UA16396U - Quasioptical dielectrometer - Google Patents

Abstract

The proposed quasioptical dielectrometer contains a disk measuring dielectric resonator, a microwave oscillator, an electric oscillation receiver, and a vessel for tested material.

Description

Description of the invention

The proposed useful model refers to the measuring technique of ultra-high frequencies (UHF) in the field of 2 microwave techniques for determining the complex dielectric constant and can find application in such fields of economy, science and medicine, where the dielectric constant of solid, powdery and liquid substances or solutions determines their quality, or the possibility of use in various devices.

Knowledge of the real and imaginary parts of the dielectric constant 5-5-E" of the substance under study is very important. It provides an opportunity to determine the overall dimensions of the devices being developed, to predict their sensitivity and frequency range of use. Also, an equally important parameter of the dielectrometer is the The volume of the substance is necessary for measuring the real and imaginary parts of the dielectric constant, as well as for determining the dynamics of the specified values depending on the frequency, pressure, temperature, or changes in the properties of the substance under study, for example, when studying the flow of a liquid or bulk substance. The minimum amount of the substance required for the study can be an important factor in biological and medical research.

Recently, in the study of various substances, including complex biological structures containing water

Iakhadov Ya.Yu. Dielectric properties of pure liquids. - M.: Izd-vo Moscow. Aviation Institute, 1999. - 412p3, ultrahigh-frequency (MHF) research methods have become widespread | Brandt A.A.

Investigation of dielectrics at ultrahigh frequencies. - M.: Fizmatgiz, 1963. - 404si1. Among the latter, the most common objects of research are microorganisms, biological tissues, biopolymers and some others.

The main goal of such research is to obtain information about intermolecular interactions and to determine the parameters and characteristics associated with them |N.D. Devyatkov. Interaction of millimeter radiation with biologically active compounds and polar liquids. // Radio engineering and electronics. - 1978. - 23,

Me9. - P. 1882-18901. 29 It is known that many biomaterials are often liquids (blood, lymph, physiological solutions, etc.), which - are characterized by a high value of dielectric constant and have large losses in the microwave, including millimeter (mm), wavelength range. In the case of small concentrations, all solutions containing water are dielectrics with large losses ( иШаш'! ), for which standard measurement methods are usually unacceptable (Brandt A.A. Issledovanie dizlektrikov na sverhvysokikh khoznych. - M.: Fizmatgiz, 1963. - 404 p.;

Shestopalov V.P., Yatsuk K.P. Methods of measuring the dielectric permittivity of matter at ultrahigh (22) frequencies // Uspekhi fiz. of science - 1961. - 74. - P.721-755). In addition, their property is very sensitive to changes in temperature. Therefore, it is necessary to develop reliable measurement methods that would allow determining the properties of the studied objects. Such methods include microwave methods aimed at measuring (Ce) the complex dielectric constant of liquids with large losses. "-

To study the complex dielectric permittivity of such materials in the mm range, various methods based on the use of waveguide transmission lines in a wide range of frequencies have been used. However, resonator methods, which differ in the type of resonance system and the type of oscillations excited in them, have greater sensitivity. Their higher sensitivity is ensured by the "multipass character" of the interaction of the microwave "40. Lolya With the substance under investigation in the process of resonance measurements (Brandt A.A. Issledovanie dizlektrikov -o na sverhvysokykh frequencies. - M.: Fizmatgiz, 1963. - 404p4. It also becomes important and the possibility of measuring samples of sufficiently small volumes.When measuring substances with large losses, the use of such structures causes certain difficulties, which is primarily associated with a decrease in the Q-factor of the resonators.

At this time, open resonator systems, which have sufficient sensitivity and are convenient to operate, have found wider application. Their quality can reach sufficiently high values, which makes it possible to measure small loss values with great accuracy. From this point of view, the methods are becoming more and more convenient

Me, measurements based on quasi-optical wave propagation. Among this type of resonator systems, quasi-optical dielectric resonators (KDR) with whispering gallery waves, which allow working in a sufficiently wide range of wavelengths, stand out. Dielectric resonators. / M.E. Ilchenko, V.F. with Vzyatishev, L.G. Hasanov and others / Ed. M.E. Ilchenko. - M.: Radio and communication, 1989. - 328 p.|.

