RU2307327C2 - Flow meter for measuring fluid flow in open reservoirs - Google Patents

Abstract

FIELD: measuring technique.

SUBSTANCE: flow meter comprises unit for measuring velocity of the flow made of a blade shaped into a tube and level gage. The pressure gage is mounted at the end of the blade. The second pressure gage, identical to the first one, is mounted in the ambient air. The signals from the pressure gages are fed to the electronic unit for determining the depth of the flow that is determined as a sum of two fluid layers, h₁ and h₂, measured from the surface to the bottom of the reservoir. The h₁ depth is determined by means of the pressure gage interconnected through the differential circuit , and h₂ depth is determined from the angle of deviation of the blade from the vertical line with regard to the length of blade and height of its suspension with respect to the bottom of the reservoir.

EFFECT: simplified structure.

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Description

The invention relates to measuring equipment for flow meters, and in particular to methods and devices for measuring the volumetric flow rate of liquid media in open reservoirs - channels, non-pressure pipelines of large cross-section and waste trays.

The class of ultrasonic flow meters based on the Doppler effect is well known, as well as the class based on the lateral drift method of a narrow sound beam. In the Doppler method, a sound wave propagating along or against a fluid flow in a given “segment” of a pipe acquires a time shift, as well as phase and frequency incursions that are proportional to the flow velocity. From these data, the volumetric flow rate of the liquid is calculated. In the case of using the second specified ultrasonic method, the flow rate is the largest lateral drift of the sound beam during the transverse passage through the layer of moving fluid.

The most important advantages of ultrasonic flow meters include the possibility of using them for any liquids, including chemically aggressive ones. The disadvantage of such flowmeters is the complexity of the measuring system, which is mainly due to the smallness of the v / c ratio, where v is the fluid flow rate; c is the speed of sound in it.

There is also a class of electromagnetic (induction) flow meters operating on the basis of using the magnetohydrodynamic induction effect of electrical signals that occur when a conductive fluid moves in a pipeline across the direction of a magnetic field. In this case, the signal electrodes are located at opposite ends of the pipe diameter. The magnitude of the EMF signal is proportional to the speed of the liquid and, therefore, its flow rate. Flowmeters of this type operate both on the basis of a constant magnetic field and an alternating, in particular a pulsed, field. An important positive quality of flow meters of this type is the possibility of their operation in various liquid media having even low electrical conductivity. However, these devices are inherent in fundamental shortcomings, namely, the occurrence of electrochemical processes in them on the electrodes, leading to polarization of the electrodes and, as a consequence, distortion of the signals. At the same time, when working in variable and pulsed magnetic fields, all kinds of electromagnetic pickups are induced for the electrical purposes of the measuring device, which are difficult to eliminate interference when registering useful signals.

The type of flow meters for open water bodies is also known, during the operation of which it is required to simultaneously and independently measure both the fluid flow rate and its level. In particular, a flow meter [patent for invention No. 2251080], which is adopted below as a prototype, relates to such flowmeters. The functional unit for measuring the average flow rate in it is made in the form of a rotary blade. One end of the blade is fixed on the axis of rotation, and the other is freely immersed in the liquid. Due to the speed of movement, the fluid exerts dynamic pressure on the blade and rotates it relative to the vertical by a certain angle proportional to the flow velocity. At the same time, a typical sensor with an integrated microcircuit is used as a sensor for measuring the angle of rotation of the blade. This sensor is sensitive to deviation from the vertical relative to the horizon.

The second functional measuring unit in the flowmeter-prototype is a level gauge, which is made in the form of a typical spherical-shaped float fastened with a lever. The float freely rotates on the axis of rotation in a vertical plane, regardless of the spatial position of the measuring blade. The angle of rotation of the float is uniquely related to the liquid level. A sensitive element for measuring a given angle of rotation is also made on the basis of the aforementioned similar microcircuit.

A positive quality of such a flow meter is the fact that it uses standardized sensitive angular rotation sensors, as well as the comparative simplicity of the design of the measuring blade and the level gauge lever. However, this flowmeter - the prototype - inherent fundamental disadvantages. The main one is the need to use two independent rotary mechanical elements - the blade and the lever. In fact, both rotary elements are located at different points of measurement of velocity and liquid level, where the flow regimes can vary greatly. This inevitably introduces into the measurement difficult to eliminate errors in determining the volume of fluid flow. At the same time, during the operation of the flowmeter, the friction coefficients of sliding on the surface of the axis of rotation of the blades and levers change differently over time, which is associated with the “harsh” conditions of their operation — high dampness and a wide range of temperature changes. Together, these factors lead to additional difficult to eliminate errors in measuring the volume of fluid flow. Along with what has been said, the “biaxial” system of the device presents certain difficulties for the prevention and technical revision of the operating state of the device.

The aim of the invention is the technical simplification of the flow meter, leading to the complete elimination of the float unit, while maintaining all the measuring functions of the flow meter.

The goal is also to increase the reliability of the flowmeter, improve the accuracy of measurement and simplify the maintenance process at the stages of operation, inspection and repair.

This goal is achieved by the fact that a new method of measuring the liquid level is introduced into the flowmeter, namely, the depth of the flowing liquid from the surface to the bottom of the channel is determined as the sum of two layers of liquid.

