RU2654889C1 - Experimental installation for imitation of gas-liquid mixture and dynamic processes in the stock of the gas well - Google Patents

Abstract

FIELD: gas industry.

SUBSTANCE: invention relates to devices intended for conducting scientific and applied research in the field of development and operation of gas and gas condensate fields, carrying out experiments related to simulation of dynamic processes occurring in a gas or gas condensate well working with sand and / or liquids, including interacting with the surface-active foaming substances and other non-corrosive chemicals. Experimental setup for simulating the motion of a gas-liquid mixture and dynamic processes in a gas wellbore contains the main and inner columns of transparent tubes, a backflow column, a system for supplying and regulating gas flow, a thermostatically controlled system for supplying and regulating the flow of water and an imitator of oil, a system for supplying and regulating the flow of reagent, a hydraulic system for reusing water and hydrocarbon fluid. Main column in the upper part is connected to a return flow column, the outlet of which is connected to a separator equipped with liquid and gas outlets. Installation is equipped with instrumentation, video and photo recording devices. Main column of pipes and the return flow column are fixed to the mast. In order to allow the reagent to be fed into the annulus, a capillary tube is introduced, with the possibility of changing the position along the entire length of the main tube string.

EFFECT: technical result is to expand the functionality of the installation and increase operational safety and reliability.

10 cl, 1 tbl, 5 dwg

Description

The invention relates to devices for scientific and applied research in the field of development and operation of gas and gas condensate fields, experiments related to the simulation of dynamic processes occurring in a gas (gas condensate) well working with sand and / or liquids, in t hours in interaction with surface-active foaming substances (surfactants) and other non-aggressive chemicals.

Many large gas and gas condensate fields in Russia are depleted and are gradually moving to the final stage of development. There are more and more “waterlogged” and “self-filling” [liquid] gas wells. The accumulation of liquid (condensate, produced water, condensation water [from gas]) inside gas and gas condensate wells leads to their gradual killing (or “crushing”) by a liquid column, i.e. bottomhole pressure is balanced by the hydrostatic pressure of the liquid column and gas flow stops.

The accumulation of fluid occurs due to the insufficient flow rate of the gas-liquid mixture in the production casing and lift pipes, necessary for self-cleaning wells. With high gas flow rates and a large gas-liquid ratio, the flow velocity may be sufficient (over 3-5 m / s). Further operation of such wells is possible using a number of methods related either to the re-equipment of the wells or to the supply of surfactants to the bottom.

A well-known stand for modeling the operation of a gas well, including a chamber with a reservoir model, made in the form of hydrodynamically coupled water and air saturated porous media, two vertical concentrically arranged measured transparent pipes, water and air supply systems with a water duct and air duct, a receiving system and control and measurement devices / SU 1699197 A1, IPC Е21В 43/18 (1995.01), publ. 05/10/1999). In order to obtain reliable and high-quality results of experimental studies, the stand is additionally equipped with a system of closed pipelines with measured transparent tubes, a make-up transparent chamber with a bottom and a cover, and vertical holes are made in the reservoir model, to which pipelines from the closed pipe system are suitable, and the measured transparent tubes are located at the level of the reservoir model, and the internal cavity of the chamber is connected to the supply system through a make-up transparent chamber connected through the bottom by means of a vertical pipe outlet with a water conduit, and through a cover - with an air duct.

A well-known installation for modeling the natural working conditions of gas, gas condensate and oil fields, consisting of one or more columns of pipes of various diameters, a node for supplying and regulating the flow of liquid, a compressor, input devices into the column and removal from the column of a mixture of gas and liquid having outputs for liquid and gas separator, a gas flow meter installed between the compressor and a gas and liquid mixture input device, a liquid flow meter installed between the unit for supplying and regulating the flow rate of the liquid and the device for introducing into the column a mixture of gas and liquid, pressure measuring instruments in the pipe string, means for draining the liquid and gas from the installation, the unit for supplying and controlling the flow rate of the liquid, storage tank and pump / RU 48581 U1, IPC Е21В 47 / 00 (2000.01), publ. 10/27/2005 /.

