SU855703A1 - Ionization-type fire alarm - Google Patents

Description

The invention relates to fire alarm devices and can be used in automatic alarm systems with the appearance of smoke or dust. Known ionization fire detectors, containing two ionization chambers (measuring and reference), connected in series, the common point of which is connected to the gate of the field-effect transistor, which is connected to an alarm system through an amplifying stage. However, these fire detectors do not contain elements that would allow in standby mode to control their operation and the accuracy of the alarm signal issued. A fire detector consisting of two series-connected ionization chambers with a common point transistor is also known. A signal resistor is introduced into the circuit of the ionization chambers, and two terminals connected to it are connected to the outer panel, to which a measuring device can be periodically connected. Measuring the voltage across the resistor, control the current in the branch of the ionization chambers. Thus, in this detector it is possible, if necessary, to manually control its operation 2. However, the device has the disadvantage that this verification is not performed automatically during the operation of the alarm system (standby mode), there is no control over the accuracy of the alarm. The purpose of the invention is to increase the reliability of the notification by automating the process of monitoring its operability® and ensuring automatic verification of the accuracy of the alarm that is issued. The goal is achieved in that the encoder, zener diodes and the first key connected in series and the first voltage divider, the second key and the second voltage divider, the connection point of the keys and the common point of two series-connected zener diodes connected in parallel to the voltage divider and key chains, the control inputs of both keys are connected to the corresponding outputs of the encoder, the input of which is connected to the output of the amplifier.

The drawing shows the principle of the proposed firefighter.

The circuit contains a measuring ionization chamber 1, connected in series with the reference ionization chamber 2, a field-effect transistor 3 is connected to a common point 1 and 2 of the cameras, which is connected through an amplifier 4 to an input of an encoder ea 5, the measuring chamber 1 is connected to the first voltage divider 6 turned on in series with the first key 7, the reference camera 2 is connected to the second voltage divider 8 connected in series with the second KEY 9, the keys 7 and 9 are connected in series, and their common point is connected to the source of the transistor 3 and with the common point of two zener diodes 10 and 11 connected in series, the control inputs of keys 7 and 9 are connected to the corresponding outputs of the encoder 5, and the control input of the key 7 is also connected to the second input of the block 12, which is turned on at the emergency output of the encoder 5.

The detector works as follows.

In the absence of smoke in the surrounding space, and consequently, in the measuring chamber, the initial voltage distribution on chambers 1 and 2 creates a potential at the gate of the field-effect transistor 3 at which the current in its drain does not cause an alarm signal at the output of the encoder 5. V In the event of environmental smoke, it penetrates into the measuring chamber 1. This causes an increase in the resistance of chamber 1 and, consequently, the redistribution of the voltage drop across the connected chambers 1 and 2. This changes according to The potential on the gate of the field-effect transistor 3, as a result of which the current flowing through its drain and amplifier 4 changes, arrives at the output of the encoder 5, which at the same time generates an alarm signal Fire, however, this signal does not appear at the output of the encoder 5 .only after checking its validity.

There are cases when the alarm signal is not caused by smoke in kgmer 1, but by a fault in the circuit. To check the reliability of the alarm, a special circuit is inserted in the device consisting of a switch 9 and a voltage divider 8.

The check is performed as follows.

The smoke produced in the measuring chamber 1 causes the current to flow in the drain of the transistor 3, which is amplified and fed to the input of the encoder 5. Using this signal, the encoder 5 generates a short-term signal fed to the control of the key input 9. The key 9 closes the splitter circuit 8, and if earlier the full voltage of the zener diode 11 was applied to the reference camera 2, now only part of it will be supplied. The change in voltage on chamber 2 causes the distribution of the voltage drop on both chambers, the opposite of that caused by the appearance of smoke in the measuring chamber 1 In case the device is in service, when the switch 9 is switched, the potential at the gate of transistor 3 should was in the absence of smoke (due to the artificial decrease in the sensitivity of the detector), i.e. the output of the encoder 5 should disappear alarm. When the signal is encrypted by encoder 5, a plausibility check from the input of key 9, the detector (if there is 1 smoke in the chamber) will respond to it again, and encoder 5 will fire the Fire signal. If there is a malfunction in the device circuit, due to which a false alarm signal is sent to the encoder 5, closing the key 9 in the signal validation circuit will not lead to the disappearance of the alarm at the output of the encoder 5, and the Fault signal appears at the output.

A health check is performed as follows. The control input of the key 7 receives periodic signals from the output of the encoder 5. When exposed to such a signal, the key 7 closes the voltage divider circuit, resulting in the measuring chamber 1 being supplied only part of the voltage of the Zener diode 10. At the same time, the voltage drop on the chambers is redistributed 1 and 2, caused by the closure of the switch 7, causes the potency of the gate of the transistor 3 to change to the value corresponding to the presence of smoke in the measuring chamber 1. If the detector is in good condition, from the drain of the transistor 3 through the amplifier 4 to the input of the encoder 5 receives a signal corresponding to the alarm. In order for the pilot signal not to cause a fire signal at the output of the encoder 5, lock node 12 is triggered. If the detector fails to close the key 7 due to the control signal, it will also cause the voltage drop to redistribute on both cameras, but this does not lead to the appearance of an alarm signal System 5 circuit will issue a Fault signal.

The use in fire alarm systems of the proposed fire detectors with high reliability of notification allows to increase the reliability of these systems, which will significantly reduce

Claims (1)

Claim An ionization fire detector containing a measuring and reference ionization chambers connected in series, a field effect transistor, the gate of which is connected to a common point of the ionization chambers, and a drain to the amplifier input, and a detector operability check circuit, characterized in that, in order to increase the reliability of the notification, it an encoder, stabilizers and series-connected are introduced. the first switch and the first divider: voltage, the second switch and the second voltage divider, connection point; keys associated with the source field; e transistors with a common point of two; zener diodes connected in series, connected in parallel to a circuit of voltage dividers and switches, the control inputs of both switches are connected; 10 ^{s corresponds to} Y * ^{0 <1 1} Their outputs are cipher ¹ ra, whose input is connected to the output of the amplifier.