RU43068U1 - DEVICE FOR MEASURING THE CONSUMPTION OF COMPONENTS OF A GAS-FLUID FLUID PRODUCT MIXTURE OF A GAS-OIL PRODUCTION PRODUCT IN A PIPELINE - Google Patents

Abstract

A device for measuring the flow rate of the components of a gas-liquid mixture of gas and oil products in a pipeline. The utility model relates to the field of measurement technology and can be used in the gas and oil industry to measure the flow rate of components of a gas-liquid mixture (GHS) without fractioning production products in pipelines directly at wells or in reservoir sections of the primary processing of gas condensate or oil fields. The technical result - the ability to measure the flow rate of the components of the liquid fraction: condensate and water, and increase the accuracy of the measurement. A device containing a built-in pipe section with a measuring channel narrowed in the cross section with cone-shaped transitions to the standard pipe section, the liquid fraction section meter is made in the form of a panoramic amplitude-frequency characteristics meter and includes a microwave oscillating frequency generator, the output of which is connected to the input measuring microwave resonator located in the measuring channel, and the resonator contains two mirrors located on two on the opposite walls of the measuring channel in the area of the mirrors, the resonator contains longitudinal ribs of a triangular profile, the microwave output of the measuring resonator is connected to an amplitude detector, the low-frequency output of which is connected to the computer-control unit, the speed meter is made in the form of a Doppler microwave radar and contains a transceiver, the microwave output of which is connected to antenna integrated

Description

The utility model relates to the field of measurement technology and can be used in the gas and oil industry to measure the flow rate of gas-liquid mixture components (GHS) without fractioning the products of production in pipelines directly at the wells or in the collector sections of the primary processing of gas condensate or oil fields.

Known flow meters, especially those oriented to oil production, often contain structural elements placed in the stream. In most cases, forced accumulation or partial separation of the components of the mixture is used, flowmeters often require the formation of a stable flow of a certain type in advance (U.S. Patent Nos. 4,458,524, 4,662,219, 5,025,160, 5,029,482, 5127,272, 5203211, 5211842, 5251488).

These devices are focused on the relatively low GHG flow rates and the volume fraction of gas in the production product, which is typical for oil production. For gas condensate fields, they often fundamentally do not work due to the high production rate of the wells, a large volume fraction of gas in the production product (more than 95%), and the presence of rapidly fluctuating unsteady flows of GHS containing a low-viscosity liquid fraction.

A device for determining the gas and water content in the flow of crude oil in the pipeline (US patent G 01 N 22/04 US5389883 "Mesurement of gas and water content in oil"). It is built into the pipeline and is made in the form of a piece of a dielectric pipe, passed through many coil resonators. Their resonant frequencies depend on the dielectric constant and volume content of any material passing through the pipe. By measuring changes in resonant frequencies, the proportions of oil, gas and water in a stream can be calculated.

The main disadvantage of this device is its unsuitability for flow measurement of gas condensate flows in pipelines. In addition, when determining the water content, its salinity, which affects the measurement result, is not taken into account.

Closest to the claimed device is the patent of the Russian Federation "Method for determining the component flow rate of a gas-liquid mixture of gas and oil products in the pipeline and a device for its implementation" RU 2164340 C2 7 G 01 F 1/74, E 21 V 47/10 (prototype).

A device for determining the component flow rate of a gas-liquid mixture of gas and oil products contains: a measuring section integrated in the pipeline, and for the purpose of forming a homogenized flow and aligning the velocities of the GHS components, the section is made narrower in the cross section, and the transition from the standard section of the pipeline to the measuring section is made in the form of a cone-shaped narrowing at the entrance of the measuring section; liquid fraction section meter (microwave resonator installed in the channel); GHS flow rate meter (Doppler radar installed at an acute angle to the channel); pressure and temperature meters (standard sensors and instruments); computational control unit.

The device provides a determination of the component-wise flow rate of GHS with any gas volume fractions and well flow rates under real unsteady flows.

The disadvantages of the device are the inability to measure the individual components of the liquid fraction: condensate and water, and the low accuracy of the measurement due to the inability to take into account the salinity of the water component, which affects the measurement results.

The technical result of the claimed utility model is the ability to measure the flow rate of the components of the liquid fraction: condensate and water, and increase the accuracy of the measurement.

