RU2306614C1 - Smoke-sensitive alarm - Google Patents

Abstract

FIELD: fire-fighting, particularly fire alarms used to determine air absorbance increase from infrared light dissipation intensity.

SUBSTANCE: smoke-sensitive alarm comprises supply voltage reset circuit, two clamps to connect the alarm to signaling means loop, unidirectional conduction member, output signal conditioner, current-limiting element, condenser, indicator, pulse registration circuit, pulse former, clock oscillator, current switch, emitter, chamber with light-absorbing walls, photodiode, amplifier, as well as resistance switch, threshold element and resistor.

EFFECT: increased stability of smoke-sensitive alarm sensitivity due to possibility of simultaneous threshold phase control, duration and amplified photo-emf signal amplitude.

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Description

The invention relates to the field of fire alarm and can be used in fire alarm systems to detect an increase in the optical density of air by the scattering intensity of infrared radiation.

Fire detectors, optical smoke detectors and smoke detectors are known that operate on the principle of periodically emitting infrared radiation pulses and then receiving, amplifying and processing the received signal in different ways, generating a signal about the presence or absence of smoke (see the journal “Communication Security Systems and telecommunications ”, 2000, 33, p.65).

The known smoke detection device (patent of the Russian Federation RU 2221278, G08B 17/10, publ. 2004.01.10) has a clock generator, an emitter connected through an optical camera with light-absorbing walls to a photodetector, a reset circuit, an output signal shaper. In addition, it has a synchronous detection circuit, a comparison and memory circuit, which is made in the form of the first and second binary counters, and the V-input and R-input of the first binary counter of the comparison and memory circuits are connected to the corresponding outputs of the clock generator, the output of the first binary the counter is connected in parallel with the input of the emitter, the V-input of the second binary counter of the comparison and memory circuit, and the first input of the synchronous detection circuit, the second and third inputs of which are connected respectively but with the outputs of the photodetector and reset circuit, and the output with the R-input of the second binary counter of the comparison and storage circuit, the output of the second binary counter of the comparison and storage circuit is connected to the C-inputs of both counters and to the input of the output signal shaper. Moreover, the synchronous detection circuit contains two AND-NOT gates, a diode, an RC circuit, the inputs of the first AND-HE element are connected to the output of the photodetector, and the output is through a diode with an RC circuit, which is connected to the input of the second AND-NOT logical element through a capacitor it is connected to the output of the first binary counter of the comparison and memory circuit, the second input of the second logical element AND NOT connected to the output of the reset circuit, and the output to the R-input of the second binary counter of the comparison and memory circuit.

A disadvantage of the known device is the low stability of sensitivity from device to device during their serial production (see clause 5.3.4. NPB 65-97 optoelectronic fire detectors. General technical requirements. Test methods) due to the significant variation in the parameters of the synchronous detector, executed on logical elements AND NOT. Logic elements are NOT intended for synchronous detection; therefore, manufacturers of these elements do not guarantee the values of the parameters required for synchronous detection. The technological spread of the parameters of the logic elements used in the synchronous detector affects the stability of the sensitivity of the detectors, which can exceed the normalized values established by NPB 65-97.

The closest in technical essence to the invention that is patented is a smoke smoke detector selected as a prototype (Optoelectronic smoke smoke detector IP212-41M; TU 4371-005-12215496-00; Passport 4371-005-12215496-00 PS), which has two terminals for connecting to the fire alarm loop, the first of which is connected to the input of the one-way conduction element, the output of which is connected to the first power output of the output driver and the input of the current-limiting element, the output of which is connected to the electric bus voltage to the first output of the first capacitor, the second output of which is connected to the common bus, the second terminal and the second power output of the output driver, the output of which is connected to the indicator, and the input to the output of the pulse registration circuit and to the first input of the pulse shaper, second the input of which is connected to the output of the clock generator, the detector also has a reset circuit for the supply voltage, and the output of the pulse shaper circuit through the current switch is connected to the emitter, which is optically connected through h camera with light-absorbing walls with a photodiode, the anode and cathode of which are connected to the input of the amplifier. In addition, the output of the amplifier is connected to the first input of the synchronous detector, the output of which is connected to the first input of the pulse registration circuit, the second input of which is connected to the second input of the synchronous detector and the output of the pulse shaper. The third input of the synchronous detector is connected to the output of the reset voltage circuit. The pulse shaper has only one output, made on the R-S trigger to provide "no-bounce" pulse formation at ultra-low frequencies.

A disadvantage of the known detector is also the low stability of sensitivity, which is manifested in the mass production of such fire detectors, due to the fact that the synchronous detector does not provide stable detection of the amplified photo-EDS signal due to the phase delays of the amplifier. In addition, in this synchronous detector, a conflict arises between the internal resistances of the outputs of two logic elements connected together, which would have to provide different logical levels. This use of a synchronous detector reduces the stability of the sensitivity of the detector as a whole.

