RU2565348C1 - Meter of flow rate of two-phase flow of dielectric materials moved by air along metal pipeline - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: in a meter of a flow rate of a two-phase flow of dielectric materials moved by air in a metal pipeline comprising serially connected a microcontroller, an indicator, a measurement insert from dielectric material built into the metal pipeline, with metering capacitor armatures arranged on it in series with registering capacitor armatures with a dielectric insert from a voltage-polarised crystal, a light polarizer, a laser radiator, a light analyser and a photodetector, at the same time at one side from the registering capacitor there is a flat mirror, and at the other side - a correcting plate, a polarizer-analyser of light connected by an optical line with a photodetector connected via a current into voltage converter with the microcontroller, connected with a liquid crystal indicator and a personal computer.

EFFECT: increased accuracy of measurement, simplified technical realisation and protection against impact of external electromagnetic fields.

4 cl, 1 dwg

Description

The invention relates to measuring technique and can be used in automatic control systems and measuring the flow rate of dielectric materials transported by air through a metal pipe. A device for measuring the speed and flow rate of a solid component in two-phase flows according to the author's certificate of the USSR No. 1275215 A1, class. G01F 1/00, G01P 5/00, published on December 7, 1986. The device comprises two capacitive differential measuring sensors mounted on a dielectric tube, the secondary signal converters of which are connected through the correlator to the first input of the multiplier, and a compensation capacitive differential sensor with a secondary signal converter, moreover, one of the measuring capacitive differential sensors through the signal converter and the adder is connected to the output of the secondary signal converter of the compensation differential sensor, and the adder output is connected to the second input of the multiplier. In order to reduce the measurement error, a measuring induction sensor, a secondary converter of an induction sensor, a divider, a correction unit, and a temperature meter are introduced into it, and a measuring induction sensor is connected through a secondary converter of a signal to the first input of the divider, the second input of which is connected to the output of the multiplier, the output of the multiplier connected to the first input of the correction unit, to the second and third inputs of which the outputs of the temperature meter and divider are connected, respectively, at The output of the correction block is the output of the device.

Moving particles of the material, falling into the induction sensor, induce the induction emf in it in proportion to the quantity and speed of charge movement. After the divider, a signal proportional to the value of the coefficient of dependence of the capacitance of the sensor on the charge of the transported material is fed to the input of the correction unit, to which a signal from the temperature meter is supplied, proportional to the value of the dependence of the temperature coefficient of dielectric constant. At the output of the correction block, a signal appears proportional to the measurement of mass flow.

The disadvantage of the device working on the correlation method is the dependence of the signals on random fluctuation processes in the pneumatic pipeline, the violation of the similarity of the signals with increasing distance between the sensors leads to a decrease in the accuracy of flow measurement. Statistical signal processing greatly complicates the technical implementation of the meter.

The output signal from block 12 for subsequent processing to the metering station is transmitted via a wire line susceptible to external electromagnetic fields, which increases the technical requirements for noise immunity of the measuring system.

Closest to the technical nature of the present invention is a flow meter for a two-phase flow of bulk dielectric materials transported by air through a metal pipe (RF patent No. 2 435141 C1, class G01F 1/00, publ. 11/27/2011). This device is taken as a prototype of the invention.

The flow meter of a two-phase flow of bulk dielectric materials transported by air through a metal pipeline contains a microprocessor and an indicator connected in series with each other, a measuring insert made of dielectric material is integrated in the metal pipe, on which are located the plates of the measuring capacitor, connected in series with the plates of the recording capacitor with a dielectric insert from polarized by the voltage of the crystal, while on the one hand from the register A light polarizer and a laser emitter are placed on the capacitor, and on the other hand, there is a light analyzer and a photodetector, the output of which is connected to the input of the amplifier, the output of which is connected to the input of the microprocessor, the output of which is connected to the indicator, and a lithium niobate crystal is used as the voltage polarized crystal.

However, the prototype has several disadvantages.

The meter uses a classic Pockels cell with a single passage of a light wave through an optical crystal, which limits the accuracy of the meter. The output of the photodetector is connected by a wire line to the processing system of the measuring signal, which increases the requirements for protection from the influence of external electromagnetic fields.

The task of the invention is to improve the flow meter of a two-phase flow of dielectric materials transported by air through a metal pipe.

The technical result from the use of the invention is to improve the accuracy of the meter and protection from external electromagnetic fields.

The specified technical result is achieved by the fact that in the flow meter of a two-phase flow of dielectric materials transported by air through a metal pipe, containing a microcontroller connected in series with each other, an indicator, a measuring insert of dielectric material embedded in a metal pipe, with measuring capacitor plates located on it, connected in series with plates of a recording capacitor with a dielectric insert made of polarizable voltage crystal, a light polarizer, a laser emitter, a light analyzer and a photodetector, with a flat mirror placed on one side of the recording capacitor, and a correction plate on the other side, a light analyzer connected to the photodetector by an optical line, connected through a current to voltage converter with a microcontroller connected to a liquid crystal display and a personal computer.

Crystals of lithium tantalate LiTaO ₃ , lithium niobate LiNbO ₃ , barium BBO beta borate, and KTP series crystals can be used as a voltage-polarized crystal.

The drawing shows a functional diagram of the meter.

The meter contains a measuring insert 1 of dielectric material embedded in a metal pipe on which are located the cylindrical plates of the measuring capacitor 2, connected in series with the plates of the recording capacitor 3 with a dielectric insert of a voltage polarized lithium tantalate crystal (LiTaO ₃ ).

On one side of the recording capacitor 3, a flat mirror 6 is placed, and on the other hand, a correction plate 4, a polarizer-light analyzer 5, connected by an optical line 8 to a laser emitter 7 and a photodetector 9, connected through a current to voltage converter 10 to a microcontroller 11 connected with a liquid crystal display 12 and a personal computer 13.

