SU878023A1 - Measuring cell for studying electric parameters of liquids - Google Patents

Description

The invention relates to a measurement technique and can be used in the millimeter and submillimeter wavelength ranges.

A known measuring cell for studying the dielectric parameters of liquids, containing a cuvette with inlet and outlet ports 1.

However, the known cuvette does not allow measurements with high accuracy in the millimeter and submillimeter wavelength ranges.

The purpose of the invention is to improve the accuracy of measurements in the millimeter and submillimeter wavelength ranges.

To do this, in the measuring cell to study the dielectric parameters of liquids, the input and output windows are made in the form of arrays of parallel conductors installed with a period not exceeding the working wavelength, the lattices are installed parallel to each other, and a dielectric shell is placed inside the cell.

FIG. 1 shows the construction of the measuring cell; in fig. 2 — input and output window designs; in fig. 3 shows the dependence of the intensity / transmitted radiation on the distance L between the gratings of the entrance and exit windows.

Measuring cell for studying dielectric parameters of liquids

contains a cuvette 1 with input and output windows, made in the form of arrays 2 Ji3 parallel conductors 3, installed with a period I, not exceeding L of the working wave, while the lattice

2 are installed parallel to each other, and a dielectric shell 4 for the liquid under study is placed inside the cuvette 1.

The dielectric shell 4 may

be made, for example, of a lavsan film with a thickness of & 3-10 microns.

One pz of the gratings 2 is equipped with a parallel displacement unit and a response device of position (not shown in Fig. 1), which makes it possible to measure and accurately measure the thickness of the layer of the test liquid 5.

Measuring cell works as follows.

Claims (2)

The investigated liquid 5, placed in the dielectric shell 4, takes the form of a plane-parallel layer bounded by a thin film of the dielectric shell 4 and flat gratings 2. Since L () 4 is much smaller than X, it practically does not affect the transmitted radiation. Lattices 2 with a period of / ;. are transparent (transmittance, 99) for a wave in which the electric vector E is perpendicular to the conductors 3. Moreover, when the coefficient {) is filled with X 0.25, where the dn is the diameter of the conductors 3, the grids 2 do not contribute to the transmitted wave phase shift. Thus, the input and output windows, made in the form of lattices 2, do not introduce amplitude and phase distortions into the transmitted radiation. Changes to the transmitted radiation are made only by the plane-parallel layer of the liquid under study 5. Having determined the transmittance coefficient T II of the phase incursion of the wave rt of this layer, the dielectric parameters of the test liquid 5 are calculated using known formulas. using a polarizer, the component with the vector E parallel to the direction of the conductors 3 is extracted from the wave and this component is passed through the grids Because of the wave polarization, a device of two gratings 2 behaves like a Fabry-Perot resonator, which allows determining the wavelength and distance between the gratings 2. To do this, remove the dependence of the transmittance / transmission and on the distance L between the grids 2 (see Fig. 3). The distance between neighboring maxima is equal to I / 2. At x 0.25, the distance between the gratings 2 is equal to H / 2, when the moving grating 2 takes the position corresponding to the first maximum. Having found this polarization, it is possible to determine the required thickness of the layer of the test liquid 5 with an accuracy of - 5 10 I ± b, using the reading device, where S is the error of the reading device. The measuring cell in comparison with the prototype provides a higher accuracy of measurements in the millimeter and submillimeter wavelength ranges. The invention The measuring cell for the investigation of dielectric parameters of liquids, containing a cuvette with an input and output windows, characterized in that, in order to improve the measurement accuracy in the millimeter and sub millimeter wavelengths, the input and output windows are made in the form of gratings of parallel conductors installed with a period not exceeding the length of the working wave, while the lattices are installed parallel to each other, and the dielectric shell for the test liquid is placed inside the cuvette. The source of information taken into account in the examination: I. Brandt A. A. Investigation of dielectrics at microwave frequencies. M., “Owls. radio, 1963, p. 297 (prototype). .. have inp