RU220701U1 - Multiphase flowmeter with fast neutron source - Google Patents

Abstract

The utility model relates to the field of measuring parameters of multiphase fluid flow and can be used in information and measurement systems of the oil production and oil refining industries. The technical result of the utility model is the high accuracy of measuring the parameters of a multiphase flow throughout the entire period of operation of the device. The technical result is achieved by the fact that a multiphase flow meter contains a housing in the form of a pipe section with fastening elements in the pipeline located at the ends, temperature and pressure sensors installed inside the housing at the inlet and outlet, mounted on the housing in a section plane perpendicular to the direction of movement of the multiphase fluid flow, on the contrary each other, a source of fast neutrons and a detector of slow neutrons, while two additional radiolucent windows are made in the wall of the housing, located on a common longitudinal axis with the slow neutron detector, in the direction of movement of the multiphase fluid flow, in each of which an additional gamma radiation detector is installed. The utility model provides high accuracy in determining the parameters of multiphase fluid flow in various pipeline systems in real time and allows monitoring the performance of the flow meter without dismantling it.

Description

The utility model relates to the field of measuring parameters of multiphase fluid flow and can be used in information and measurement systems of the oil production and oil refining industries.

Currently, in the oil and gas industry there is a global trend towards digitalization and optimization of processes for monitoring various parameters. One of these processes is the control and accounting of flow rates of hydrocarbons obtained on the surface. The traditional way to account for well fluid is separation followed by measuring the flow rates of each phase separately. However, this method is significantly outdated, does not meet modern requirements and needs to be replaced.

Over the past decades, several flowmeters have been developed that fall under the category of multiphase flowmeters (MPF) and do not require prior separation of the well fluid. Such MFRs make it possible to measure the quantitative characteristics of a multiphase flow directly in linear conditions and convert them into standard conditions in a wide range of flow modes. Most often, MFRs are used when carrying out hydrodynamic testing of wells, as well as for recording production during the industrial operation of wells. The compact size of the MFR compared to separator units allows the creation of mobile metering systems to effectively meet customer needs.

Despite the significant advantages of MFR, these systems also have characteristic disadvantages:

low accuracy of determining the liquid fraction at large values of the gas condensate fraction (GVF);

high sensitivity to changes in fluid composition, requiring stopping the process and reconfiguring the MFR;

inability to determine flow speed;

high cost of ensuring radiation safety, transportation and operation of the gamma radiation source.

A multiphase flow meter is known (see patent RU No. 2632249, IPC G01F1/58, published 10/03/2017), containing:

a channel containing a multiphase fluid flow;

a radioisotope source and a radioisotope sensor configured to detect nuclear energy emitted by the radioisotope source through the channel and flow of the multiphase fluid; and an electronic instrument configured to:

determining the flow regime and gas content of a multiphase fluid stream based on the nuclear energy detected by the sensor compared to the expected noise of the radioisotope sensor under steady-state flow conditions;

determining the stationarity of a multiphase fluid flow based on the detected flow regime;

selecting a variable from a plurality of variables based on the detected gas content and the detected stationarity; and simulating multiphase fluid flow by adjusting the selected variable.

The main disadvantage of the known flow meter is the insufficient accuracy of determining the parameters, due to the fact that for different conditions of fluid flow and its composition, correction factors are determined on the basis of mathematical modeling, the results of which in different cases have different errors.

A multiphase flow meter is known (see patent RU No. 2663418, IPC G01F1/74, published 08/06/2018), containing a radiation device, an X-ray transparent section of the pipeline for studying a multiphase liquid, after which an anti-scattering X-ray mask is located to reduce the influence of radiation on the image, a matrix X-ray detector as a detection means, an analysis tool configured to determine the flow rate of one or more liquid phases and/or its composition, while an X-ray filter is installed in front of the matrix X-ray detector, which is made of two types of filter materials having different absorption coefficients and located in a checkerboard pattern so that each filter cell is located above its own pixel of the matrix detector, while after the radiolucent section, parallel to the matrix X-ray detector, a spectrometer is installed, which serves to measure the intensity of X-ray radiation, taking into account its distribution over photon energies.

The known device allows the use of an X-ray tube with a broadband radiation spectrum as a means of radiation and increases the accuracy of calibration, but also does not provide sufficient measurement accuracy due to losses of radiation power when passing through the X-ray filter.

A mass flow converter accepted as the closest analogue is known (see patent RU No. 2112929, IPC G01F 1/78, G01F 1/86, published 06/10/1998), containing a flow sensor, including a source of fast neutrons and two detectors of slow neutrons, placed on the measuring section of the pipeline, and an electronic converter made in the form of a computing device with two inputs connected to the corresponding detectors, the output of which is the output of the mass flow converter, while these detectors are placed with the ability to measure the number of slow neutrons in two equidistant from the source of fast neutrons points on the outer surface of the measuring section, located on the surface of the Earth and oriented with respect to the meridian at an angle other than 90°, for the occurrence of Coriolis acceleration.

The known technical solution provides high accuracy of mass flow for single-component flows, but does not allow determining the mass fractions of each component in multiphase flows. In addition, its implementation requires a specified positioning of the measuring section of the pipeline.

