RU2459268C1 - Electric induction fire annunciator - Google Patents

Abstract

FIELD: instrument making.

SUBSTANCE: electric induction fire annunciator comprises a metering amplifier, a data processing unit, a supply unit, a high-voltage pulse generator and a metering line, comprising a discharge chamber, an induction electrode, and an aerosol flow exciter, and also comprises a controller of voltage supplied to the high-voltage pulse generator, and a resistive chain made of two serially connected resistors between an internal electrode - a needle of the charging chamber and a common wire, and connected in parallel to the resistor connected with the common wire, a capacitor and a stabilitron.

EFFECT: higher durability and provision of explosion safety of an annunciator due to preservation of permanent parameters of the charge chamber by means of stabilisation of a corona discharge current.

Description

The claimed invention relates to the field of instrument-making (measuring) equipment and is intended to detect in a guarded object an unusual or abnormal situation that can be classified as dangerous or fire hazard.

Currently, there are many devices that implement the electro-induction principle of measuring the parameters of the aerodisperse system. These include the devices described in A.S. USSR No. 340942 "Method for measuring the concentration of the dispersed phase of the aerosol", publ. in B.I. No. 18 for 1972; A.S. USSR No. 523333 "Device for continuous measurement of dustiness of gases", publ. in B.I. No. 28 for 1976; A.S. USSR No. 525007 "Device for measuring the bulk density of electric charges in gas", publ. in B.I. No. 30 for 1976; A.S. USSR No. 602829 "Device for measuring the volumetric density of charges of particles in a gas" publ. in B.I. No. 14 for 1978; A.S. USSR No. 1182557 "Method for detecting a fire hazard", publ. in B.I. No. 36 for 1985, etc.

The principle of operation of these devices is based on charging particles in the aerosol stream in the zone of a pulsed unipolar corona discharge and subsequent measurement of their total space charge by induction. The electro-induction principle of continuous control of aerosols has high sensitivity, speed and ease of use. Allows you to instantly register any changes in the concentration of aerosol particles of any color, chemical composition and size.

The closest in technical essence solution is the IP 213-32EI electric induction fire detector, described in the article “Possibility of early detection of a fire hazard on ships and coastal facilities of the fleet” in the journal “Marine Herald” No. 3 (27) for 2008, selected as a prototype . A well-known electric induction fire detector consists of a measuring amplifier, an information processing unit, a power supply unit, a high-voltage pulse generator and a measuring line containing a charging chamber, an induction electrode and an aerosol flow inducer.

The principle of operation of the prototype device is as follows.

The aerosol under study is pumped at a constant speed by the flow inducer through the measuring line. Passing through the charging chamber, aerosol particles are charged in a pulsed unipolar electric field of a corona discharge excited between the electrodes of the charging chamber by a high-voltage pulse generator. As a result, in the volume of aerosol that passed through the charging chamber during the corona discharge pulse, the particles receive an electric charge, and the aerosol flow is modulated by the density of the space charge. The total electric charge received by all particles located in a unit volume of the aerosol depends on their calculated concentration and size. Passing through an induction electrode, charged aerosol particles induce a charge on it, creating a voltage proportional to this charge at the input capacitance of the measuring amplifier, which is then amplified and subjected to logical processing.

The disadvantage of the prototype device is the dependence of the corona discharge current, which directly affects the efficiency of charging aerosol particles, on a number of factors:

- instability of the corona discharge current due to external factors (changes in temperature, pressure, humidity, the appearance of conductive dust) and changes in the geometric dimensions of corona electrodes due to erosion, or due to adhesion or diffusion during molecular interaction of the surface layer of electrodes with aerosol particles,

- ensuring the lowest possible energy consumption and wide dynamic range due to the minimum corona discharge current at which stable monitoring of aerosol particle concentrations is possible, starting from 0.01 mg / m ³ .

During the operation of the fire detector, it is highly likely that due to the above factors, the detector will lose its operability due to a drop in the corona current below the permissible value. This will lead to the decay of the corona, the disappearance of the ion flow in the charging chamber, the cessation of particle charging and the absence of a useful signal at the input of the measuring amplifier, and, being practically operational, the detector will lose its operability.

The described situation is possible due to the fact that in order to realize the maximum possible measurement range of the aerosol concentration and ensure the minimum signal level in clean rooms, the operating point for low aerosol concentrations is located at the very edge of the range. This is achieved by selecting the minimum value of the corona discharge current necessary to obtain a stable useful signal at the output of the measuring amplifier.

In addition, if there is conductive dust in the charging zone or a sudden surge in power supply, a spark breakdown between the electrodes is possible, which in the presence of combustible gases in the air can lead to an explosion.

The present invention aims to eliminate the above disadvantages.

It is known (see Mirzabekyan GZ “Charging aerosols in the field of corona discharge.” - In the book “Strong electric fields in technological processes.” - M .: Energy 1969, pp. 20-39.) That aerosol particles during charging, a charge is received in the corona discharge field, which is the sum of the shares acquired according to the drift and diffusion laws. The magnitude of these fractions directly depends on the density of the ion flux between the electrodes of the corona discharge, or, which is the same thing, the current of the corona discharge.

