UA80313C2 - Smoke fire detector - Google Patents

Abstract

The proposed smoke fire detector would generate a fire alarm signal when the intensity of the scattering of the infrared radiation changes due to the increase of optical density of air induced by the presence of smoke. The fire detector contains a circuit consisting of a capacitor and a resistor connected in series. This circuit provides flashing of the light-emitting diode indicator of the smoke detector when the detector operates in a stand-by mode. As a result, the performance monitoring of the fire detector is possible without increasing consumed power.

Description

Description of the invention

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 based on the intensity of infrared radiation scattering.

There are known fire detectors, optical smoke sensors and smoke registration devices that 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 70 smoke (see the magazine "System! and security of communications and telecommunications", 2000, 33, p. 65).

The well-known photoelectric smoke detector

She rpoeyesigis. ER 0755037 Ah! (z08817/103 22.01.1997), containing a microcontroller, the first output of which is connected to the input of the smoke registration signal generator, a transistor switch, the output of which is connected to an emitter, connected through an optical camera with light-absorbing walls to a photodiode, the outputs of which are connected to inputs of the amplifier, the input of the microcontroller is connected to the output of the amplifier, and the outputs of the generator of the smoke detection signal are connected to the fire alarm loop through the terminals.

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 transistor key controlling the emitter are powered. In addition, such a photoelectric smoke detector does not have an indication of possible states: "FIRE" mode and regular operation mode.

Also known is the smoke fire detector |Izveshatel pozharnyi dmovoy optiko-zlectronny iIP212-67 (DYP-I) TU 4371-002-59069151-2002 m/mlm.Itsiv.gsh|, which contains a microcontroller, the first output of which is connected to the input of the first of a transistor key, the first output of which is connected to the first input terminal through an element of one-sided conduction, the first output of the capacitor is connected to the second input terminal, the cathode of the LED indicator 29, the first outputs of the power supply of the microcontroller and the current and voltage limiter, Go) the first output of the first resistor with connected to the emitter circuit of the second transistor key, the collector circuit of which is connected to the first output of the emitter 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 second power output of which is connected to the output of the limiter current and voltage, and the second output of the capacitor is connected to the output of the current and voltage limiter. The second output of the emitter is connected to the second input terminal. what

The second output of the first resistor is connected to the second power output of the microcontroller, the second and third outputs of which are connected through resistors to the input of the second transistor key. The fourth output of the microcontroller is connected through a resistor to the anode of the LED indicator. The second output of the first transistor key (c3) is connected to the second output of the current and voltage limiter. 325 The disadvantage of the known detector, which is powered by a two-conductor loop, is a high impulse current consumption. The pulse indication of the next operating mode is carried out due to the impulse current consumption directly from the loop fire alarm, which significantly reduces the number of detectors that can be simultaneously connected to the fire alarm loop. With such "pulse power supply organization with an increase in the number of detectors in one fire alarm loop Z, the probability of false activation of the receiving and control device on this loop significantly increases. c The most close to the proposed invention is the smoke fire detector 2151 chosen as a prototype:

From" company Zuviet Zepzog | Izveshatel pozharnyi dmovoi optiko-zlectronnyi 2151EE" TU 4371-001-52635653-00 mimlu. zuvietvzepsog.hy) containing a microcontroller, the first output of which is connected to the input of the first transistor key, the collector circuit of which is connected to the first 49 input terminal for connecting the slide 4) of the fire alarm, and the emitter circuit of the first transistor

The key is connected through the LED indicator to the second input terminal, to which the first outputs of the av! the power supply of the microcontroller, the current and voltage limiter, as well as the first outputs of the first resistor, the first and second capacitors and, the second output of the first resistor is connected to the emitter circuit of the second o transistor key, the input of which is connected to the second output of the microcontroller, the second power output - 20 of the microcontroller 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 first output of the emitter, the second output of which is connected to the collector circuit of the second transistor switch, the emitter is optically connected connected through an optical camera with light-absorbing walls to a photodetector, the output of which is connected to the input of the microcontroller. 29 The disadvantage of the prototype is the low probability of control due to the impossibility of visual indication of operability

GF) of the detector in the regular mode of operation. The lack of a visual indication of the device's performance leads to the need for excessively frequent control of the fire alarm system's performance by other, more time-consuming methods.

