DE2939462C2 - Process and device for the identification of individual detectors in intrusion or fire alarm systems - Google Patents

Description

The invention relates to a method for identifying individual detectors in a burglary or Fire alarm system according to the features of the preamble of claim I and a device for Implementation of the procedure.

An alarm should be set in burglar or fire alarm systems can not only be recognized in a monitoring area, but also the response of the individual detectors. If this is known in the control center, the fire fighting operations can be directed in a targeted manner in the event of a fire. In the case of an intrusion alarm system is the location of the break-in from the control center or the route the intruder has taken as soon as have addressed several detectors, clearly identifiable and therefore a targeted approach possible.

In conventional signaling systems, only the individual lines are generally identified. There are Hazard alarm systems are also known that allow individual detectors to be identified. This requires a considerable technical effort and specially designed reports

From DE-AS 25 33 382 a method for the transmission of measured values in a fire alarm system is known in which the individual detectors are identified can be. For this procedure you need special detectors with many electronic ones Components are provided, have to be queried continuously and within a detector line via timing elements have to be switched on one after the other. From the number of previous increases in the Line current, the respective reporting address is determined in the control center. In the older registration DE-OS 28 22 240 describes a fire or burglar alarm system that is monitored for closed-circuit current. There will In the event of an alarm, a voltage that deviates from the idle spinning is applied to the detector line in order to control an optical display in the detector that triggered the alarm. One Identification and display in the control center of the alarm-triggering detector of several detectors one Line is not provided there.

DE-OS 25 00 759 describes a fire protection system with a control center and fire alarms, each have two diodes switched in opposite directions parallel to the detector line. There is no identification of the individual detectors provided. Rather, a voltage change in the line should be the one that triggers the alarm Detector control an auxiliary device assigned to it.

From DE-AS 21 18 304 is a fire alarm system with a control center and a plurality of detectors connected to it in parallel via a line known. There is a controlled semiconductor diode for each detector and one in series in opposite directions Switched Zener diode is provided, the Zener voltage of which is the characteristic value for the detector in question and in the control center with one for it provided display device indicates the response of the relevant detector. With such a The alarm-triggering detector can be identified in the control center. The disadvantage here is that the Detectors have a complex structure and each detector on a line has a Zener diode with one each has another Zener voltage. A structure with

Components of the same size, · values oriorrfsrt to each To be able to identify detectors in the control center, at least one additional semiconductor component in each detector and a third conductor for a message line.

The object of the invention is therefore to provide a method for identifying individual detectors in such an intrusion or fire alarm system with which the alarm-related detector can be reliably recognized and displayed in the case of detectors of simple and equivalent construction. Here are existing detectors - ^v r.-r existing alarm system to be mounted with only a few additional components for a detector identification in a simple manner.

This object is achieved according to the invention with the features of the characterizing part of claim 1 solved If a detector responds, it interrupts the closed-circuit monitored line. This gives the line another resistance value This is recognized in the control center and the line is connected to one of the Line voltage at rest deviating line voltage is queried for its resistance value due to one characteristic of the detector that triggered the alarm Resistance value, the addressed detector is identified.

A comparison device is expediently provided in the control center for querying the resistance, the resistance value of the line with stored resistance setpoints that are characteristic for each alarm-issuing detector. »Compares one after the other. Is the alarming detector recognized, this is indicated with a designated Display device displayed All signal lines are queried cyclically.

In a further development of the invention, there are additionally 3> sabotage lines in addition to the alarm lines, which are interrupted in the event of sabotage. As a result, a cyclical resistance query of the sabotage lines with a voltage that differs from the open-circuit voltage, z. B. umpoled resting tension, carried · "> leads. As with de ^r query the alarm lines in the inquiry of sabotage lines of the line resistance value with stored resistance reference values compared, characteristic of the respective triggering sabotage detector or switch and the *> Sabotageort are .

