UA13221U - Smoke fire detector - Google Patents

Abstract

The proposed smoke fire detector contains a microprocessor control unit, a unit for generating a smoke detection signal, a unit for limiting current and voltage, a current-to-voltage converter, two capacitors, a diode, an optical radiation source, a photodetector, and light-emitting diode indicator.The unit for generating a smoke detection signal contains two bipolar transistors, a diode, and resistors. The power-supply of the said units are connected to the corresponding terminals of the power-supply source. The first output of the control unit is connected to the input of the unit for generating a smoke detection signal. The input of the current-to-voltage converter is connected to the second output of the control unit. The optical radiation source is optically coupled with the photodetector via a hollow lightguide with internal light-absorbing surface. The output of the photodetector is connected to the input of the control unit. The fire detector provides a possibility to generate a fire alarm signal.

Description

Description of the invention

The useful model refers 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 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 "Communication Systems and Telecommunications", 2000, 33, p.65).

The well-known photoelectric smoke detector

She rpoiioeiesigis. EP 0755037 A1 5088 17/103 22.01.1997), containing a microcontroller, the first output of which is connected to the input of the smoke detection signal generator, and the second output - to the input of the voltage-current converter, the output of which is connected to the emitter connected through the optical camera with 79 light-absorbing walls with a photodetector, the output of which is connected to the input of the microcontroller, and the outputs of the generator of the smoke detection signal through the terminals are connected to the fire alarm loop.

The disadvantage of this detector is the significant consumption of electric current from the fire alarm loop, which must contain a separate power supply bus from which the microcontroller and the voltage-to-current converter controlling the emitter are powered. In addition, such a photoelectric smoke detector cannot work if it is powered by a fire alarm loop with alternating voltage.

The nearest to the proposed useful model is the smoke fire detector ANZ-871, manufactured by "Nogipd (ii IpdiziaI So., Ma), Taiwan (mmly.gadetipa.sot), selected as a prototype, containing a microcontroller, the first output of which is connected to the input of the smoke detection signal generator, the first power supply terminal of which is connected to the first power supply terminals of the current and voltage limiter, 29 of the microcontroller and the voltage-to-current converter, as well as the first terminals of the first and second capacitors, -o the second power supply terminal of the smoke detection signal generator with connected to the second terminal of the power supply of the current and voltage limiter and the output of the unidirectional conduction element, the input of which is connected to the first input terminal, the input of the voltage-current converter is connected to the second output of the microcontroller, the second power terminal of which is connected to the second terminal of the first capacitor and to -- 30 of the first output of the current and voltage limiter, the second output of which is connected to the second output of the second Ha of the capacitor and the second output of the power supply of the voltage-current converter, the outputs of which are connected to the emitter, which is optically connected through an optical camera with light-absorbing walls to the photodetector, the output of which is connected to the input of the microcontroller. The first output of the power supply of the current and AC voltage limiter is connected to the second input terminal through the second element of one-way conduction. LED

The indicator, which is connected in series with a resistor between the third output and the second power output of the microcontroller, provides only an indication of the next operating mode. The generator of the smoke registration signal is made on a thyristor, which provides memory of operation, only if the detector is powered by constant voltage. "

The disadvantage of the prototype is the improper formation of signals in the fire alarm loop with alternating voltage Z 50. When such a detector is triggered in the fire alarm loop with alternating voltage, the signal FAILURE is generated, not FIRE, and after the end of the factors under which it was triggered, the detector automatically returns to the next mode of operation, which does not meet the requirements of the regulatory and technical documentation - international standard EM54-7. In addition, the built-in LED indicator of the detector does not generate an optical signal "FIRE". 45 The useful model is based on the task of ensuring the formation of the "FIRE" signal by the detector - in the sign-changing loop of the fire alarm, as well as ensuring the retention of the "FIRE" signal in the sign-changing loop of the fire alarm after the end of the factors that triggered the detector by using the registration signal generator smoke of another implementation on two transistors and instead of a thyristor, which allows you to preserve the state of the open first key after a short-term absence of voltage ka 20 power supply (for 0.1-0.2s), even after the end of the control pulse on the first output of the microcontroller. An LED indicator is connected to the outputs of such a smoke detection signal generator, which provides optical and reproduction of the "FIRE" signal.

