RU2305325C1 - Smoke fire alarm - Google Patents

Abstract

FIELD: fire signaling, possible use in fire signaling systems to detect increase of optical density of air based on intensiveness of infrared radiation dissipation.

SUBSTANCE: in accordance to the invention, smoke fire alarm, which contains microcontroller 1, two transistor keys 2,11, one-sided conductivity element 3, two input clamps 4,6 for connecting fire alarm loop, light diode indicator 5, current and voltage limiter 7, resistor 8 and two capacitors 9,10, emitter 12, optical chamber 13 with light-absorbing walls, photo-receiver 14, additionally contains a serial RC-circuit 16,17, which connects circuits of emitters of first 2 and second 11 transistor keys. In suggested device due to usage of serial RC-circuit with its connection to other elements, creation of short light flashes is ensured in standby operation mode by light diode indicator 5, with extensive intervals between these flashes.

EFFECT: increased trustworthiness of alarm serviceability without increased current consumption of device as a whole.

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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.

Known fire detectors, optical smoke detectors and smoke detectors operating on the principle of periodic emission of infrared radiation pulses and their subsequent reception, amplification and processing of the received signal in various ways, generating a signal about the presence or absence of smoke (see the journal "Communication and Telecommunication Security Systems" , 2000, 33, p. 65).

Known photoelectric smoke detector [Photoelectric smoke detector and disaster monitoring system using the photoelectric. EP 0755037 A1, G08B 17/103, 01/22/1997], containing a microcontroller, the first output of which is connected to the input of the signal generator of the smoke detection signal, a transistor switch, to the output of which is connected an emitter connected through an optical camera with light-absorbing walls with a photodiode, the terminals of which are connected to the inputs of the amplifier, the input of the microcontroller is connected to the output of the amplifier, and the outputs of the shaper of the smoke registration 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 should contain a separate power supply bus, from which the microcontroller and the transistor switch that controls the emitter are powered. In addition, such a photoelectric smoke detector does not have an indication of the possible states: the “FIRE” mode and the standby mode.

Also known is a smoke fire detector [Optoelectronic smoke fire detector IP212-67 (DIP-I) TU 4371-002-59069151-2002, www.luis.ru], containing a microcontroller, the first output of which is connected to the input of the first transistor switch, the first whose output is connected through a single-sided conduction element to the first input terminal, the first capacitor terminal, the cathode of the LED indicator, the first power terminals of the microcontroller and the current and voltage limiter, the first terminal of the first resistor are connected to the second input terminal is connected to the emitter circuit of the second transistor switch, the collector circuit of which is connected to the first output of the emitter connected via an optical camera with light-absorbing walls to a 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 current and voltage limiter, and the second output of the capacitor connected to the output of the current and voltage limiter. The second output of the emitter is connected to the second input terminal. The second terminal of the first resistor is connected to the second power terminal of the microcontroller, the second and third outputs of which are connected through resistors to the input of the second transistor switch. 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 switch is connected to the second terminal of the current and voltage limiter.

A disadvantage of the known detector, the power of which is carried out from a two-wire loop, is the high pulsed current consumption. The pulse indication of the standby mode of operation is carried out due to the pulsed current consumption directly from the fire alarm loop, which significantly reduces the number of detectors connected simultaneously to the fire alarm loop. With such an organization of switching power supply with an increase in the number of detectors in one fire alarm loop, the likelihood of false positives of the receiving and control device for such a loop increases significantly.

Closest to the proposed invention is the selected as a prototype smoke detector 2151E from System Sensor (“Optical smoke electronic smoke detector 2151E” TU 4371-001-52635653-00 www.systemsensor.ru) containing a microcontroller, the first output of which is the output "fire" mode and is connected to the input of the transistor switch, the collector circuit of which is connected via a one-way conductor to the first input terminal for connecting the fire alarm loop, and the emitter circuit of the first transistor switch is connected via The LED indicator is connected to the second input terminal, to which the first power leads of the microcontroller, the current and voltage limiter, as well as the first leads of the first resistor, the first and second capacitors, and the second lead of the first resistor are connected to the emitter circuit of the second transistor switch, the input of which is connected to the second the output of the microcontroller, which is the output of the "standby mode", the second power output of the microcontroller is connected to the second output of the first capacitor and to the first the output of the current and voltage limiter, the second output of which is connected to the collector circuit of the first transistor switch, and the second output of the current and voltage limiter 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 coupled through an optical camera with light-absorbing walls with a photodetector, the output of which is connected to the input of the microcontroller.

