DE3012130C2 - Monitoring system - Google Patents

Description

The invention relates to a monitoring system according to the preamble of claim 1.

In large companies, a hazard alarm system is often used also operated guard control systems. In addition to fire and smoke detectors, the hazard alarm system is generally also equipped with fire alarms, mostly push button alarms, equipped A guard control system is independent of it operated. In many cases, the hazard alarm system is purchased first and then the guard control system When installing a guard control system In addition, new lines must be laid, often parallel to the lines of the hazard alarm system get lost. The guard control switches are then also activated mounted next to the push button alarms

DE-PS 8 92 570 describes a reporting device for issuing various types of messages for different actuators of the drive common to all message types are provided. Included know as different types of messages throw a fire and a guard message, whereby A separate actuating device is provided for actuating the guard control avoidance. The detector has a common drive for both types of messages, which is triggered when the button is pressed, with the A fire alarm is issued, the quiescent current is interrupted in pulses by means of mechanically operated contact springs will. A certain number is mechanically controlled to issue a guard control message the pulses by short circuit suppressed Apart from the fact that such a mechanical alarm device has been replaced by modern electronic detectors, such a reporting device has the disadvantage that only one other message, namely a guard message, is transmitted to a control center for the fire alarm can be.

It is also known to use relays to transmit several commands over a two-wire line. For example, circuits with voltage-current and frequency steps are used. These known measures (the master electrician, Issue 14, 1957, pages 784 to 786, relay and valve cells for power savings) require expensive and complicated circuits with frequency stages, for example Special relay. These measures in a monitoring system however, it is not possible to provide four different commands for four commands, for example Frequencies must be generated and evaluated accordingly.

In a monitoring system described at the beginning, however, in addition to the hazard notification, that is, to an alarm signal that can be generated in the event of an alarm, and a guard message form a further reporting criterion can be.

It is the object of the invention. with a monitoring system of the type described above without major Switching effort to transmit two different guard messages to the control center.

This task is carried out in a hazard alarm system described above solved with the characterizing features of claim 1.

Are there a rest or an alarm signal and a Guard messages can be generated, according to the invention, two different guard messages are created two guard control switches assigned to the hazard detector. With the first guard control switch the quiescent current is interrupted for a short time to issue a first watchdog message. With the second guard control switch is to leave a / permanent alarm signal generated only briefly from the duration of the idle or alarm states pending on the line, the respective existing ones Guard message determined.

With the guard control switches on the one hand a guard control message and on the other hand a Guard alarm message can be sent. For example, the guard can make an emergency call if he is threatened will.

The hazard alarm can advantageously be a frequency alarm. This has an oscillator, a first frequency that is transmitted to the control center as a quiescent signal and a second frequency that generates at z. B. Fire alarm by pressing the alarm switch is generated, with the oscillator on the second frequency is switched. To submit a guard control message, the hazard detector is on The first guard control switch is assigned to which the pending on the message line for a defined period of time first frequency (idle signal) interrupted To issue a guard alarm message, the hazard detector a second guard control switch is assigned that switches the oscillator on to the second for a defined period of time The frequency switches over and an alarm signal is generated for a short time a frequency discriminator is connected upstream and a comparison device is connected downstream, whereby the comparison circuit the idle or alarm signals and the two guard messages by means of logical links can be evaluated and displayed.

In an advantageous embodiment of the invention, the first guard control switch can have a first Be subordinate to the timing element. This Zeitg'ied forms a defined time grid and causes a defined time frame for it Time the opening of an eri'.an switching element arranged in the message line. Likewise the second Guard control switch can be followed by a second timer. This also forms a defined time grid. The second timing element is followed by a second switching element, which controls the oscillator from the first Frequency switches to the second frequency for this defined time in order to briefly, d. H. the defined time long to turn on the alarm signal. The two time grids can be of the same size.

In a further development of the invention, the hazard alarm can only have one guard control switch, which acts either on the first or second timing element by pressing the button for different times and thus generates the two different watchdog messages

In order to be clearly defined from the different lengths of actuation of the guard control switch, from each other To obtain distinguishable signal states, the guard door control switch can be provided with further switching elements be ordered. A first differentiating element connected downstream of the guard control switch is generated a switch-on pulse and sends this to a monostable downstream of the first differentiating element Flip-flop. A second differentiating element arranged parallel to it generates a switch-off pulse and gives this to a first AND gate, which this signal, with the signal of the unstable output of the monostable Kippgiiedes linked and supplied to the first Zeitgiied.

