RU2536184C1 - Concentration meter - Google Patents

Abstract

FIELD: measurement technology.

SUBSTANCE: invention relates to a measurement technology and can be used for high-precision determination of concentration of binary mixes of various fluid matters, pumped over the pipelines. The concentration meter has a high-frequency transducer installed in the measurement section of the pipeline with pumped fluid which comprises a section of the long line with the sensitive element made a load resistance on one of its ends, located on the measurement section in some cross-section of the pipeline, and connected to its another end the unit of electromagnetic oscillations and registration of the oscillation performance of the long line section, to the output of which the first input of the evaluation unit is connected, the evaluation unit itself is connected to the indicator. It contains also the installed in the same measurement section in the same cross-section of the pipeline the ultrahigh-frequency ring resonator, connected through the devices of excitation and retrieval of oscillations, respectively, to the UHF generator and the unit of registration of resonant frequency of electromagnetic oscillations of this resonator, the second input of the evaluation unit is connected to this output.

EFFECT: higher accuracy of measurement.

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Description

The invention relates to measuring equipment and can be used for high-precision determination of the concentration of binary mixtures of various liquid substances pumped through pipelines.

Known devices for determining the concentration of binary mixtures of various liquids, in particular moisture content (Viktorov V.A., Lunkin B.V., Sovlukov A.S. Radio wave measurements of process parameters. M .: Nauka, 1989. P. 168-177) . These devices contain radio wave (HF and microwave) sensitive elements in the form of antennas, waveguides, long lines, strip lines, resonators. In particular, for measurements in pipelines, such devices contain flow-through volume resonators with end elements in the form of metal polarization gratings, reflecting plates, transverse waveguides (Viktorov V.A., Lunkin B.V., Sovlukov A.S. Radio wave measurements of technological process parameters M.: Nauka, 1989.S. 173-174). The disadvantage of such concentrometers is the low measurement accuracy when changing the grade of controlled substances, in particular the base substance in the mixture (emulsion, solution, etc.).

A technical solution is also known (SU 1497531, 07/30/1989), containing a pipeline with a pumped substance, two flow-through volume resonators, included as frequency-setting elements in the circuits of the corresponding oscillators, a calculation unit and an indicator. These resonators are built into the pipeline in its measuring section in series. The device allows you to determine the concentration (moisture content) of a substance, regardless of its grade, which is a function of the electrophysical parameters of the substance. The disadvantage of this device is the low accuracy of the measurement. This is due to the control of different areas of the pumped liquid located simultaneously in the electromagnetic field of two flowing resonators, which obviously predetermines a decrease in the measurement accuracy when changing the grade (and, therefore, electrophysical parameters) of the liquid.

There is also known a technical solution (RU 2152024, 06/27/2000) containing a description of the device closest in technical essence to the proposed concentrator and adopted as a prototype. The prototype device contains the first sensitive element in the form of a flowing cavity resonator installed on the measuring section of the pipeline with the pumped substance and connected through the elements of excitation and removal of vibrations, respectively, to the microwave generator and the unit for recording the resonant frequency of electromagnetic waves of this resonator, to the output of which is connected the first input is a calculation unit connected to an indicator. It also contains a high-frequency measuring transducer, including a long line segment with a second sensitive element in the form of a load at one of its ends, located on the measuring section, and a unit for generating high-frequency electromagnetic waves and registering the vibrational characteristics of the long line segment connected to its output which is connected to the second input of the calculation unit.

The disadvantage of this device is the low accuracy of the measurement. This is due to the fact that a sensitive element in the form of a flowing microwave resonator provides information on the electrophysical parameters of the liquid, which is averaged over the volume of this resonator. This volume can be relatively large: both the diameter of the resonator, due to the value of the diameter of the pipeline, and its length can be several centimeters. At the same time, another sensitive element in the form of an RF resonator based on a long line segment allows obtaining data on local, less than 1 cm (near the terminal load of a long line segment), values of the electrophysical parameters of the liquid. This obviously predetermines a decrease in the measurement accuracy with a change in the grade (and, therefore, electrophysical parameters) of the liquid. Therefore, even joint functional processing of the informative parameters of these two sensitive elements does not allow us to achieve the required invariance to the electrophysical parameters of the base substance in a controlled binary mixture of liquids.

