RU2583704C2 - Self-contained smoke detector - Google Patents

Abstract

FIELD: physics, signalling.

SUBSTANCE: invention relates to fire alarms and can be used as a self-contained smoke detector for detecting increase in the optical density of air from infrared radiation scattering strength. The self-contained smoke detector has a battery supply, a controller, an optical indicator, a voltage-to-current converter, an emitting infrared diode, a photodiode, two terminals, a piezoelectric radiator, two resistors and a capacitor.

EFFECT: providing the required current consumption in stand-by mode, where it is possible to make a self-contained alarm with a built-in battery with an operating life of 10 years or more.

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Description

The invention relates to the field of fire alarm and can be used as a standalone smoke detector to detect an increase in the optical density of air by the scattering intensity of light infrared radiation.

Known self-contained smoke detector (Autonomous optoelectronic smoke detector IP 212-47 "AGAT" 01 TU 4371-002-10848582-00), based on the typical application of the controller MC 145010 (Photoelectric Smoke Detector with I / O. For Battery - Powered Applications. MC 145010. Motorola. Semiconductor technical data). Such a self-contained smoke detector has a battery, a controller, an optical indicator, a voltage-current converter emitting an infrared diode, a photodiode, two terminals for combining the detectors, a piezoelectric emitter, two resistors and a capacitor. The positive and negative terminals of the power battery are connected to the first and second terminals of the power supply of the controller, an optical indicator is connected between the third terminal of the controller and the positive terminal of the power battery, the emitting infrared diode is optically connected through the smoke sensor chamber to the photodiode, the anode and cathode of which are connected to the fourth and fifth, respectively controller pins, the first pins of two resistors and a capacitor are interconnected, the second pins of the capacitor are connected to the sixth pins of the controller, and the second pins are a seventh resistor is connected to the controller output. The input of the voltage-current converter is connected to the eighth terminal of the controller, the first and second power leads of which are connected respectively to the positive and negative terminals of the power battery, and the emitting infrared diode is connected to the voltage-current converter outputs. The second terminal of the second resistor is connected to the first terminal of the piezoelectric emitter, the second terminal of which is connected to the second terminal of the capacitor, and the third terminal is connected to the second terminal of the first resistor. The ninth pin of the controller is connected to the first pin of the capacitor.

The disadvantages of the known detector are a significant dependence of the sound pressure level generated by the piezoelectric emitter on the voltage of the power supply battery and significant current consumption in standby mode, which does not allow creating an autonomous detector with a built-in battery with a life of 10 years or more.

The closest in technical essence to the invention to be patented is a prototype photoelectric smoke detector (CMOS Low Voltage Photoelectric Smoke Detector ASIC RE46C190 DS22271A page 3), which has a battery, controller, optical indicator, smoke detector camera with an emitting infrared diode and a photodiode , a piezoelectric emitter, two resistors and four capacitors, the positive and negative terminals of the power battery are connected respectively to the first and second terminals of the power supply of the controller and the first capacitor, a photodiode the smoke sensor is connected to the first and second inputs of the controller, the first and second outputs of the controller are connected respectively to the anode and cathode of the emitting infrared diode of the smoke sensor chamber, the anode of which is connected through the second capacitor to the negative terminal of the battery and the first terminal of the third capacitor, the second terminal of which is connected to the first terminal of the optical indicator and the cathode of the first diode, the anode of which is connected to the third output of the controller and through the inductor with the positive terminal of the battery, the second terminal is optical Skog indicator connected to the fourth output of the controller, a fifth output which via a fourth capacitor connected to the first terminals of the first and second resistors. The second output of the first resistor is connected to the first output of the piezoelectric emitter and the sixth output of the controller, the fifth output of which is connected to the second output of the piezoelectric emitter, the third output of which is connected to the second output of the second resistor.

The prototype was made using a controller Microchip RE46C190. The disadvantage of the prototype is also a significant current consumption in standby mode, in which it is impossible to create a standalone detector with a built-in battery with a lifespan of 10 years or more.

The basis of the invention is the task of ensuring the necessary current consumption in standby mode, in which it is possible to create a standalone detector with a built-in battery with a life of 10 years or more.

