SU173272A1 - A method of improving a stabiliser controlled by a photo cell. - Google Patents

Description

In known stabilizers for currents above 1a, composite transistors (sd (vobnnye and stroyennye) or schemes of direct current amplifiers with power supply of terminal stages from a stabilized and current source are used as regulating elements. In such stabilizers, a regulating transistor drops a large voltage and there is a greater useless power that causes the transistor to heat up, and the instability of its parameters. The change in the temperature profile strongly influences the parameters of the dual and built-in transistors, which causes awn in powerful cooling systems. When using a DC amplifier transistors required complicated temperature compensating circuit, their production is difficult because of large scatter parameters.

A stabilizer circuit made of transistors in combination with an electron tube does not require thermal compensation, but the operation of the lamp stage is affected by changes in the supply voltage.

The known phycompensation stabilizers allow to obtain a high stabilization factor (up to several tens of thousands of hours) with a wide range of output voltage control. However, when the output control limits are changed

current over a wide range varies and the coefficient of stabilization.

Thus, in order to build a photocompensation stabilizer with a sufficiently large stabilization factor and a wide voltage regulation (or current), it is necessary to dramatically increase the stabilization factor, which leads to auto-oscillation of the systems and limits the possibilities of building photocompensation stabilizers with a high stabilization factor and a wide range of output adjustment voltage (or current). To eliminate this drawback and increase the stabilization factor of the photocompensation stabilizer with a wide range of voltage or current control, it is proposed to change the value of the

amplification of the dc amplifier.

In order to clarify the proposed method, the figure shows a schematic diagram of a photo compensating stabilizer, the stabilization coefficient of which when changing

the voltage control or current control limit remains high by simultaneously changing the magnitude of the gain of the dc amplifier.

rrm Lr1-Ci, in series with the load, two powerful transistors UTi, ПТ, are included as a regulating element in parallel. The current amplifier of the bases of these transistors is made on a JAGS transistor and is supplied from a separate unstable source consisting of a rectifier based on diodes B and BQ and a Df2-Co filter. The emitter circuit of the amplifier transistor PT includes a large stabilizing resistance Ri, which significantly increases the stability of the amplifier.

In the DC amplifier, IJTs and an electronic lamp / 7i are applied together, powered by a rectifier on diodes B -; - BS through a Cz-Drs-S filter and a Zener diode L 2.

The switch P changes the magnitude of the compensation resistance R, and, consequently, the output current is controlled. At the same time, the switch P2, which is located on the same axis as the switch 7, changes the gain of the DC amplifier so that the stabilization factor remains constant.

The lamp load L is the base circuit of the transistor PTz together with the resistances. The voltage on the control grid of the lamp L is fed from the bridge diagonal consisting of photoresistance of the FS and resistance Rg and RIO and fed from the intermediate transformer Tr through the rectifier Vd-BIO I filter 11-Sz. Thus, the coherence of the regulating element depends on the distribution of light between the parts of the photoresistance. The output current of the stabilizer, the passage across the resistance Rs, creates by itself a voltage drop, which is compared with the voltage of the supporting element OE. In the steady state, the compared voltages are equal, and there is no current in the galvanometer G circuit. When the output current changes due to changes in the supply voltage, load and circuit parameters, the voltage across the resistance R changes and a current arises in the galvanometer circuit.

causing a rotation of the movable galvanometer system with a mirror mounted on it. The luminous flux of the lamp L--, reflected from the galvanometer mirror, is redistributed between parts of the photoresistance of the FS so that the changed resistance of the regulating element restores the previous value of the output current. As a result, comparable stresses are

equal, and the current in the galvanometer circuit ceases.

The transition from one adjustable output current limit to another is performed when the resistance is changed by switch IJi. Resistance R2 at the same time is a universal shunt ammeter A, showing the value of the output current of the stabilizer. Smooth adjustment of the output current on

each limit is produced by rheostats (roughly), Dxs (medium), Ru (exactly), which change the value of the voltage taken from the supporting element OE. In order to avoid regulatory overload

transistors simultaneously with the switching of the output current limits by the switch Zz, the alternating voltage applied to the rectifier on the BI-B diodes is changed. When transistors PT and YAG are overheated, the thermal relay PI includes the relay coil PS, which disconnects the stabilizer from the network. The stabilizer is powered from the AC mains through the power transformers Grg and Trz. To compensate for the initial current power

The transistors use a separate transformer winding current rectified by a diode rectifier and filtered by a / 15-CT filter.

Subject invention

The method for increasing the stabilization factor of a photo-compensating stabilizer with a wide range of current regulation and charging, is different in that when the control limit is changed, the value of the gain coefficient of the DC amplifier also changes.

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