The disadvantage of the prototype is the low reliability of the control due to the impossibility of a visual indication of the health of the detector in standby mode. The lack of a visual indication of the operability of the device leads to the need for excessively frequent monitoring of the operability of the fire alarm system by other more labor-intensive methods.

The basis of the invention is the task: to provide a visual indication of the detector’s operability in standby mode without increasing the current consumption by creating conditions for a pulsed mode of operation of the LED indicator, which improves the reliability of monitoring the device’s operability.

The problem is solved in that the smoke detector, 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 a one-way conductor to the first input terminal for connecting the fire alarm loop, and the emitter circuit of the first transistor the key through an LED indicator is connected to the second input terminal, to which the first power leads of the microcontroller, the current and voltage limiter, and 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 switch, the input of which is connected to the second output of the microcontroller, which is the output of the "standby mode", the second power output of the microcontroller is connected to the second terminal 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 switch, and the second output of the current limiter and voltage 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 coupled through an optical camera with light-absorbing walls to a photodetector, the output of which is connected to the input of the microcontroller, according to the invention, further comprises a serial RC -chain that connects the emitter circuit of the first and second transistor switches.

In the proposed device due to the use of a series-connected RC-circuit with its connections with other elements, the formation of the LED indicator of short light flashes with long intervals between these flashes in standby mode of operation is provided. By this optical signal, it is possible to judge the operability of this smoke detector and the presence of a supply voltage on the fire alarm loop to which this smoke detector is connected. At the same time, the consumed current by the detector does not increase, since the proposed solution provides for the separation of current in the discharge circuit of the first capacitor, without changing the magnitude of the current pulse flowing through the emitter. Thus, the use of the proposed design allows to increase the reliability of monitoring the health of the detector without increasing the current consumption.

The drawing shows a block diagram of a smoke detector.

The smoke 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 through the element 3 of one-sided conductivity to the first input terminal 4 for connecting the fire alarm loop. The emitter circuit of the first transistor switch 2 is connected via a LED indicator 5 to the second input terminal 6. The first power terminals of the microcontroller 1, current and voltage limiter 7, as well as the first conclusions of the first resistor 8, first and second capacitors 9 and 10 are connected to this second terminal 6 The second terminal of the first resistor 8 is connected to the emitter circuit of the second transistor switch 11, the input of which is connected to the second output of the microcontroller 1. The second power terminal of the microcontroller 1 is connected to the second terminal of the first the capacitor 9 and to the first output of the current and voltage limiter 7, 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 photodetector 14. The output of the photodetector 14 is connected to the input of the microcontroller 1. A series-connected RC circuit 15 contains a second resistor 16 and a third capacitor 17, the first conclusions of which are connected ezhdu themselves, and second terminals of the second resistor 16 and third capacitor 17 connected to the emitter circuits of the first and second semiconductor switches 2 and 11.

Smoke detector works this way. When a supply voltage is supplied to the input terminals 4 and 6 through the one-way conduction element 3 and the current and voltage limiter 7, the first and second capacitors 9 and 10 are charged. One-way conduction element 3 protects other elements of the smoke detector when the polarity of the power supply cable is incorrectly connected alarm. While the voltage at the power leads is insufficient for the normal operation of the microcontroller 1, low potential voltage levels are held at its outputs and two transistor switches 2 and 11 will be turned off. After reaching the minimum value of the operating voltage, the microcontroller 1 carries out a program delay of the start of work with minimal current consumption. This delay ensures a guaranteed voltage output on the first capacitor 9 by 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 subsequent stable operation of the emitter 12. After this delay, short pulses with a duration of several tens of microseconds of stable amplitude will go to the input of the second transistor switch 11. The second transistor switch 11 provides not only the formation of current pulses stable hydrochloric amplitude through the radiator 12, but also the current pulses through the LED 5 due to the presence of RC-circuit 15. This provides indication standby mode. With a strict periodicity of about 1 second, LED 5 will flash for a short time, which indicates that the detector is in standby mode, that is, that the detector is supplied with a supply voltage, and microcontroller 1 is operating.

