DE1297008B - Signaling system with detectors connected in parallel in a two-wire loop - Google Patents

Description

Known reporting systems, e.g. B. Fire alarm systems, guard control systems and the like, are now mainly implemented in relay technology. Maintenance and functional control these systems can only be carried out cumbersome and expensive because they must always be carried out at the location of the detector, which may not is accessible at all times. Regular monitoring, e.g. B. always before switching on, but can be important if the detector is only activated at certain times, for example must be switched on at night or on weekends.

Circuit arrangements for guard alarm systems are also known, where via a common transmission line from a triggered detector drive Power surges are transmitted to a central point and there a corresponding Drive associated display device is switched on until the The next triggered detector drive will receive power surges. To a bigger one For example, the number of detectors must be accommodated in a common loop divided into two groups, which are differentiated by the control center in that which one group sends out a long initial impulse after it has been triggered. By this measure, the detectors can send out the same identification, and still another display device is switched on in the control center.

With this circuit arrangement, the detectors do not switch automatically and cannot be switched on centrally from a control center. Switching on from one detector to the next can be influenced from the outside and therefore often inadmissible Way are unnecessarily delayed, which corresponds to an interruption of the pulse delivery. With this signaling system, the sequence of the individual submitted can also be determined Impulse not correctly set.

There is also a circuit arrangement for an alarm system two-wire loop known, in which there are always several alarm transmitters, for example thermal contacts, are grouped together. Detectors are connected upstream of each such group. As soon as by a thermal contact of a group or by a switch in the detector an alarm is triggered, the balance is one in the two-wire loop switched bridge arrangement disturbed. Only by adding a number of resistors by means of a manually adjustable group finder the bridge equilibrium to be restored. The number of resistors switched on corresponds to then the group in which an alarm was triggered.

With this alarm system is only a rather cumbersome one Manual regulation determines the group in which an alarm was triggered or line damage has occurred. The reporter himself who has given the alarm must then be searched within the displayed group, so that with this alarm system the detectors in a group are all individually checked on the spot Need to become.

In the case of new plants, therefore, not only the operational control should be significant can be simplified, but also a reliable function monitoring provided in that the status of each detector can be determined from a control center. Even should it be possible to set up very specific detectors, such as B. Call pillars, of which in one Loop several can be arranged to call individually while doing any initiate a certain process, for example to enable an announcement. Even such a system should be independent of whether the detector has mechanical contacts equipped or whether electronic contacts are used.

According to the invention, this is done in a signaling system with detectors that run in parallel are connected to each other in a two-wire loop, achieved in that signaling circuits, which are assigned to each detector in a loop when the loop voltage is switched on emit current pulses from a central unit to the central unit in such a way that the pulses with not addressed detectors with a short time interval and with addressed detectors are given with a considerably longer time interval to the control center, whereby the addressed Detectors in the control center are marked, and that the signaling circuits are triggered by a change in current the control panel automatically adjusts the loop voltage after a certain time switch to the next signaling circuit in the loop.

So it corresponds to the number of a query cycle in one Central incoming pulses of the number of detectors present in the loop, whereby the pulse train provides information about the current status of the detectors can get in the loop. By changing the current from the control center mark each detector in an alarm state there. There is also a phone call each detector in a loop, for example a call from the m-th detector, thereby to achieve that after switching through the m-l-th detector from the control center the loop current is modulated in a suitable manner. You can also use simple Reversing the polarity of the line to all detectors connected in the loop of a common command. In the event of a line break or a short circuit In the line, the fault can very easily be transferred from the control center to a line section after a specific detector. In the electronic switching units can be used as electronic switching elements, for example, transistors, thyristors, Field effect transistors are used. As a switching unit for individual identification each detector can, for example, be provided with a transistor in its emitter branch there is a resistor with a capacitor connected in parallel via a diode, which sends a pulse to the control center each time the signaling circuit is switched on. A thyristor, for example, is used as a switching unit for automatic switching can be used, the control electrode of which can be switched on via a capacitor and a Zener diode is and in the case of preventing incorrect switching between the control electrode and an RC element is connected to the base of the thyristor. The reporting circuits according to the invention are used to control and monitor both detectors with mechanical contacts, such as fusible link detectors, bimetal detectors, as well as detectors with electronic ones Contacts, for example NTC thermistors, PTC thermistors, transistors, are suitable.

