RU2717701C1 - Method for measuring volume flow in vortex flowmeters - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention relates to measurement equipment and can be used in vortex counters of flow meters for measurement of volume flow using Karman vortices. Method of measuring volume flow in vortex flowmeters involves creating in a measuring channel of a counter a regular sequence of vortices, recording each vortex in the form of an electric pulse, measuring current values of pulse repetition frequency f, as well as temperature and pressure of substance, calculation by indirect method of current value of kinematic viscosity of substance ν: for liquid – by temperature, for gas or steam – by temperature and pressure. Volumetric flow rate Q is calculated in accordance with the expression Q=f·C/Sh, using the measured vortex frequency f, the constant C coefficient, which is equal to the geometric constant of the measurement channel and the calculated current value of the Strouhal number Sh based on the linearized expression of the dependence of the number Sh on the inverse value of the dimensionless numbers Ro, which allows to expand range and increase accuracy of flow rate measurement. Coefficients a and b for the linearized dependence Sh (1/Ro) are determined by the method of least squares during calibration of the vortex flow meter based on specified reference points of flow rate. Volume W of the leaked substance is defined as the product of the sum of pulses recorded during the measurement period by the pulse weight, W=ΣN·P_P, wherein the pulse weight supplied to the flow meter output can have any given fixed value equal to the substance volume. Using the linearized expression for the Strouhal Sh number of the form Sh=a+b/Ro as linear dependence of the number Sh on the inverse value of the dimensionless number Ro, the coefficients a and b of which are calculated using the least squares method, enables to expand the measurement range for the vortex flowmeters for given measurement error. It also makes it possible to avoid calculation of the current value Sh through the approximating dependence of the number Sh of the Strouhal through the Reynolds number – Sh (Re), which introduces additional errors into the flow measurement due to determination of the number Re through the additional approximating function Re(Ro), thus providing higher measurement accuracy . Calculation of flow rate, performed using parameters of medium (dimensionless number Ro), frequency f of vortices and geometrical constants of measuring channel (number C), allows to leave in calculations from weight coefficient, unequal in general case ratio C/Sh, which makes it possible to use any weight of the pulse arriving at the output of the vortex flow meter, equal to the volume of the last substance, and to expand the measurement range.

EFFECT: high measurement accuracy while widening the operational capabilities of the vortex flow meter.

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Description

The invention relates to measuring technique and can be used in vortex counters, flow meters for measuring volumetric flow using Karman vortices.

A known method of measuring the volumetric amount of a substance using Karman vortices, which are recorded by a sensitive element in the form of an output periodic signal and converted into a pulse signal. The volume W of the leaked substance is determined by the number N of pulses recorded for a controlled period of time, multiplied by the weight coefficient K, W = ΣN⋅K. In this case, the weight coefficient K, m ³ / imp, the volume of the substance per pulse is assumed to be a constant value K = const and determined by preliminary calibration of the flow meter.

A disadvantage of the known method for measuring the volumetric quantity of a substance is a limited range of flow measurements, defined by Re Reynolds numbers, at which the linearity of the characteristics of the weight coefficient is preserved (K = const). The values of the boundary numbers Re _gran are Re _gran = (1 ÷ 2) ⋅10 ⁴ (P.P. Kremlevsky, Flowmeters and counters of quantity. L., Mechanical Engineering, Leningrad Branch, 1989, p. 364). When the Reynolds numbers are lower than the above (Re <Re _gran. ), The linearity of the characteristic is violated and the measurement error of the volumetric amount of the substance in this region becomes significantly high. The weight coefficient K can be written:

where ΔW is the volume per pulse;

f is the Karman vortex oscillation frequency corresponding to the period T, T = 1 / f;

C is the geometric constant of the measuring channel, C = h⋅S;

h is the characteristic size of the flow body in the measuring channel of the flow meter;

S is the cross-sectional area of the measuring channel;

Sh is the Strouhal number.

The volume of the leaked substance W will then be equal to:

The number Sh is constant Sh = const at the numbers Re> Re _gran and the vortex flow meter in this area has a linear measurement characteristic, while the weight coefficient K = const and does not depend on the physical properties of the substance and the value of the volume flow (P.P. Kremlevsky, Flowmeters and quantity counters. L., Mechanical Engineering, Leningrad Branch, 1989, p. 364).

