SU187359A1 - - Google Patents

Description

Photoelectric pyrometers are known in which a radiation detector — a vacuum photocell or photoresistance — is powered by direct current, and an alternating signal is obtained by periodically switching the light flux by a vibrating flap or disk.

The proposed photoelectric pyrometer is of the compensating type and provides an increased circuit sensitivity, and excludes the influence of the spread and fluctuations of the parameters of the radiation detector.

It differs from the known ones in that it contains additional photoresistance, which is illuminated by the lamp, controlled through the system of auto-regulation by a signal of static unbalance of the bridge, and also by the fact that the compensation lamp is included in the circuit consisting of a dynamic unbalance amplifier of the bridge, current regulator and the motor moving engine of this controller.

The drawing shows the scheme of the proposed pyrometer, which contains a photoresistance / (radiation detector) included in the AC bridge circuit 2, and a corrective photoresistance 3, a vibration light switch 4, a compensation lamp 5, a voltage amplifier 6, a phase-sensitive stage 7, a filter 8 tuned to the frequency of the selector,

servo amplifier 9, reversible motor 10, calibrated notciometer 11, voltage converter 12 to proportional current, filter / 5 from a long time constant, current amplifier 14, correction lamp 15 and generator 16.

The infrared flux emitted by the monitored object 17 affects the photoresistance I, and if it is not equalized by the flow of the compensation lamp, an imbalance appears in the output of the bridge in the form of a generator subcarrier modulated by the signal carrier.

This voltage is amplified by amplifier 6 and fed to a phase-sensitive stage. The output of the latter is divided into two circuits. One of the circuits includes a carrier filter (50 Hz) to which the auto-compensation system servo amplifier is connected. With a carrier, the reversing motor begins to rotate and moves the two-way potentiometer.

The nanowire removal from the potentiometer is proportionally converted at node 12 into a current that powers the compensation lamp. The engine does not move until the luminous flux of the lamp 5 becomes equal to the flux from the object being monitored.

stops. Since the scale arrow is connected with the potentiometer slider, the temperature can be measured from the readings of the latter.

Through the second circuit, the voltage from the output of the cascade 7 is transmitted to the filter 13, which deeply smoothes the signal, and therefore a smoothly varying voltage proportional to the static unbalance of the bridge is fed to the input ycIv of the current indicator 14. A correction lamp is connected to the output of amplifier 14.

The phase ratio in the auto-correction circuit (bridge-amplifier-phase-sensitive cascade filter-current amplifier) is chosen such that a change in resistance 1 causes a change in resistance 3, and therefore the equilibrium of the bridge is not disturbed.

Subject invention

Claims (2)

1. A photoelectric pyrometer containing a radiation detector — a photoresistance included in the AC bridge, a compensation lamp, a voltage amplifier, a phase-sensitive stage, a filter with a long time constant, a current amplifier with a lamp, a carrier filter, a servo amplifier, a reversible motor, and a regulator current, characterized in that, in order to increase its sensitivity, an additional the photoresistance of the lamp, controlled by the system of autoregulation of the signal of static unbalance of the bridge. 2. A pyrometer according to claim 1, wherein that, in order to eliminate the influence of scatter and fluctuations in the parameters of the radiation detector and an increase in the measurement accuracy, the compensation lamp is included in a circuit consisting of a current regulator, an amplifier for dynamic unbalance of the bridge and a motor coupled to the slider of the said current regulator.