The invention is based on the task of providing a visual indication of the functionality of the detector in the 60-shift mode of operation without increasing the current consumption by creating conditions for the pulse mode of the LED indicator, which makes it possible to increase the probability of monitoring the functionality of the device.

The task is solved by the fact that a smoke fire detector containing a microcontroller, the first output of which is connected to the input of the first transistor switch, the collector circuit of which is connected to the first input terminal for connecting the loop of the fire alarm, or rather the emitter circuit of the first transistor key is connected through the LED indicator to the second input terminal, to which the first terminals of the microcontroller power supply, current and voltage limiter, as well as the first terminals of the first resistor, the first and second capacitors, the second terminal of the first resistor is connected to the emitter circuit of the second transistor key, the input of which is connected to the second output of the microcontroller, the second power output of the microcontroller 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 first output of the emitter, the second output of which is united ny with the collector circuit of the second transistor key, the emitter is optically connected through an optical camera with light-absorbing walls to the photoreceiver, the output of which is connected to the input of the microcontroller, according to the invention, additionally contains 70 serial KS-circuit connecting the emitter circuits of the first and second transistor keys.

In the proposed device, due to the use of a serial CS-chain with its connections to other elements, the formation of short light flashes with long intervals between these flashes is ensured by the LED indicator in the alternate mode of operation. By this optical signal, it is possible to judge the operability of such a smoke fire detector and the presence of power supply voltage on the loop of fire /5 signalization, to which this smoke fire detector is connected. At the same time, the current consumption by the detector does not increase, because the proposed solution provides for current separation in the discharge circuit of the first capacitor without changing the value of the current pulse passing through the emitter.

Thus, the use of the proposed design makes it possible to increase the probability of monitoring the functionality of the detector without increasing the current consumption, which increases the reliability of the device as a whole.

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 first transistor switch 2, the collector circuit of which is connected to the first input terminal 4 for connecting the loop of the fire alarm through the single-sided conductivity element. The emitter circuit of the first transistor key 2 is connected through the LED indicator 5 to the second input terminal 6. The first terminals of the power supply of the microcontroller 1, the current and voltage limiter 7, as well as the first terminals of the first resistor 8, the first and the second are connected to this second terminal 6 capacitors В and 10. The second output of the first resistor 8 i) is connected to the emitter circuit of the second and transistor key 11, the input of which is connected to the second output of the microcontroller 1. The second power output of the microcontroller 71 is connected to the second output of the first capacitor 9 and to the first output of the limiter 7 of current and voltage, the second output of which is connected to the second output of the second capacitor 10 and the first output of the emitter 12. The second output of the emitter 12 is connected to the collector circuit of the second transistor switch 11. The emitter 12 is optically connected through - - an optical camera 13 with light-absorbing walls with a photoreceptor 14. The output of the photoreceptor 14 is connected to the input of the microcontroller Figure 1. The series CS circuit 15 contains a second resistor 16 and a third capacitor 17, the first terminals of which are connected to each other, and the second terminals of the second resistor 16 and the third capacitor 17 are connected to the emitter circuits of the first and second transistor keys, respectively 2 and 11. So

A smoke fire detector works in the following way. When the supply voltage is applied to input terminals 4 and 6, the first and second capacitors 9 and 10 are charged through the one-sided conduction element Z and the current and voltage limiter 7. The one-sided conduction element Z protects other elements of the smoke fire alarm when the polarity of the supply voltage of the fire alarm loop is mistakenly connected signaling 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 outputs and two transistor switches 2 and 11 will be turned off. After reaching the minimum value of the operating voltage, 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 V to a value that does not exceed the maximum value of the operating voltage of the microcontroller 1.

The charge accumulated on the second capacitor 10 will ensure the next stable operation of the emitter

Go! 12. After this delay, pulses of stable amplitude with a duration of several tens of microseconds will arrive at the input of the second transistor switch 11. The second transistor switch 11 provides not only the formation of current pulses of stable amplitude through the emitter 12, but also current pulses through the LED 2) indicator 5, due to the presence of CS-chain 15. This ensures the indication of the next mode of operation. With a stable periodicity of about 1 s, the LED indicator 5 will flash for a short time, which indicates - that the detector has entered the next mode of operation, that is, that the detector has power supply and 4) microcontroller 1 is working.