Ф It is known that for the study of materials with a dielectric constant of -1-100 and a dielectric loss tangent of zd-107 in the frequency range of 20-300 GHz, it is advisable to use a measuring dielectric resonator with azimuthal oscillations in dielectrometers. Dielectric resonators! / M.E. 22 Mlchenko, V.F. Vzyatishev, L.G. Gassanov, etc.; Edited by M.E. Ilchenko. - Moscow: Radio and Communications, 1989. - 328 p. 1. The choice of material for the manufacture of a measuring dielectric resonator depends on from the values \u200b\u200b" and is" of the material under investigation. If substances with low losses here"107 and dielectric permeabilities of 57:10 are being investigated, then it is advisable to choose the material for the manufacture of the measuring resonator with similar characteristics (for example, a dielectric disc resonator made of leuco sapphire provides the measurement error is 00595, and yes - 195). atmospheric temperature and Oo5108-109 at the temperature of liquid helium).

A well-known device for measuring parameters of dielectric materials (As. USSR Mo991828 MKY 7 65 501K27/26, 1985). It has a measuring resonator in the form of a dielectric disk with a cutout, connected to a high-frequency generator and an indicator. The cutout can be made in the form of a radial slit or a hole, the axis of which is parallel to the axis of the dielectric disk, in addition, the device has a mechanism that changes the width of the radial slit. A wave of the "whispering gallery" type is excited in the measuring dielectric resonator, which is doubly degenerate with respect to the azimuthal index. When the investigated dielectric material is placed in the gap, the degeneracy of natural oscillations, which is characteristic of traveling wave resonators, is removed. Each of the resonant frequencies of the measuring resonator is split into two standing waves, one of which has the antagonism of the transverse (electric) field, and the second - the node of the same field at the location of the irregularity. The disadvantage of this device is the need to make measuring samples according to the size of the gap or hole in the resonator, the sample sizes are quite large, otherwise it is necessary to take into account the air gaps in the gap or hole, 7/0, which reduces the accuracy of the dielectric constant measurement. It is not possible to measure the real and imaginary parts of the dielectric constant of liquids, bulk and gaseous substances on this device.

There is a well-known dielectric resonator that allows measuring the dielectric constant of liquids, gases, and bulk materials with low losses (As. USSR Mo1107072 MKIZ p012527/26; C01K7/10, 19841, which is made in the form of a cylinder of high-quality dielectric with an axial hole, annular grooves along 75 lateral surface, connected to the axial hole by radial passages. The disadvantages of this device are the relative complexity of the resonator, a large amount of liquid or gas to completely immerse the resonator in the substance under study, the dimensions of the resonator must satisfy certain conditions relating the radius of the resonator to the wavelength and dielectric permittivity of the resonator material and the substance under study.

The dielectric permeability of the substance must be lower than the permeability of the resonator material.

The closest in terms of technical essence is the quasi-optical dielectrometer (Patent of Ukraine Мо59568А, МКИ" вО1К27/26, 2003), which contains a measuring dielectric resonator connected to an ultra-high-frequency generator for exciting waves of the "whispering gallery" type and a receiver. In the resonator, clamped by two metal plates with metal holes, a groove with concentric side surfaces is created so that the investigated substance filling this groove interacts with the "whispering gallery" wave field, which

They are excited by dielectric waveguides. The groove filled with the measuring substance is fixed from below by the bottom of the groove, and from above by one of the metal plates. The spectrum of the resonance frequencies of the ring dielectric in the resonator is measured according to the "through" scheme with weak coupling. The frequencies and Q-factors of the observed oscillations are experimentally measured, their type is determined, and then the measured frequencies and Q-factors are compared with the theoretical ones. Gee)

The disadvantage of this device is the impossibility of its use for the study of liquids of small volumes, which may include biological objects and various binary compounds and which have large values of dielectric losses. When working with this type of resonator, the substance under study is given the shape of a disk (ring). In this case, when working with liquid dielectrics, it is difficult to ensure the homogeneity of the measured substance in terms of thickness, which is disturbed due to surface tension or the formation of bubbles on the i-th surface in the field region. These difficulties are especially pronounced in the case of liquids that have high dielectric losses "- (for example, water, acetone and others). The presence of even a very small air bubble in the groove with the liquid can lead to large errors, which makes it impossible to study it in dynamic mode.