The technical result of the present invention is to improve the accuracy of measurement.

The technical result in the proposed concentrator is achieved by the fact that it contains a high-frequency measuring transducer installed on the measuring section of the pipeline with the pumped liquid, including a long line segment with the first sensitive element in the form of load resistance at one of its ends, located on the measuring section in a certain section of the pipeline, and a unit for generating electromagnetic waves and registering the oscillatory characteristic of the a long line, the output of which is connected by the first input to the calculation unit connected to the indicator, while it also contains a microwave ring resonator installed on the same measuring section in the same section of the pipeline, connected through the excitation and removal elements, respectively, to the microwave the generator and the registration unit of the resonant frequency of electromagnetic waves of this resonator, the output of which is connected to the second input of the computing unit. The proposed method is illustrated by drawings.

In FIG. 1 shows a diagram of the proposed device. In FIG. 2 and FIG. 3 shows a cross section of a pipeline in cross section with elements of a device (two embodiments of the device).

The notation is introduced here: 1 - pipeline with pumped liquid, 2 - long line segment, 3 - load resistance, 4 - unit for generating high-frequency electromagnetic waves and recording the vibrational characteristics of the long line section, 5 - calculation unit, 6 - ring resonator, 7 - microwave -generator, 8 - electromagnetic oscillation excitation element, 9 - electromagnetic oscillation pick-up element, 10 - resonator electromagnetic oscillation frequency registration unit, 11 - indicator, 12 and 13 - open ends of the ring resonator, 14 and 15 - transceiver general antennas.

The device operates as follows.

The structural elements of the device are located on the measuring section of the pipeline 1 (Fig. 1). In the RF measuring transducer (first measuring channel), formed by a segment of a long line 2 with the first sensing element connected at its end - load resistance (reactive load) 3, electromagnetic waves in the RF range (~ 1-100 MHz) are excited. Block 4 is used to excite electromagnetic waves in this segment of a long line and to determine one of its vibrational characteristics, which is the first informative parameter.

An ultra-high-frequency (microwave) ring resonator (second sensitive element) can be made in the form of a waveguide 6 with open ends 12 and 13 located in the diametrical plane of the pipeline 1 at its measuring section and directed into the pipeline 1 towards each other (Fig. 2). Moreover, in the region formed by the waveguide 6 and the cross-section of the pipe 1 between the open ends of the waveguide 6, in which the controlled fluid is located, there is a standing electromagnetic wave, excited in the ring structure under consideration, resonating sequentially one of the frequencies of a discrete set of frequencies (spectrum) depending from the frequency of the connected microwave generator. In this ring resonator located in the same diametrical plane of the measuring section of the pipeline 1 as the load resistance 3 of the first (high-frequency) measuring channel, using the microwave generator 7 (in the frequency range actually ~ 1-50 GHz) through the oscillation excitation element 8 excite electromagnetic waves. The determination of the second informative parameter - the resonant frequency of electromagnetic waves of a given ring resonator, taken using element 9, is performed using the frequency registration unit 10.

In the first measuring channel, electrical capacitance, inductance, and a metal pin can be used as the load resistance of a section of a long line. In the latter case, this pin can be formed by lengthening the inner conductor of a long line; the load resistance is formed by this pin and the wall of the pipeline. To increase the amplitude of the received signal coming from a length of a long line to block 9, the pin can be covered with a dielectric sheath; in this case, a controlled fluid with arbitrary electrophysical parameters is characterized in a segment of a long line by the effective dielectric constant of a two-layer medium (controlled fluid and shell). In the RF measuring transducer, formed by a segment of a long line 2 with a load resistance 3 connected at its end, electromagnetic waves in the RF range (~ 1-100 MHz) are excited. Block 4 is used to excite electromagnetic waves in this segment of a long line and to determine one of its vibrational characteristics, which is the first informative parameter.

The measured values of both informative parameters come from the corresponding blocks 4 and 10 to the first and second inputs of the computing unit 5, respectively. From its output, the signal obtained as a result of the joint conversion of the output signals of blocks 4 and 10 goes to indicator 11. This signal corresponds to a high-precision value of the concentration of the binary mixture, independent of the electrophysical parameters (dielectric constant) of the base substance of this mixture, the degree of content of which is different substances, in particular the water content or other substances with a frequency dispersion of the substance, to be determined.