This goal is achieved by the fact that an autonomous smoke detector containing a battery, a controller, an optical indicator, a smoke sensor chamber with a radiating infrared diode and a photodiode, a piezoelectric emitter, two resistors and four capacitors, plus and minus terminals of the battery are connected respectively to the first and the second power leads of the controller and the first capacitor, the photodiode of the smoke detector camera is connected to the first and second inputs of the controller, the first and second outputs of the controller with respectively, with the anode and cathode of the emitting infrared diode of the smoke detector chamber, the anode of which is connected through the second capacitor to the negative terminal of the battery and the first terminal of the third capacitor, the second terminal of which is connected to the first terminal of the optical indicator and the cathode of the first diode, whose anode is connected to the third output of the controller and through a choke with a positive battery terminal, the second terminal of the optical indicator is connected to the fourth output of the controller, the fifth output of which is through the fourth capacitor Connected to the first terminals of the first and second resistors, additionally contains an amplifier, a second diode and a third resistor, the first terminal of which is connected to the sixth output of the controller and the input of the amplifier, to the output of which a piezoelectric emitter is connected, the amplifier power leads are connected to the terminals of the second capacitor, the second terminal of the first the resistor is connected to the third input of the controller, and the second output of the third resistor is connected to the second output of the second resistor and through the second diode to the first output of the second resistor.

The figure shows a block diagram of an autonomous smoke detector.

The self-contained smoke detector contains a battery 1, a controller 2, a first capacitor 3, a smoke sensor chamber 4, a photodiode 5, 6, an infrared emitting diode, a second capacitor 7 and a choke 8, a first diode 9, a third capacitor 10, an optical indicator 11, and a fourth a capacitor 12, three resistors 13, 14 and 15, a second diode 16, a low-frequency amplifier 17 and a piezoelectric emitter 18.

Controller 2 contains a 2/1 pulse generator, a 2/2 logic unit, a 2/3 photoelectric amplifier, a 2/4 voltage-current converter, two transistor switches 2/5 and 2/6, as well as two logical elements 2I-NOT 2/7 and 2/8.

The positive and negative terminals of the power battery 1 are connected respectively to the first and second terminals of the power supply of the controller 2 and the first capacitor 3. The photodiode 5 of the camera 4 of the smoke sensor is connected to the first and second inputs of the controller 2, the first and second outputs of the controller 2 are connected respectively to the anode and cathode emitting infrared diode 6 camera 4 smoke sensor. The anode of the emitting infrared diode 6 through the second capacitor 7 is connected to the negative terminal of the power battery 1 and the first terminal of the third capacitor 10, the second terminal of which is connected to the first terminal of the optical indicator 11 and the cathode of the first diode 9, the anode of which is connected to the third output of the controller 2 and through the inductor 8 with a positive battery terminal 1. The second terminal of the optical indicator 11 is connected to the fourth output of the controller 2, the fifth output of which through the fourth capacitor 12, to the first terminals of the first and second resistors 13 and 14. In addition, the detector contains a low-frequency amplifier 17, a second diode 16 and a third resistor 15, the first output of which is connected to the sixth output of the controller 2 and the input of the low-frequency amplifier 17, to the output of which a piezoelectric emitter 18 is connected, the power leads of the low-frequency amplifier 17 are connected to the terminals of the second capacitor 10, the second terminal of the first resistor 13 is connected to the third input of the controller 2, and the second terminal of the third resistor 15 is connected to the second terminal of the second resistor 14 and through the second diode 16 to the first terminal of the second resistor 14.

The output of the 2/1 pulse generator is connected to the first input of the logic 2/2 block of controller 2. The output of the photoelectric amplifier 2/3 is connected to the second input of logic 2/2, the inputs of which are the first and second inputs of controller 2. The first output of block 2/2 logic connected to the input of the Converter 2/4 voltage-current, the outputs of which are the first and second outputs of the controller 2. The second output of the block 2/2 logic is connected through the first transistor switch 2/5 to the third output of the controller 2. The third output of the block 2/2 logic connected through a second transistor the second key 2/6 to the fourth output of controller 2. The fourth output of block 2/2 of the logic is connected to the first inputs of logic elements 2I-NOT 2/7 and 2/8, the outputs of which are the fifth and sixth outputs of controller 2, respectively. The second input of the second logical element 2I-NOT 2/8 is connected to the output of the first logic element 2I-NOT 2/7, the second input of which is connected to the third input of the controller 2.