The meter works as follows.

A two-phase material - air flow when passing between the cylindrical plates of the measuring capacitor 2 causes a change in capacitance proportionally to a change in the concentration of the material in the volume of the measuring insert 1, which leads to a change in the electric field strength in the recording capacitor 3 connected in series. This causes amplitude modulation of the light flux passing through the dielectric an insert from a voltage polarized lithium tantalate crystal (LiTaO ₃ ). The luminous flux is generated by a laser emitter 7, transmitted through the fiber optic cable 8 to the Glan prism 5, which is used as a polarizer at the input of the luminous flux. After passing through the polarizer, the light flux acquires linear polarization, passes in the forward direction, and is reflected from the plane mirror 7 in the opposite directions through a recording capacitor 3 (amplitude optical light modulator based on the Pockels transverse effect) and a correction plate 4 that carries out optical bias of the first kind, transforming circularly polarized light waves into it into linearly polarized light waves. Twice amplitude-modulated, depending on the concentration of the volume of substance passing through the measuring insert 1, the light flux passes through a Glan prism 5, which is used as an analyzer at the output of the light flux and enters the photodetector 9 through the fiber optic cable 8, the output of which an electric signal through a current to voltage converter 10 is transmitted for processing according to the algorithm to the microcontroller 11, from the output of which information is supplied to the indicator 12 and personally th computer 13, information related to the automated process control system (automated process control system). The microcontroller creates an image of the presentation of the results of flow measurement in the form of numbers, graphs, histograms on the indicator 12. Improving the accuracy of the measurement in the flow meter is achieved by doubling the optical path of the light flux in the electro-optical element due to reflection in a flat mirror.

The optical scheme used in the device allows you to use only one Glan prism at a time as a polarizer and analyzer, which technically simplifies the device. The use of fiber optic fibers significantly increases the noise immunity of the meter from external electromagnetic fields.

The mass flow rate Q _{m of the} flow created by the pneumatic conveying installation is determined by the formula Q _m = K × S, where K is the calibration mass coefficient determined experimentally by passing the standard calibration mass of the measured substance through the measuring insert m _cm , S is the area bounded by the graphical dependence sensor signal intensity versus time during the measurement period.

, где S_cm - площадь, ограниченная кривой графической зависимости интенсивности сигнала датчика за контрольный период измерений.The calibration factor is determined according to the dependence: $$K=\frac{m_{cm}}{S_{cm}}$$

, where S _cm is the area bounded by the curve of the graphical dependence of the intensity of the sensor signal for the control period of measurements.

, где ρ - плотность транспортируемого вещества.The volumetric flow rate Q _v is determined according to the dependence: $$Q_v=\frac{Q_m}{\rho }$$

where ρ is the density of the transported substance.

As the recording capacitor 3, an electro-optical Pockels cell was used, representing a 6 × 6 × 30 mm lithium tantalate crystal with deposited electrodes from G + Au on the X-surface manufactured by Elan LLC (St. Petersburg). (It is also possible to use crystals of lithium niobate, barium beta borate, and KTP). As a polarizer-analyzer of light 5, a Glan prism and a λ / 8 plate manufactured by Elan LLC (St. Petersburg) were used. As a laser emitter 7, a KLM - D650-5-5 laser module with a power supply unit manufactured by the FTI-Optronic (St. Petersburg) was used. As an optical radiation receiver 9, an avalanche photodiode of the SAE 650 NM series manufactured by Laser Components (Germany) was used. The current to voltage converter 10 is assembled on the MAX 323 2 CUE + integrated circuit manufactured by Maxim integrated (USA). As microcontroller 11, a cFP - 2020 microcontroller manufactured by Nationale Instruments (Hungary) was used. As an indicator 12, an Acer monitor, LSD Monitor V 193A (China) was used. As a personal computer 13, any computer no lower than Pentium 4, 1.5 GHz can be used. For optical communication, a multimode optical cable 8 with end lenses was used to input and output the light flux produced by the Eurocable-1 plant (Russia), and it is possible to use the BELDEN GIPS2E2 optical cable (USA) and other manufacturers.

Thus, the present invention improves the accuracy of the measurement by increasing the resolution of the measuring system as a result of doubling the optical path length of the modulated light flux in the electric element.

In addition, it increases the protection of the meter from the influence of external electromagnetic fields through the use of a multimode fiber-optic cable for transmitting measurement information from the Pokels cell, which is structurally located on the measuring insert in the pipeline, to the information processing and display system, which can be installed in the control center on significant distance.

Simplification of the technical implementation of the device is achieved through the use of complete products commercially available from the industry.

The expected economic effect of using the meter was 1.5% of the cost of the dielectric material transported through the pipeline.

Claims (4)

1. A flow meter of a two-phase flow of dielectric materials transported by air through a metal pipe, comprising a microcontroller connected in series with each other, an indicator, a measuring insert of dielectric material embedded in a metal pipe, with measuring capacitor plates located on it, connected in series with the plates of the recording capacitor with dielectric insert from a voltage-polarized crystal, light polarizer, laser radiation a detector, a light analyzer and a photodetector, characterized in that a flat mirror is placed on one side of the recording capacitor, and on the other hand a correction plate, a polarizer-light analyzer connected by an optical line to a photodetector connected via a current to voltage converter to a microcontroller connected to LCD indicator and personal computer. 2. The meter according to claim 1, characterized in that the λ / 8 plate is used as the correcting plate. 3. The meter according to claim 1, characterized in that one Glan prism is used as a polarizer-analyzer of light. 4. The meter according to claim 1, characterized in that a cylindrical capacitor is used as the measuring capacitor.