The relative position of the reactive load 3, for example, a pin, a segment of a long line 2 and open ends 12 and 13 of the microwave ring resonator in the measuring section of the pipeline 1 can be arbitrary, in particular such as shown in FIG. 2. Here all these elements are located in the same diametrical section of the measuring section; load resistance 3 is built into the wall of the pipe 1 (load resistance - pin 3 is passed through an insulator in the wall of the pipe 1).

The microwave ring resonator may have transceiver antennas 14 and 15 at the ends 12 and 13 of the waveguide 6, respectively (Fig. 3). These antennas are installed in the diametrical plane of the pipeline 1 on its measuring section opposite each other and are directed inside the pipeline towards each other and the waveguide 6 connecting them. Such a design of the ring resonator is suitable for measurements in the pipeline of sufficiently large diameter for the concentration of electromagnetic energy within a narrow beam and, thereby improving the quality factor of the ring resonator.

In this device, as in other devices (SU 1497531, 07/30/1989; RU 2152024, 06/27/2000), the presence of a frequency dispersion of the dielectric constant in the frequency ranges used for measuring at least one of the substances in their mixture (emulsion) plays a fundamental role , solution, etc.). However, another substance may not have such a dispersion, which is typical for many real substances, in particular oil and oil products. For example, water, alcohols, and other polar liquids possess frequency dispersion in the microwave range. So, in water the dielectric constant at frequencies less than 100 MHz has a value of about 80, and at frequencies in the microwave range it is much lower (for example, ~ 65 at frequencies of ~ 10 GHz). The controlled substance is characterized by the dielectric constant ε (ε _b1 , ε _b2 , K), where ε _b1 and ε _b2 are the values of the dielectric constant of the substances (denoted by "b1""b2"), the concentration K of the mixture (emulsion, solution, etc.) of which definition. To carry out measurements, it is necessary to know the analytical expression for ε for the two used HF and microwave frequency ranges; in the absence of such a calculated dependence for any controlled substances, it is established experimentally with its subsequent approximation by the corresponding analytical expression. The calculated ratios for specific controlled substances are given in the technical solution (SU 1497531, 07/30/1989).

As an informative parameter in the first (HF) measuring channel, implemented on the basis of a long line segment 3, the following can be used: resonant frequency ƒ (K) of electromagnetic oscillations of a long line segment; input impedance Z _I (K) of the long line segment; phase shift Δφ (K) of the incident (from the generator to the load) and reflected (from the load to the registrar) electromagnetic waves.

Carrying out in the block of calculations 5 a joint functional transformation of two informative parameters - one of the vibrational characteristics of the long line segment 2 and the resonant frequency of the microwave ring resonator 6 and, it is possible to determine the concentration K with high accuracy regardless of the electrophysical parameters (dielectric constant) of one (base of substances in their mixture); this substance can be either a non-polar dielectric, as described in the prototype, or have other electrophysical parameters. In this case, the solution of the compiled system of equations for the dependence of ε on informative parameters at two operating frequencies of the HF and microwave ranges also allows us to determine the dielectric constant of the base substance itself in a mixture of substances and, therefore, to characterize this substance, for example, to determine its grade.

The location of both sensitive elements in the same diametrical plane of the measuring section of the pipeline allows you to perceive information about the concentration of the binary mixture in the same section of the pipeline, thereby increasing the accuracy of measurements.

Thus, the proposed device allows you to determine the concentration of the binary mixture (emulsion, solution, etc.) with high accuracy regardless of the electrophysical parameters (dielectric constant) of the base substance in the mixture.

Claims (1)

A concentrator containing a high-frequency measuring transducer installed on a measuring section of a pipeline with pumped liquid, including a long line segment with a sensing element in the form of a load resistance at one of its ends, placed on a measuring section in a certain section of the pipeline, and an electromagnetic generation unit connected to its other end oscillations and registration of the vibrational characteristics of a segment of a long line, the output of which is connected to the first input of the unit computing, connected to the indicator, characterized in that it also contains installed in the same measuring section in the same section of the pipeline microwave ring resonator connected through the elements of excitation and removal of vibrations, respectively, to the microwave generator and the unit for recording the resonant frequency of electromagnetic oscillations of this resonator, the output of which is connected to the second input of the computing unit.

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