UA9923U - Smoke fire detector - Google Patents

Abstract

The proposed smoke fire detector contains an electronic valve element, a power-supply unit, an alarm signal former, a current-limiting element, an integrator, a capacitor, an indicator, a binary counter, a clock pulse generator, a comparator, a current switch, a threshold element, a direct-current pulse amplifier, a reset circuit, an infrared light-emitting diode, and a photodiode. The input of the valve element is connected to the first terminalfor connecting the fire detector to the fire alarm loop, and the output is connected to the first terminal of the power-supply unit and the input of the current-limiting element. The output of the current-limiting element is connected to the input of the integrator and the first terminal of the capacitor. The second terminal of the capacitor is connected to the second terminal for connecting the fire detector to the fire alarm loop and the secondterminal of the power-supply unit. The output of the alarm signal former is connected to the input of the indicator, and the input is connected to the output of the counter, the counting input of the counter, and the input of the clock pulse generator. The first output of the clock pulse generator is connected to the timing input of the counter, the second output is connected to the first input of the comparator, and the third output is connected to the input of the switch. The power-supply terminals of the switch are connected to the corresponding terminals of the capacitor. The output of the comparator is connected to the reset input of thecounter. The second input of the comparator is connected to the output of the amplifier via the threshold element. The first power-supply terminal of the amplifier is connected to the output of the integrator, and the second power-supply terminal is connected to the second terminal of the capacitor. The third input of the comparator is connected to the output of the reset circuit. The infrared light-emitting diode is connected to the output of the switch. The photodiode is optically coupled with the infrared light-emitting diode. For the purpose to extend the operating temperature range, the fire detector contains a resistor and a low-pass filter. The output of the filter is connected to the output of the photodiode. The resistor is connected in parallel to the photodiode.

Description

Description of the invention

The useful model refers to the field of fire alarm and can be used in fire alarm 2 systems to detect an increase in the optical density of air based on the intensity of infrared radiation scattering.

Known fire detectors, optical smoke detectors and smoke registration devices, which work on the principle of periodic emission of infrared radiation pulses and their subsequent reception, amplification and processing of the received signal in various ways, forming a signal about the presence or absence of smoke 70 I | see. magazine "Security Systems of Communication and Telecommunications", 2000, 33, p. 651.

A known smoke detection device (patent of the Russian Federation KO 2221278, 7 (308817/10, publ. 2004.01.10), containing a clock generator, an emitter connected through an optical camera with light-absorbing walls to a photo receiver, a reset circuit, a smoke detection signal generator. In addition, the device contains a synchronous detection circuit, a comparison and memory circuit, which is made in the form of 12 first and second binary counters, and the M-input and K-input of the first binary counter of the comparison and memory circuit are connected to the corresponding outputs clock generator, the output of the first binary counter is connected in parallel with the emitter input, the M-input of the second binary counter of the comparison and storage circuit and the first input of the synchronous detection circuit, the second and third inputs of which are connected to the outputs of the photodetector and the reset circuit, respectively, and the output - with the K-input of the second binary counter of the comparison and memorization scheme, the output of the second binary counter and the comparison and memory circuits are connected to the C-inputs of both counters and to the input of the smoke registration signal generator.

The disadvantage of the known device is the low probability of its operation at high levels of background illumination from natural or artificial light sources, as well as - at an increased value of the upper limit of the working temperature of the detector, for example, up to 7592C, when the photodetector does not provide separation of pulse signals from the 29 infrared emitter and from the visible light entering the light-absorbing-walled chamber (SPW) through smoke slits, as well as photodetector leakage current caused by elevated temperature.

The closest to the proposed solution is the smoke fire detector chosen as a prototype (Izveshatel pozharnyi dmovoi optiko-zlectronnyi IP212-41M TU 4371-005-12215496-00; Passport Shk 4371-005-12215496-00 PS, which contains an element of one-sided conduction, the input of which connected to the first Ge terminal for connection to the fire alarm loop, and the output is connected to the first output of the power supply of the smoke detection signal generator and the input of the current limiting element, the output of which is connected to the b input of the integrator and to the first output of the capacitor, the second output of which is connected to the second terminal for Ge") connection to the fire alarm loop and with the second output of the power supply of the signal generator

