RU2478916C2 - Vortex measurement method of flowing substance volume - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: in the measuring channel of the substance amount counter, a regular sequence of vortexes is created, each vortex is recorded in the form of an electric pulse, current frequency values of pulse sequence f, as well as medium temperature and pressure are measured. Current value of kinematic substance viscosity v is calculated by an indirect method: for liquid - as per temperature, for gas or steam - as per temperature and pressure. Roshko number is calculated as per the formula: Ro=h²·f/v, where h - width of bluff body. Substance volume ΔW per pulse is calculated for each pulse separately using the current value of Strouhal number Sh as per the formula: ΔW=K_G/Sh, where K_G- geometrical factor determined for example as a product of width of bluff body h and cross sectional area of the measuring channel in its narrowest section (πd⁴/4-hd). Current value Sh is calculated by adding the current value of Reynolds number Re to the relationship Sh(Re) obtained at calibration of the counter in the operating range of values Re. Current value Re is calculated as per formula: Re=-b+Ro/a, where a and b - coefficients of approximating dependence Sh=a·(1+b/Re). Flowing substance volume W is determined by the following formula:

where N - total number of pulses recorded during the measurement.

EFFECT: improving measurement accuracy in the whole range of operating values of Reynolds number.

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Description

The invention relates to measuring equipment, and in particular to vortex methods for measuring the volumetric amount of fluid, liquid or gaseous substances in pressure pipelines, and can be used to control the flow of substances in the energy, utilities and other industries.

Known vortex method [1] for measuring the volume of a substance, namely liquid, gas or steam flowing through an amount counter, according to which a regular sequence of vortices is created in the meter’s measuring channel, the passage of each vortex transferred by the flow is recorded in the form of an electric pulse, the pulses are summed for a given time interval At and determine the volume of the past medium W as the product of the number of summed pulses N and determined by pre-calibration of the constant weight coefficient Quota K:

The disadvantage of this method is the reduced accuracy in the lower part of the measurement range due to the variability of the weight coefficient K.

The vortex method of measuring the volumetric quantity of the leaked substance selected as a prototype is devoid of this drawback [2], according to which a regular sequence of vortices is created in the measuring channel of the substance quantity counter, the passage of each vortex transferred by the flow is recorded as an electric pulse, the pulses are summed over a controlled period of time Δt, measure the current values of the pulse repetition rate f, as well as the temperature and pressure of the medium, indirectly calculate the current value the kinematic viscosity of the medium ν: for a liquid - by its temperature, for a gas or vapor - by its temperature and pressure, an auxiliary parameter is calculated

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 counter in a given range of r values, and the volume of the leaked substance W is determined as the product of the number of pulses N summed over time Δt and the variable weight coefficient 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, since according to the equation of measurement of a vortex counter of the amount of substance [3]

where Sh is the Strouhal number, C is a constant coefficient,

but in the general case

The technical effect of the invention is to increase the accuracy of measurements in the entire range of working (corresponding to operating conditions) values of the Reynolds number Re.

, где N - общее число зарегистрированных за время измерения импульсов.The specified technical effect is achieved by the fact that in the method of measuring the volumetric amount of a substance, namely liquid, gas or steam, which consists in creating a regular sequence of vortices in the metering channel of the quantity of substance in the measuring channel, registering each vortex in the form of an electric pulse, measuring the current values of the pulse repetition rate f as well as the temperature and pressure of the substance, indirect calculation of the current value of the kinematic viscosity of the substance ν: for a liquid - by temperature, for gas or steam - temperature and pressure, calculating the volume of the substance ΔW, per one pulse, and the summation ΔW values, the amount ΔW is calculated for each pulse separately using the current value Sh formula ΔW = K _r / Sh, where K _G - geometrical factor, determined, for example, as a product h bluff body width on the cross section of the measuring channel area having an inner diameter d at its narrowest cross section (πd ^2/4-h · d), wherein the current value Sh calculated by substituting the actual value Re in the resulting during calibration score In the working range of Re values, the dependence Sh (Re), the current value of Re is calculated by the formula Re = -b + Ro / a, where a and b are the coefficients of the dependence Sh = a · (1 + 6 / Re ), Rо is the Roshko number, which is calculated by the formula Rо = h ² · f / ν, and the volume of the leaked substance W is determined by the formula

where N is the total number of pulses recorded during the measurement.

The equation for measuring a vortex flowmeter has the form [4]:

where V _T is the flow velocity in the narrowest section, h is the width of the flow body.

The speed V _T is related to the average flow rate V at the inlet to the measuring channel by the ratio:

where m = h / d. Passing to the volumetric flow rate Q, we obtain:

where К _Г = h · (πd ² /4-h · d) = d ³ · (π / 4-m) m.

As is known, Sh is a function of Re [5]:

where ν is the kinematic viscosity, which is a function of temperature θ (for liquid) or temperature θ and pressure p (for vapor and gas).

Thus, in the general case, the volume of the substance W that has passed through the counter during the time Δt is equal to

where is the value under the sum sign

represents the volume of matter per pulse, i is the serial number of the pulse and N is the total number of pulses recorded in a controlled time interval Δt.

Based on the available experimental data, the function φ (Re) for a vortex flowmeter with a body flowing around a trapezoidal section can be written in the form:

Since F (Re) << 1, then:

Using the definition of the Roshko number Ro [6]

from (12) and (13) we obtain:

Re≈-b + Ro / a. (16)

Expression (16) determines the approximate value of Re, calculated through Ro. Substituting the obtained value of Re in formula (13), we obtain the corresponding value of φ (Re), and substituting φ (Re) in (12) is the value of the volume of the substance ΔW per one pulse, which is determined with almost the same accuracy as with graduation dependence Sh (Re). As calculations show, the additional error due to the inaccuracy of the determination of Re according to formula (14) has a second order of smallness compared to the error of the counter and is no more than 0.01%. Thus, the proposed method provides a determination of the volume of a substance per pulse, practically with the greatest possible accuracy.