Further details of the invention can be found in the drawings illustrated embodiments. It shows F i g. 1 one basic structure of a security system; F i g. 2 a to 2 c show in one Central incoming pulse diagrams of a security system according to FIG. 1; F. i g. 3 shows a possible embodiment of a signaling circuit and FIG. 4 one Extension of a signaling circuit according to FIG. 3.

When the control center is switched on, voltage is applied to a signaling loop via a switch 1 (Fig. 1), which consists of signaling circuits Me 1, Me 2 ... Me n, the individual detectors M 1, M 2 ... M n are connected upstream, and a line termination La consists. First of all, it is assumed that all detectors are in the rest position, that is, each signaling circuit automatically switches the line through from one to the next signaling circuit up to the line termination La. In the center then roughly sawtooth-shaped pulses arrive (FIG. 2 a), which are shortened by a pulse shaper 3 and, for example, converted into square pulses. These square-wave pulses are then fed to a counter 4. At the same time, each pulse resets the timing element for a marking 5 with the delay time t 2 (FIG. 2 a) and the timing element for a monitoring 8 with the delay time t 3 (FIG. 2 a). The status of the respective detector can be derived from the distance between the incoming pulses; For this reason, the line termination La must also generate a pulse without this pulse corresponding to a connected detector; this is indicated in the drawing by hatching this pulse (FIG. 2 a). As long as the evaluated pulses arrive in short order, ie the time t 1 from one pulse to the next is less than the mentioned time t 2, the timer of the marker 5 is reset with each pulse, and the counter 4 sets a memory 6 and thus at the same time a display 7 accordingly. If all the pulses, including the pulse generated by the line termination La , have been evaluated, the entire loop is switched through and a corresponding loop current flows. Now the mentioned timers are no longer reset because there are no further impulses. After the time t 2 (FIG. 2 a) has elapsed, the marking 5 now responds and, for example, a current attenuation stage 2 briefly lowers the loop current (FIG. 2 a). After a further time t 3 (FIG. 2 a), the entire loop is switched off, and the monitoring stage 8 switches off the entire loop voltage of the loop via switch 1 for a time t 4 (FIG. 2). When the loop voltage is switched on again by means of switch 1, the process described runs again and is repeated accordingly.

In Fig. 2 b have addressed the detectors M 2 and M 5, for example. In this case, the signaling loop is automatically switched through only up to the second signaling circuit Me 2 belonging to the detector M 2. After the time t 2 has elapsed, detector M 2 is now marked in the control center; For example, »M 2 addressed« appears in the display 7 of the control center. At the same time, the loop current is briefly reduced from the control center, as already described, and thus switched from the second signaling circuit to the third. This process is repeated accordingly, as shown in FIG. 2 b can be seen when the impulse coming from the signaling circuit Me 5 arrives. The other switching functions remain compared to those in FIG. 2a described received unchanged.

In Fig. 2c, for example, has only addressed detector M 3, while detectors M 2, M 4 and M 5 are called by the control center, which is caused, for example, by a current weakening during the pulses generated by the signaling circuits of detectors M 2, M 4 and M 5 is indicated.

In Fig. 3 shows a possible embodiment of a signaling circuit. In this exemplary embodiment, a transistor T 1 is provided to connect each signaling circuit Me 1 ... Me n , while a thyristor Ty 1 is used to switch from one detector to the next. Because of the thyristors used in the series branches in this exemplary embodiment, the loop voltage cannot be completely interrupted to count the number of detectors in the control center (Figs. 2a to 2c), otherwise the thyristors that have already been ignited would go out again. In the emitter branch of the transistor T 1 there is a resistor R 5, to which a capacitor C 3 with a parallel resistor R 4 is connected in parallel via a diode D 2. When each signaling circuit is switched on, this capacitor C 3 emits a voltage pulse to the control center Z, which in the exemplary embodiment is indicated schematically by a resistor Rs, a voltage source B and a switch s. The time in which the transistor T 1 is conductive is mainly determined by a signaling contact MK and by the duration of the voltage connection from the control center. In the idle state, all capacitors of each signaling circuit are discharged, namely the capacitor C 3 via the resistor R 4, a capacitor C 2 lying parallel to the detector contact MK via resistors R 1, R 2 and one between the control electrode and the base of the thyristor Ty 1 lying capacitor C 1 through a resistor R 1. The parallel connection of the resistor R 1 and the capacitor C 1 is provided in order to prevent incorrect triggering of the thyristor Ty 1. The time constant (R 1 + R 2) - C 2 is chosen so that it is small compared to the time constant R 4 - C 3. A resistor R 3 is used to divert the residual currents occurring in the base lead from a diode D 1 and the transistor T 1 and ensures that the transistor T 1 can be safely blocked.

