RU169540U1 - FLOW MICROWAVE HUMIDIFIER - Google Patents

Abstract

The utility model is aimed at expanding the measurement range and improving the accuracy of measuring the moisture content of the material in the stream. This technical result is achieved by the fact that in the microwave flowmeter containing a source of electromagnetic energy, the measuring unit connected to the computing unit, the measuring section in the form of a pipe section equipped with the elements of excitation and removal of electromagnetic energy, made in the form of horn antennas located in a direction perpendicular to the movement of the flow from the external are opposite x the sides of the measuring section in the form of a pipe segment, connected respectively to a source of electromagnetic energy and the measuring unit, an additional dielectric plate is inserted inside the measuring section in the form of a pipe segment located in the center of the pipe along its axis in the direction of flow between the elements of excitation and removal of electromagnetic energy, made in the form of horn antennas.

Description

The proposed utility model relates to the field of measurement technology and can be used to determine the moisture content of various materials in the process stream, including liquid, gaseous, granular with varying degrees of dispersion of particles. Such materials may include oil, industrial fluids, natural gas, cryogenic media, building bulk and liquid materials, chemical and food bulk products, and cereal products.

Known devices for measuring the moisture content of materials based on the measurement of its electrophysical parameters using radio frequency sensors (US patent No. 4862060, M. CL G01N 22/00; No. 4996490, M. CL G01R 27/04, G01N 22/00; No. 5157339, M. cl. G01N 22/00; No. 3933030, M. cl. G01N 9/00, N 5103181, cl. 324-637, 92), USSR Copyright Certificate No. 271104, cl. G01N 23/24, publ. Bull. No. 17, 05/12/1970

The disadvantage of these devices is a narrow measurement range, depending on the selected thickness of the controlled material, and the dependence of the accuracy of the moisture measurement results on inhomogeneities in the material flow, due to the fractional composition of bulk materials, varying degrees of mixing of various liquids in water (for example, oil-water emulsion may be present in pipelines and separately oil and water), uneven distribution of water in the volume of materials, uneven flow of moisture in Yemeni.

The closest (prototype) is a device for determining the parameters of dielectric materials, containing a source of electromagnetic energy, a measuring unit connected to the computing unit, and a measuring section in the form of a pipe section equipped with elements of excitation and removal of electromagnetic energy connected respectively to an electromagnetic energy source and measuring block (RF Patent No. 2111120, IPC G01N22 / 00).

The main disadvantage of the prototype is also a narrow measurement range, depending on the selected thickness of the controlled material, and the dependence of the accuracy of the moisture measurement results on inhomogeneities in the material flow, due to the fractional composition of bulk materials, varying degrees of mixing of various liquids in water (for example, oil pipelines may be present in oil pipelines emulsion and oil and water separately), uneven distribution of water in the volume of materials, uneven flow in the wet news in time. Show it.

In the most general form, the relationship between the parameters of the electromagnetic field and the medium with which it interacts is described by the Maxwell equations (NN Fedorov. Fundamentals of Electrodynamics, Moscow: Vysshaya Shkola, 1980).

The solutions of these equations for the case of a plane wave incident on a plane-parallel layer of a homogeneous dielectric of infinite length have the form

where A, ϕ, R, ψ are, respectively, attenuation, phase incursion of the transmitted wave, reflection coefficient and phase of the reflected wave,

β ₀ is the phase coefficient of the vacuum,

α, β are the attenuation coefficients and phases of the material, respectively,

- толщина материала.

- the thickness of the material.

и коэффициентами ослабления α или фазы β материала. Начиная с определенной влажности, α и β становятся такими, что при заданной толщине материала

прошедший СВЧ-сигнал не поддается измерению, т.к. его амплитуда становится ниже уровня шумов элементов измерительного блока.From (2) it follows that by any parameter of the microwave wave it is possible to judge the moisture content of the material. When measured by the parameters of a wave passing through the material, the measurement range is determined by the thickness of the material

and attenuation factors α or phase β of the material. Starting from a certain humidity, α and β become such that for a given material thickness

the transmitted microwave signal cannot be measured, because its amplitude becomes lower than the noise level of the elements of the measuring unit.

Consider the effect of heterogeneity.

Let the direction of propagation of the electromagnetic wave coincide with the z axis, perpendicular to the plane of the x, y axes.