A disadvantage of the known method for measuring the volumetric quantity of a substance using Karman vortices is the increased measurement error when the flowmeter is operating in the region of small Reynolds numbers Re <Re _gran , since the number Sh is not constant and the linearity of the measurement characteristic is violated, the measurement error becomes larger as less than the number Re at which the measurement is carried out.

вычисляют через r текущее значение весового коэффициента К(r), реперные (опорные) значения которого определяют путем предварительной градуировки расходомера в виде зависимости К(r)=а+b/r, где a, b - коэффициенты аппроксимации, или в виде зависимости K(r)=c+d/rⁿ, где с, d, n - коэффициенты аппроксимации и показатель степени, которые затем используют в измерениях при определении текущего значения K(r). Объем W протекшего вещества определяют как произведение числа N импульсов, просуммированных за время измерения, на переменный весовой коэффициент К(r): W=ΣN⋅K(r). При этом весовой коэффициент K(r) отождествляется с объемом вещества ΔW, приходящимся на один импульс.Known vortex method for measuring the volumetric amount of leaked substance [RU No. 2291400 C2, IPC G01F 1/32 (2006.01), G01F 15/02 (2006.01), publ. 07/20/2004], according to which a regular sequence of vortices is created in the measuring channel of the meter of the flowmeter of the quantity of substance, the passage of each vortex transferred by the flow is recorded in the form of an electric pulse, the pulses are summed over a controlled period of time, the current values of the pulse repetition rate f, as well as temperature and pressure medium, indirectly calculate the current value of the kinematic viscosity ν of the medium: for a liquid - at its temperature, for a gas or steam - at its temperature and pressure NIJ, calculated auxiliary parameter

calculate through r the current value of the weight coefficient K (r), the reference (reference) values of which are determined by preliminary calibration of the flow meter in the form of the dependence K (r) = a + b / r, where a, b are the approximation coefficients, or in the form of the dependence K (r) = c + d / r ⁿ , where c, d, n are approximation coefficients and exponent, which are then used in measurements to determine the current value of K (r). The volume W of the leaked substance is defined as the product of the number N of pulses summed during the measurement by the variable weight coefficient K (r): W = ΣN⋅K (r). In this case, the weight coefficient K (r) is identified with the volume of the substance ΔW per one pulse.

The disadvantage of this method is the impossibility of achieving maximum measurement accuracy over the entire range of Re numbers, since the weight coefficient K (r) in the general case is not equal to the C / Sh ratio and does not take into account the geometric parameters of the measuring channel.

A known method of measuring the volumetric amount of a substance, namely liquid, gas or steam, is selected as a prototype [RU No. 2478916 C2, IPC G01F 1/32 (2006.01), publ. 04/10/2013], which consists in creating a regular vortex sequence in the measuring channel of the vortex meter of the flowmeter, registering each vortex as an electric pulse, measuring the current values of the pulse repetition rate f, as well as the temperature and pressure of the substance, indirectly calculating the current value of the kinematic viscosity ν of the substance : for liquid - in temperature, for gas or steam - in temperature and pressure. The volume W of the leaked substance is calculated by summing during the measurement of the volume ΔW of the substance per pulse. The volume ΔW is calculated for each pulse individually using the current value of the Strouhal number Sh according to the formula ΔW = K _g / Sh, where K _g is the geometric coefficient, defined as the product of the width of the body flowing around the cross-sectional area of the measuring channel. The current value of the number Sh is calculated by substituting the current value Re into the dependence Sh (Re) obtained by calibrating the counter in the operating range of Re values, the current value of Re is calculated by the formula Re = -b + Ro / a, where a and b are the coefficients of the approximating function Sh ( Re) the dependences Sh = a⋅ (1 + b / Re), Ro is the Roshko number, Ro = h ² ⋅f / ν, where: h is the width of the flow body, ν is the kinematic viscosity.

The volume W of the leaked substance is determined by the formula:

where ΔW is the volume of the substance for one pulse, N is the total number of pulses recorded during the measurement.