From the smoke register, the output of which is connected to the indicator, and the input is connected to the output of the binary counter, to the C-input of this counter and to the input of the clock generator, the first output of which is connected to the M-input of the binary counter, the second output of the clock generator is to the first input comparison circuit, and the third output of the clock generator is connected to the input of the current switch, the power terminals of which are connected to the corresponding terminals of the capacitor, the output of the comparison circuit is connected to the K-input of the binary counter, the second input of the comparison circuit 70 is connected through a threshold element to the output of the DC pulse amplifier, the first terminal of which is connected to the output of the integrator, and the second terminal of the power supply is connected to the second terminal of the capacitor, "from the third input of the comparison circuit is connected to the output of the reset circuit according to the supply voltage, and the emitting infrared is connected to the outputs of the current switch a diode optically connected through a camera with light-absorbing walls to a photodiode, the anode of which is connected connected to the second terminal of the first capacitor, and the cathode is connected to the input of the DC pulse amplifier. The disadvantage of this detector is also the low probability of its operation at high levels of background (Se) illumination by natural or artificial light sources, as well as at an increased value of the upper limit of the detector's operating temperature, for example, up to 752С, when the input of the DC pulse amplifier with the photodiode receives a total current pulse from the infrared emitter and from visible light, which penetrates into the chamber with light-absorbing walls through slits for the passage of smoke, as well as from the leakage current of the photodiode caused by the increased temperature.

The basis of the proposed solution is the task of increasing the probability of control in a wide range of working temperatures of the detector, as well as in conditions of increased background illumination from external natural or artificial lighting sources due to the simultaneous allocation of a pulsed useful signal

So" before its amplification and reduction of the level of electromagnetic inductions on the input circuit of the photodiode.

The task is solved by the fact that the smoke fire detector, which contains an element of one-way conduction, the input of which is connected to the first terminal for connection to the fire alarm loop, and the output is connected to the first output of the power supply of the smoke detection signal generator and the input of the current limiting element, output which is connected to the input of the integrator and to the first output of the capacitor, the second output of which is connected to the second terminal for connecting to the fire alarm loop and to the second power supply output of the smoke detection signal generator, the output of which is connected to the indicator, and the input is connected to the output of the binary counter , to the C-input of this counter and to the input of the clock generator, the first output of which is connected to the M-input of the binary counter, the second output of the clock generator is connected to the first input of the comparison circuit, and the third output of the clock generator is to the input of the current bo key, the power terminals of which connected to the corresponding terminals of the capacitor, the output of the pore circuit is connected to the K-input of the binary counter, the second input of the comparison circuit is connected through a threshold element to the output of the DC pulse amplifier, the first supply terminal of which is connected to the output of the integrator, and the second supply terminal is connected to the second terminal of the capacitor, the third input of the circuit comparator is connected to the output of the reset circuit according to the supply voltage, and to the outputs of the current switch is connected an emitting infrared diode, which is optically connected through a camera with light-absorbing walls to a photodiode, according to the proposed solution, additionally contains a resistor and a high-pass filter, the output of which is connected to the input of the DC pulse amplifier, and the parallel outputs of the photodiode and resistor are connected to the inputs of the high-pass filter. 70 Due to the use of a high-pass filter, smooth changes in the potential difference at the resistor terminals do not change the signal at the output of the DC pulse amplifier, and accordingly, increasing the upper limit of the detector's operating temperature to the upper limit of the photodiode's operating temperature does not lead to a false alarm. Background illumination from natural or artificial light sources, which penetrates into the chamber with light-absorbing walls through slits for the passage of smoke, increases the total 7/5 Value of photo-ercs released on the resistor, but practically does not change the pulse component due to the infrared radiation of the diode. Thus, when the specific air density is below the threshold value, the detector will remain in the regular mode of operation in conditions of high background illumination. The detector will remain in the regular mode of operation even in conditions of significant changes in the background illumination, because the probability of false activation of the detector will be quite small thanks to the temporary selection carried out by the comparison circuit. In addition, the use of a photodiode as a photo-ERS source allows you to significantly reduce the size of the electrical circuit of the photodiode load, and thereby reduce the level of electromagnetic interference in this circuit.

In Fig. a block diagram of a smoke fire detector is presented.