The task is solved by the fact that the smoke fire detector containing a microcontroller, the first output of which is connected to the input of the smoke detection signal generator, the first power output of which is connected to the first power outputs of the current and voltage limiter, the microcontroller and the voltage-to-current converter , as well as the first terminals of the first and second capacitors, the second terminal of the power supply of the smoke detection signal generator is connected to the second terminal of the power supply of the current and voltage limiter and the output of the first unidirectional conduction element, the input of which is connected to the first input terminal, the input of the voltage-to-current converter is connected to of the second output of the microcontroller, the second output of which is connected to the second output of the first capacitor and to the first output of the current and voltage limiter, the second output of which is connected to the second output of the second capacitor and the second output of the power supply of the voltage-to-current converter, the outputs of which are connected emits h, which is optically connected through an optical camera with light-absorbing walls to a photoreceiver, the output of which is connected to the input of the microcontroller, differs in that the LED indicator is connected to the outputs of the smoke registration signal generator, which is made using two transistors, the second element of one-way conduction, a third capacitor, and six resistors, the cathode of the LED indicator through the first output of the smoke detection signal generator is connected to its first power supply terminal, which is connected to the second input terminal, the anode of the LED indicator through the second output of the smoke detection signal generator and the first resistor are connected with the input of the second element of unidirectional conductivity and the collector of the first transistor, the emitter of which is connected to the second output of the power supply of the smoke registration signal generator, and through the second resistor to the base of the first transistor, which is connected through the third resistor to the collector of the second transistor, the emitter of which is under connected to the first terminal of the power supply of the smoke detection signal generator, the first terminals of the third capacitor and the fourth resistor, the second terminal of which is connected to the base of the second transistor and the first terminals of the fifth and sixth resistors, the second terminal of the fifth resistor is connected to input of the smoke detection signal generator, and the second output of the sixth resistor is connected to the output of the second unidirectional conduction element and the second output of the third capacitor.

In the proposed useful model, due to the use of a smoke registration signal generator with a capacitor memory on the third capacitor, the second element of one-way conduction and their connections with /5 other elements of the detector, the "FIRE" state of the detector is preserved after a short-term absence of supply voltage (at 0 ,1-0.2s), even after the end of the pulse at the first output of the microcontroller, that is, after the end of the process of scattering infrared radiation by smoke in a chamber with light-absorbing walls.

The drawing shows a block diagram of a smoke fire detector.

The smoke fire detector contains a microcontroller 1, the first output of which is connected to the input of the generator 2 of the smoke registration signal, the first power supply output of which is connected to the first power supply outputs of the current and voltage limiter C, the microcontroller 1 and the voltage-to-current converter 4, as well as the first terminals of the first and second capacitors 5 and 6. The second terminal of the power supply of the shaper 2 of the smoke registration signal is connected to the second terminal of the power supply of the current and voltage limiter Z and to the output of the first element 7 of unidirectional conductivity, the input of which is connected to the first input terminal 8. The input of the converter 4 voltage-current is connected to the second output of the microcontroller 1, the second output of which is connected to the second output of the first capacitor 5 and to the first output of the current and voltage limiter.

The second output of the current and voltage limiter Z is connected to the second output of the second capacitor b and the second output of the power supply of the voltage-to-current converter 4, with the outputs of which the emitter 9 is connected. absorbing walls with a photodetector 11, the output of which is connected to the input of the microcontroller 1. The LED indicator 12 is connected to the outputs of the generator 2 of the smoke registration signal in such a way that the cathode of the LED indicator 12 is connected to its first power supply output through the first output of the generator 2 of the smoke registration signal , which is connected to the second input terminal 13. The anode of the LED indicator 12 is connected to the input of the second element 15 of one-way conductivity and the collector of the first transistor 16 through the second output of the generator 2 of the registration signal of the medium and the first resistor 14. The emitter of the first transistor 16 connected to the second output of the power supply of the generator 2 of the smoke registration signal, and through the second resistor 17 - to the base of the first transistor 16. The base of the first transistor 16 through the third resistor 18 is connected to the collector of the second transistor 19. The emitter of the second transistor 19 is connected to the first terminal of the power supply of the generator 2 of the smoke registration signal, the first terminals of the third capacitor 20 and the fourth resistor 21. The second output of the fourth resistor 21 is connected 3 /-plv) with the base of the second transistor 19 and the first outputs of the fifth and sixth resistors 22 and 23. The second output of the fifth . resistor 22 is connected to the input of generator 2 of the smoke registration signal, and the second output of the sixth resistor 23 and? connected to the output of the second unidirectional element 15 and the second terminal of the third capacitor 20.