A known flow meter consists of a measuring channel and an electronics unit. In the input part of the measuring channel there is a poorly streamlined body in the form of a prismatic rod of trapezoidal cross section, the longitudinal axis of which is perpendicular to the axis of the measuring channel, and the larger base is directed towards the incoming flow. Behind the body of the flow around the flow there are sensitive elements of flow, temperature and pressure. With the help of the flow body, a regular sequence of vortices is created in the measuring channel. Using the flow sensing element, the passage of the vortices is recorded, and using the temperature and pressure sensing elements, the temperature and pressure of the controlled medium are measured. The output signals of the flow sensor and the temperature and pressure sensors are amplified, normalized and fed to the corresponding inputs of the microcontroller with an external non-volatile memory. The following is recorded in the memory of the microcontroller: dependence Sh (Re) in the form, for example, of the coordinates (Sh _j , Re _j ) of the points on the Sh-Re graph; the dependence of the viscosity of the medium on temperature and pressure in the form, for example, of coefficients approximating this dependence; coefficients a and b approximating the dependence Sh (Re), the values of geometric parameters.

The microcontroller program provides the calculation of the average value of the output vortex frequency, the current value of the kinematic viscosity, the Ro number and the Re number equal to Re = -b + Ro / a. From the values of the number Re, the values of the number Sh are determined based on the dependence Sh (Re) taken during calibration of the counter. After that, the volume per each pulse is calculated by the formula ΔW = Kr / Sh and, as pulses arrive, the current value of the volume of the leaked substance W = ΣN⋅ΔW of the number of pulses during the measurement is calculated.

The disadvantage of this method is the reduced accuracy of the measurements, since according to equation (2) of the measurements of the vortex meter of the flowmeter, the volume of the leaked substance is equal to: W = ΣN⋅ΔW = ΣN⋅C / Sh. Moreover, for this method, the calculation of the number Sh through the approximating dependence Sh (Re) introduces additional measurement errors that appear when calculating the number Re through the approximating function Re (Ro) based on the measured pressure and temperature of the medium, which leads to an increased measurement error .

Another disadvantage of this method is the limited operational capabilities of the flow meter counter, since the weight ΔW of the pulse supplied to the output of the flow meter counter has a variable value, tied to the geometric parameters of the measuring channel, which causes inconvenience in the operation of the vortex flow meter counter in gas meters or heat meters.

The objective of the method is to increase the accuracy of measurements while expanding the operational capabilities of the vortex counter of the flow meter.

The problem is solved in that in the method of measuring the volumetric flow in vortex flowmeters, which consists in creating a regular sequence of vortices in the measuring channel of the vortex meter of the flowmeter, registering each vortex as an electrical pulse, measuring the current values of the pulse repetition rate f, as well as the temperature and pressure of the medium , indirectly calculating the current value of the kinematic viscosity v of the substance, calculating the volumetric flow rate Q of the leaked substance according to the formula taking into account the measurement the frequency v of the vortices, the current value of the Strouhal number Sh, the kinematic viscosity ν of the substance, the geometric coefficient C of the measuring channel, equal to the product of the flow body width by the cross-sectional area of the measuring channel, ACCORDING TO THE INVENTION, when calibrating a vortex flowmeter for given reference flow points over the entire operating range flow rates at which there is a regular sequence of vortices is determined by measuring the volumetric flow rate of the least square method the coefficients a and b Ymir Shl number depending on the reciprocal of the number of Ro, equal Shl = a + b / Ro, where Ro = h number ² ⋅f / ν, h - the width of the flow body, f - frequency of the vortices, ν - kinematic viscosity substance, and calculating a current volume flow rate Q according to the formula Q = f /C / Shl, where Shl is the calculated current value of the number Sh, the volume W of the leaked substance is defined as the product of the sum of the number N of pulses recorded during the measurement by any given weight of the pulse, P equal to the volume of the substance : W = ΣN⋅Pи, while the period Ti of pulses at the output of the flowmeter is determined as Tи = Pи / Q.