If now, by closing the switch s, voltage is applied to the signaling loop, which in the exemplary embodiment consists of signaling circuits Me 1, Me 2 ... Me n, which in turn are connected upstream of detectors that are only indicated by their contacts MK, and the line termination La exists, the transistor T 1 receives base current via a resistor R 6 and the diode D 1 and becomes conductive. The current essentially flows through the transistor T 1, the diode D 2 and the capacitor C 3 to the resistor Rs of the schematically indicated control center Z.

As already mentioned, the capacitor C 3 is at the moment it is switched on discharged, and the full loop voltage is therefore at the resistor Rs in the control center at. The falling flanks of the short pulses in the F i g. 2 a to 2 c of the detectors in the idle position correspond to the voltage decrease on Resistance Rs of the control center, which in turn depends on the extent to which the Capacitor C 3 is charging. The maximum voltage that can be applied to capacitor C 3 is which allows a voltage divider from the respective resistor R 5 of a signaling circuit and the evaluation resistor Rs.

The capacitor C 3 charged by the loop current reaches after a certain time the zener voltage of a zener diode D 3, and only then flows also a current through this Zener diode D 3, the detector contact which is in the rest position MK to thyristor Ty 1. This thyristor Ty 1 then switches the line to the next Signaling circuit through, at the same time the transistor T 1 is blocked. To this Way switches every signaling circuit in which the signaling contact MK is in the rest position is, automatically to the next signaling circuit of the following detector.

When the detector contact MK is open, i.e. in the alarm state the voltage across the capacitor C 3 rises unhindered to the steady-state value on, which, as already mentioned, through the voltage divider from the resistors R 5 and Rs is determined because the voltage across the capacitor C 2 adapts without am Resistance R 1 the ignition voltage of the thyristor Ty 1 is reached. In this case meet at the head office, d. H. here at the resistor Rs, no further impulses. After a certain test time, which is a multiple of the time required for a automatic switching through via the Zener diode is required, weakens the control center briefly the current in the loop, but only so far that the already switched through Thyristors do not go out. This current weakening marks in the control center, which detector responded. The voltage drops during the current weakening at the emitter of the transistor T 1, since the diode D 2 decouples the capacitor C 3. At the same time, the capacitor C 2 is discharged through the resistors R 1 and R 2. When the current weakening ends, the voltage at the emitter of the transistor increases T 1 immediately again, since the capacitor C 3 is decoupled via the diode D 2 and has hardly lost any charge via the resistor R 4. This now becomes the thyristor Ty 1 ignited via the Zener diode D 3 and the capacitor C 2.

In Fig. 4 is an extension of the signaling circuit Me 1 according to FIG. 3, which, in contrast to the exemplary embodiment in FIG. 3 can be called directly from the control center. Both directions of transmission are completely independent of each other. The elements in FIG. 4, which in FIG. 3 used are provided with the same reference numerals. The extension compared to FIG. 3 is highlighted by a dashed line. The capacitor C 3 in series with the diode D 2 is connected to the wire L 2 of the loop via a resistor R 7 and to the base of a transistor T 2 via a further capacitor C 4 and a resistor R 8. A resistor R 9 is connected in parallel with the capacitors C 3 and C 4 and the resistor R 8. The collector of the transistor T 2 is connected to the emitter of the transistor T 1 via the resistor R 5. At the same time, the base of a further transistor T 3 and a resistor R 10 are connected to the collector of the transistor T 2 and connect the base of the transistor T 3 to the wire L 2 of the loop. The emitters of both transistors T 2 and T 3 are connected directly to the wire L 2 of the loop.

