SU45683A1 - Method of testing electronic tubes for microphone effect - Google Patents

Description

The damage caused by the presence of a microphone effect on the electron tubes is determined by the magnitude and duration of the electrical oscillations that occur in the circuit of the tubes when exposed to mechanical pulses.

The test of lamps for the microphone effect is intended to determine whether the amplitude of the oscillations created by the lamp does not exceed a certain amount allowed by the conditions of lamp exploitation, and also to determine if the oscillations have time to die out at a certain permissible time.

The present invention relates to similar tests. In contrast to the already known methods of determining the microphone effect by the average amplitude of oscillations with continuous shaking of the lamp, it allows one to judge not only the magnitude but also the duration of the microphone effect of the lamp when a mechanical pulse is imparted to it.

The production scheme of such tests is shown in the attached drawing. Here 7 depicts the lamp being tested. By selecting the voltage of the filament, the displacement of the grid and the anode voltage, it is set to the desired mode. The oscillations of the anode current of a lamp appearing on impact are amplified by the force of light (242)

On-board 2. After the amplifier, the kenotron 3, galvanometer 4, capacity 5, resistance 6, potentiometer 7, and battery 8 are turned on.

Before starting the test, the key 9 is set to the right position. At the same time, the capacitor 5 is charged up to some desired voltage, set on the voltmeter JO. Then, simultaneously with striking the lamp, the key is moved to the left position.

In order for both of these phenomena to occur at the same time, the knife switch 9 is made bipolar, with the second knife being used to turn on any electromagnetic device that strikes the lamp.

It is obvious that the galvanometer 4 is deflected only when the amplitude of the alternating voltage generated by the lamp and amplified by the amplifier is the voltage on the capacitor 5, since the polarity of the voltage on the capacitor is such that a negative potential is applied to the cathode anode.

If the initial amplitude of the AC voltage at the output of the amplifier is less than the set voltage on the capacitor, then the galvano-gaht will not give a deviation.

From the moment of switching, the capacitor 5 begins to discharge through the resistance b, and the voltage on it will decrease according to some exponential law. At the same time, according to a similar law, the voltage supplied by the amplifier will decrease.

If the AC voltage at the output of the amplifier drops more slowly than the voltage of the capacitor, then after some time its amplitude may exceed the voltage across the capacitor and the galvanometer will deflect.

For testing the lamps, setting the permissible initial amplitude of the microphone oscillations and the damping time of the voltmeter JO sets the corresponding initial voltage of the capacitor and the time of its discharge by selecting the capacitance 5 and opposite 6.

The test lamp is produced after

blowing image. First one switch to the right by / yu, and then to the left. If the galvanometer 4 was rejected at the same time, it would mean that the lamp has too much of a microfone effect and is a marriage. If there is no deviation, then the microphone effect does not exceed the norm.

The subject matter of the invention.

A method of testing electron tubes for a microphone effect, characterized in that the damped oscillating voltage produced on the anode resistance under the influence of a mechanical pulse imparted to the lamp, after preliminary amplification and rectification, is supplied to a precharged capacitor that discharges from supplying oscillating voltage to a certain resistance.