A smoke fire detector works in the following way. When the power supply voltage is applied from the fire alarm loop to the input terminals 8 and 13 through the first element 7 of one-way conduction and the limiter. The first and second capacitors 5 and 6 are charged from the current and voltage. The first element 7 of one-way conduction protects other elements of the smoke fire detector when wrong polarity connection about the power supply voltage of the fire alarm loop. As long as the voltage at the power supply terminals is insufficient for the normal operation of microcontroller 1, low potential voltage levels are maintained at its two outputs.

The voltage-current converter 4 will be closed, and the emitter 9 will not emit infrared light. In this case, the shaper 2 of the smoke detection signal will also be closed, that is, both transistors 16 and 19 will be closed. The LED indicator 12 will not light up, so the detector will consume current from the fire alarm loop limited to the value set by the current and voltage limiter.

After reaching the minimum value of the operating voltage, the microcontroller 1 implements a program delay of the start of work at the minimum value of the consumption current. This delay provides a guaranteed voltage output on the first capacitor 5 to a value that does not exceed the maximum value of the operating voltage from the microcontroller 1. The charge accumulated on the second capacitor b will ensure the next stable operation of the emitter 9. After this delay, stable amplitude pulses lasting several tens of microseconds will arrive to the input of the 4 voltage-current converter. This converter 4 ensures the formation of current pulses of stable amplitude through the emitter 9. In this way, the discharge of the second capacitor b is carried out with a stable amount of current through the emitter 9. The amount by which the second capacitor 6 will be discharged will depend on the duration and period of the pulses that appear on the second output of the microcontroller 1, as well as from the ratio of the charge current of the second capacitor 9 through the current and voltage limiter to the discharge current of this capacitor 6 through the emitter 9. Thus, 65 Voltage fluctuations on the second capacitor 6 will not interfere with the operation of the microcontroller 1, power supply which is carried out from the first capacitor 5.

The infrared radiation of the emitter 9, scattered by the optical camera 10 with light-absorbing walls, enters the photoreceiver 11. After amplification, the photo EMF pulses are processed by the microcontroller 1. The signal received at the input of the microcontroller 1 will significantly depend on the optical density of the air in the optical chamber 10. So, when absolute transparency of the air at the output of the photodetector 11, there will be a background signal: low-amplitude pulses, because there will be some reflection from the walls of the optical chamber 10. As the optical density of the air in the optical chamber 10 increases, the amplitude of the pulses at the output of the photodetector 11 will also increase. While the amplitude of these pulses will not reach the set limit value, the state at the outputs of microcontroller 1 will not change. A low potential level will remain at the input of smoke detection signal generator 2, so it will be closed. The detector will remain in the regular operation mode, consuming current from the fire alarm loop, the value of which is limited by the current and voltage limiter.

If the amplitude of the photo-EMF pulses exceeds the limit value, and if such a signal level appears at the input of microcontroller 1 several times in a row, for example 4, then a change of states will occur at its outputs. A high potential level will appear on the /5 first output, at which the shaper 2 of the smoke registration signal will open and a current will flow through the LED indicator 12, which will ensure the formation of the "FIRE" state in the fire alarm loop. A low potential level will be set on the second output of microcontroller 1.

