RU2218603C2 - Method of signal processing in optic smoke detector - Google Patents

Abstract

FIELD: fire alarms. SUBSTANCE: method involves prior sensing of unacceptable suspended dust level in working chamber using of triple- threshold signal regime. EFFECT: increased reliability by false response prevention. 3cl

Description

 The invention relates to an automatic fire alarm, in particular to the inclusion of a fire alarm in the presence of smoke or gases using light emitting and light receiving devices.

 A known method of processing a signal in an optical smoke detector containing a housing with a protective grid, inside of which there is a holder and optically coupled radiation source and photodetector, a logical device, the holder is made in the form of a trihedral isosceles prism with channels entering the side faces of the prism, the channels are fixed source of radiation and a photodetector, the optical surfaces of which are directed to the side faces of the prism, the axis of the channels are located in the same plane. The method includes supplying a signal from a logic device to a radiation source and reading a response signal from a radiation receiver so that if the specified threshold value of the signal is exceeded, the logic device generates a control signal for the actuator (SU 1001131, class G 08 V 17/10, 1983 )

 The disadvantage of this method is the increased sensitivity of the detector to electromagnetic fields.

 A known method of processing a signal in an optical smoke detector containing a radiation source, a radiation receiver separated by a light barrier, an amplifier, a logic device and an actuator, the output of which is connected to the output of the detector, including periodic supply of a pulse signal from the logic device to the radiation source and reading the response the signal from the radiation receiver so that if the specified threshold value of the signal is exceeded, the logical device generates Igna control actuator (SU 649 005, cl. 08 In the G 17/12, 1977).

 The disadvantage of this method is the low reliability of the detector, associated with its sensitivity to electromagnetic fields.

 The closest technical solution to the invention is a signal processing method in an optical smoke detector containing a radiation source, a radiation receiver separated by an opaque barrier, an amplifier, a logic device and an actuator connected to the signal line of the control panel, an integrated and remote optical indicators, including periodic supply of a pulse signal from the logic device to the radiation source and reading the response signal from the reception ika radiation so that in the event of exceeding a response threshold value of the main signal by a logic device formed main actuator control signal and the latter is formed using an output main signal. The actuator changes the internal resistance of the detector, increasing the current in the signal line, which is recorded by the device as an alarm (Opto-electronic smoke smoke detector IGO 12-44 "DIP-44", IVS-Signalspetsavtomatika, operating manual, 1999, p. 5).

 The disadvantage of this method is the lack of dust control of the optical camera detector. Dust entering the chamber leads to light scattering similar to smoke and causes a false alarm, which reduces the reliability of the fire alarm system. In this regard, there is a need for periodic maintenance of the detector to clean the smoke chamber. In addition, to increase the reliability of alarm and control systems, it is required to install an additional detector so that a fire alarm occurs only when two detectors are triggered simultaneously.

 Within the framework of this application, the task of increasing the reliability of the smoke detector by protecting it from false alarms is solved.

 This problem is solved in that in the method of processing a signal in an optical smoke detector containing a radiation source, a radiation receiver separated by a light barrier, an amplifier, a logic device and an actuator connected to the signal line of the control panel, an integrated and remote optical indicators, including periodic supply of a pulse signal from the logic device to the radiation source and reading the response signal from the radiation receiver so that in the case If the response signal exceeds the main threshold value, the main control signal of the actuating device is formed using the logic device, and the last main output signal is generated using the latter; in this method, one or two additional control signals of the actuating device are generated using the logic device when the radiation level of the receiver reaches two additional thresholds: the first additional threshold not exceeding the value of the main threshold, and the second additional th threshold exceeding the value of the main threshold, and using the actuator form additional output signals that differ from the main output signal.

 In this case, the level of the first additional threshold is set equal to 10-50% of the value of the main threshold, and the level of the second additional threshold is set to 200-400% of the value of the main threshold, and the signal and threshold levels are counted from zero.

 In this case, the time-averaged value of the radiation receiver signal is determined, the main and second additional thresholds are counted from this averaged value, the level of the second additional threshold is determined as 200-400% of the value of the main threshold, and the level of the first additional threshold is determined for the specified average value relative to zero at when he reaches 100-300% of the value of the main threshold.

 In this case, using the actuator, additional output signals are generated that differ from the main signal by the magnitude of the current or voltage limitation with constant or pulse switching, and the frequency of the pulse signal.

 The ratio of the values of the additional and main thresholds is determined empirically.

 The essence of the invention lies in the fact that in addition to the main threshold of sensitivity, two additional thresholds are introduced, while the first additional threshold (or threshold of increased sensitivity) is intended for preliminary detection of an unacceptable dust level of the working chamber, which can lead to false alarms of the detector. When the threshold value is less than 10%, the noise immunity of the detector sharply decreases due to an excessive increase in sensitivity, when the threshold value is more than 50%, the reliability decreases due to the difficulty of distinguishing between the main and the first additional threshold, which can also lead to false alarms. In this case, all signals and thresholds are counted from zero.