Furthermore, the output of the second differentiating element is parallel to this with the stable output of the monostable Flip-flop linked via a second AND element, so that its output signal is the downstream second timer can be supplied. Further details can be found in the explanation of the drawings.

Key-operated switches can be provided for the guard control sounder.

Appropriate facilities are provided in the control center for evaluating the various signal states. Appropriately, a frequency discriminator, a downstream time measuring device, can be installed in the control center and a comparison device can be provided downstream of this. The timing device detects the different times for the queuing or absence of the idle or alarm signal. By means of logical Links are made in the comparison facility

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3 shows a basic circuit diagram of a frequency meter; with two assigned guard control switches.

Fig. 4 is a circuit diagram of a frequency detector with ei a guard control switch,

F i g. 5 a block diagram of an evaluation device: in the main office,

6 shows a circuit diagram of an evaluation and display device in FIG. 2!

F i g. 7 different time grids.

1 shows a control center Z with several Mcldelines ML 1 to MLn . At each reporting line Ml. 1 to MLn, which e.g. B. can be a two-wire line, isi each connected a detector M 1 to Mn . This can be, for example, direct current, frequency or pulse avoidance. Several detectors can also be connected in parallel to one detection line, provided that each detector can be identified individually by the control center, e.g. B. chain-synchronized pulse detectors. The execution runocK <»icrwi>! cinrf PVf »nii #> nvmplHpr 7ΐισπιηΗρ Οΐ * \ (* α1

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Time grid the different, d. H. the originals and derived the additional signal states. These can then either be further processed or via a downstream display device are displayed.

In order to form a defined time pattern, several monoflops can advantageously be used in the control center. z. B. three, with different delay times and several differential elements to generate more defined Sound pulses and a logic link, e.g. B. a NOR element may be provided. Will be in the Monitoring system, for example, frequency detectors are used, the monoflops are over a first Line connected to the first output of the frequency discriminator. At the first and second exit of the frequency discriminator is a third and a fourth differentiator, each of which is the trailing edge differentiate the respective signals, and a NOR gate connected to its two inputs. This one is followed by a fifth differentiator.

The outputs of the first and second monoflop and the output of the fifth differentiating element of a coincidence circuit connected downstream of the NOR element are fed. This can be followed by a display device for guard control messages be. The monoflops can have different delay times.

To evaluate a guard alarm message, a 6th AND element can be provided in the control center first input is connected to the output of the 4th AND element and its second input is connected to the output of the 4th differential is connected. About one of the 6 ·. AND element downstream display device a guard alarm can be displayed.

To evaluate a hazard alarm, e.g. B. fire alarm, A 7th AND element can be provided with a downstream display device. To evaluate further Interference signals that may be caused, for example, by manipulation that are outside the formed A 9th AND element with a downstream display device can occur in the control center be intended for sabotage. Further details can be found in the drawing.

Exemplary embodiments of the invention are described in more detail with the aid of the drawing. It shows

1 shows a basic structure of a monitoring system,

2 shows a basic circuit diagram of a frequency detector with an encoder,

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In Fig. 2 shows a frequency detector M 1 with an oscillator OSZ 1, which can generate four different frequencies F1 to F 4 and transmit them to the center Z via the message line ML. A coding device COD is assigned to the oscillator OSZ 1 Lsi and connects to one of the four taps of the coil SP 1 of the oscillator OSZ 1 via lines. The coding device COD is a hazard alarm switch GMS, z. B a push button switch for triggering a fire alarm, and a guard control switch WKS assigned. By pressing the guard control switch IVKS for different lengths of time with the time T1 or T2wirc by means of the coding device COD and the oscillator; OSZl generates a first and a second guard message Fl and F 4. These two guards messages Fl and FA are evaluated in the central office with a corresponding decoder and displayed as a criterion for guard control message or as a guard alarm message. The frequency F \ represents the rest frequency. The frequency Fl is generated when the hazard alarm switch GMS is operated: in the control center this is a hazard alarm, e.g. B. Fire alarm, evaluated and displayed.

3 shows a frequency detector M 2 with an oscillator OSZ2, which in the normal state generates the frequency Fl as a rest signal. A hazard alarm switch GMS, e.g. B. a push button switch for fire alarm switches the oscillator OSZ2 from the resting frequency Fl to the frequency F2 for danger alarm (alarm signal) when pressed.