The invention is illustrated in the drawing, which schematically shows a device that implements the proposed method.

The substance quantity counter consists of a measuring channel (nodes 1-5) and an electronic unit (nodes 6-11). In the input part of the measuring channel 1, a poorly streamlined body 2 is arranged in the form of a prismatic rod with a trapezoidal cross section, 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. Sensitive elements of flow rate 3, temperature 4 and pressure 5 are arranged behind the flow body in the flow. Using the flow body 2, a regular sequence of vortices is created in the measuring channel 1. Using the flow sensing element 3, the passage of the vortices is recorded, and using the sensing elements 4 and 5, the temperature and pressure of the controlled medium are measured. The output signals of the flow sensor 3 and the temperature and pressure sensors 5 and 5 are fed to the inputs of the amplifiers-shapers 6, 7 and 8, which convert them to output normalized pulse and current signals. The latter are fed to the corresponding inputs of the microcontroller 9 with an external non-volatile memory 10. The following is recorded in the memory of the microcontroller 9: 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 the coefficients of a function approximating this dependence; the coefficients a and b approximating the dependence Sh (Re) of the function Sh = a · (1 + b / Re), the values of the parameters K _G and d.

, где N - общее число просуммированных импульсов. По поступлении внешнего сигнала, например, от таймера вычисления прекращают и фиксируют величину объема на табло 11.The program of the microcontroller 9 provides the following operations. Using an external signal, the measurement of each period of the output signal of the sensing element is started by filling it with pulses of a stabilized frequency and calculating the moving average value of the output frequency f. The current values of the kinematic viscosity ν are calculated from the current values of the signals of the sensing elements of temperature 4 and pressure 5. Next, Ro = h ² · f / ν is calculated, and through Ro, Re = -b + Ro / a is calculated. The Sh values are determined from the Re values, using the dependence Sh (Re) taken during calibration of the counter; intermediate values are determined by linear interpolation. 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 passed substance is calculated

where N is the total number of summed pulses. Upon receipt of an external signal, for example, from a timer, the calculations are stopped and the amount of volume is fixed on the scoreboard 11.

From the above description it follows that the inventive method provides measurements directly in accordance with the basic equation of the vortex flowmeter (11), which ensures the practically maximum possible measurement accuracy in the entire range of flow velocities of ~ 0.2-10 m / s. Moreover, since the ΔW value is determined separately for each pulse, high measurement accuracy is also ensured at a variable flow rate.

An experimental verification of the proposed method was carried out on water, for which a vortex liquid meter-dispenser of the VDU-65 type with a flow diameter of d = 40 mm was appropriately programmed. The meter had a built-in temperature converter. Before checking the error, the meter was calibrated, i.e. Dependence Sh (Re) on a volumetric flowmeter stand equipped with a high-precision pipe-piston unit was removed.

The error of the VDU-65 was determined on water on a weighing calibration unit, certified with a measurement error of the mass of ± 0.05%. In this regard, the operation of multiplying the weight coefficient by the density of water was introduced into the microcontroller program. The difference between the readings of the VDU-65 and the calibration unit at a dose of 500 kg at a cost of 3.5; 12 and 24 m ³ / h did not exceed ± 0.15%. Thus, it was confirmed that the application of the proposed method provides the possibility of creating vortex counters of the amount of liquid with an error of ± 0.2%.

Literature

1. Kiyasbeyli A.Sh., Perelshtein M.E. Vortex measuring instruments, M., Mechanical Engineering, 1978, pp. 73-79.

2. Patent RU No. 2291400, C2, IPC G01F 1/32, publ. 07/20/2007.

3. Kiyasbeyli A.Sh., Perelshtein M.E. Vortex measuring instruments, M., Mechanical Engineering, 1978, p.75.

4. Kremlin P.P. Flowmeters and Counters: Reference. - 4th ed., Revised. and add. - L .: Mechanical engineering. Leningra. Department, 1989, p. 364.

5. Sedov L.I. Methods of Similarity and Dimension in Mechanics, Main Edition of Physics and Mathematics Literature of the Nauka Publishing House, 1967, pp. 71-76.

6. USA patent No. 7487686 C2, IPC G01F 1/32, NCI 73 / 861.22, publ. 06/19/2008.

Claims (1)

A vortex method for measuring the volumetric amount of a leaked substance, namely liquid, gas or steam, which consists in creating a regular sequence of vortices in the metering channel of the substance quantity meter, registering each vortex as an electric pulse, measuring the current values of the pulse repetition rate f, as well as temperature and pressure substances, indirectly calculating the current value of the kinematic viscosity of the substance ν: for a liquid - by temperature, for a gas or steam - by temperature and pressure, techniques, are the volume of material ΔW, per one pulse, and the summation ΔW values, characterized in that the amount ΔW is calculated for each pulse separately for formula ΔW = K _r / Sh, where K _G - geometrical factor determined, for example, as the product of the width body flow around h on the cross-sectional area of the measuring channel with an inner diameter d in its narrowest section (πd ² /4-h · d), Sh is the current value of the Strouhal number, which is calculated by substituting the current value of the Reynolds number Re into that obtained by calibrating the counter in slave than the Sh (Re) dependence range of Re values, the current Re value is calculated by the formula Re = -b + Ro / a, where a and b are the coefficients of the approximating dependence Sh = a (1 + b / Re), Ro is the Roshko number, which calculated by the formula Ro = h ² · f / ν, and the volume of the leaked substance W is determined by the formula

where N is the total number of pulses recorded during the measurement.