The first of them extends from the surface of the liquid to the level of immersion of the end of the blade in the process of measuring the speed of the liquid. The second layer is counted from the end of the blade to the bottom of the channel. In this case, the thickness of the first layer is determined using two identical pressure sensors that are electrically interconnected according to a difference scheme. One of these sensors is mounted at the end of the measuring blade, and the second sensor is placed in an air atmosphere. The depth of the next - the second layer of liquid - is determined by the angle of deviation of the blade from the vertical, taking into account the full length of the blade and the height of its suspension relative to the bottom of the channel.

Thanks to the introduction of a new method for measuring the liquid level and a corresponding change in the technical device of the flow meter, the block of the float level meter is completely excluded from its block design. As a result, the entire design of the flowmeter is technically simplified, the reliability and accuracy of operation are increased, and the operation of this device is also facilitated.

To illustrate the operation of the invention, a block of a level gauge is schematically shown in the drawing. The following notation is accepted here: 1 - rotary blade; 2 - angle sensor β of rotation of the blade, made on the basis of microcircuit type ADXL; 3 - axial connection of the blade; 4 - pressure sensor made on the basis of the MPX10D chip; 5 - the second similar pressure sensor; 6 - an electronic unit that processes signals from sensors 2, 4, 5; h ₁ - the thickness of the liquid layer from the surface level to the level of the immersed end of the blade; h ₂ - the second layer of liquid from the end of the blade to the bottom of the channel; h = h ₁ + h ₂ is the total height of the liquid level at the time of measuring speed; N is the height of the suspension of the blade relative to the bottom of the channel; V is the fluid flow rate in the vicinity of the segment AB, i.e. submerged part of the blade 1.

The level gauge operates as follows. When the flow velocity V changes, which occurs when the fluid level h changes, the hydrodynamic effect of the flow on the immersed part of the blade AB simultaneously changes. The blade 1, which is under the action of hydrodynamic pressure force, as well as hydrostatic buoyancy force and gravitational gravity, is automatically shifted as a result of rotation about axis 3 to a new equilibrium position, determined by the angle β. At the same time, the redistribution of the thickness of the liquid layers h ₁ and h ₂ corresponding to the new liquid level h = h ₁ + h ₂ occurs. In this case, the sensor 2 generates an electric signal about the value of the angle β, which is transmitted to the receiving electronic unit 6. The sensor 4 generates its signal about the total pressure of the "column" of liquid above it and the pressure of atmospheric air. The pressure sensor 5 accordingly generates a signal about the value of atmospheric pressure. The signals from the sensors 4 and 5 are fed to the receiving unit 6. In this block, the angle β is calculated by the signal of the sensor 2. The signals of the sensors 4 and 5 are the thickness of the first liquid layer h ₁ . In turn, the layer thickness h _{2 is} calculated from the known values of the suspension height of the blade N, the full length of the blade and the angle of deviation β.

Therefore, as a result of the joint calculation processing of the listed data entering the measuring unit 6, the effective cross-section of the flow and the average speed for “a given moment in time” are determined. Based on this information, in the same block 6 is calculated the volumetric flow rate of the liquid according to the usual rule "area × speed".

The invention is implemented in a pilot version corresponding to the circuit shown in figure 1. The rotary blade 1 is made of stainless steel in the form of a cylindrical tube with a length of 1530 mm, a diameter of 22 mm and a wall thickness of 1.5 mm. At the end of the tube in its cavity there is a pressure sensor 4 made on the basis of the MPX10D microcircuit. At the beginning of the tube is placed a sensor 2 of the angle of rotation of the blade, made on the basis of the ADXL chip. In the atmosphere of air - outside the blade - a pressure sensor 5 is installed, made on the basis of the MPX10D microcircuit. The electronic unit 6 for receiving and processing electrical signals from these sensors is a complex of standard electronic circuits. The device is tested in natural conditions, i.e. it was installed in a tray with a given cross-sectional geometry. Water flowed through the tray at an average speed in the range of 10 to 200 cm / s.

The results of the experiments showed high stability of the device, ease of operation, as well as good accuracy and reproducibility of the results of measuring water flow.

This embodiment of the invention in the form of a prototype does not exclude other variants of the flowmeter device within the scope of the claims.

Thus, the invention is technically and functionally significantly simplified relative to the prototype. The invention also gained great reliability, ease of operation and the extended dynamic range of accurate measurement of fluid flow in open water.

Claims (1)

A liquid flow meter in open reservoirs comprising a flow velocity measuring unit including a blade configured to deviate from a vertical by a certain angle β, a level gauge, and an electronic unit for receiving and processing signals from a blade deflection angle sensor, characterized in that it contains two identical sensors pressure, one of which is installed on the end of the blade made of the tube, and the second is placed in the atmosphere of air, while the signals of the pressure sensors are fed to the electronic unit to determine the depth flow from the surface level to the bottom of the reservoir as the sum of two fluid layers h ₁ and h ₂ , the first of which extends from the surface level to the immersion level of the end of the blade in the process of measuring the flow velocity, and the second layer from the end of the blade to the bottom of the reservoir, and the depth h _{1 is} determined using pressure sensors electrically interconnected according to a difference scheme, and the depth h ₂ is determined by the angle β of deviation of the blade from the vertical, taking into account the length of the blade and the height of its suspension relative to the bottom of the reservoir.