в плоскости x, y по двум взаимно перпендикулярным направлениям. При этом имеемWe decompose the vector

in the x, y plane in two mutually perpendicular directions. Moreover, we have

. Если отношение амплитуд a ₁, а ₂ и сдвиг фаз между ними в любой точке пространства в контролируемом материале не изменяются во времени, то электромагнитная волна эллиптически поляризована.where t is time, a ₁ , a ₂ , ϕ ₁ , ϕ ₂ are the actual amplitudes and phases of the orthogonal projections of the vector

. If the ratio of the amplitudes a ₁ and ₂ and the phase shift between them at any point in space in the controlled material do not change in time, then the electromagnetic wave is elliptically polarized.

в плоскости x, y. Исключая из соотношения (3) временной множитель, получимWe determine how the position of the vector changes

in the x, y plane. Eliminating the time factor from relation (3), we obtain

, где Δ=ϕ₂-ϕ_1,

where Δ = ϕ ₂ -ϕ _1,

ellipse equation. When a ₁ = a _{2, the} ellipse degenerates into a circle.

(Vinogradova MB, Rudenko O.V., Sukhorukov A.P. Wave Theory, M: Nauka, 1979, pp. 40-41).

в плоскости x, y равновероятны). (Виноградова М.Б., Руденко О.В., Сухоруков А.П. Теория волн, М: Наука, 1979, с. 41).However, the condition for the constancy of the ratio of the amplitudes a ₁ and ₂ and the phase shift between them at any point in space in the controlled material is fulfilled only during laboratory measurements in the selected samples, because while the material is stationary. In the flow, the amplitudes a ₁ and ₂ and the phase shift Δ between them depend on time, i.e. a ₁ (t), a ₂ (t) and Δ (t). In this case, the transmitted electromagnetic wave becomes unpolarized (all positions of the vector

in the x, y plane are equally probable). (Vinogradova MB, Rudenko O.V., Sukhorukov A.P. Wave Theory, M: Nauka, 1979, p. 41).

The technical result of the proposed utility model is to expand the measurement range and increase the accuracy of measurements of material moisture in the stream.

This technical result is achieved by the fact that in a microwave flowmeter hydrometer containing a source of electromagnetic energy, a measuring unit connected to the computing unit, a measuring section in the form of a pipe segment, equipped with elements of excitation and removal of electromagnetic energy, made in the form of horn antennas located in the direction perpendicular to the movement of the flow from the opposite sides of the measuring section in the form of a pipe segment, respectively connected to a source of electromagnetic energy and and Measuring unit inside the measuring section of the tube segment further introduced dielectric plate, located in the center of the tube along its axis in the direction of flow between the elements of the excitation and removal of electromagnetic energy, made in the form of horn antennas.

The essence of the proposed utility model is as follows.

в каждой точке пространства контролируемого материала будет определяться неоднородностями потока и в силу случайного характера неоднородностей представляет случайный характер, т.е. получается эффект многократных измерений как бы при вращении контролируемого образца в случае линейно-поляризованной волны. При этом амплитуда прошедшей через материал волны в любой момент времени уже характеризует усредненную интегральную влажность материала, не зависящую от неоднородностей. Для устранения влияния неравномерности потока по влажности во времени применяются многократные измерения с последующим усреднением результата за определенный промежуток времени.If a homogeneous dielectric plate is installed in the plane of the microwave microwave moisture meter between the transmitting and receiving antennas in a plane parallel to the movement of the material, as shown in FIG. 1, the amplitude a ₂ and the phase ϕ _{2 of the} component E _y at any point on the dielectric plate are independent of time, and α ₁ , ϕ _{1 of the} component (E _x ) change in time due to the inhomogeneity of the material flow. The direction of the total vector of electromagnetic field strength

at each point in the space of the controlled material it will be determined by the inhomogeneities of the flow and due to the random nature of the inhomogeneities it is random the effect of multiple measurements is obtained, as if during the rotation of a controlled sample in the case of a linearly polarized wave. In this case, the amplitude of the wave transmitted through the material at any instant of time already characterizes the averaged integral moisture of the material, which is independent of inhomogeneities. To eliminate the effect of flow non-uniformity in humidity over time, multiple measurements are used, followed by averaging the result over a certain period of time.

For multiple measurements with averaging of the measured value, the confidence interval of the random error component at the level of 0.95 is determined from the expression:

where x _i is the measured random variable, t _0.95 is the Student's coefficient, N is the number of observations, S (x _i ) is the estimate of the standard deviation of the random variable. This is true for independent random variables distributed according to the normal law and uniform measurements. All these conditions in the considered method are fulfilled: the independence of random variables is determined by the independence and randomness of the location of inhomogeneities in the flow of the controlled material, for large N random variables are considered distributed according to the normal law, the uniformity of measurements is ensured by the use of the same measuring device.

