EP0121048A1 - Circuit arrangement for the interference level control of detectors, arranged in a danger detection device - Google Patents

Abstract

The interference level monitoring of detectors arranged in a hazard detection system is carried out by circuits (5,9) which generate at least one interference alarm threshold (2,2 '), which interference alarm threshold is at a certain distance from the operating point (1) of the signal from the detector (4) of the detector and the shifts in the working point are taken into account. If the fault alarm threshold (2,2 ') is exceeded, the alarm memory (10) arranged in the detector is set without alarm. The interference level monitoring takes place during normal operating time and informs early enough whether there is a tendency towards false alarms in the detector.

Description

The invention relates to a circuit arrangement for monitoring the interference level of detectors which are arranged in a hazard detection system, each detector containing an alarm memory which is set in the event of an alarm and circuits which generate an alarm threshold and compare the signal from the detector detector with the alarm threshold .

Hazard detection systems are designed to report hazards such as break-ins, theft, fire, smoke, gases, etc. Special types of detectors have been developed for each of these dangers. So there are intrusion, fire, smoke, heat, gas detectors. These detectors can be installed in the alarm systems, and different types of detectors can be combined in one system. Such alarm systems must always be ready for operation. Therefore, they are checked for their functionality at certain intervals. This check applies to the entire system including the control center as well as to each individual detector. The functionality check also includes the display of the current status of each detector. If, for example, a detector has been brought into the alarm state, it must pass through the Be service personnel are reset so that they can function properly again.

In the case of a known detector, information about its alarm status is given by a so-called alarm memory, which is set when the alarm is triggered. This causes a lamp on the detector to light up. The operator, who has to check all the detectors of a hazard detection system after the alarm has been triggered, will recognize the detector that triggered the alarm and bring the detector back into its normal, functional idle state. Such a functional idle state is greatly impaired by external influences, some of which are not in the control area of the operator or the system. Such external influences are, for example, air turbulence, air pollution, temperature fluctuations and radiation influences. The unfavorable influences also stem from causes that lie within the individual detector or the hazard alarm system, such as signs of aging and thus defects in the electronic components.

The object of the invention is to recognize at an early stage the susceptibility to faults which result from both external and internal causes. The test mode can be controlled on the detector itself or from the control center. In particular, this interference level monitoring is also possible during the active operating time of the relevant detector. In addition, the shift in the working point of the signal from the detector due to aging processes and sample scatter is constantly taken into account, so that a constant sensitivity to the alarm and fault alarm is always guaranteed.

The object is achieved by the features listed in claim 1.

• Fig. 1und 2 in grafischer Darstellung die Anordnung der Störalarm- und Alarmschwellen zum Arbeitspunkt des Signales, das der Detektor des Melders erzeugt;
• Fig. 3 eine elektronische Blockschaltung, in die die Erfindung eingebaut ist.

An embodiment of the invention is based on the Drawing explained in more detail. Show it:

• 1 and 2 in a graphical representation the arrangement of the fault alarm and alarm thresholds for the operating point of the signal generated by the detector of the detector;
• Fig. 3 is an electronic block circuit in which the invention is incorporated.

The time t is plotted on the abscissa in FIG. The ordinate shows the voltage U. The operating point of the output signal, which the detector 4 of the detector generates due to environmental conditions such as fire, fire, radiation, etc., is shown in FIG. 1 as a straight line 1. The output signal of the detector (FIG. 3) shows normal noise in the time interval t1. In the time interval t2, the output signal of the detector shows an increased interference noise, which is caused by internal or external interference sources. If the threshold value 2 is exceeded, a fault alarm is triggered according to the invention. This is discussed in more detail in connection with FIG. 3. In FIG. 1, the interference threshold 2 is only drawn on one side of the working point 1. This interference threshold can easily be double-sided. An alarm is shown in the time interval t3. If the output signal exceeds the upper alarm threshold 3 and / or falls below the lower alarm threshold 3 ', an alarm is triggered using the circuit of FIG. 3.

2 shows the relationships of the output signal with a changing operating point. This change in the working point can be caused by the aging processes of the electronic components, by the scattering of the relevant ones electronic components or caused by temperature changes. The change in the working point is uncontrolled. You cannot predict the amount and direction of this change in operating point. Both the time t and the scatter of the specimens N are plotted on the abscissa of FIG. 2. The ordinate shows the voltage U. It is assumed that the operating point of the output signal of the detector of the detector (FIG. 3) changes in the form of a slightly rising curve. The output signal, which is shown in this figure as normal noise, moves around this operating point. The disturbance alarm threshold 2 maintains the same distance from the curve 1 of the operating point of the output signal. It can also be designed as a double-sided threshold 2,2 ', as shown in dashed lines. The alarm thresholds 3 and 3 'take into account curve 1 of the changing working point in the same way, ie the same distance.

