SU168382A1 - - Google Patents

Description

At present, the time constant of inertial photosensitive elements is determined by oscillography of the transient current arising from an abrupt change in the luminous flux incident on the photocell. This method is laborious and gives an idea of the inertial properties of the photosensitive elements in conditions that differ sharply from the operating conditions. The proposed method allows the determination of the time constant of inertial photosensitive elements under conditions close to the conditions of operation, and consists in the fact that said photosensitive element is included in the photocompensator circuit, the latter is introduced into the self-oscillatory mode and the desired time constant is calculated, the outcome from the critical conditions of dynamic stability, or is calculated according to the compensation resistance pre-calibrated in units of constant time, included in the reverse circuit th communication compensator. FIG. 1 is a schematic diagram of a photo-compensator; in fig. 2 is a scheme with the help of which the photo-compensator is pre-calibrated. This element, for example, the differential photoresistance Φ, is included in the photo-compensator circuit containing a galvanometer G with a known moment of inertia of the moving part /, a coefficient of calm P, a mechanical specific opposing moment W ,,; lighting lamp L; power sources B and compensatory resistance g. When the moving part of the galvanometer G is deflected, the light flux of the lamp L reflected by the mirror fixed on the moving part will change the illumination of the photoresistance F, which will cause imbalance of the photocircuit and flow through the resistance r ,. current, seeks to return the moving part to its original position. In this case, the dynamic mode of the galvanometer D is described by the equation: + (P. + /) i a- (p + -iv7,) Jfl dr di - dt, - Ut). h --1-g / where l (t) is a disturbing effect; Gg is the resistance of the galvanometer; t is the time constant of the photoresistance (photocell); a is the deflection angle of the galvanometer; TO,. - the gain of the photo amplifier, defined as the ratio of the increment of the output current to the change in current through the galvanometer that caused it.

It is known from the theory of automatic regulation that the stability of the system described by equation (1) depends on the magnitude of the term

   (Pt4 J) ()

.. (l +

(2) V r ,, - i-r.

Since usually W.irC, the equation determines

.-.

nv. ,, (i + v r ,,,

All the dynamic coefficients of the galvanometer (/, P, W) entering into formula (3) are known, and the magnitude / C, and the value of r, at which the system becomes unstable, are determined from experience.

Thus, the determination of the time constant of photosensitive elements is reduced to determining the value of / at which the photocompensator is excited, and to calculating it using formula (3) or directly determining the time constant and the specified resistance GK previously specified in its units. photocell switched on instead of the photosensitive element under study, and inertial link with a known time constant included in the amplification path of the photocompensator .

The circuit with which graduation is performed is shown in FIG. 2, where f -

Inertia-free photocell with internal resistance Gf (for example, vacuum or silicon);

TI - resistance; C-capacitor;

L is an electron lamp with a load in the cathode circuit, and the remaining elements are the same as in FIG. one.

If Гф tl, then the time constant of the inertial unit consisting of capacitor C and resistances TI is equal to m. By choosing different values of r and C, it is possible to check the results or graduation of the resistances Hc, which will be relieved only for a given value of Ku.

The described method can also be used in production, for example, for sorting photovoltaic cells according to constant time values.

Subject invention

The method for determining the time constant of photosensitive elements, by changing their illumination, characterized in that, in order to determine a constant time in conditions close to the conditions of operation, said photosensitive element is included in the photocompensator circuit, the last is introduced into the auto-oscillatory mode and its COMOMA the time constant is calculated based on the critical conditions of dynamic stability, or is calculated from the compensation time that was previously measured in units of time constant leniyu included in Exalt feedback compensator.

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