In this embodiment of a signaling circuit Me 1 a, in which a call facility is provided, the state of charge of the capacitor C 3 is used. In the event of a current weakening shortly after the voltage is applied to the signaling circuit Me la , that is to say at a point in time at which the capacitor C 3 is still taking charge, the voltage across the resistor R 7 suddenly drops. As a result, the transistor T 2 is temporarily blocked via the capacitor C 4 and the resistor R 8 in series with it, while the transistors T 3 and T 4 are briefly conductive via resistors R 5 and R 11 and are switched on via a resistor R 13 Ignite thyristor Ty 2, between its base and control electrode there is an RC combination of a resistor R 14 and a capacitor C 6. As a result of this measure, the alarm circuit and thus the associated alarm is called, as shown in FIG. 2 c is shown for the signaling circuits of the detectors M 2, M 4 and M 5 . An auxiliary voltage BH can be supplied separately between the wires L 1 and L 2 for each reporting point, or a third wire can be supplied from the control center. If, however, this current weakening is carried out with an open detector contact MK after the time t 2, then the voltage in the previous exemplary embodiment according to FIG. 3 only the line switched through. A current weakening at this point in time is not counted as a call, since the capacitor C 3 is already fully charged at this point in time.

Since the different pulse spacing in the center, in the simplified It is represented by the evaluation resistor Rs, which is used as a measurable pulse Quite possible, apart from yes-no signals to the detectors, there are also continuous intermediate values to be transmitted when the detector contact is, for example, through a variable resistor is replaced so that the time t 1 can be varied. For example, the usage is of PTC thermistors in heat detectors or of field effect transistors as links to the ionization chambers of ionization fire alarms possible.

Calling a very specific detector with the help of a message circuit can be used, for example, in guard control systems to acknowledge a message or through the connection a very specific guard can be used to speak will be prompted. If there are several call stations within a loop thus the possibility of very specific call columns for an announcement from the control center prepare. Since the functional check of the individual signaling circuits and thus the detector is carried out by counting the pulses arriving at the control center the loop current that is measured after the last evaluated pulse for Differentiation of the different types of disturbance information. In case of failure-free operation the loop current after the last evaluated pulse is essentially of the already mentioned line termination La determined. It can so In this security system, the individual detectors with their associated signaling circuits are also further apart, because everyone is identified individually in the headquarters can be.

Claims (5)

Claims: 1. Signaling system with detectors which are connected in parallel in a two-wire loop, characterized in that signaling circuits (Me 1, Me 2 ... Men), which each detector (M 1, M 2 ... Mn) a loop are assigned, when switching on (1, S, Fi g. 1, 3 and 4) the loop voltage from a control center (Z) emit current pulses to the control center (Z) in such a way that the pulses for unresponsive detectors (M 1, M 2 ... Mn) with a short time interval and with addressed detectors (M 1, M 2 .. Mn) with a considerably longer time interval to the control center (Z), whereby the addressed detectors (M 1, M 2 ... Mn) are marked in the control center (Z) and that the signaling circuits (Me 1, Me 2 ... Men) automatically transfer the loop voltage to the next signaling circuit (Me 1, Me 2 ... menu) to advance the loop. 2. Signaling system according to claim 1, characterized in that that in the electronic switching units as switching elements, transistors, z. B. field effect transistors are also used. 3. Signaling system according to claim 1, characterized in that a transistor (T 1) is used as a switching unit for the individual identification of a detector, in the emitter branch of which there is a resistor (R 5) to which a via a diode (D 2) controlled RC- Member (R 4, C 3) is connected in parallel. 4. Signaling system according to claim 1, characterized in that a thyristor (Ty 1) is provided as a switching unit for automatic switching, the control electrode of which is a Zener diode (D 3) and a capacitor (C 2) connected in series. 5. Signaling system according to claim 1 to 4, characterized in that to expand a signaling circuit the capacitor (C 3) and the resistor (R 5) via resistors (R 8, R 9, R 11, R 13) further transistors (T 2 , T 3, T 4) and another thyristor (Ty 2) are connected downstream.