SU118392A1 - Photoelectric refractometer - Google Patents

Description

The known photoelectric refractometers, made using a transparent body modulator with a large permanent Verde, have a complex structure, require the use of two photocells, double the number of polarization parts and others, which increases their cost, makes it difficult to operate and does not provide the required accuracy of readings p de practical cases.

The proposed device is devoid of these disadvantages, has a simpler design, is convenient in operation and provides increased accuracy of work.

This is achieved by the fact that the indicator of the device is made in the form of a modulated luminous flux of a wedge or plate of optically active matter, for example quartz, placed in the path.

This provides phase and frequency changes in the variable component of the light flux used as the driving pulse of the tracking system.

The device is made using a transparent body with a large constant Verde located between the polarizer and the analyzer as a modulator, and has an optical system that projects the light and shade of the measuring cell to the indicator, after which the light enters the photocell of the follow- ing reference system.

The structure and operation of the photoelectric refractometer is shown in the drawing.

The light from the bulb 1 is designed by a condenser system with two lenses 2 and 5 on the flowing measurement fluid that enters the cuvette 4 glued to the measuring prism 5- A light filter 6 is installed to discolor the light-shade boundary. The lens consisting of lenses 7 and S The polarizer 9 is located in the form of a poloid film. The light coming out of the polarizer falls into the modulator 10 and then onto the wedge indicator //, made of an optically active substance (quartz, mica, etc.). To rectify

No. 118392-2 -

a glass beam is used in the light beam. Thus, a wedge indicator with a counter-wedge constitutes a plane-parallel plate. Then, the light passes through the analyzer 13 in the form of a polaroid film and enters the photocell 14 of the follow-up reading system, connected to the input of the amplifier 15, which amplifies the variable component of the photocurrent.

At the output of the amplifier included one of the windings of a two-phase electric motor 16; The second motor winding is connected to the AC network in parallel with the winding of the modulator 10. The motor shaft 16 is connected via a reducer to the rotation mechanism of the measuring prism 5, to which the scale 19 is attached and the illuminator with a projection device containing a light bulb 17, a condenser 18 and a lens 20. Image Scales are projected on screen 21.

The modulator 10 is made in the form of a solenoid with a core of a body with a large constant Verde. In a modulator, linearly polarized light is modulated along the polarization plane at a frequency proportional to the frequency of the alternating current that feeds the modulator coil. The light tray from the modulator is aimed at the diaphragm 22 installed in front of the wedge indicator. When the middle part of the luminous flux is balanced by the analyzer so that it will have a minimum of light, i.e. the oscillation frequency on the photocell will be equal to 100 periods per second, respectively, for the left and right parts of the stream, the unbalanced oscillations of the luminous flux will be equal in amplitude and frequency and phase opposite, i.e. mutually exclude each other. When one of the side portions of the stream decreases in intensity, a variable component will appear in the photocell circuit with a frequency of 50 periods, but with an inverted phase. The light and shade limit is established by balancing the instrument so that it covers one third of the light surface of the diaphragm. Then the side parts of the stream of light are equal in intensity. The deviation of the light and shade boundary causes a variable component in the photocell circuit to produce phase and frequency changes, which are used as the driving pulse of the tracking system. The variable component of the photocurrent through the amplifier 15 is applied to one of the windings of the motor 16, which rotates the measuring prism and the illuminator.

In this case, the motor windings are turned on so that when the prism rotates, the light and shadow border moves on the wedge to the equilibrium position, the variable winding in the 50 periods disappears in the winding of the motor connected to the amplifier, only the frequency of 100 periods remains and the motor stops.

The change in the density of the fluid flowing on the surface of the measuring prism causes its corresponding rotation. The reading of the instrument is observed on screen 21 in an enlarged view. When the instrument is balanced, the tuning point is determined by the redemption of the signal lamp 23, which is lit only when there is a current with a frequency of 50 periods in the network.

Subject invention

A photoelectric refractometer made using a transparent Verde high body as a modulator, located between the polarizer and the analyzer, and having an optical system projecting the light-shade of the measuring cell to the indicator, the light after which goes to the photocell of the next reading system that differs the fact that, in order to obtain phase and frequency changes in the variable component