The technical result is achieved by the fact that in a device containing a pipe section embedded in the pipeline with a measuring channel narrowed in cross section with cone-shaped transitions to the standard pipeline section, a liquid fraction section meter, speed, pressure and temperature meters, a computing-control unit, wherein: a meter section of the liquid fraction is made in the form of a panoramic meter of amplitude-frequency characteristics and includes a microwave oscillating frequency generator, the output of which connected to the input of the measuring microwave resonator located in the measuring channel, and the resonator contains two mirrors located on two opposite walls of the measuring channel of the pipeline,

and on two other opposite walls of the measuring channel in the area of the mirrors, the resonator contains longitudinal ribs of a triangular profile, the microwave output of the measuring resonator is connected to an amplitude detector, the low-frequency output of which is connected to the computer-control unit, the speed meter is made in the form of a Doppler microwave radar and contains a transceiver, microwave the output of which is connected to an antenna built into the pipe section at an acute angle to the longitudinal axis of the measuring channel Through a radiotransparent insert with an outer surface that repeats the profile of the inner surface of the measuring channel, and the low-frequency output of the transceiver is connected to a computer-control unit, the outputs of which are connected to the outputs of the pressure and temperature meters of the gas-liquid mixture, and a dielectric frame is built into the tube section as an extension of the measuring channel on which two identical coils are wound sequentially, one of which is connected to the reference, the other to the measuring oscillator ramie, wherein inside the coil connected to the reference oscillators disposed electrical shield with a longitudinal slot covering frame.

A device for measuring the flow rate of the components of the flow of a gas-liquid mixture of gas and oil products in the pipeline is shown in Figure 1. It contains a pipe section 1 with a narrowed in cross-section measuring channel 2 with cone-shaped transitions to the standard section of the pipeline, and meters: speed 3, section of the liquid fraction 4, pressure 5, temperature b and section of the water component 7.

The speed meter 3 is made in the form of a Doppler radar and includes a transceiver 8, the microwave output of which is connected to the antenna 9, which is built into the tube section 1 at an acute angle to the longitudinal axis of the measuring channel 2 through a radio-transparent insert 10 with an outer surface repeating the profile of the inner surface of the measuring channel 2, and the low-frequency output of the transceiver 8 is connected to the computing and control unit 11.

The cross-section meter of the liquid fraction 4 is made in the form of a panoramic meter of amplitude-frequency characteristics and includes a microwave oscillating frequency generator 12, the output of which is connected to the microwave input of the half-open measuring resonator 13, which contains two mirrors 14 located opposite each other in the side walls of the measuring channel pipe section, and on the other two opposite

the walls of the measuring resonator 13 in the area of the mirrors 14 are longitudinal ribs 15 of a triangular profile. The microwave output of the measuring resonator 13 is connected to an amplitude detector 16, the low-frequency output of which is connected to the computing-control unit 11, to which the outputs of the pressure and temperature meters 5 and temperature 6 are also connected.

The cross-sectional meter of the water component 7 contains a dielectric frame 17 built into the pipe section 1 as an extension of the measuring channel 2, on which two identical coils 18 and 19 are wound in series. The coil 18 is connected to the reference oscillator 20, the coil 19 to the measuring oscillator 21. In this case the coil 18 is wound directly on the electric screen 22 with a longitudinal slot 23, covering the measuring channel 2 and preventing the interaction of the electric field of the coil with the flow of the GHS.

The calculation of the costs of GHS components is based on the measurement of five variables - temperature, pressure, velocity of the homogenized GHS flow, as well as cross sections of the liquid fraction and the water component. Pressure and temperature data are automatically entered into the computing and control unit 11 from standard sensors 5 and 6 in the form of voltages or currents, data on the GHS flow rate and cross sections of the liquid fraction are generated directly by the corresponding meters 3, 4 and 7.

The measurement of the flow rate of the GHS is carried out as follows. The transceiver 8 of the speed meter 3 generates a frequency-stable continuous signal of the microwave wavelength range, which is emitted by the antenna 9 through the radio-transparent insert 10 into the interior of the measuring channel 2. The microwave signal reflected from the particles of the liquid fraction of the stream is received back by the same antenna 9 and then transferred to the microwave the input of the transceiver 8, where it is converted into a beat signal, which is filtered by frequency, is amplified and from the low-frequency output enters the computational control unit 11.