Using for calculating the flow rate of the linearized expression for the Strouhal number Sh of the form Sh = a + b / Ro, as a linear dependence of the number Sh on the inverse of the dimensionless number Ro, the coefficients a and b of which are calculated using the least squares method, allows us to expand the measurement range for vortex flowmeters for a given measurement error. It also makes it possible to get away from calculating the current value of Sh through the approximating dependence of the Strouhal number Sh through the Reynolds number - Sh (Re), introducing additional errors in the flow measurement due to the determination of the Re number through the additional approximating function Re (Ro), thereby increasing the measurement accuracy . Calculation of the flow rate using the parameters of the medium (dimensionless number Ro), the frequency f of the vortices and the geometric constants of the measuring channel (number C) allows us to avoid the weight coefficient, which is generally unequal in the C / Sh ratio, which makes it possible to use any weight the pulse arriving at the exit of the vortex flowmeter equal to the volume of the leaked substance, and expand the measurement range.

The technical result is an increase in measurement accuracy while expanding the measurement range.

The inventive measurement method has a novelty in comparison with the prototype, differing from it by such significant features as the determination during calibration of a vortex flowmeter for given reference flow points in the entire working range of flow rates at which there is a regular sequence of vortices using the least squares coefficients a and b the linearized approximating dependence of the number Shl on the inverse value of the number Ro equal to Shl = a + b / Ro, where the number Ro = h ² ⋅f / ν, h is the width of the body around the flow, f is the frequency of the vortices, ν is the kinematics viscosity of the substance, calculation of the current volumetric flow rate Q using the measured vortex frequency f, constant coefficient C equal to the geometric constant of the measuring channel and the calculated current value of the Strouhal number Sh based on the linearized expression of the dependence of the number Sh on the inverse of the dimensionless number Ro according to the formula Q = f ⋅C / Shl, where Shl is the calculated current value of the number Sh, the definition of the volume W of the leaked substance as the product of the sum of the number N of pulses recorded during the measurement by any equal to the volume of the substance, the specified weight of the pulse P1: W = ΣN⋅Pi, and the determination of the period Tp of pulses at the output of the flowmeter as Tp = Pi / Q, which together ensure the achievement of a given result.

The applicant is not aware of technical solutions that have the above distinguishing features that would ensure the achievement of a given result, therefore, he believes that the claimed method meets the criterion of "inventive step".

The inventive method of measuring the volumetric flow rate in vortex flowmeters can be widely used in measuring technology and therefore meets the criterion of "industrial applicability".

The invention is illustrated by drawings, which are presented in:

- FIG. 1 is a functional diagram of a vortex flowmeter counter;

- FIG. 2 is a functional diagram of a calculation algorithm;

- FIG. 3 shows test results for a vortex counter of a flowmeter of type 1;

- FIG. 4 shows test results for a vortex meter of type 2 flowmeter.

The proposed method for measuring volumetric flow in vortex flowmeters

provides measurements directly in accordance with the basic equation of the vortex flowmeter. It consists in creating a regular sequence of vortices in the measuring channel of the counter, registering each vortex as an electric pulse, measuring the current values of the pulse repetition rate f, as well as the temperature and pressure of the substance, indirectly calculating the current value of the kinematic viscosity of the substance ν: for a liquid, by temperature , for gas or steam - by temperature and pressure. The volume flow rate Q is calculated in accordance with the expression Q = f⋅C / Sh using the measured vortex frequency f, constant coefficient C equal to the geometric constant of the measuring channel and the calculated current value of the Strouhal number Sh based on the linearized expression of the dependence of the number Sh on the inverse value dimensionless Ro number, which allows you to expand the range and improve the accuracy of cost measurement. Coefficients a and b for the linearized dependence Sh (1 / Ro) are determined by the least squares method when calibrating a vortex flowmeter at given reference flow points. The volume W of the leaked substance is defined as the product of the sum of the pulses recorded during the measurement by the weight of the pulse, W = ΣN⋅P, and the weight of the pulse supplied to the output of the flow meter counter can have any given fixed value equal to the volume of the substance.