If there is a deviation from the line resistance value at rest on an alarm line or a sabotage line and if neither an alarm message nor a sabotage message can be detected when ^queried , a fault is displayed

A plant-like device for carrying out the method has clock-controlled switch groups in the control center. which switch the line to be queried to a comparison device and this in turn to the resistance setpoints for the respective detector or for the respective sabotage message. The time-controlled resistance value interrogation and the cyclical interrogation of the lines are advantageously carried out by a microcomputer. The Alarmme'der and ^hn tamper detector can inventively constructed similarly! A. A low-ohmic series resistor and a trip contact are arranged in the line, and a high-ohmic resistor with a semiconductor diode connected in series is arranged parallel to the line. ^h > The mode of action is as follows. If the actual value of the quiescent current of the line deviates from the setpoint. a higher voltage is first applied to an alarm line and a microcomputer compares the resistance value of the line with the stored resistance setpoints, which is characteristic of the individual alarm-giving detectors, in a timed manner. If they are the same, there is an alarm message. A display device in the control center signals the response d.- ¹ -. . ^ Kprcvhenden alarm indicator, for example optical. Address several detectors one after the other. For example, in a burglar alarm system in which several zones are secured, the route taken by the intruder can be seen from the sequence of the detectors addressed and their display sequence. If there is no alarm message, the query cycle for sabotage is initiated after the end of the query cycle for alarm. B. because the thickness of a detector's housing was removed without permission and the sabotage contact!

It is advisable to have one in each alarm detector high resistance and in series with a Zener diode connected in parallel to the line, with the Zener voltage of the diode is greater than the open-circuit voltage. Normally, flows through the Zener diode and the Parallel resistance no current. Only in the event of an alarm, i.e. when the higher voltage is applied, flows through the alarm-triggering detector and the detectors in front of it in a line of electricity.

The detector advantageously has a similar structure with regard to the sabotage line. Here is instead of the Zener diode a normal diode in series rr.with a high resistance parallel resistor in parallel in the sabotage line arranged, with the diode in Sperrichiung *. 'jr Rest voltage is provided. Becomes the sabotage contact opened, the open-circuit voltage is reversed in the control center and through the diode and the parallel resistor electricity flows.

Further details of the invention are set out below described in more detail with reference to the drawing of an exemplary embodiment.

Show it

1 shows the block diagram of the basic circuit arrangement in the main office.

2 shows a circuit arrangement for a detector for the alarm line.

F i g. 3 a circuit arrangement for the .Sabotage line.

Di '' in r g. I, the basic circuit arrangement shown in the control center shows an evaluation device for a line /. 1. to which several detectors M 1. M 2 etc. are connected. The switch groups .V1 and V 2 are shown in the basic position, ie the McI of the M 1. M2 etc. were monitored for quiescent current IR. One in the line /. The ammeter M lying on the table measures the current / 1 flowing on the line L 1, feeds it to cmc », comparator K. This comparison: it with the nominal value of the quiescent current IR. If the current / 1 is equal to the setpoint IR. so there is a>"!" signal at the output of the comparator K. ie there is no alarm oclr ··· some other fault. If the comparator K detects an impermissibly large deviation, am disappears

Output of the comparator K is the "actual" signal. The counter ZI is thus switched to the alarm position via an OR element I and the increased voltage U2 is applied to the line L I via the switch group 5 1 via switching contact 5 11. If, for example, the rest voltage U \ = 18 volts, the increased voltage U2 = 20 volts. Line L 1 is now queried by counter Z2 in response to an alarm message. The counter Z2 receives counting pulses 4 from a clock generator (not shown) via an AND element 3, which is enabled by the flip-flop FF via its output Q. The switch group 52 is thus switched on by the counter Z2. The comparator K compares the stored resistance setpoint values or the setpoint currents IA 1, IA 2 etc. with the line resistances or the line current / 1. If one of these values agrees with the actual line resistance, the "actual" signal at the output of the comparator K resets the flip-flop FF via a negation element 2 and the clocking for the counter Z2 is interrupted by means of the AND element 3. The current of a supply voltage UB flowing through 522 of the switch group 52 brings the light-emitting diode DA assigned to the corresponding detector M to the display. For example, if the 3rd detector M 3 has triggered an alarm, the corresponding diode DA 3 lights up.

If there is no May message, ie if the actual line current / 1 does not match a possible alarm current IA, after the line query for an alarm from counter Z2 via OR element 1, a signal is sent to counter Z \ , which advances by one step . The voltage Ui = - U \ is now applied to line L 1 via 511. The counter Z2 continues to run and initiates the request for sabotage. Here, the actual line current / 1 is again compared with the possible setpoint currents / 51, / 52 etc. for sabotage by means of the comparator K. The process corresponds to that of the alarm query.