Preserving the constancy of the parameters of the charging chamber, due to stabilization of the corona discharge current, will increase the detector's durability and ensure its explosion safety, avoiding spark breakdown.

The invention consists in the following.

An electric induction fire detector consisting of a measuring amplifier, an information processing unit, a power supply unit, a high-voltage pulse generator and a measuring line containing a charging chamber, an induction electrode and an aerosol flow inducer, in contrast to the prototype, contains a voltage regulator whose output is connected to the input of the high-voltage pulse generator , and the input with the power supply, and a resistive chain consisting of two series-connected resistors between the internal electrode is a charge needle hydrochloric chamber and a common wire and connected in parallel with the resistor connected to the common wire, a capacitor and a zener diode, and the common point of resistors connected to the control input of the voltage regulator.

The invention is illustrated in the drawing, figure 1, which shows a structural diagram of an electric induction fire detector and introduced the following notation.

1. High voltage pulse generator.

2. Voltage regulator.

3. The power supply.

4. Measuring amplifier.

5. Information processing unit.

6. The external electrode is the ring of the charging chamber.

7. The inner electrode is the needle of the charging chamber.

8. Capacitor.

9. Resistor.

10. Resistor.

11. The zener diode.

12. The induction electrode.

13. LED.

14. The driver of aerosol consumption.

F - The output signal.

The electro-induction fire detector contains a measuring line in which a charging chamber is installed in series with the aerosol flow (consisting of an external electrode - ring 6 and an internal electrode - needle 7), an induction electrode 12 and an aerosol flow inducer 14. The output of the high-voltage pulse generator 1 is connected to the external electrode - the ring 6 of the charging chamber, and the input to the voltage regulator 2. The internal electrode - the needle 7 of the charging chamber, through series-connected resistors 9 and 10, is connected to a common wire y (earth). In parallel to the resistor 10, a capacitor 8 and a zener diode 11 are connected. A common connection point of the resistors 9 and 10 is connected to the control input of the voltage regulator 2, the input of which is supplied with voltage from the power supply 3. The input of the measuring amplifier 4 is connected to the induction electrode 12, and the output to the processing unit information 5. The measuring amplifier 4, the information processing unit 5 and the aerosol flow inducer 14 are connected to the power supply 3.

Electro-induction fire detector operates as follows.

The aerosol flow inducer 14 provides a continuous and constant flow of air containing aerosol through the measuring line. Passing through the charging chamber (consisting of electrodes ring 6 and needle 7), in which a unipolar pulsed corona discharge is carried out, the flow acquires a volumetric electric charge proportional to the concentration of particles during the pulse. Further, passing through the induction electrode 12, the flow induces a charge on it, the variable component of which is proportional to the volume electric charge. The measurement is carried out according to the voltage created by the induced charge on the input capacitance of the measuring amplifier 4 with subsequent processing of the induced charge in the information processing unit.

The output signal of the information processing unit 5 - F, is used for communication with the control panel. LED 13 is used for external indication of the status of the fire detector.

The power supply 3 provides the necessary voltage supply voltage regulator 2, measuring amplifier 4, the information processing unit 5 and the flow driver 14.

Voltage regulator 2 maintains the supply voltage of the high-voltage pulse generator 1 at the level necessary to provide the required corona discharge current (ion flux density) in the charging chamber. This is done by stabilizing, using the voltage regulator 2, the voltage drop across the resistor 10, which is proportional to the corona current through the charging chamber or the ion flux density. The capacitor 8 serves to smooth the ripple of high voltage and, accordingly, the corona current. The zener diode 11 serves to protect the input stage of the voltage regulator 2 from the inrush current at the moment of ignition of the crown, while the stabilization voltage of the zener diode 11 is chosen larger than the voltage drop that needs to be stabilized on the resistor 10. If the magnitude of the corona is increased or decreased for one reason or another current through the charging chamber, the voltage drop across the resistor 10 will change, which will lead to changes in the output of voltage regulator 2, which feeds the high-voltage pulse generator in the direction of compensation tion of the changes.

Thus, the corona discharge current (ion flux density) in the charging chamber is stabilized and the task of increasing the durability of the fire detector and its fire and explosion safety is achieved.

As follows from the foregoing, the achievement of a technical result, namely: the detection of a non-standard or abnormal situation in a guarded facility that can be classified as dangerous or fire hazard, for a long time without additional routine maintenance, and ensuring fire and explosion safety by the detector itself, is ensured by that stabilization of the corona discharge current is carried out. This ensures a significant increase in the life of the detectors and the expansion of their scope in fire and explosion hazard zones.

In addition, the proposed device is suitable for monitoring any aerosol pollution in a guarded object, an unacceptable change which can lead to a non-standard or emergency situation.

Claims (1)

An electric induction fire detector, consisting of a measuring amplifier, an information processing unit, a power supply unit, a high-voltage pulse generator and a measuring line containing a charging chamber, an induction electrode and an aerosol flow inducer, characterized in that a voltage regulator is introduced into it, the output of which is connected to the input of the high-voltage pulse generator, and the input with a power supply, and a resistive chain consisting of two series-connected resistors between the internal electrode - the needle a charging chamber and a common wire and connected in parallel with a resistor connected to a common wire, a capacitor and a zener diode, and the common point of the resistors is connected to the control input of the voltage regulator.

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