The inventive method of measuring the volumetric flow rate is implemented in a vortex counter flow meter (Fig. 1), consisting of a measuring channel 1 and block 2 of the electronics. In the measuring channel 1, the flow body 3 is arranged in the form of a poorly streamlined rod, the longitudinal axis of which is perpendicular to the axis of the measuring channel 1, and the larger base is directed towards the incoming flow 4. A regular sequence of vortices 5 is created with the help of the body 3 around the flow channel, the frequency of which is proportional flow rates 4. Sensitive elements of vortices 6, temperature 7 and pressure 8 are located behind the body 3 around the flow in the stream 8. The sensitive element 6 of the vortices captures the passage of vortices, and with omoschyu sensing elements 7 and 8 is measured by the temperature and pressure environment. The output signals of the sensing element 6 of the vortices and the sensing elements 7 of the temperature and 8 pressure are supplied to the inputs of the shapers 9, 10 and 11, which amplify and convert them into output normalized signals. The latter are supplied to the corresponding inputs of the microcontroller 12 with an external non-volatile memory 13. The following data are entered into memory 13: approximation coefficients a and b of the linearized approximating dependence Sh (1 / Ro) obtained during calibration of the flow meter counter; the dependence of the viscosity ν of the medium on temperature and pressure in the form, for example, of tables or coefficients of the approximating function; geometric constants C of the measuring channel; pulse weight equal to the volume of the substance. The calculated volumetric flow rate Q (14) from one output of the microcontroller 12 goes to the indicator 15 and is used to calculate the frequency of the output pulses 16, the weight of which has a fixed value equal to the volume of the substance. The pulses 16 from the other output of the microcontroller 12 pass through the former 17 and are fed to the output 18 of the flow meter counter.

The calculation algorithm (Fig. 2), programmed in the microcontroller 12, implements a method of measuring the volumetric flow rate by performing the following operations. When you turn on the unit 2 of the electronics automatically begins the measurement of each period of the output signal from the output of the sensing element 6 of the vortices and the calculation of the average frequency f of the vortices. Based on the current values of the signals of the sensing elements 7 temperature and 8 pressure, the density of the medium is calculated: for liquid from the current values of the temperature of the medium, for gas from the current values of temperature and pressure of the medium. The current value of the kinematic viscosity ν of the medium is calculated, the value of the number Ro is calculated using the width h of the body 3 around the flow, the kinematic viscosity ν and the frequency f of the vortices. The values of the number Ro are used to calculate the values of the number Sh, according to the linear dependence formula Sh = a + b / Ro with approximation coefficients a and b obtained by calibrating the flow meter counter. The current value of the volumetric flow rate is calculated in accordance with the expression Q = f ShC / Sh, using the measured vortex frequency f, a constant coefficient C equal to the geometric constant of the measuring channel, and the calculated value of the number Sh. Based on the calculated volumetric flow rate Q, the period and frequency of the pulses arriving at the flowmeter output are calculated. To calculate the period and frequency of the pulses, the set value of the pulse weight Pi, equal to the volume of the substance, and the measured volumetric flow rate Q, the pulse period is equal to Ti = Pi and Q, the frequency is equal to f = Q / Pi. The volume W of the leaked substance is determined in external devices, such as gas meters or heat meters, as the product of the sum of the pulses recorded during the measurement by the weight of the pulse, W = ΣN⋅P and.

The tests confirmed the effectiveness of the claimed method for measuring volumetric flow, in terms of improving the accuracy of measurements and expanding the operational capabilities of the vortex meters of flowmeters.

The tests were carried out on a pouring plant with a stated relative error in measuring the volumetric flow rate and the liquid volume equal to ± 0.05% for 2 types of vortex flowmeters: Type 1 - vortex counter flowmeter with measuring channel parameters: nominal diameter of the measuring channel Du = 24.1 mm; flow body width h = 6.6 mm; geometric constant of the measuring channel C = 3.01E-06 m ³ ; Type 2 - vortex counter flowmeter with the parameters of the measuring channel: diameter of the nominal passage of the measuring channel DN = 25.5 mm; flow body width h = 6.5 mm; geometric constant of the measuring channel C = 3.32E-06 m ³ . The tests were carried out for a water medium, water temperature 24 ° C, pressure from 0.23 to 0.4 MPa.