Autonomous smoke detector works as follows. The detectors are located indoors in the places of the most likely occurrence of fire and smoke accumulation. When connecting the battery 1 power to the controller 2 through its conclusions Vdd and Vss supplied voltage. The 2/1 pulse generator starts to work, from which the pulses arrive at the first input of the 2/2 block of the logic. At the second output of the logic block 2/2, pulses begin to appear, through the first transistor switch 2/5 they go to the inductor 8. The self-induction emf created on this inductor 8 charges the third capacitor 10 through the first diode 9. Thus, the low voltage of the amplifier 17 frequency, the optical indicator 11 and the output of the controller 2 is supplied with a voltage Vbst, which is 2.5-3 times higher than the voltage Vdd of the battery 1 power. At the first output of the logic block 2/2, pulses of several hundred microseconds duration appear through the 2/4 voltage-current converter to the inputs of the emitting infrared diode 6. Once in a few seconds, the current passes through the emitting infrared diode 6 the value of which significantly exceeds the average value of the current that the converter consumes 2/4 voltage-current from the battery 1 power. The infrared light of the emitting diode 6 scattered in the chamber 4 of the smoke sensor enters the photodiode 5, and the photo-emf through the first and second inputs of the controller 2 enters the inputs of the photoelectric amplifier 2/3. After amplification, the signal is fed to the second input of the 2/2 block logic. If this signal reaches the set value, then pulses synchronous with the pulses that appear on the first output of this logic block 2/2 will appear on the second input of the logic block 2/2. If the value of the optical density of air is in a normal state, then the output of the photoelectric amplifier 2/3 will have a small signal, and therefore, a short-time signal will be generated at the third output of the logic block 2/2 once in a few minutes, through the second transistor switch 2/6 and the fourth output of controller 2 activates the optical indicator 11. When the smoke level reaches the set level, i.e. with an increase in the optical density of air at the detector location, the scattered radiation intensity increases, and pulses will periodically arrive at the second input of the 2/2 logic unit. In this case, first, pulses with a frequency of about 1 Hz begin to form on the third output of the logic block 2/2, which arrive at the optical indicator 11, and after several confirmations that the pulses from the output of the photoelectric amplifier 2/3 arrive synchronously with the pulses at the first output of the controller 2, the logic block 2/2 begins to form pulses at its fourth output, which are fed to the first inputs of logic elements 2/7 and 2/8. By connecting the fourth capacitor 12 and three resistors 13, 14 and 15 and the second diode with the outputs of two logic elements 2I-NOT 2/7 and 2/8, as well as the second input of the first element 2I-NOT 2/7, an audio signal is generated which is fed to the input of the low-frequency amplifier 17 and further to the piezoelectric emitter 18, which will convert electrical vibrations into acoustic ones. Thus, when a fire is detected by the detector itself, an intermittent sound frequency signal will be reproduced by the piezoelectric emitter 18, and both the current of the low-frequency amplifier 17 and the sound signal power will depend on the duty cycle of the electrical pulses. The optimal ratio of the sound signal power to the current consumption of the low-frequency amplifier 17 and the entire detector in the fire alarm mode depends on the choice of the ratio of the resistances of the second and third resistors.

Claims (1)

A self-contained smoke detector containing a battery, a controller, an optical indicator, a smoke sensor chamber with a radiating infrared diode and a photodiode, a piezoelectric emitter, two resistors and four capacitors, plus and minus terminals of the battery are connected to the first and second terminals of the power supply of the controller and the first the capacitor, the photodiode of the smoke sensor chamber is connected to the first and second inputs of the controller, the first and second outputs of the controller are connected respectively to the anode and the method of the emitting infrared diode of the smoke detector chamber, the anode of which is connected through the second capacitor to the negative terminal of the battery and the first terminal of the third capacitor, the second terminal of which is connected to the third input of the controller, the first terminal of the optical indicator and the cathode of the first diode, whose anode is connected to the third output of the controller and through a choke with a positive battery terminal, the second terminal of the optical indicator is connected to the fourth output of the controller, the fifth output of which is connected through the fourth condensate p to the first conclusions of the first and second resistors, additionally contains an amplifier, a second diode and a third resistor, the first output of which is connected to the sixth output of the controller and the input of the amplifier, to the output of which a piezoelectric emitter is connected, the power leads of the amplifier are connected to the terminals of the second capacitor, the second terminal of the first the resistor is connected to the third input of the controller, and the second output of the third resistor is connected to the second output of the second resistor and through the second diode to the first output of the second resistor.