The basis of the invention is the task of increasing the stability of sensitivity by simultaneously threshold monitoring the phase, duration and amplitude of the amplified signal photo - EMF. Due to the use of a pulse shaper with additional outputs, a threshold element, a resistor and a resistance switch, as well as their connections with other detector units, sensitivity stability is ensured. Achieving stability in conditions of mass production is also important because the requirements of the Russian standard NPB 65-97 to this parameter are more stringent than the requirements of the European standard EN-54-7.

This goal is achieved by the fact that the smoke detector, which has a reset circuit for the supply voltage and two terminals for connecting to the fire alarm loop, the first of which is connected to the input of the one-way conduction element, the output of which is connected to the first output of the power supply of the output signal shaper and the current limiting input an element whose output is connected to the power supply bus and to the first output of the capacitor, the second output of which is connected to a common bus, the second terminal and to the second power supply of the output driver, the output of which is connected to the indicator, and the input to the output of the pulse registration circuit and to the first input of the pulse generator circuit, the second input of which is connected to the output of the clock generator, and the first output of the pulse former circuit is connected to the emitter through the current switch, which optically connected through the camera with light-absorbing walls with a photodiode, the anode and cathode of which are connected to the input of the amplifier, according to the invention further comprises a resistance switch, a threshold an element and a resistor, and the pulse shaper has second and third outputs, the second output of the pulse shaper is connected to the first input of the pulse registration circuit, the second input of which is connected to the output of the OR logic element, the first input of which is connected to the output of the reset voltage supply circuit, and the second the input is through a threshold element to the output of the resistance switch, the control input of which is connected to the output of the amplifier, and the third output of the pulse former through a resistor is connected to the input of the threshold element .

The drawing shows a block diagram of a smoke detector.

The smoke detector contains indicator 1, as well as terminals 2 and 3 for connecting to the fire alarm loop. The first terminal 2 is connected to the input of the single-sided conduction element 4, the output of which is connected to the input of the current-limiting element 5 and the first power output of the output driver 6. The second power output of the output driver 6 is connected to the second terminal 3, the common bus 7 and the first output of the capacitor 8. The output of the current-limiting element 5 is connected to the power supply bus 9 and to the second output of the capacitor 8. The output of the output driver 6 is connected to the indicator 1, and the input - to the output of the pulse registration circuit 10, as well as to the first input of the pulse shaper 11. A clock generator 12 is connected to the second input of the pulse shaper 11. The first output of the pulse shaper 11 is connected to the emitter 14 through a current switch 13. The second output of the pulse shaper 11 is connected to the first input of the pulse registration circuit 10. The emitter 14 is optically connected through the camera 15 to the light-absorbing walls with a photodiode 16. The outputs of the photodiode 16 are connected to the input of the amplifier 17. To the output of the amplifier 17 is connected the input of the resistance switch 18, the output of which is connected to the input of the threshold element 19. The logical element 20 OR is connected to its first input with the output of the reset voltage circuit 21, and the second input with the output of the threshold element 19. The output of the OR gate 20 is connected to the second input of the pulse registration circuit 10. The third output of the pulse shaper 11 through a resistor 22 is connected to the input of the threshold element 19.

The power supply terminals of the elements are connected respectively to the power bus 9 and to the common bus 7 of the detector (these connections are not shown).

Smoke fire detector operates as follows. When a supply voltage is applied to the input terminals 2 and 3, the capacitor 8 is charged through the one-way conduction element 4 and the current-limiting element 6. The one-way conduction element 4 protects other elements of the smoke detector when the polarity of the supply voltage is incorrectly connected. As long as the voltage at the terminals of the storage capacitor 8 is not enough for the smoke detector to operate normally, a potential level is formed at the output of the power supply voltage reset circuit 21, which, through the OR logic element 20, sets a high potential level at the second input of the pulse registration circuit 10. In this case, the pulse detection circuit 10 will be in the zero state regardless of the signal at its first input. The driver 6 output signal will be closed, and indicator 1 will be off. At the same time, the low potential level that will come from the output of the pulse registration circuit 10 to the input of the pulse shaper 11 will allow the formation of a series of pulses at its outputs. Due to the operation of the clock generator 12, a series of short, several tens of microsecond pulses with a repetition period of about one second is formed at the three outputs of the pulse shaper 11.

