SU886024A1 - Fire indicator - Google Patents

Description

I

The invention relates to fire alarm devices and can be applied in digital automatic smoke alarm systems.

Known ionization fire detectors containing connected in series measuring and reference ionization chamber, which are connected to the recording unit and alarm J.

The disadvantage of fire detectors is that they are sensitive to destabilizing factors (ambient pressure, temperature and

.D.)

The closest technical solution to the present invention is a device comprising serially connected measuring and reference ionization chambers, which are connected to a temperature stabilization unit made on a voltage divider and a transistor t2.

The disadvantage is the sensitivity to changes in environmental pressure, which reduces the reliability of the device.

The purpose of the invention is to increase the reliability of the device.

Claims (2)

The goal is achieved in that the keys, pulse generator, null organ, And element and reversible code counter, the external electrode of the reference chamber are sectioned, each section of which is connected to a fire detector containing serially connected measuring and reference ionization chambers and a voltage divider. through the corresponding key, one power supply bus is connected, the control input of each key is connected to the corresponding output of the reverse code counter, the counting input of which It is connected to the output of the element I, one input of which is connected to the output of the pulse generator, and the other input to one of the outputs of the null organ, the other output of which is connected to the control input of the reversible code counter, one input of the null organ to the common point of both ionization chambers, the second input of the null organ is connected to a voltage divider, and the external electrode of the measuring ionization chamber is connected to another power supply bus. The drawing shows the block diagram of the fire detector. The device contains a measuring ionization chamber 1, connected in series with the reference chamber 2, a null organ 3, the first input of which is connected to the common point of both chambers, an And k element, a pulse generator 5, a reversible code counter 6, a section 7 of the external electrode of the reference ionization chamber , keys 8 and a voltage diode on a zener diode 9. The fire detector works as follows. In the absence of smoke, the ionization currents generated by sources of radiation emit through the measuring and reference ionization chambers 1 and 2 and these cameras. The geometric dimensions of the chambers and the interelectrode distances in them are selected in such a way that the supply voltage is distributed equally between the chambers. In this connection, the voltage at the common point of both chambers is equal to the voltage of the common point of the Zener diodes 9. In this case, a voltage balance occurs at the input of the zero-organ 3, the voltage at its output is zero, and the pulses of the generator 5 pulses through the element I It does not pass to the input of the reversible code counter 6. This initial position of the circuit corresponds to the maximum or low current of the ionization chambers 1 and 2 and, therefore, to the maximum code at the output of the reversible code counter 6 in the forward code and the minimum in the reverse code. If in the measuring ionization chamber 1 a certain concentration of smoke is created, its ionization resistance will increase and the magnitude of the ionization current through this chamber will decrease. This will lead to a change in the voltages between the ionization chambers 1 and 2, as a result of which there is no voltage unbalance at the input of the null organ 3 of the firing and along the switch 4. 4, The voltage at its outputs. The AND element will open and the generator input of the reverse code counter 6 will begin to receive pulses from the generator 6 of the pulses 5. A signal will appear at the input controlling the counting direction that will switch it to read mode. Then the number accumulated in the reversible code counter 6 will begin to decrease in the direct code and control inputs of the keys 8 will receive signals which, as the code is reset, will disconnect the corresponding electrode 7 of the external electrode of the reference ionization chamber 2 from the power source. the ionization current taken through the keys 8 is reduced. This process will continue until the equilibrium of the currents of both chambers and, consequently, the balance of the voltages at the input of the zero-body 3, is equal to. Balance of the voltages at the input The ul-organ will cause the element 4 to be locked, as a result of which a direct code will be set at the output of the reversible code counter 6 proportional to the number of the included sections 7 (the increment of the return code corresponds to the concentration of smoke in the measuring ionization chamber 1. If the smoke of the measuring ionization chamber 1 will begin to decrease, its current will begin to rise, the voltage at the output of the null organ 3 will change sign, the element I will open, and a pulse will begin to arrive at the counting input of the reversible code counter 6 s pulse generator 5. Since the output of the zero-body 3 acts as a voltage in the reverse phase, the input to the control input to the counter of the reverse code counter 6 is transferred to the addition mode. At the output of the reversible code counter 6, the direct code will begin to increase, as a result of which the previously disconnected keys 8 will turn on and the supply voltage will start to be supplied to the section 7 of the external electrode of the reference ionization chamber 2, which were previously in the disconnected state. The current of this chamber 2 will increase to the onset of the balance of the currents of both chambers and, therefore, the disappearance of the voltage at the output of the null organ 3. The new code value at the output of the reversible code counter 6 will correspond to the new concentration smoke in the measuring ionization chamber. Possible changes in ambient temperature and pressure will cause identical changes in the currents of both chambers, which will not disperse them and, consequently, will cause a voltage at the output of the zero-body 3. The digital code does not depend on changes in temperature and pressure of the environment, i.e. It has a higher reliability of operation, which allows to reduce the likelihood of spurious insertions of fire extinguishing equipment. Claims of Invention A fire detector comprising measuring and reference ionization chambers connected in series and a voltage divider, differing from the fact that, in order to increase reliability of operation, keys, an impulse zero-organ, an element And a reversible code counter, and an external electrode are installed in it. This chamber chamber is sectioned, each section of which is connected via a corresponding key to one power supply line, the control input of each key is connected to the corresponding output of the reversing cable ov counter, the counting input of which is connected to the output of the element I, one input of which is connected to the output of the pulse generator, and the other input - to one of the outputs of the zero-body, the other output of which is connected to the control input of the reversible code counter, one input of the zero-body connected to the common point of both ionization chambers; the second input of the null organ is connected to the voltage divider; and the external electrode of the measuring ionization chamber is connected to another power supply bus. Sources of information taken into account in the examination 1. US patent number, class. H 0-237, published 1976. 2. Ilyinsk LA Elements of fire automatics. Energia, 19b9 p. 0-45 (prototype). rhJ