SU462276A1 - Pulse generator - Google Patents

Description

The invention relates to the field of automotive technologies and radio electronics, in particular to infra-low frequency pulse generators, and can be used to generate rectangular pulses with a thermo-dependent characteristic of duration and squall.

Known pulse generator containing a thyratron, the anode of which is connected to one end of the load resistor, two power sources, each of which is made, for example, on the transformer winding, diode and capacitor, the time setting capacitor, one plate of which is connected to the cathode of the thyratron and the negative zero of the first power supply, and the second with one end of the resistor and minus the second power supply.

The aim of the invention is to derive the dependence of the duration of the generated pulses on temperature and ambient light.

To do this, parallel to the power sources, the first and second voltage dividers are connected, each of which consists of series-connected resistors, a thermistor and a photoresistor optically connected to the thyratron, parallel to the thermistor, and the photoresistor of the first voltage divider are included resistors, a common point between successively connected by a resistor and thermorestern. m of the first splitter of the connection, connected to the second end of the specified resistor, and the common point between the but connected by a resistor and a thermistor of the second voltage divider, through an additional resistor, is connected to the thyratron grid, one end of the winding of the transformer of the first power supply is connected via a donor diode to the second end of the load resistor, and the second end of this winding is a voltage. The drawing shows the principal

electrical circuit of the proposed generator.

It contains a thyratron 1, a time setting capacitor 2, thermistors 3 and 4, photoresistors 5 and 6, a load resistor 7 (for example, a relay, control winding of a magnetic amplifier, etc.), a ferroresonant voltage regulator 8 and diodes 9-11 .

Resistor 12 forms a thermistor 3, a photoresistor 5 and resistors 13 n 14, a nerve divider, and resistor 15 forms a second voltage divider with a thermistor 4, resistor 16, and a photo resistor 6. When the generator is turned on under the voltage applied to the resistor 12, capacitor 2 is charged through resistor 17. When the thyratron is off, the resistance of the photoresistor 6 is large and the main part of the voltage, rectified by the diode 9 and the filter capacitor 18, drops on the photoresistor 6. When the capacitor charges to voltage Equal in amount to the residual voltage drop across the resistor 15, ignition voltage thyratron 1 but the grid-cathode gap (Ua), the latter is ignited and through its load resistor 7 flows pulsating current. Capacitor 2 begins to discharge through the resistors 15 and 19 into the grid – cathode gap of the thyratron, maintaining it in the high state between the pulses of the rectified current. Simultaneously, the thyratron, when ignited, sharply reduces the resistance of the photoresistor 6 and the voltage drop across resistor 15 increases dramatically due to the redistribution of voltage between resistor 16 and thermistor 4 and resistor 15. Condenser 2 will discharge to voltage Uc - Ur-E (1 / 1- is the voltage of the thyratron quenching across the grid – cathode gap, E is the voltage falling across the resistor 15). When the voltage on the capacitor 2 reaches the value of Uc, the thyratron goes out in the dips between the pulses of the rectified current. The voltage on the resistor 15 decreases sharply, and the current passing through the load resistor 7 decreases to zero. The introduction of light feedback allows increasing the depth of discharge of capacitor 2 to the voltage Uc U | -E, due to a sharp increase in the voltage drop E and at the same time to increase the time of its discharge, i.e. the duration of the generated pulses and their stability.

The duration of the pulse pause is determined by the time constant of the RC circuit formed by resistor 17 and capacitor 2, the voltage drop across resistor 12 and the ignition voltage of the thyratron Us and the pulse time is determined by the time constant of RC circuit formed by resistor 19 and capacitor 2, falling the voltage across the resistor 15 and the voltage of the tyratron quenching Ur. The decrease in temperature of the medium in which thermistors 3 and 4 are installed, the resistance of thermistor 3 increases dramatically, and the voltage across it increases, while the voltage across resistor 12 decreases. Consequently, the pause time increases. As the resistance of thermistor 4 increases, the voltage drop E decreases and the discharge time of capacitor 2 decreases, i.e. the duration of the pulses decreases.

The resistance of the photoresistor 5 varies with the illumination. With increased illumination, its resistance decreases sharply. In this case, the voltage drop across the resistor 12 increases and the pause time decreases. Since the charge of the capacitor 2 does not stop even after the thyratron is ignited, it is necessary that the time constant of the charge circuit exceeds the time constant of the discharge circuit. To eliminate the effect of the charge value on the discharge resistor 12, it can be connected via the break contacts of the emergency relay.

Subject invention

A pulse generator containing a thyratron, the anode of which is connected to one end of a load resistor, two power sources, each of which is made, for example, on a transformer winding, a diode and a capacitor, the time setting capacitor, one plate of which is connected to the cathode of the thyratron and the negative pole of the first source power supply, and the second one with one end of the resistor and minus the second power source, characterized in that, in order to obtain the dependence of the duration of the generated pulses on temperature and illumination The first and second voltage dividers, each of which consist of series-connected resistors, a thermistor and a photoresistor optically connected to the thyratron, and parallel to the thermistor and the photoresistor of the first voltage divider are included the point between the two resistors and the thermistor of the first voltage divider are included resistors, the common point between the successively connected resistors the first voltage divider and thermistor are connected to the second end of the specified resistor, and the common point between the second voltage divider connected in series and the thermistor is connected via an additional resistor to the second end of the transformer through the additional diode through an additional resistor the load resistor, the other end of this winding is the negative output of the first power source.