 The second additional threshold (or threshold of reduced sensitivity) is intended to confirm the fire detection signal issued earlier when the main threshold was reached. The second fire signal complies with the fire safety standards for fire alarm systems designed to control engineering systems, automatic fire extinguishing and smoke removal. When using the prototype method in such cases, it is required to install two similar detectors to compensate for their insufficient reliability, while when using the proposed method, one detector is sufficient, which generates both fire signals. When the value of the second additional threshold is less than 200%, the reliability decreases due to the difficulty of distinguishing between the main and second additional threshold, which can lead to false positives on this threshold. When the value of the second additional threshold is more than 400%, the sensitivity of the detector to smoke is excessively reduced. The experimentally established by the author values of additional thresholds are optimal in relation to the technical problem being solved.

 It is advisable to compensate for the dustiness of the detector chamber by monitoring the time-average value of the radiation receiver signal and determining the main and second additional thresholds relative to this average value. Compensation of the dust content of the detector chamber allows you to further increase the duration of operation without maintenance.

 When the time-averaged value of the signal level of the radiation receiver reaches the first additional threshold equal to 100-300% of the value of the main threshold, an additional control signal for the actuator is generated using a logic device. The threshold value is selected maximum to increase the duration of the detector without maintenance, but is limited from above by the quality of the design and execution of the working chamber, radiation source and receiver.

 The specific form of the signal generated by the actuator is determined by the requirements of the protocol for transmitting information from the detector to the control panel, which can be organized both in a pulse or analog mode, or in combinations thereof. As the signals of the actuator can be used signals of direct or pulse current or voltage.

 The method of signal processing in an optical smoke detector is as follows.

 The detector is connected to a communication line with a control panel. In standby mode, the actuator is disabled, which corresponds to the "Normal" signal, the detector consumes the small current required to power it.

 A source (LED), controlled by a signal from a logic device, in a pulsed mode emits light into the space of the working chamber. Synchronously with the LED, the logic device turns on the photodetector amplifier. The photodetector is separated by a partition from the emitter and in standby mode, in the absence of smoke or dust in the working chamber, the light from the LED does not reach the photodetector, the amplifier does not generate a signal that reaches a predetermined response threshold.

 When the working chamber is dusted, the light from the LED scattered by the dust particles enters the photodetector. The amplifier amplifies the signal received by the photodetector, and when the first additional threshold is exceeded by the current (or averaged) value, the logic device supplies a control signal to the actuator, which generates an output signal other than the "Normal" signal, for example, short pulses in the current or voltage limit mode. This change registers the control panel as a “Dustiness” or “Service” signal.

 When smoke appears in the environment and its concentration gradually increases, optical pulses from the radiation source, reflected from the smoke particles, are fed to a photodetector, the electric signal of which, having passed the amplifier, overcomes the main threshold, which leads to the formation of a control signal for the actuator and a corresponding change in its state , for example, switching on the DC limiting mode. This change is perceived by the control panel as a “Fire-1” or “Caution” signal.

 With the further development of the fire and an increase in smoke concentration in the working chamber, the second additional threshold is exceeded, the logic device generates a control signal for the actuator, which leads to the next change in the state of the actuator, for example, an increase in direct current or the formation of frequent pulses of direct current, and is received by the control panel as the signal "Fire-2" (or "Fire").

 With the real development of the fire, the receipt of the "Fire-1" and "Fire-2" signals does not occur simultaneously, but after a certain period of time, therefore successive overcoming of two thresholds is an additional protection against false alarms. So, for example, the effect of electromagnetic interference can be determined by the appearance of a high level signal - above the third threshold.

 The advantages of the invention are ensured by the fact that it implements a three-threshold alert mode. This allows you to increase its reliability by controlling the dustiness of the working chamber and reduce operating costs - not to carry out preventive cleaning of the chamber, but only by the signal of the control panel. The presence of a second additional threshold in the detector increases the reliability of fire detection by transmitting the signals "Fire-1" and "Fire-2" and allows you to install one detector in the room instead of two.

 Thus, the introduction of additional thresholds in the detector can reduce the likelihood of false alarms, leading to the launch of engineering fire protection systems.

 It is possible to use the detector with only one additional threshold, for example, with the main and first additional threshold or with the main and second additional threshold.

Claims (3)

1. A method of processing a signal in an optical smoke detector with ambient light containing a radiation source, a radiation receiver, a logic device and an actuator connected to the signal line of the control panel, including periodic supply of a pulse signal from the logic device to the radiation source and reading the response the signal from the radiation receiver so that if the response signal exceeds the main threshold of operation using a logical device, basically th control signal of the actuator, and with the help of the latter form the output main signal, characterized in that, in order to protect the detector from false alarms due to preliminary detection of an unacceptable dust level of the working chamber, the first additional actuator control signal is generated using the logic device when the level of the response signal of the radiation receiver of the first additional threshold, less than the main threshold, or the second additional ADDITIONAL actuator control signal when the response signal level of the second additional threshold exceeding the threshold value of the main and via the actuator form additional output signals differing from the main signal output, which are received by the control panel. 2. The method according to claim 1, characterized in that the level of the first additional threshold of operation is set equal to 10-50% of the value of the main threshold of operation, and the level of the second additional threshold of response is 200-400% of the value of the main threshold of operation. 3. The method according to claim 1, characterized in that using the actuator generate additional output signals that differ from the main signal by the magnitude of the current or voltage limitation with constant or pulse switching, the frequency of the pulse signal.