The second transistor switch 11 ensures the discharge of the second capacitor 10 with a stable amount of current through the emitter 12. The amount by which the second capacitor 10 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 on the current ratio charge of the second capacitor 10 through the current and voltage limiter 7 to the discharge current (F) of this capacitor 10 through the second transistor key 11. Thus, the voltage established across the second capacitor 10 will provide the necessary voltage drop on the first resistor 8, the second transistor key 11 and on the emitter 12. Due to the use of two storage capacitors 9 and 10, as well as separate circuits of their charge from the current and voltage limiter 7, stable operation of the detector is ensured. Short-term voltage drops at the terminals of the second capacitor 10 at the moment of its discharge by the second transistor key 11 will not change the potential difference on the terminals of the first capacitor 9, i.e. between the power terminals of the microcontroller.

Scattered by the optical camera 13 with light-absorbing walls, the infrared radiation 65 of the emitter 12 enters the photoreceiver 14. 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 13. Yes with absolute transparency of the air, a background signal will be present at the output of the photodetector 14: low-amplitude pulses, because there will be some reflection from the walls of the optical chamber 13. As the optical density of the air in the optical chamber 13 increases, the amplitude of the pulses at the output of the photodetector 14 will increase. Until the amplitude of these pulses reaches the set limit value, the state at the outputs of the microcontroller 1 will not change. A low potential level will remain at the input of the first transistor switch 2, so this switch 2 will be closed. The detector will remain in the standby mode, consuming from the loop of the fire station alarm system m, the value of which is limited by the current and voltage limiter 7. 70 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 at the first output, at which the first transistor switch 2 will open, a current will flow through the LED indicator 5, 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 second transistor switch 11 will be closed. The second capacitor 10 will not discharge through the emitter 12.

Due to the current flowing through the first transistor switch 2, the potential difference between terminals 4 and 6 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 5, because the CS-chain 15 will not have a shunting effect with a constant voltage on the LED indicator 5. It is possible to remove the detector from this state only by disconnecting the power supply voltage of the fire alarm loop (voltage between input terminals 4 and 6) for a time sufficient to discharge the first capacitor 9 to the value at which the voltage below the minimum worker is established at the power inputs of the microcontroller 1.

Due to the introduction of an additional CS-chain, an indication of the next working mode of the detector is provided, without increasing the current consumption in this mode. Thus, the use of the proposed design makes it possible to increase the probability of monitoring the functionality of the detector without increasing the current and) consumption, which increases the reliability of the device as a whole.

The new element - KS chain 15 - is widely known. Other elements correspond to the prototype. Microcontroller 1 with low current consumption can be the same as in the prototype, MC 145010 of the company "Moyogoia", or made on the microcircuits of the company MISKOSNIR, type RISTOR202 or similar.

Claims (1)

"- Formula of the invention and. "c) A smoke fire detector containing a microcontroller, the first output of which is the output of the "fire" mode and is connected to the input of the first transistor switch, the collector circuit of which is connected through the unidirectional conduction element to the first input terminal for connecting the fire alarm loop , and the emitter circuit of the first transistor key is connected through the LED indicator to the second input terminal, to which the first power outputs of the microcontroller, current and voltage limiter, as well as the first outputs " 70 of the first resistor, the first and second capacitors, the second output of the first resistor with connected to the emitter 73s circuit of the second transistor key, the input of which is connected to the second output of the microcontroller, which is the output of the "alternating mode of operation", the second output of the microcontroller's power supply is connected to the second output of the first capacitor and to the first output of the current and voltage limiter, the second power output of which is connected to the collector circuit of the first transistor key, and d the second output of the current and voltage limiter is connected to the second terminal of the second capacitor and the first terminal of the emitter, the second terminal of which is connected to the collector circuit of the second transistor switch, the emitter 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, ("which differs in that it additionally contains a serial CS circuit connecting the circuits of the emitters of the first and second transistor switches. - 50 siu" F) name) 60 b5