A first guard control switch WKS 1, the contacts of which are closed in the non-actuated state, is arranged in the hazard alarm M 2 in the alarm line ML. When actuated, the contacts are opened and the rest frequency Fl is interrupted. This is a first guard message z. B. for a guard control message generated. If the guard control switch WKS 1 is opened for a short, defined period of time (TWK), a timing device (not shown here) in the control center will recognize this defined interruption of the rest frequency F 1 and evaluate it as a first guard message. This is displayed in a display device provided for this purpose. further, the hazard detector M 2 is a Gefahrcnmeldeschalter GMS on, causing this danger signaling switch when actuated einrasteL the switching of the oscillator OSZ2 from the rest frequency Fl to frequency FZ the danger alarm message z. B. fire alarm signaled This signal is available in the general

until the alarm switch triggering the fire alarm is reset by hand. An evaluation device (not shown here) in the control center recognizes the then continuously pending signal as an alarm signal with the frequency F2 as a fire alarm. A second guard control switch WKS2 is connected in parallel to the hazard alarm switch GMS. If this is actuated by the guard for a short, defined period of time (TWa / ! Ang, a time measuring device located in the control center recognizes a guard alarm signal. The alarm signal with the frequency F7, e.g. fire alarm, is therefore not permanent, but only one short defined time TWA long in. This time is measured in the central and derived from a signal which is supplied as a second guard message, namely switch alarm, display means for eincr guard alarm.

In Fig. 4 the circuit diagram of a frequency detector M is shown. An oscillator OSZ. which is made up of an inductance Sp, a capacitor C and an amplifier V , generates a certain frequency Fl _1, the quiescent frequency. This is given as a rest signal to the control center Z via the message line ML. In the message line ML there is a first switching element Sl, which is normally closed. The inductance Sp of the oscillator OSZ has a tap on a winding. With the hazard alarm switch GMS, whose first switching contact SK 1 is applied once to ground and the other time to the tap of the inductance Sp of the oscillator OSZ , the frequency Fl of the oscillator OSZ is changed to a second frequency F2 by pressing. The hazard alarm switch GMS is generally a push button switch which is designed so that it remains locked after actuation and can only be reset manually. It is used to trigger an emergency call or a fire alarm message, for example. The second generated frequency F2 is therefore the alarm criterion that is recognized by the central ZaIs hazard message. The hazard alarm switch GMS has a second switching contact SK 2, which is mechanically coupled to the first switching contact SK 1. One connection of the switch contact SK 2 is connected to ground, the other to a voltage, not described further, which is passed through a resistor R 1 and is passed to the first inputs of two AND gates GX and G2 . The guard contact switch WKS is used to send a guard control message as well as a guard alarm message. For example, it can be designed such that it can be closed. One connection of the guard control switch WKS is connected to ground, the other to a line 1 which is supplied with voltage via a resistor R 2. This line 1 leads to two differentiating elements D 1 and D 2. The output of the differentiating element D 1 goes to the input of a monostatic flip-flop MK, whose unstable output Q leads to the second input of the first AND gate, and whose stable output Q leads to the second AND element. The output of the second differentiating element D 2 is fed to the third inputs of the two ω AND elements Gi and G2 . The output of the AND element G 1 leads to a first timing element ZG i, which has a defined delay time TWK . The output of this timing element ZG 1 acts on the switching element S 1. The output of the AND element G 2 leads to a second timing element ZG 2, the delay time TWA of which also forms a defined time grid. The output of the second timing element ZG 2 acts on a switching element S 2. This switching element 52 is connected in parallel to the hazard alarm switch GMS.

The circuit of the detector M works in the following way. A hazard message, for example a fire alarm message, is triggered via the hazard alarm switch GMS with the contact SK 1 and thus the mechanically coupled switch contact SK 2 is also switched over. This is the frequency Fl, the rest frequency of the oscillator OSZ. switched to frequency F2, which is evaluated in the control center Z as a hazard alarm. The switch contact SK 2, which is switched over at the same time as SK 1, electrically blocks the two AND gates G 1 and G 2, so that actuation of the guard control switch WKS remains ineffective.