Indeed, it follows from (4) that, as N → ∞, the confidence interval Δ → 0. In this case, the average value of the measured quantity (x) tends to its true value, because

, каждое его положение соответствует отдельному измерению, т.к. вносит долю ослабления в СВЧ-сигнал при соответствующей ориентации к неоднородности и все эти доли суммируются в общее ослабление проходящего через материал СВЧ-сигнала. Поскольку положений вектора

бесчисленное множество, то N-N→∞, и в соответствии с выражением (4) для доверительного интервала случайной погрешности в каждый момент времени (для каждого результата измерения) справедливо:With a random arrangement of the vector

, each its position corresponds to a separate measurement, because introduces a fraction of attenuation into the microwave signal with an appropriate orientation to heterogeneity, and all these fractions are summed into the total attenuation of the microwave signal passing through the material. Since the provisions of the vector

countless, then NN → ∞, and in accordance with expression (4) for the confidence interval of a random error at each moment of time (for each measurement result) it is valid:

In this case, the reduction of random error is also carried out during in-line measurements due to multiple measurements with subsequent averaging of the results.

The extension of the measurement range is achieved due to the fact that the amplitude a ₂ and phase ϕ _{2 of the} component E _y depend only on the dielectric parameters of the dielectric plate, and for any maximum moisture content of the material, it is possible to select such dielectric parameters of the dielectric plate so that the level of the total transmitted microwave signal is measurable modern measuring instruments.

The scheme of the in-line microwave moisture meter is shown in FIG. 2.

The microwave microwave flowmeter contains an electromagnetic energy source 1 connected to the computing unit 6, a measuring section 4 in the form of a pipe segment, equipped with excitation elements 2 and electromagnetic energy removal 3 made in the form of horn antennas located in a direction perpendicular to the flow from external opposite the sides of the measuring section 4 in the form of a pipe segment connected respectively to a source of electromagnetic energy 1 and a measuring unit 5, a dielectric plate 7 located in the center tre tube along its axis in the direction of flow between the excitation elements 2 and 3 detachably electromagnetic energy made in the form of horn antennas.

An in-line microwave moisture meter works as follows: electromagnetic energy from a source 1 is supplied through an electromagnetic energy excitation element 2 in the form of a horn antenna to a measuring section 4 in the form of a pipe segment, an electromagnetic wave transmitted through it is output through an electromagnetic energy removal element 3 in the form of a horn antenna, and using the measuring unit 5 determines the magnitude of the attenuation of the electromagnetic wave. According to the measured parameter in the computing unit 6, the moisture content of the test substance is calculated according to previously obtained calibration dependencies. The influence of material inhomogeneities in moisture is reduced due to the propagation of part of the electromagnetic energy in the dielectric plate 7, which, as shown above, gives the effect of multiple measurements for each moment in time.

To reduce the random error due to the non-uniformity of the flow of humidity over time, multiple measurements are carried out with the subsequent averaging of the results in the computing unit 6.

The extension of the measurement range is achieved by choosing the dielectric parameters of the dielectric plate, providing for any maximum moisture content of the material the level of the total transmitted microwave signal, measurable by modern measuring instruments.

The proposed in-line microwave moisture meter is applicable not only to bulk but also liquid and pasty materials.

Verification of the developed in-line microwave moisture meter by simulation has shown that for N> 70, the total random error due to the effects of material inhomogeneities and flow non-uniformity in humidity within 20% (relative) is practically zero.

Experimental studies conducted on a specially created in-line installation of humidity control based on the amplitude microwave method also confirmed the correctness of the theoretical justification of the developed in-line microwave moisture meter.

Claims (1)

An in-line microwave moisture meter containing a source of electromagnetic energy, a measuring unit connected to a computing unit, a measuring section in the form of a pipe segment, equipped with electromagnetic excitation and removal elements made in the form of horn antennas located in a direction perpendicular to the flow from opposite sides measuring section in the form of a pipe segment, respectively connected to a source of electromagnetic energy and a measuring unit, characterized in that inside ritelnoy section a further section of pipe inserted dielectric plate, located in the center of the tube along its axis in the direction of flow between the elements of the excitation and removal of electromagnetic energy, made in the form of horn antennas.

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