The objective of the proposed technical solution is to increase the accuracy of measurements for fluids with different flow parameters and phase composition.

The technical result of the invention lies in the high accuracy of measuring the parameters of a multiphase flow throughout the entire period of operation of the device.

The technical result is achieved by the fact that a multiphase flow meter contains a housing in the form of a pipe section with fastening elements in the pipeline located at the ends, temperature and pressure sensors installed inside the housing at the inlet and outlet, mounted on the housing in a section plane perpendicular to the direction of movement of the multiphase fluid flow, on the contrary each other, a source of fast neutrons and a detector of slow neutrons, while two additional radiolucent windows are made in the wall of the housing, located on a common longitudinal axis with the slow neutron detector, in the direction of movement of the multiphase fluid flow, in each of which an additional gamma radiation detector is installed.

The claimed utility model is illustrated by drawings, where

Fig. 1 shows a schematic diagram of a multiphase flow meter,

in fig. 2 - section A-A according to Fig. 1.

The multiphase flow meter contains a housing 1 with a source 2 of fast neutrons and a detector 3 of slow neutrons mounted on it, X-ray transparent windows 4 and 5 made in the housing with gamma radiation detectors 6 and 7 installed in them, pressure sensors 8 and 9, temperature sensors 10 and 11 .

The procedure for working with the device is as follows:

1. The device is built in series into the hydrocarbon transportation line.

2. Before inclusion in the main work, the device is calibrated according to the following data: the number of slow neutrons and gamma radiation absorption for a single-phase medium; calibration coefficients of housing 1; clarifying absorption coefficients of different mixtures obtained experimentally.

3. The device is included in the main operation, the calculation results are recorded on a computer to collect and store information. Upon request, all data is transferred to a remote server. Additional and periodic calibration of the device is carried out in accordance with the requirements of the device maintenance regulations.

During the operation of the device, various physical parameters are measured, the processing of which allows one to determine with high accuracy the phase quantitative composition of the fluid passing through it.

Conventionally measured parameters can be divided into several groups.

The first group is associated with measurements of pressure, pressure drop and temperature (P_line, ΔP, T_line) along the body 1 inside it, on the basis of which the primary calculation of fluid density and flow rate is made.

The difference in static pressure at the entrance to housing 1 and the exit from it is measured by pressure sensors 8 and 9 (together representing a differential pressure gauge), and the temperature difference by temperature sensors 10 and 11.

The second group of parameters is associated with the registration of slow (thermal) neutrons by detector 3, as well as the registration by detectors 6 and 7 of gamma radiation obtained as a result of the interaction of fast neutrons emitted by source 2 with particles of a multiphase fluid flow passing through body 1. In this case, functions of the number of particles N(E,t), depending on energy and time, are recorded. This makes it possible to determine the component composition of the fluid and the molar composition of the components contained in it.

For this:

1. In body 1, windows 4 and 5 are made of radiolucent material, which do not violate the geometry of the internal section of body 1.

2. A source 2 of fast neutrons is installed on one side of the housing 1, emitting them through the wall of the housing 1 into a multiphase fluid flow in a plane perpendicular to the direction of its movement.

3. On the other hand, in the same plane where the collimator of the incoming fast neutron beam is located, opposite the source 2 on the housing 1, a slow neutron detector 3 is installed.

4. On a common longitudinal axis with detector 3, closer to the exit from housing 1, there are x-ray transparent windows 4 and 5 with gamma radiation detectors 6 and 7 installed in them.

When fast neutrons pass through a flow of a multiphase fluid, one part of them interacts with the atoms of the fluid, as a result of which they are decelerated (transformed into slow ones) with the simultaneous emission of gamma radiation at an arbitrary angle, the second part passes through the flow without experiencing any absorbing or scattering effects.

Detector 3 detects part of the slow neutrons falling into it, and detectors 6 and 7 detect fluxes of gamma quanta emitted at appropriate angles. The density of the medium is determined by the ratio of the number of fast neutrons emitted by the source 2, the number of slow neutrons detected by the detector 3 and gamma rays detected by detectors 6 and 7.

The presence of additional detectors 6 and 7, located on a common longitudinal axis with detector 3 in the direction of flow inside housing 1, recording scattered gamma radiation for specified angles relative to source 2, makes it possible to correct the data obtained by detector 3, which increases the accuracy of determining the components of the phase composition fluid, especially in cases of high gas factor (≥ 80%).

The claimed technical solution provides high accuracy in determining the parameters of multiphase fluid flow in various pipeline systems in real time and allows monitoring the performance of the flow meter without dismantling it.

Claims (1)

A multiphase flow meter containing a housing in the form of a pipe section with fastening elements in the pipeline located at the ends, temperature and pressure sensors installed inside the housing at the inlet and outlet, mounted on the housing in a cross-sectional plane perpendicular to the direction of movement of the multiphase fluid flow, and a source of fast neutrons opposite each other and a slow neutron detector, characterized in that two additional radiolucent windows are made in the housing wall, located on a common longitudinal axis with the slow neutron detector, in the direction of the multiphase fluid flow, in each of which an additional gamma radiation detector is installed.