RU1795287C - Method of measuring gas mass flow rate - Google Patents

Abstract

Usage: when measuring mass flow in the gas, chemical industry and in the power system. SUMMARY OF THE INVENTION: In parallel with the main pipeline containing the first hydraulic resistance, an additional pipe is installed containing the second and adjustable hydraulic resistance, where a part of the flow from the main pipe is directed, the flow in the auxiliary pipe is controlled to maintain a constant pressure drop across the second hydraulic resistance, the volumetric flow rate and pressure drop into the analog signals, using which are calculated in mass flow rate. 1 silt

Description

The invention relates to instrumentation, namely to a flow metering technique, and can be applied when measuring | 1 mass or reduced to normal conditions volume flow and the amount of gas in a gas, chemical industry and in a power system. Most of the advantages of the invention are disclosed under variable pressure gas conditions in large diameter pipelines.

A known method for measuring the mass flow rate of a medium (1) is to measure the pressure drop across the hydraulic resistance CKOJM and the volume flow rate (speed) through it, followed by calculating the ratio of these values.

A disadvantage of the known method is the low accuracy of the measurement due to the low accuracy of measuring the differential pressure at values less than 30% of the maximum allowable value. The need for individual graduation of the volume flow converter and the entire device as a whole limit the scope of the known method, since the capital cost of creating a computer. Lexa flow metering systems, covering the entire range of modern industrial devices, are extremely high.

A known method for determining the mass flow rate of a gas is to measure the differential pressure across the hydraulic resistance and gas density, and then extract the square root from the product of the differential pressure and density signals. As hydraulic resistance, the most common when implementing the known method received standard narrowing devices.

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A disadvantage of the known method is the low accuracy of measuring the gas mass flow rate due to the increased influence of viscosity, temperature, industrial vibration on the density measurement results and, consequently, the gas mass flow rate. The widespread use of this method is hindered by the high cost of densitometers and the lack of metrological verification facilities at the operating sites.

The closest in technical essence and the achieved result is the method for determining the mass flow rate of gas, described on page 14 (2), which consists in measuring the differential pressure on the hydraulic resistance, measuring pressure, temperature, gas humidity, determining the gas composition and the value of the coefficient . compressibility factor. In practice, this method has gained predominant distribution due to the versatility of use, the convenience of mass production of hardware that implements the method, and the lack of the need for shaped flowmeter installations.

The disadvantages of this method are the low accuracy of the measurement due to the fact that the experimental data on the gas composition is obtained from the results of periodic laboratory analyzes, and the compressibility coefficient is determined by the calculation method from the values of pressure, temperature and gas composition, as well as a large number of information measuring signals, drive General to a large number of hardware tools for its implementation.

The purpose of the invention is to improve accuracy.

The purpose of the invention is achieved in that in the method for determining the mass flow rate of gas in a pipeline, which consists in measuring the pressure drop across the hydraulic resistance of the main pipe, converting this value into an analog signal, from which the mass flow rate is determined in the computing device, and the differential pressure is measured pressure in an additional parallel to the main pipeline provided with a second and adjustable hydraulic resistances, where a part of the flow from novnogo pipeline. The flow in the auxiliary pipe is regulated to maintain a constant pressure drop on the second hydraulic resistance, the frequency signal proportional to the volumetric value is determined

the pressure drop across the second and adjustable hydraulic resistances, and the mass flow rate is found from the expression

5GM (K2 fiZpT / fQ) (K2)

Y | DGL + | DR,

(V

where fa is the frequency proportional to the volumetric flow rate through an additional parallel pipeline;

1Dr 1D | Ј current differential pressure signals respectively at the adjustable and second hydraulic resistances;

Ki, K2, KQ are predefined calibration coefficients, moreover.

 main pipe M Api + ApO

wires

K2 l Q - additional pipeline;

1dr fa

KQ - second hydraulic co Q2

baking sheets;

Gi, G2 - mass flow rates respectively through the primary and secondary parallel pipelines during graduation;

Q2 is the volumetric flow rate through the second hydraulic resistance during calibration;

p is the gas density during graduation. The drawing shows a diagram of a device that implements the claimed method of determining the mass flow rate of gas, and

the implementation of the method is automatic.

The device comprises a main pipe 1 with installed in it hydraulic resistance, made,

for example, in the form of a nozzle 2, an additional parallel pipe 3. In an additional parallel pipe 3, a volume flow converter 4, which is simultaneously the second hydraulic resistance, a differential pressure stabilizer 5, which is simultaneously adjustable hydraulic resistance, and differential pressure transmitters 6 and 7 are installed. Outputs

volumetric flow rate transducers 4 and differential pressure 6 and 7 are connected to the inputs of the computing transducer 8 containing a constant input unit 9 and an indicator 10. Input and output are designated by 11 and 12, respectively

additional parallel pipeline 3.