Each flow meter counter was calibrated against 9 reference points of the specified reference costs. The error in measuring the flow rate for each reference point of the reference flow rate was determined by comparing the reference costs and measured costs. A linearized dependence of the number Sh on the inverse value of the dimensionless number Ro was found by the flow parameters at the reference points. The approximation coefficients a and b were calculated by the least squares method for the values of the numbers Sh and the inverse value of the numbers Ro.

The flow rate Q = f⋅C / Sh was calculated using the linearized expression for the number Sh for each reference flow point. The error in measuring the flow rate was calculated by comparing the specified reference costs and the calculated costs using the linearized expression for the number Sh.

In FIG. Figure 3 shows the results of testing the flow meter counter Type 1. The graph shows a linearized dependence of the number Shl on the inverse value of the dimensionless number Ro for given reference flow points, equal to Shl = 0.2414 + 3.90 / Ro, where the approximation coefficients a and b are: a = 0.2414, b = 3.90. The table shows the data on the results of testing the flow meter counter Type 1. When calibrating the flow meter counter at 9 reference flow points, the maximum error was 3.02% for the flow rate of 0.5 m3 / h for the number Re = 7900. When measuring the flow rate using the linearized expression for the Shl number, the maximum error value was 0.534% for the flow rate of 0.5 m3 / h and Re = 7900.

In FIG. Figure 4 shows the results of testing the flow meter counter Type 2. The graph shows the linearized dependence of the number Shl on the inverse value of the dimensionless number Ro for given reference flow points, equal to Shl = 0.2232 + 4.525 / Ro, where the approximation coefficients a and b are: a = 0 , 2232, b = 4.525. The table shows the data on the results of testing the flow meter counter Type 2. When calibrating the flow meter counter at 9 reference flow points, the maximum error was 2.66% for the flow rate of 0.66 m ³ / h for the number Re = 10366. When measuring the flow rate using the linearized expression for the number Shl, the maximum value of the error of the flow rate measurement was 0.054% for the flow rate of 0.66 m ³ / h and Re = 10366.

The tests confirmed the effectiveness of the proposed method for measuring the volumetric flow rate in vortex flowmeters, which allows to obtain maximum measurement accuracy in the entire working range of the flow rate of the vortex flowmeter at which a regular sequence of Karman vortices is formed. Using the method allows to expand the measurement range for vortex flowmeters for a given measurement error of the flow in the direction of the numbers Re <Re _gran .

The calculation of the volume of the leaked substance using a given fixed pulse weight, equal to the volume of the substance, allows simplifying its operation.

Compared with the prototype, the inventive method allows to obtain maximum measurement accuracy in the entire operating range of the flow rate of the vortex flowmeter, at which a regular sequence of Karman vortices is formed, and to expand the measurement range for vortex flowmeters for a given measurement error in the direction of the numbers Re <Re _gran .

Claims (1)

A method for measuring the volumetric flow rate in vortex flowmeters, which consists in creating a regular vortex sequence in the vortex flowmeter meter channel, registering each vortex as an electric pulse, measuring the current values of the pulse repetition rate f, as well as the temperature and pressure of the medium, indirectly calculating the current kinematic value viscosity ν of the substance, calculating the volumetric flow rate Q of the leaked substance according to the formula taking into account the measured frequency f of the vortices, the current value Strouhal number Sh, kinematic viscosity ν of the substance, geometric coefficient C of the measuring channel, equal to the product of the flow body width by the cross-sectional area of the measuring channel, characterized in that when calibrating the vortex flowmeter for given reference flow points in the entire working flow range for which there is a regular a sequence of vortices, using the least squares method, the coefficients a and b of the linearized approximating dependence of the number Shl on the inverse value are determined I number Ro, equal Shl = a + b / Ro, where Ro = h number ² ⋅f / ν, h - the width of the flow body, f - frequency of the vortices, ν - kinematic viscosity substance, and calculating a current volumetric flow rate Q according to the formula Q = f⋅C / Shl, where Shl is the calculated current value of the number Sh, the volume W of the leaked substance is defined as the product of the sum of the number N of pulses recorded during the measurement by any given weight P and pulse equal to the volume of the substance: W = ΣN⋅P and in this case, the period Ti of pulses at the output of the flowmeter is determined as Ti = Pi / Q.

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