The basis of the useful model is the task of improving the quasi-optical dielectrometer through "the interaction of the whispering gallery wave of maximum field amplitude with the substance under study, which will provide 70 increase in measurement accuracy and expansion of the range of dielectric loss values." - с The problem is solved by the fact that in a quasi-optical dielectrometer, which contains a measuring and dielectric resonator made in the form of a disk, with two end conductive plates, "" an ultra-high-frequency generator for exciting waves of the whispering gallery type and a receiver, according to a useful model, at a distance of (where хр is the wavelength of the whispering gallery in the resonator) from the side surface of the resonator there is a hole for placing a container with the substance under study in it. In one of the conducting plates, parallel to the hole for placing the substance under study in the resonator, a hole and a cylindrical b resonator with a piston for adjusting the test signal. The container is made with the possibility of moving the test substance through the hole. o The essence of the useful model is explained by illustrations: Fig. 1 shows the diagram of the dielectrometer according to item 1; Fig. 2

Ge) 20 shows the scheme of the dielectrometer according to p. 2 and p. 3; Fig. 3 shows a comparison of losses and frequency shift for the studied liquids (ethyl alcohol, acetone, water) located in the container, relative to the container with air filling.

The proposed quasi-optical dielectrometer contains a dielectric measuring resonator 1 with an axial hole 2, clamped between two metal plates 3. The container with the substance under study 4 29 is made with the possibility of studying the substance, both for a fixed volume and for a flowing substance. Mirror waveguides 5 and 6 are used to excite whispering gallery waves in a dielectric resonator, which are connected to the generator (waveguide 5) on one side, and to the receiver (waveguide 6) on the other. Cylindrical resonator 7 with piston 8 is located in the conductive plate in line with hole C for adjusting the test signal. The height n of the resonator 1 is chosen so that only oscillations with an axial number 60 of 1 are excited. This condition is fulfilled at Yhild, where x is the wavelength at which the dielectrometer works, and the radius of the measuring resonator B is x/2Pl, where n is the number of wavelengths along the perimeter of the resonator.

The proposed device works as follows: in the dielectric measuring resonator 1 with mirror dielectric waveguides 5 and 6, whispering gallery waves are excited. The spectrum of resonance 65 frequencies of resonator 1 is measured according to the "through" scheme with a weak connection. The frequencies and Q-factors of the observed oscillations are experimentally measured, their type is determined, the signal is adjusted to the maximum value with a cylindrical resonator with a piston, and then the measured frequencies and Q-factors are compared with the corresponding values for the resonator, samples measured on the same dielectrometer or compared with theoretically calculated ones.

The proposed quasi-optical dielectrometer was manufactured and tested in the range of 37-40 GHz, the diameter of the resonator was equal to 78 mm, its height was -7.2 mm, the internal diameter of the container for the study of the substance varied from 0.45 mm to 1.85 mm. The smallest inner diameter of the container made of fluoroplastic provided the minimum amount of the investigated substance, which is quite significant for biophysical and medical-biological research. 70 The quasi-optical dielectrometer was tested on liquids - water, ethyl alcohol, acetone; and also, the concentration dependence of alcohol in water was measured, including, in a dynamic state - when the liquid passes through a container located in the resonator.

Claims (2)

The formula of the invention 1. A quasi-optical dielectrometer containing a measuring dielectric resonator made in the form of a disk with two end conductive plates, an ultra-high-frequency generator for exciting waves of the whispering gallery type, and a receiver, which is distinguished by the fact that at a distance nya ; where nya is the wavelength of the whispering gallery in the resonator, there is an opening from the side surface of the resonator for placing a container with the substance under study in it. 2. Quasi-optical dielectrometer according to claim 1, which differs in that in one of the conducting plates, coaxially with the hole for placing the substance under investigation in the resonator, there is a hole in which a cylindrical resonator with a piston for adjusting the test signal is placed. Z. Quasi-optical dielectrometer according to claim 2, which is characterized by the fact that the capacity is made with the possibility of moving the substance under investigation. (Se) (o) (ze) (Se) yo - and? - (o) (95) se) 4) 60 b5