The smoke fire detector contains an indicator 1, as well as terminals 2 and C for connection to the fire alarm loop. The input of the element 4 of unidirectional conductivity is connected to the first terminal 2, the output of which is connected to the first output of the power supply of the generator 5 of the smoke registration signal and the input of the current-limiting element 6. The output of the current-limiting element 6 is connected to the first output of the first capacitor 7, the power output of the current switch 8 and the input of the integrator 9. The output of the integrator 9 is connected to the first power output of the amplifier 10 of direct current pulses, the second power output of which is connected to the second terminal c z o z, the second power outputs of the current switch 8 and the generator 5 of the smoke registration signal. An infrared emitting diode 11 is connected to the outputs of the current switch 8, which is optically connected through the camera 12 with light-absorbing walls to the photodiode 13. The output of the generator 5 of the smoke registration signal is connected to Ge! indicator 1, and the input is to the output of the binary counter 14, to the C-input of this counter 14 and to the input of the clock generator 15, the first output of which is connected to the M-input of the binary counter 14. The second output of the clock (22) of the generator 15 is connected with the first input of the comparison circuit 16, and the third output - with the input of the current switch 8.

The second input of the comparison circuit 16 is connected to the output of the reset circuit 17 on the supply voltage, and the third input is through the threshold element 18 to the output of the amplifier 10 of direct current pulses. The output of the high-frequency filter 19 is connected to the input of the amplifier 10 " of direct current pulses, to the inputs of which the parallel-connected outputs of the photodiode 13 and the resistor 20 are connected. o)

In Fig. the power outputs of the circuit 17 reset by the supply voltage, the clock generator 15, the circuit 16 with comparison, the threshold element 18 and the binary counter 14 are conditionally not shown.

The smoke detector works as follows. When supplying voltage to input terminals 2 and З;» through element 4 of one-way conductivity and current-limiting element 6, the storage capacitor 7 is charged. Element 4 of one-way conductivity provides protection of other elements of the smoke fire detector in case of erroneous connection of the polarity of the supply voltage of the fire alarm loop. While the voltage at the terminals of the storage capacitor 7 is insufficient for the normal operation of the smoke fire detector, a low potential level is formed at the output of the power supply voltage reset circuit 17, which, through the comparison circuit 16, sets a high potential level at the K-input of the binary counter 14. In this case, the binary counter 14 is in the zero state regardless of the signals on its other inputs. The generator 5 of the smoke registration signal is closed, and the indicator 1 is turned off. At the same time, the low c" potential level coming from the output of the binary counter 14 to the first input of the clock generator 15 and to

The C-input of the same counter 14 allows the operation of the clock generator 15 and the binary counter 14.

Since the current consumption of the clock generator 15 significantly depends on the supply voltage, for its small (tens of microamperes) value, it is necessary that the switching of the reset circuit 17 according to the supply voltage with 55 is carried out at an operating voltage close to its minimum value, but exceeding it. At the moment of change of state at the output of the circuit 17, reset by the supply voltage, the clock generator 15 is started, and the potential level is set at the K-input of the binary counter 14, which allows the change of states of the binary counter 14 during voltage drops at its M-input. At the outputs of the clock generator 15, pulses with a transit time of about one second are formed. At each negative signal drop at the first output of the clock generator 15, the binary counter 14 will change its state. But at a low level of the specific optical density of the medium, when a constant potential level will be observed at the output of the threshold element 18, the pulses coming from the second output of the clock generator 15 through the comparison circuit 16 on

The K-input of the binary counter 14, the latter will be reset immediately after the end of the drop at its M-input.

From the third output of the clock generator 15, pulses are sent to the input of the current switch 8. The current switch v5 8 provides the discharge of the storage capacitor 7 with a given amount of current through its output to the emitting infrared diode 11. The amount by which the storage capacitor 7 is discharged will depend on the duration and period pulses appearing at the third output of the clock generator 15, as well as from the ratio of the charge current of the storage capacitor 7 through the current limiting element 6 to the discharge current of this capacitor 7 Through the current switch 8. Thus, the voltage drop established on the storage capacitor 7, will exceed the voltage drop at the power supply terminals of the amplifier 10 pulses of direct current by the amount of the voltage drop at the integrator 9. Due to this potential difference, stable operation of the amplifier of 10 pulses of direct current is ensured, because short-term voltage drops at the terminals of the storage capacitor 7 in mome nts of its discharge by the current switch 8 at the expense of the integrator 9 will not change the operating modes of the amplifier 10 of direct current pulses. 70 The infrared radiation of the diode 11 scattered by the optical camera 12 with light-absorbing walls enters the photodiode 13. The photo-erc pulses isolated on the resistor 20 through the high-pass filter 19 enter the input of the amplifier 10 of direct current pulses. The amplitude and phase of the DC pulses amplified by the amplifier 10 will depend significantly on the optical density of the air in the optical chamber 12. Thus, with absolute transparency of the air at the output of the amplifier 10, triangular pulses /5 of small amplitude will be present, because some reflection will take place from the walls of the optical camera 12. The triangular-shaped pulse at the output of the amplifier 10 of direct current pulses reaches its maximum at the end of the pulse at the third output of the clock generator 15. At a small amplitude of these pulses, the reset pulses of the binary counter 14 appear at the output of the comparison circuit 16. Thus thus, for each positive signal drop at its M-input, the binary counter 14 will switch, counting only one pulse, and will immediately be reset from the pulses arriving at its K-input. In the next mode of operation, when the specific optical density of air is below the set level, after each pulse at the second output of the clock generator 15, the binary counter 14 is reset. At the output of the higher digit of the binary counter 14, to which the input of the generator 5 of the smoke registration signal is connected, a low potential remains level, indicator 1 is off, and generator 5 of the smoke registration signal is off. The detector remains in the regular mode of operation, consuming current from the fire alarm loop connected to terminals 2 and 3, the value of which is limited by the current limiting element 6.