The implementation of the method is as follows,

Before starting operation of the device, individual values of the calibration coefficients Ki, K.2, KQ are entered into the memory of the computing converter 8 using the constant input unit 9. Prior to the appearance of the flow, the control element of the differential pressure stabilizer 5 automatically takes a position that ensures the maximum gas flow rate for the volumetric flow transducer 4. Computing transducer 8 corrects the zero offset of the differential pressure transducer 6, 7 and, if necessary, the volume flow transducer 4. As a differential pressure transducer, a Sapphire-2; 2DD-Vn transducer can be used as a differential pressure stabilizer (SPD) (dash. 08870027), as the volumetric flow converter — the SAG-200 self-contained jet generator (Fig. 08882096), and the Lomicont L-110 logical microprocessor controller as the computational converter. All of the listed hardware was developed at NIIITeplopribor and are commercially available. When a flow occurs through the device, the differential pressure stabilizer control element 5 redistributes the gas flows through two parallel pipelines so that the differential pressure at the second hydraulic resistance, which is used as a volume flow converter 4, is kept close to a constant value, thereby optimal operating conditions of the differential pressure transducer 7 are provided. The volumetric flow transducer 4 converts the flowing gas flow in proportion An electric signal, for example a pulse frequency, signal fa. Differential pressure transmitters 6 and 7 convert the differential pressure they perceive into standardized current signals dr and tApfc. The signals TQ, lApi and IAr are supplied to the inputs of the computing converter 8. The current value of the mass flow rate of gas is calculated by the computing converter 8 according to the formula (1). The calculation results are displayed on the screen of the indicator 10, for which, for example, the BTA2000-15M video terminal can be used.

The invention is based on the fact that the pressure drop in the measuring section of a device that implements a new method for determining the mass flow rate of gas, D «PCT, therefore, the compressibility of the gas can be neglected. Here pct is the average value of the static gas pressure in the main pipeline 1. The mass flow through the device G is determined by the obvious ratio

 + G2,

where Gi and G2 are the mass flow rates of gas, respectively, through the primary and secondary parallel pipelines;

p is the density of the gas.

Mass gas flow through pipelines 1 and II can be represented as

Gi KiY / (lApi + 1DRO.

G2 K2 (2)

Calibration coefficient Kt can be obtained by individual calibration of the first hydraulic resistance or in the case of using a standard constriction device by calculation. The calibration factor "2 is determined from the individual graduation of an additionally parallel pipeline 3 separately from the main pipeline 1, which allows for a standard-sized series of devices implementing the inventive method to have a single flow meter installation, for example, similar to the installation of UPSG ( Fig. 08898144). Here, by individual calibration of an additional parallel pipeline 3 we mean the calibration of the hydraulic path, which includes the pipeline itself, a 4- volumetric flow converter and a differential pressure stabilizer 5. The same flow meter allows the individual calibration coefficient of a 4 KQ volumetric flow converter to be determined. The density of the measured gas can be represented as p G2 / Ct2 - (Ka / Co) IAfЈ / fa, then the mass flow of gas through the main pipeline 1 will be equal to

Gi Ki / KQ VIAp (Dp, + IAp,) / fQ.

Hence, taking into account (2), the mass flow rate through the device G can be found by the formula (1).

The application of the invention allows the mass flow rate to be determined with high accuracy, which is achieved by not having to determine the humidity, composition and compressibility factor of the gas. The high accuracy of measuring the differential pressure at the second hydraulic resistance is ensured by keeping it close to a constant value near the upper limit of measurement. The limitation of the differential pressure value by the adjustable hydraulic resistance favorably affects the operation of the volumetric flow converter 4, since the range of measurement of the volumetric flow rate is also limited.

In addition, the advantage of this technical solution is the possibility of elementwise calibration and verification of each transducer from the set of the device and the ability to use standard narrowing devices, the calibration coefficients of which are determined by calculation. This is extremely important for devices for commercial and technological metering of large gas consumption, for example, in trunk pipelines due to the extremely high cost of metrological stands,

A significant advantage of the claimed technical solution is the high reliability of the registration of metrological failures, since the failure of the device elements can be fixed during operation, and the replacement of the elements does not reduce the metrological characteristics of the device. Since the differential pressure stabilizer 5 maintains the flow parameters within a limited range, the failure of the volume flow converter 4 can be detected by comparing the signal with the reference obtained by calibration. The unstable readings of the differential pressure transmitter 7 characterize either

its own failure, or failure of the differential pressure stabilizer 5. By switching the input of the differential pressure transducer 6 from the output 12 of the additional parallel pipeline 3 to the input 11,

it is possible to judge the operability of differential pressure transducers 6 and 7 by comparing their signals.

Thus, during operation, the operability of each hardware of a device that implements the claimed method can be monitored without dismantling them.

The application of the method is not limited to changing the gas mass flow rate.

The method can be used to measure the mass flow rate of steam, liquids, suspensions, etc., and to limit the flow rate of the fluid, the compressibility of the medium is completely removed.

Claims (1)

The claims The method of determining the mass flow rate of gas, which consists in measuring the pressure drop across the hydraulic resistance of the main pipeline, converting this value into an analog signal, by which the mass flow rate is determined in the computing device, characterized in that, with the purpose of increasing accuracy, measuring the pressure drop is carried out t in an additional parallel main pipeline equipped with a second and adjustable hydraulic resistances, where a part of the flow from the main of the pipeline control the flow in the additional conduit for sub. holding the second hydraulic resistance at a constant pressure drop, determine the frequency signal proportional to the volumetric flow rate from the pressure drop at the second and adjustable hydraulic resistance, and the mass flow rate is found from the expression GM (K2 iZjt / fa) (Ki / V | QK2) VlApi + 1Dr +% / 1ArG, where fa is the frequency proportional to the volumetric flow rate through an additional parallel pipeline; Др 1Др - current signals of pressure drops, respectively, at the adjustable and second hydraulic resistances; Ki, K2 and KQ are predefined calibration coefficients, moreover Gi Ki M Api + Lee) gs.- coefficient of the main pipeline; K2 - g-- - coefficient complement Ar2 solid pipeline; coefficient of second hydraulic resistance; Gi. G2 - mass flow, respectively, through the primary and secondary parallel pipelines during graduation; AV / # 9 Q2 is the volumetric flow rate through the second hydraulic resistance during calibration: p is the gas density during calibration.