The second transistor switch 11 provides the discharge of the second capacitor 10 with a stable amount of current through the emitter 12. The value 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 the ratio of the charge current of the second capacitor 10 through the current and voltage limiter 7 to the discharge current of this capacitor 10 through the second transistor switch 11. Thus, a steady voltage drop across the second capacitor 10 will ensure ivat required voltage drop across the first resistor 8, a second switching transistor 11 and emitter 12. By using two storage capacitors 9 and 10, as well as separate chains from their charge current and voltage limiter 7, stable operation is ensured by the detector. Short-term voltage drops at the terminals of the second capacitor 10 at the time of its discharge by the second transistor switch 11 will not change the potential difference at the terminals of the first capacitor 9, that is, between the power terminals of the microcontroller 1.

The infrared radiation of the emitter 12 scattered by the optical camera 13 with light-absorbing walls is fed to the photodetector 14. After amplification, the photo-emf pulses are processed by the microcontroller 1. The signal fed to the input of the microcontroller 1 will substantially depend on the optical density of the air in the optical chamber 13. Thus, with absolute transparency of air at the output of the photodetector 14 there will be a background signal: pulses of small amplitude, since there will be some reflection from the walls of the optical camera 13. As increasing the optical density of air in the optical chamber 13 will increase the amplitude of the pulses at the output of the photodetector 14. Until the amplitude of these pulses reaches the set threshold value, the state at the outputs of the microcontroller 1 will not change. At the input of the first transistor switch 2, a low potential level will remain, which means that this switch 2 will be closed. The detector will remain in standby mode, consuming current from the fire alarm loop, the value of which is limited by the current and voltage limiter 7.

If the amplitude of the photo-emf pulses exceeds the threshold value, and if such a signal level appears at the input of the microcontroller 1 several times in a row, for example 4, then the states at its outputs will change. At the first output, a high potential level appears, at which the first transistor switch 2 opens, a current flows through the LED indicator 5, which will ensure the formation of the “FIRE” state in the fire alarm loop. At the second output of the microcontroller 1, a low potential level is established. The second transistor switch 11 will be closed. The second capacitor 10 will not be discharged through the emitter 12. Due to the current flowing through the first transistor switch 2, the potential difference between terminals 4 and 6 decreases sharply. If this voltage drop exceeds the minimum operating voltage of the microcontroller 1, then the detector will be in the state " FIRE »infinitely long. Almost the entire current consumed by the detector in the “FIRE” mode will flow through the LED indicator 5, since the RC circuit 15 will not have a shunting effect with a constant voltage drop 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 loop alarm (voltage between input terminals 4 and 6) for a time sufficient to discharge the first capacitor 9 to a value at which a voltage below m is established at the power inputs of the microcontroller 1 minimality worker.

By introducing an additional RC circuit, the standby mode of the detector is provided without increasing the current consumption in this mode. Thus, the use of the proposed design allows to increase the reliability of monitoring the health of the detector without increasing the current consumption.

The newly introduced element, the RC circuit 15, is widely known. The remaining elements correspond to the prototype. Microcontroller 1 with low current consumption can be the same as in the prototype, or MC145010 from Motorola, or made on microchips from MICROCHIP type PIC10F202, or similar.

Claims (1)

A smoke detector that contains 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 a one-way conductor to the first input terminal for connecting the fire alarm loop, and the emitter circuit of the first transistor switch the LED indicator is connected to the second input terminal, to which the first power leads of the microcontroller, the current and voltage limiter, as well as the 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 switch, the input of which is connected to the second output of the microcontroller, which is the output of the "standby mode", the second power output of the microcontroller is connected to the second terminal 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 switch, and the second output of the current limiter and voltage 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 through an optical camera with light-absorbing walls to a photodetector, the output of which is connected to the input of the microcontroller, characterized in that it further comprises a serial RC -chain that connects the circuit of the emitters of the first and second transistor switches.