The guard control message is triggered via the guard control switch WKS in such a way that a brief closing, for example for the time 71 = 1 see. of the guard control switch WKS causes a guard control message, while closing the guard control switch WKS for a longer period of time, for example Γ2 = 4 seconds, causes a guard alarm. When the guard control switch IVTCS is closed, the switch-on pulse is generated via the differentiating element D 1, which switches the monostable multivibrator MK to the unstable state for a defined time Tin. The time 7 is less than 72, for example the four seconds just mentioned. For this time, a potential is present at the unstable output Q of the monostable flip-flop element, which potential is fed to the AND element G 1. So it's 71 <7 <72. If the guard control switch WKS is opened again before the delay time 7 of the monostable trigger element MK has elapsed, a second pulse is generated by means of the differentiating element D 2 , which reaches both AND elements Gl and G2. In the case of the AND element G 1, this pulse comes into effect, since there is also a potential from the output Q of the monostable multivibrator MK and via the resistor R 1. All three inputs of the 1st AND gate have a potential so that the timing element ZG 1 is started and acts on the switching element S 1 via its output for a defined time TWK and thus interrupts the idle frequency Fl for this defined time TWK. As will be described in more detail below, this is recognized by the control center Z as a guard control message. However, if the guard control switch is not opened until after time 72, after which the monostable multivibrator MK no longer has any potential at output Q , then the AND element G 1 cannot come into action. There is now a potential at the stable output <? 'Of the mono-stable multivibrator MK and thus at the second input of the second AND element G 2. If the pulse from the differentiating element D 2 now arrives at the third input of the second AND element G 2, then there is a potential at the output of this AND element G2 a potential that starts a second timing element ZG 2. This second timing element ZG 2 acts for a defined time TWA on the switching element S 2. This means that the oscillator OSZ switches to the frequency F2 that is precisely defined TWA is pending in the control center Z for a long time and is evaluated as a guard alarm. Advantageously, the delay times of the timing elements ZG1 and ZG 2 are chosen to be the same, that is to say TWTi = TWA = TW, that is to say the time raster for the signaling for guard control and guard alarm are the same.

5 shows a block diagram of an evaluation device in the control center Z. The switching states generated by the detector M are transmitted via the

line ML to the control center Z. A frequency discriminator FDI differentiates between the rest signal Fl and the alarm signal Fl, which can be generated by the danger detector M. If, for example, Fi is the quiescent frequency, this signal is sent from the frequency discriminator FDI to the time measuring device ZME via the line L 1. In the event of a fire alarm, the alarm signal F2 is active and is sent as Sign? ¹ from the frequency discriminator FDl via the line L 2 to the timing device ZME. In the timing device ZME , the times of waiting or the absence of the two different signal states F 1 and F2 are measured. In a downstream comparison device VGE , the two guard messages, namely guard control message and guard alarm message, are derived therefrom based on logical links and fed to a display device for guard alarm A WA and for guard control message A WK. In the following Fig. 6 this is described in more detail using an exemplary embodiment.

In Fig. 6 shows a circuit diagram for the evaluation and display of the signal states in a control center Z. The line ML coming from the detector M leads to the frequency discriminator FDI to distinguish between the idle frequency Fl and the fire alarm frequency F2. These two signal states reach the actual evaluation circuit as signal voltages U 1 and U 2 via lines L 1 and L 2. The line L 1 leads to a first input of a NOR element G 3, further to the inputs of three monoflops MF1 to 3 and to the input of a third differential element D 3. The line L 2 leads to the second input of the NOR element G 3 , also to the input of a fourth differentiating element D4 and to the input of an AND element G 7. The output of the NOR element G 3 is on the one hand via a fifth differentiating element D5 to an AND element G 5 and on the other hand to a further AND element Gb led.

The output of the second monostable multivibrator MF2 is connected to the first input of an AND element G4, the output of the first monostable multivibrator MX is connected to the second input of the AND element G4 via a first negation element NG 1. The output of this AND element G 4 leads, on the one hand, to one input each of the AND elements G6 and G5 and, on the other hand, via a further negation element NG2 to an AND element G9. The differentiating element D 4 is connected to the second input of the AND element G6. The output of this AND element G6 leads to a display device AWA for guard alarm, the output of the AND element G 5 to a display device A WK for guard control message. The output of the third monoflop MF3 is connected to the input of the AND elements GT, G 8 and negated (NG 3) with G9. The output of the AND element G 8 leads to a display device AST for fault messages, the output of the AND element Gl leads to a display device A GA for a hazard alarm message, e.g. B. fire alarm, and the output of the AND element G9 leads to a display device ASA for sabotage messages.

