 of encoder G2. They are fed to the decoder 124 while from the message receiver 121 corresponding to diagram D 12 of FIG. 3. further processed received signal is passed to the decoder 124.

In the decoder 124 of the receiver E2. are received by the encoder 131 of the Gebers encrypted criteria "rest" or "alarm" decrypted again this is achieved in that in the decoder 124 the diagram D 12 of the F i G. 3 corresponding input signal with the corresponding routing in Coding of these criteria stored in it is compared. When there is a match with the one saved for the »Alarm« criterion. Coding sounds after expiry of the cycle, for example, an acoustic signal generator 126. On the other hand, if the input signal is correct corresponds to one of the codings stored for the »calm« criterion, see above there is no further display. The decoder 124 does after the completion of a cycle no match with a coding for the criterion »alarm« or »silence« detected, but received an input signal, thereby ensuring that the message line L 2 is undisturbed, for example a lamp 127 lights up. This then indicates that in the reporting device, for example, for the purpose the sabotage, an intrusion was carried out.

When using time division multiplexing. can via the message line L2 several such encrypted codings from different ones in succession Encoders are transmitted to one or more receiving points.

Claims (7)

Claims: 1. Signaling system with a large number of detectors arranged in one or more loops, in which the operational readiness is monitored with the aid of a test current flowing between the transmitter and receiver, indicating that a test device (1, 3_, 1, 5) is firmly connected and switches (104, 105, 106, 107) controlled by a clock generator (103) operate in a rapidly repeating sequence the control means (21, 108) which change the current amplitude in such a way that if the line is not disturbed ( L1), depending on the position of an alarm button (108), at least two chronologically successive current values with different amplitudes and, in the event of a faulty line (line break, short circuit), current values of the same amplitudes flow over the message line, which are set in the receiver (E1) by means of switching means (6_, .7, $, 2) can be evaluated to display the operating or fault status of the message line (L1). 2. Signaling system according to claim 1, characterized in that by an alarm switch (108) when the signal line (L 1) is not disturbed, the sequence of the two successive, different current values can be interchanged, and that the synchronization means (103, 3_, 4) the detectability of Ensure order. 3. Signaling system according to claim 2, characterized characterized in that the alarm switch (108) is designed as a changeover switch, the when using an alternating voltage generator, the polarity of one in the message line looped directional conductor to reverse and when using a DC voltage source (102) the on and off times of the load resistor (110) against each other swap allows. 4. Signaling system according to claim 1, characterized in that that a with a stepping mechanism (130) fed back clock (129) between Transmitter (G2) and receiver (E2) by means of a synchronization pulse of a different duration than that of the normal pulses causes the synchronization. 5. Signaling system according to claim 1 to 4, characterized in that several donors and receivers have the same Message lines are connected to each other and the messages assigned to them by means of a time division multiplex method transmitted one after the other. 6. Reporting system according to Claim 4 or 5, characterized in that for the detection of interference from an encoder station (G2) by means of one from the clock generator (129) via the stepping mechanism (130) controlled encoder (131) and converter (120) encrypted messages are transferable to a receiving point (E2) and in this one from another, with the clock (129) in the encoder (G2) synchronously running clock (122) controlled decoder (124) control the at least a message recognizes the "interference" and activates a signal transmitter (127). 7th Signaling system according to Claim 6, characterized in that there is a code switch in the transmitter (G2) (119) selects different, equivalent, coded messages in the encoder (131).