From the first output of the pulse shaper 11, the first pulse is fed to the input of the current switch 13. The current switch 13 provides a discharge of the capacitor 8 with a given current through its output to the emitter 14, which creates infrared radiation pulses in the optical chamber 15 with light-absorbing walls. The value by which the capacitor 8 will be discharged will depend on the duration and period of the pulses that appear on the first output of the pulse shaper 11, as well as the ratio of the charge current of the capacitor 8 through the current-limiting element 5 to the discharge current of this capacitor 8 through the current switch 13 and emitter 14 The infrared radiation scattered by the optical camera 15 with light-absorbing walls is fed to the photodiode 16. The pulses amplified by the amplifier 17 in their amplitude and phase will substantially depend on the optical the density of air in the optical chamber 15. Thus, with absolute transparency of the air, small amplitude pulses will be present at the output of amplifier 17, since there will be some reflection from the walls of optical camera 15. The pulse at the output of amplifier 17 will reach its maximum or at the end pulse at the first output of the shaper 11 pulses, or after the completion of this pulse. The waveform at the output of the amplifier 17 substantially depends on the speed of the amplifier 17 and the pulse duration at the first output of the pulse shaper 11. With a small pulse amplitude, the output resistance of the resistance switch 18 significantly exceeds the resistance of the resistor 22, therefore, for each signal switching at the third output of the pulse shaper 11, the threshold element 19 will switch. Therefore, in each pulse of the formation of a series of pulses, the outputs of the pulse shaper 11 will be reset to the initial state of the pulse recording circuit 10. Shaper 6 of the output signal will be in the closed state, and indicator 1 will be turned off.

The detector will remain in standby mode, consuming from the fire alarm loop, which is connected to terminals 2 and 3, a current whose value is limited by the current-limiting element 5.

As the specific optical density of the medium increases, the amplitude of the pulses at the output of the amplifier 17 increases until it reaches a value at which the output resistance of the resistance switch 18 changes its value so that the resistance value of the resistor 22 becomes much larger than the output resistance of the resistance switch 18. In this case, when the state changes at the third output of the pulse shaper 11, the state of the threshold element 19 will not change. If the specific optical density of the medium reaches its threshold value, then in each cycle of formation of a series of pulses at the outputs of the pulse shaper 11, a change in the internal state of the pulse registration circuit 10 will occur.

Upon reaching the smoke level of the established level, i.e. with increasing specific optical density of air, the intensity of the scattered radiation of the optical camera 15 increases. In this case, for each series of pulses at the outputs of the pulse shaper 11, the state of the pulse registration circuit 10 will increase by one until the senior discharge of the pulse registration circuit 10 is switched over, according to which further pulse formation at the outputs of the pulse shaper 11 is prohibited. If there is a high potential level at the high level of the pulse registration circuit 10, the output driver 6 opens slightly, thus providing an abrupt decrease in the internal resistance of the detector, i.e. resistance to the direct current that flows between the input terminals 2 and 3. It is possible to remove a smoke detector from this state only by turning off the supply voltage for a time sufficient to discharge the storage capacitor 8, to a value at which the output of the reset circuit 21 for the supply voltage is low potential level.

Using the introduced resistance switch 18, a threshold element 19, a resistor 22, and a pulse shaper 11 with additional outputs and their connections with other elements made it possible to increase the detector sensitivity stability, since the phase, duration, and amplitude of the amplified photo-EMF signal are threshold-controlled.

All elements used in the detector are widely known, in addition, they can be performed by different means, for example, a clock 12 as a pulse generator, known on bipolar transistors, and on logic elements - two or three elements NOT, etc. Shaper 11 pulses, known as a chain with waiting single-shots or as a binary counter with a decoder. Current switch 13, known on bipolar and field effect transistors, operational amplifiers, etc. An infrared emitter 14, an optical camera 15 with light-absorbing walls, and a photodiode 16 are known as the optoelectronic components of any point optical smoke detector. The amplifier 17 can be made on the basis of an operational amplifier or two to three cascade transistor amplifiers. The resistance switch 18 can be performed on a field-effect or bipolar transistor, it is also possible to execute it on the basis of a diode current switch. The threshold element 19 may be performed based on a comparator, Schmitt trigger, etc. The pulse detection circuit 10 is known based on a register or a binary counter. Shaper 6 of the output signal can be performed on a field or bipolar transistor. The power supply voltage reset circuit 21 is known based on an RC circuit, a transistor stage, or a special chip. The current-limiting element 5 can be made on the basis of a resistor, a current limiter on a field effect transistor, etc. One-way conduction element 4, known as a diode or other pn junction.

Claims (1)

A smoke fire detector that has a voltage reset circuit and two terminals for connecting to a fire alarm loop, the first of which is connected to the input of a one-way conduction element, the output of which is connected to the first power output of the output signal shaper and the input of the current-limiting element, the output of which is connected to power supply bus and to the first terminal of the capacitor, the second terminal of which is connected to a common bus, the second terminal and the second terminal of the power supply of the driver a signal whose output is connected to the indicator, and the input to the output of the pulse registration circuit and to the first input of the pulse shaper circuit, the second input of which is connected to the output of the clock generator, and the first output of the pulse shaper circuit is connected to the emitter, which is optically connected through a camera with light-absorbing walls with a photodiode, the anode and cathode of which are connected to the input of the amplifier, further comprises a resistance switch, a threshold element and a resistor, and the pulse shaper c has a second and third output, the second output of the pulse shaper is connected to the first input of the pulse registration circuit, the second input of which is connected to the output of the OR logic element, the first input of which is connected to the output of the reset circuit by the supply voltage, and the second input through the threshold element to the output a resistance switch, the control input of which is connected to the output of the amplifier, and the third output of the pulse shaper through a resistor is connected to the input of the threshold element.