The mode of operation of the invention is discussed below with reference to the exemplary embodiment in FIG. 3. The detector 4 generates an output signal which corresponds to the environmental conditions. Under normal environmental conditions, the detector generates an output signal which is referred to in FIG. 1 (time t1) or in FIG. 2 as normal noise. In this case there is no evaluation in the circuit of FIG. 3. The threshold value generator 5 generates the thresholds 2,2 ', 3,3' (FIG. 1, 2). Filters 7 and 18 filter the detector signal (Fig. 3)

It is now assumed that a fault has occurred, which can have either internal or external causes. The output signal of the detector now has higher amplitudes, as is shown in the period t2 in FIG. 1. These higher amplitudes pass through amplifier 6, line 8 into comparator 9, which compares them with thresholds 2, 2 '. If the output signal exceeds or falls below one of these thresholds, the comparator 9 generates a signal on the line 91, which reaches the logic circuit 92. This sets appropriate inputs when entering status signals Z1 the alarm memory 10 via the OR circuit 95. The alarm memory is set without alarm. The status signals, which are either programmed on the detector itself or transmitted from the control panel to the detector, indicate the status of the detector or the system, such as "switched on" or "test mode". The alarm memory 10 outputs an output signal to the logic 11 which, in the presence of corresponding status signals Z2 (for example "switched on" or "test mode"), switches on a display 12 which is arranged on the detector. This display can be visual or acoustic. The _F ig. 3 shows an LED display. The alarm memory 10 outputs the same signal to the logic 13, which gives a corresponding signal to the control center or to other detectors via the output 131. This indicates that the detector is malfunctioning on itself and in the control center.

It is now assumed that the output signal of the detector 4 exceeds or falls below the alarm thresholds 3, 3 '. This means an alarm. The detector signal passes through amplifiers 6, line 8 compared to the comparator 9 and is larmschwellen with the _A. The comparator 9 outputs on lines 94 an alarm signal to the logic circuits 11, 14 and 93. With a suitable input of the state signals Z2 _L can ogikschaltung 11 enable the display 12th The logic circuit 14 controls the input of suitable status signals Z3 ("switched on" or "test mode") the alarm relay 15, the contacts of which generate an alarm in the control center. The logic circuit 93 sets the alarm memory 10 via the OR circuit 95 when suitable state signals Z4 (for example “switched on” or “test mode”) are input other detectors there. This shows other detectors and also the control panel that a detector is in the alarm state. The control center now initiates the appropriate countermeasures to combat the alarm condition. Those other notifiers who have this Received signal are prevented via line 132 that its alarm memory 10 can be set by a normal alarm. This measure gives the detector that first triggered the alarm priority over the other detectors. At this point it should be pointed out that the other detectors can have the same electronic circuit as shown in FIG. 3.

The upper part of FIG. 3 shows the constant power supply of the detector with the monitoring circuit 17. The monitoring circuit 17 responds when the tolerance range of the supply voltage 16 falls below or is exceeded by any external circumstances. It gives a control signal to logic 14, which controls the alarm relay 15. The contacts of the alarm relay 15 give the alarm the alarm that the detector is faulty due to poor power supply.

Claims (9)

1. Circuit arrangement for the interference level monitoring of detectors which are arranged in a hazard detection system, each detector containing an alarm memory which is set in the event of an alarm and circuits which generate an alarm threshold and compare the signal from the detector detector with the alarm threshold, characterized in that the current wave (5,9) generate at least one fault alarm threshold (2,2 ') with respect to the working point (1) of the signal from the detector (4) taking into account the working point shift and if the fault alarm threshold is exceeded by the signal of the detector (4) the alarm memory (10) set without alarm. 2. Circuit arrangement according to claim 1, characterized in that a display device (12) shows the set state of the alarm memory (10) only with a certain switchover (Z2) of the hazard alarm system from one state to the other state. 3. Circuit arrangement according to claim 1, characterized in that the circuits (5,9) are arranged in the detector or in the control center. 4. Circuit arrangement according to claim 2, characterized in that the circuits have a threshold generator (5) for generating alarm thresholds (3,3 ') and reduced alarm thresholds (2,2 ') included. 5. Circuit arrangement according to claims 1 and 4, characterized in that the threshold value generator (5) generates the threshold values (2,2 ', 3,3') in such a way that they follow slow changes in the operating point (1) of the detector signal. 6. Circuit arrangement according to claim 1, characterized in that a logic circuit (92) is provided on the input side of the alarm memory (10), which sets the alarm memory (10) when the reduced alarm threshold (2,2 ') is exceeded by the detector signal, if at least Parts of the alarm system are in test operation. 7. Circuit arrangement according to claim 1, characterized in that a logic circuit (92) is provided on the input side of the alarm memory (10), which sets the alarm memory (10) when the reduced alarm threshold (2,2 ') is exceeded by the detector signal the detector is in test mode. 8. Circuit arrangement according to claim 1, characterized in that each detector contains a bistable relay (15) for alarm from the detector to the control center. 9. Circuit arrangement according to claim 1, characterized in that a circuit (14, 17) is provided for monitoring the power supply (16) of the detector, which brings the bistable relay (15) into the alarm state when the supply voltage falls below a certain value.

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