As the specific optical density of the medium increases, the amplitude of the pulses at the output of the amplifier 10 of direct current pulses increases until it reaches the threshold value of the switching of the threshold element 18, at which a low potential level is set at the K-input of the binary counter 14, which allows the counting of pulses that are received at the M-input of this counter 14. In this case, for each pulse at the first output of the clock generator 15, the state of the binary counter 14 increases by one until the switching of the higher digit of the binary counter 14 occurs, which prohibits the further counting of pulses corresponding to alarm status - "Fire". When there is a high potential level on the higher digit of the binary counter 14, the generator 5 of the smoke registration signal opens, the me) indicator 1 starts to light up, and the specified current consumption is ensured from the fire alarm loop, to which the smoke fire detector is connected with its input terminals 2 and 3. In addition , this signal prohibits the operation of the clock generator 15. In this state, the current consumption of the clock generator 15, the amplifier 10 and other elements of the circuit is significantly reduced, at the same time, due to the current flowing through the generator 5 of the smoke registration signal, the potential difference between the terminals is sharply reduced 2 and 3. If this voltage drop does not lead to a change in the state of the signal at the output of the circuit 17 reset by the supply voltage, then the detector will be in the "Fire" state indefinitely. It is only possible to remove the detector from this state. by disconnecting the power supply voltage of the fire alarm loop for a time sufficient for the discharge of the storage capacitor 7 to the value at which a low potential level will be established at the output of the reset circuit 17 according to the supply voltage.

The proposed detector can be manufactured using well-known and widely used ones

Ge) component products: resistors, capacitors, transistors, diodes, logic chips. For example, a binary counter can be made on the KOETLYE1O or CO4520 microcircuit, and the clock generator and IC comparison circuit - on elements of the K5b61TL1 or CO4093 microcircuit. An element of one-sided conduction can be

The GI is made on a diode KD521B or similar to it. The current-limiting element can be made on a 5p unipolar transistor, the registration signal generator - on a transistor with a large amplification factor or c" on a unipolar transistor.

Claims (1)

The formula of the invention Su; A smoke fire detector containing an element of one-way conduction, the input of which is connected to the first terminal for connecting to the fire alarm loop, and the output is connected to the first power output of the generator of the smoke registration signal and the input of the current limiting element, the output of which is connected to the input of the integrator and to the first output of the capacitor, the second output of which is connected to the second terminal for connecting to the fire alarm loop and to the second output of the power supply of the smoke detection signal generator, the output of which is connected to the indicator, and the input is connected to the output of the binary counter, to the C-input of this counter and to the input of the clock generator, the first output of which is connected to the M-input of the binary counter, the second output to the first input of the comparison circuit, and the third output to the input of the current switch, the power terminals of which are connected to the corresponding terminals of the capacitor, the output of the comparison circuit to united with 65 K-input of the binary counter, the second input of the comparison circuit is connected through a threshold element to the output of the DC pulse amplifier, the first supply terminal of which is connected to the output of the integrator, and the second supply terminal is connected to the second terminal of the capacitor, the third input of the comparison circuit is connected to the output reset circuit according to the supply voltage, and an emitting infrared diode is connected to the outputs of the current switch, which is optically connected through a camera with light-absorbing walls to a photodiode, which differs in that the detector additionally contains a resistor and a high-pass filter, the output of which is connected to the input of the pulse amplifier direct current, and the parallel outputs of the photodiode and resistor are connected to the inputs of the high-pass filter. z z (ze) Zo sch (o) (o) . and? se) se) ime) syu S; at 60 b5