The voltage-current converter 4 will be closed. The second capacitor 6 will not be discharged through the emitter 9. Due to the current flowing through the generator 2 of the smoke registration signal and the LED indicator 12, the potential difference between the input terminals 8 and 13 is sharply reduced. If this voltage drop will exceed the minimum value of the operating voltage of the microcontroller 1 , then the detector will be in the "FIRE" state indefinitely. Almost all the current consumed by the detector in the "FIRE" mode will flow through the LED indicator 12, because the current in the circuit of the current and voltage limiter Z, as well as in the circuit of the sixth resistor 23 does not exceed one percent of the current in the circuit of the LED indicator 12. Due to the drop about the voltage on the first resistor 14 and the LED indicator 12 through the second element 15 of one-way conduction, the third capacitor 20 is rapidly charged. Due to the current flowing through the sixth resistor 23, the base current of the second transistor 19 increases, reliably ensuring the open state of the second transistor 19. in the event of the end of the control signal applied to the input of the generator 2 of the smoke registration signal, i.e. after establishing a low potential level at the first output of the microcontroller 1, the second transistor 19 will remain open. Even with short-term (for 0.1-0.2s) interruptions in the power supply voltage of the detector, both simultaneous and periodic due to the charge accumulated on the third capacitor for 20 seconds, the base current of the second transistor 19 will be sufficient to maintain the "FIRE" state of the detector. with

It is possible to remove the detector from this state only by disconnecting the power supply voltage of the fire alarm loop for a time longer than 2-3 seconds, which is sufficient for the complete discharge of the third capacitor 20. During the same time, the complete discharge of the second capacitor 5 is also carried out. Therefore, with the duration of the voltage interruption power "- more than Zs the detector will always start its work from the next mode.

Thus, due to the use of two transistor shapers 2 of the smoke registration signal with a trigger memory on the third capacitor 20 and the second element 15 of unidirectional conductivity, as well as their connections with other elements, the "FIRE" state of the detector is preserved not only in the case of power its constant current, but also in the case of using a variable-sign fire alarm loop, in which the direction of the current changes with a frequency of about 1Hz o /plv) s for a time of up to 100ms. Optical signal "FIRE" of the detector connected to . of the variable-sign loop of the fire alarm, will be restored after each pulse of negative voltage. and?" The proposed useful model uses well-known elements. In addition to the generator 2 of the smoke registration signal, other elements correspond to the prototype. And the shaper 2 of the smoke registration signal itself is made of ordinary radio elements: resistors, transistors, capacitors, diodes (the second element 15 is unilateral - conductivity). Microcontroller 1 can be the same as in the prototype, MC145010 of the company "Moyogoia", or made on microcircuits of the company MISKOSNIR, type РИС1ОЕ202 or similar. (95) where

Claims (1)

The formula of the invention with 50 shk Smoke fire detector containing a microcontroller, the first output of which is connected to the input of the smoke detection signal generator, the first output of the power supply of which is connected to the first outputs of the power supply of the current and voltage limiter, the microcontroller and the voltage-to-current converter, and also by the first terminals of the first and second capacitors, the second terminal of the power supply of the smoke detection signal generator is connected to the second terminal of the power supply of the current and voltage limiter and the output of the first unidirectional conduction element, the input of which is connected to the first input terminal, the input of the voltage-to-current converter is connected to the second the output of the microcontroller, the second power output of which is connected to the second output of the first capacitor and to the first output of the current and voltage limiter, the second output of which is connected to the second output of the second capacitor and the second output of the power supply of the voltage-to-current converter, to the outputs of which the emitter is connected , which is optically from knitted Through an optical camera with light-absorbing walls with a photodetector, the output of which is connected to the input of a microcontroller, which differs in that the LED indicator is connected to the outputs of the smoke registration signal generator, which is made using two transistors, the second element of one-sided conduction, the third b5 / Capacitor and six resistors, the cathode of the LED indicator through the first output of the smoke detection signal generator is connected to its first power supply terminal which is connected to the second input terminal, the anode of the LED indicator through the second output of the smoke detection signal generator and the first resistor is connected to the input of the second element of one-sided conductivity and the collector of the first transistor, the emitter of which is connected to the second output of the power supply of the smoke registration signal generator, and through the second resistor - to the base of the first transistor, which is connected through the third resistor to the collector of the second transistor, the emitter of which is connected to the first terminal of the power supply of the generator of the smoke registration signal, the first terminals of the third capacitor and the fourth resistor, the second terminal of which is connected to the base of the second transistor and the first terminals of the fifth and sixth resistors, the second terminal of the fifth resistor is connected to the input of the generator of the registration signal smoke, and the second terminal of the sixth resistor is connected to the 7/0 output of the second unidirectional conduction element and the second terminal of the third capacitor. that 2 "- s s (ze) є - and? - (95) ime) ime) - 60 b5