The operation of the center is as follows. If there is no message, the signaling AiL arrives in the central Zuber and the frequency discriminator FDI arrives at the idle frequency F1. This signal state is present on line L 1 as signal voltage U 1 and does not trigger any function. If the signal status for guard control message comes from detector M , then from detector M the idle frequency Fl for a defined time TWK = TW, we at F i g. 4 described, interrupted. The lack of Fl or Ui starts the monoflops MF1 to MF3. The recurrence of the frequencies Fl or U 1 and F2 or t / 2 triggers a pulse via the NOR element G 3 and by means of the downstream differentiating element D5 which arrives at an input of the AND element G5. The monoflop MF2 gives a potential for the time TW ₊ = TW + Δ TZ to the AND element G 4. Here, Δ TZ is the still permissible tolerance time. The monoflop MF1 gives a potential for the time TW. = TW-Δ TZ from, which is negated via the negation element NG 1, so that a signal is present at the output of the AND element G 4 only during the time TW ± Δ TZ. This signal is passed to the AND gates G6 and G 5. If the pulse from the differentiating device D 5 arrives at the input of the AND element G5 within the time TW ± Δ TZ , then due to the AND link on the downstream display device A WK a guard control is displayed.

If the guard message for guard alarm is issued by the detector M, the frequency F2 is sent from the detector M to the message line ML for a defined time TWA . (Fig. 4). TWA = TWK = TW should be. The frequency Fl or the signal voltage Ui is missing on the line L l during this time, so that a signal is present at the respective inputs of the AND gates G 6 and G 5 for this time. The AND gate G 5 has no effect, since no pulse or signal arrives at its second input. In contrast, the AND element G 6 in this case receives a pulse within the time TW ± Δ TZ via the line L 2 and the fourth differentiating element D 4, so that the display device AWA responds and a guard alarm is displayed.

A hazard alert message, e.g. B. a fire alarm, is recognized in the control center Z that the lack of frequency Fi or Ui of the signal voltage for a defined time TGA> TW + Δ TZ long over the drill

• to Monoflop MF3 causes a blocking signal at the first input of the AND element G 7. The presence of the frequency F2 or the voltage U 2 causes a signal via the line L 2 at the second input of the AND element G 7. The AND gate G 7 triggers the display device AGA after the time TGA , so that a hazard alarm message, z. B. fire alarm is displayed.

A fault is present if both frequencies F1 and F2 are missing for a defined time TGA. A signal is sent to the first input of the AND element G8 via the NOR element G 3. The absence of the frequency F1 is indicated as a signal via the third monoflop MF3 after the time TGA and is given to the second input of the AND element G8. The output of the AND element G8 triggers the display device AST and indicates a fault.

The third differentiating element D 3 differentiates the trailing edge of the voltage U 1 (- frequency Fl), ie when Fl is present again after the absence, and sends a signal to the first input of the AND element G9.

If this signal arrives outside of the above-mentioned, defined time grid (which are still shown in FIG. 7), a sabotage message is output via the coincidence circuit of the AND element G 9 via the display device ASA . The signals that are formed by the monoflops MF i to AiF3 and the logic gates NG 1, G 4 and NG 3, G 3 reach the other inputs of this AND element G9.

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7 shows the time raster formed by three monoflops MFX to MF3 and the logic elements WCI, NC2 and G4. The potential profile is shown at the output of the corresponding components when the signal voltage U 1 is missing. It shows

; i) the time grid for danger alarm, which is formed by the third monoflop MF3 for the time TCA ;

b) the time grid for guard messages (both control and alarm messages) plus a tolerance time that is formed by the second monoflop MF 2 for the time TW + = TW + Δ TZ ;

υ) the time grid for guard message minus a tolerance time, which is formed by the first monoflop MF1 for the time TVV- = TW- Δ TZ ;

d) the time grid for the watchman message, which is formed from the two aforementioned time frames by means of logical links between the elements NC 1 and C 4 for the line TlV)

c) the time asterisk for sabotage detection, which is formed from the time asterisks for danger alarm and guard messages by means of the negation elements NG 2 and NC 3.