These query cycles are repeated for the other lines. There is neither an alarm nor a sabotage message. so the counter Z2 runs to its end position. The flip-flop FF is reset via 523 of the switch group 52 and logic gates 5 and 6, thus ending the query. The light emitting diode ß57 ~ which is now lit indicates another malfunction.

The in F i g. 2 shown circuit arrangement of a detector for the alarm line has in addition to a series resistor RL, the z. B. 500 ohms, an alarm contact KA in the line. In parallel, there is a resistor RP. the z. B. can be 20 kt2, and a Zener diode D 1 is arranged in series. The Zener voltage UZ is, for example, 19 V. With an idle voltage U I of, for example, 18 V, the Zener diode D 1 is blocked and no current flows through RP. The control center only measures the quiescent current on the line , which depends on the number of detectors and thus on RL, the resistance of the line termination RLA and the line resistance. Only when KA is opened, which is recognized by the ammeter M in the control center, does a current flow through the detector that has responded due to the increased voltage (72. e.g. 20 volts. And through the detector located in front of it.

A similar arrangement is shown in FIG. 3 given. This arrangement is made for the sabotage line. Here, instead of the Zender diode D 1, a simple diode D 2 is provided. It is arranged so that it is blocked on the line when the open circuit voltage U 1 is applied. The polarity of the line voltage is only reversed when it is queried for sabotage, U 3 = - Ui, and diode D 2 becomes conductive. Here then the same thing as with the alarm line.

This arrangement for the alarm and sabotage line enables existing detectors to be easily converted, because in the case of the alarm line only a parallel resistor and a semiconductor component, for example one Zener diode. is required. The same applies to the sabotage line. Instead of the Zener diode, a simple diode used. All detectors can be set up in the same way. So it is with proportion easy to identify the detectors individually. This in turn enables you to pro Line can connect more detectors than was previously the case, because a more precise identification of the appealing area is possible through the individual detector.

For this purpose 2 sheets of drawings

Claims (7)

20 claims: 1. A method for identifying individual detectors of a burglar or fire alarm system from a control center, with at least one two-wire line, several detectors per line, a line voltage applied by the control center, an interrogation device in the control center and with semiconductor diodes contained in the detectors, which are im Normally blocked, characterized in that in the event of an alarm, the responding detector (Mi, MZ ...) interrupts the line (LX) at the location of this detector (KA) and the control center sends a resistance query to the line (LX) with a changed line voltage (U2) is carried out, so that the semiconductor diodes (DX) become conductive and a query result that is characteristic of the alarm-issuing detector is displayed (D _A ) . 2. Vaiahren according to claim 1, characterized in that the for asv. alarming detector (Mi, MZ ...) characteristic query result is determined by comparing (K) the resistance value (H) of the line (L i) with stored resistance setpoints (Ui. Iaj ■■■) that are characteristic for the respective «alarming detector, that several lines are provided, which are queried cyclically and compared with the respective resistance setpoints, and that in the event of an alarm message, the response of the alarm-giving detector a · is shown (Da) . 3. The method according to claim 1 or 2, characterized in that in addition to the alarm lines sabotage lines are provided, which are interrupted ^{in the event of sabotage * 5} (KS) and cyclically queried in the control center with a changed line voltage (U3) , the resistance values of the sabotage lines with the respective resistance setpoints (lsi. Is2 ■ ■ ■) for sabotage messages are compared (K) * ° and a corresponding sabotage message is displayed (Ds) . 4. The method according to any one of claims I bi * 3, characterized in that first the alarm lines with a higher voltage (Ul) and then the sabotage lines with the negative voltage (U3) compared to the normally applied voltage (Ui) are queried, and that if there is a change in the resistance value of a line and there is no alarm or sabotage message for this line, flow (Dst) is recognized. 5. Device for carrying out the method according to claim 1 or 2, characterized in that the individual detectors (Mi, M2, ...) have a low-resistance series resistor (RL) and an alarm contact (KA) in the line and parallel to it a high-resistance resistor (RF) in series with a Zener diode (Di) , and that the control center has clock-controlled (Zi, Zl) switch groups (S 1.5 2) for querying. 6. Device for carrying out the method according to claim 3, characterized in that a low-resistance series resistor (RL ') and a sabotage contact (KS) in the sabotage line and, in parallel, a high-resistance resistor (RP) in series with a semiconductor diode ( D 2) is arranged. 7. Device according to claim 5 or 6, characterized characterized in that the individual detectors are constructed in the same way.