The result of the speed meter 3 is to obtain a spectrum of Doppler frequencies, the components of which are linearly related to the speed of moving particles of the liquid fraction.

The measurement of the cross section of the liquid fraction of the GHS is carried out as follows. Sweeping frequency microwave generator 12 drives

electromagnetic field in the resonator 13 through the communication hole in one of the mirrors 14 in the frequency sweep band. The presence in the resonator 13 of the ribs of a triangular profile 15 eliminates the possibility of transverse spurious resonant oscillations due to the placement of mirrors 14 in a metal semi-enclosed space. The resonant electromagnetic field excited in the measuring resonator 13 enters through the coupling hole of the second mirror 14 to the amplitude detector 16. From the output of the amplitude detector, a sequence of pulses following with a period of frequency sweep is fed to the input of the computing and control unit 11.

The result of the meter is to obtain a sequence of resonant responses and measure their frequency shifts, directly proportional to the amount of liquid fraction filling the volume of the measuring resonator relative to the frequency filled with one resonator gas.

Measurement of the cross section of the water component with compensation for the influence of its salinity is carried out as follows: using the meter’s oscillators 7, a magnetic field inside the coil 18 and the electromagnetic field inside the coil 19 are excited and the oscillators are tuned to the same frequency in the absence of liquid in the measuring channel 2. When the flow of the GHS is measured, the difference the frequency of the measuring and reference oscillators, while in the difference the frequency shifts caused by the influence of water salinity on the magnetic fields of the coils compensate each other a friend. Therefore, the frequency difference will be determined only by the influence of the dielectric constant of the GHS, which, in turn, depends on the cross section of the channel occupied by water. The proportionality coefficient equal to the frequency difference by one percent of the cross section of the channel occupied by water is set during calibration.

Calculation of the costs of GHS components for a specified time t is as follows.

According to the measured section occupied by water, calculate the flow rate of water according to the formula:

where Q _in - water consumption;

S _in - the measured section occupied by water;

V _and - the speed of the speed meter.

Condensate flow rate is calculated by the formula:

where Q _to - condensate flow;

Q _W - flow rate of the liquid fraction.

The flow rate of the liquid fraction is calculated by the formula:

where Og is the flow rate of the liquid fraction;

8g - measured section occupied by the liquid fraction.

Gas consumption is calculated by the formula:

where Q _g is the gas flow rate;

S _g - calculated cross-section occupied by gas.

Accounting for the water content in the liquid fraction makes it possible to optimize the costs of the collector sections of the primary processing of gas and oil products, as well as to predict the lifetime of the wells.

Claims (1)

A device for measuring the flow rate of components of the flow of a gas-liquid mixture of gas and oil products in a pipeline, comprising a pipe section embedded in the pipeline with a measuring channel narrowed in cross section with cone-shaped transitions to a standard pipeline section, a liquid fraction cross-section meter, speed, pressure and temperature meters, a computing and control unit moreover, the meter of the cross section of the liquid fraction is made in the form of a panoramic meter of amplitude-frequency characteristics and includes a microwave oscillating frequency generator, the output of which is connected to the input of the measuring microwave resonator located in the measuring channel, the resonator containing two mirrors located opposite each other on the side walls of the measuring channel of the pipeline, and on the other two opposite walls of the measuring channel in the mirror area, the resonator contains longitudinal ribs of a triangular profile, the microwave output of the measuring resonator is connected to an amplitude detector, the low-frequency output of which connected to the computing and control unit, the speed meter is made in the form of a Doppler microwave radar and contains a transceiver, the microwave output of which is connected to the antenna integrated into the tube section at an acute angle to the longitudinal axis of the measuring channel through a radiotransparent insert with an external surface repeating the profile of the measuring surface channel, and the low-frequency output of the transceiver is connected to the computer control unit, to the other inputs of which you are connected an ode to measuring pressure and temperature of a gas-liquid mixture, characterized in that a dielectric frame is built into the pipe section as an extension of the measuring channel, on which two identical coils are wound in series, one of which is connected to the reference coil, the other to the measuring oscillators, while inside the coil, connected to the reference oscillator, placed an electric screen with a longitudinal slot covering the frame.