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Claims (12)

Patent claims: 1. Monitoring system with hazard alarms connected to a control center via signal lines, whereby an idle signal or an alarm signal can be generated on a message line and evaluated in the control center is, and with a guard control switch assigned to the respective hazard alarm the alarm status can be influenced by this marked, that two guard control switches (WKSX, 2) are provided, that the idle signal (Fl) can be interrupted with the first guard control switch (WKS 1) to issue a first guard message,
that the hazard detector emits the alarm signal (F2) continuously until it is reset,
that the alarm signal (F 2) can be generated briefly with the second guard control switch (WKS 2) to issue a second guard message,
and that in the control center (Z) by means of a time measuring device (ZME ) the first or the second guard message can be derived from the duration of the idle or alarm signals (Fi, F2) pending on the Le \\\ ing (ML) 2. Monitoring system according to claim 1, characterized in that the hazard detector has an oscillator with which a first frequency (Fi) can be generated as a rest signal or a second frequency (F2) as an alarm signal and that the timing device arranged in the control center (Z) is (ZME) preceded by a frequency discriminator (FDI) and a downstream Vergleichseinrichfing (VGE), wherein by the Vcrgleichseinrichtung (VGE) by means of logical operations, the Ruhebzw. Alarm signals and the two guard messages can be evaluated and displayed via downstream display devices (A WK, A WA ... 3. Monitoring system according to claim 1 or 2, characterized in that the first guard control switch (WKS 1) is followed by a first timing element (ZG 1) for forming a defined first time pattern (TWK) , with which a first arranged in the reporting line (ML) Switching element (Sl) can be actuated, which interrupts the reporting line (ML) , and that the second guard control switch (WKS2) is followed by a second timing element (ZG 2) for forming a defined second time pattern (TWA) , with which a second switching element (52) can be actuated that turns on the alarm signal (F2). 4. Monitoring system according to claim 3, characterized in that the function of the two guard control switch is formed by a single guard control switch (WKS) and an evaluation device (Di, D2, MK, Gi, G 2) connected to this , which have different lengths of actuation for the evaluates both watchdog messages and acts on the first timing element (ZG i) or the second timing element (ZG 2). 5. Monitoring system according to claim 4, characterized in that the guard control switch (WKS) is followed by a first differentiating element (D 1) generating a switch-on pulse with a downstream monostable flip-flop element (MK) and a second differentiating element (D 2) generating a switch-off pulse, that the output of the second differentiator (D 2) is linked via a first AND element (G i) to the unstable output (Q) of the monostable multivibrator (MK) and the first timing element (ZG 1) is fed, and that the output of the second differentiating element (D 2) linked in parallel via a second AND element (G 2) with the stable output (Q ') of the monostable flip- flop element (MK) and fed to the second timing element (ZG 2) 6. Monitoring system according to one of the preceding claims, characterized in that the guard control switch or switches are key-operated switches. 7. Monitoring system according to one of claims 2 to 6, characterized in that the time measuring device (ZME) has several, preferably three, monoflops (MFi and MF3) connected via a first line (L 1) to the first output of the frequency discriminator (FDI) different delay times (TW-, TW ₊ , TGA) to create a defined time pattern, a third differentiator (D 3) connected to the first line (L 1) and a second line (L 2) to the second output of the frequency discriminator ( FDl) has connected fourth differentiating element (D 4), and also has a NOR element (G 3), each of which has an input connected to a respective line (L 1, L 2) and which is followed by a fifth differentiating element (DS) is. 8. Monitoring system according to claim 7, characterized in that the output of the first monoflop (MFi) is inverted (NG 1) and together with the outputs of the second monoflop (MF 2) and the fifth differentiator (DS) via a coincidence circuit (G 4, G 5) a guard control display device (A WTQ is supplied. 9. Monitoring system according to claim 7, characterized in that the output of the first monoflop (MFi) is inverted (NG i) and together with the outputs of the second · * monoflop (MF2) and the fourth differentiator (D 4) via a coincidence circuit (G 4, GS) is fed to a guard alarm display device (A HM). 10. Monitoring system according to claim 7, characterized in that the output of the third monoflop (MF3) and the second output of the frequency discriminator (FDI) with the second line (L 2) via a coincidence circuit (G 7) of a hazard alarm display device (AGA) is fed. 11. Monitoring system according to claim 7, characterized in that the output of the third monoflop (MFZ) and the output of the NOR element (G 3) via a coincidence circuit (G 8) of a fault display device (/ 4S7? 7u is led. 12. Monitoring system according to claim 7, characterized in that the output of the first monoflop (MFi) inverted (NG 1) and the output of the second monoflop (MF? ) Inverted via a coincidence circuit (G 4) (NG 2) together with the outputs the third monoflop (MF3) inverted (NG 3) and the third differentiating element (D 3) is fed to a sabotage display device (4S / 4 ^) via a further coincidence circuit (G 9).