A device for researching a gas-liquid flow is known, comprising a test column made of transparent material and installed in an upright position, at the base of which a gas and liquid mixer is installed, a gas inlet and outlet valve is provided in the device, which is connected by a pipeline to the gas outlet of the separator on one side and to the inlet of the centrifugal gas supercharger on the other, a liquid pump connected to the liquid flow meter is installed at the outlet of the liquid stream of the separator, centrifugal th gas supercharger is connected through a gas flow meter to a gas and liquid mixer, a block of differential pressure sensors and a block of pressure and temperature sensors / RU 2571473 C1, MPK Е21В 47/10 (2012.01) are installed on the test string, publ. 12/20/2015 /. Indications from the differential pressure sensor block and the pressure and temperature sensor block, as well as from the gas flow meter, are sent through the analog-to-digital conversion block to the data processing and visualization unit of the observation results. The known device provides an extension of functionality and allows you to determine the water content of the vertical test column in real time.

Known devices provide experimental studies of the processes occurring in the well during the development and operation of gas, gas condensate and oil fields.

The disadvantages of the known stands include limited use.

The technical problem to be solved by the claimed invention is aimed at expanding the assortment of installations (stands, devices) for modeling (simulating) well operating conditions by developing a device for creating / configuring a multi-parameter model of processes occurring in a gas well, studying processes occurring in a gas, gas condensate wells working with water (and / or hydrocarbon fluid and / or sand) and reagents - surfactants, refinement of experimental correlations in the field of motion of multiphase mixtures in borehole (vertical or inclined) obtained by other researchers.

The technical result consists in the implementation of this purpose, as well as expanding the functionality of the experimental setup and improving operational safety and reliability.

This result is achieved due to the fact that the experimental installation for simulating the movement of a gas-liquid mixture and dynamic processes in a gas well bore is characterized by the fact that it contains the main and inner columns of transparent pipes, a gas supply and control system for gas flow, a thermostatic water supply and control system for gas flow and a simulator oil, a system for supplying and regulating the flow of reagent, exits for liquid and gas separator, means for removing liquid and gas from the installation, a hydraulic system for repeated use of water and hydrocarbon fluid (oil simulator) in a vicious circle, instrumentation, video and photo recording devices, while the external pipe string is mounted on the masts, and to ensure the possibility of supplying the reagent to the annulus contains a capillary tube installed with the possibility changes in the position along the entire length of the main column.

It is possible to carry out the installation with a vertical or inclined arrangement of the pipe string. In addition, the installation may contain a funnel to allow swirling of the flow. The separator output can be performed either in a closed circle through the receiver, or with the release of air into the atmosphere through the DICT. To ensure the process of simulating gas inflow from the well formation, the installation may include a controller for automatically controlling the air flow, which is changed according to the law P ₀ ² -P _zab ² = aQ. To ensure different modes of the expiration of air bubbles in the installation in the lower part of the main pipe string can be located dispersant. High-resolution photo and video surveillance devices with backlight can be installed at several points along the flow direction to ensure registration and subsequent analysis of the flow structure and foam. As control and measuring instruments, high-precision pressure / temperature and / or differential pressure sensors are used. Instrumentation can be installed at several points in the direction of flow, with two sensors installed at each point, to ensure accurate readings, their duplication and diagnostics of sensor malfunctions. The installation may contain at several points along the flow direction density control means distributed over the diameter of the pipes to provide control of the density of the flow over the cross section of the pipes.

The constructive design of the installation provides simulation of the wellbore using a column of transparent pipes (main column), inside of which there are transparent lift pipes of a smaller diameter for studying the flow regimes of a gas and gas condensate mixture with a high gas-liquid ratio, self-cleaning processes of a gas / gas condensate well from incoming liquid and sand , the processes of accumulation of liquid and sand of various fractions in the trunk of a gas / gas condensate well (in various conditions), the process a cleaning gas / condensate well by flowing fluid and sand using various reagents (surfactants), and other non-aggressive reagents (a variety of conditions). The position of the inner column (elevator pipe) in the main column is adjusted by installing either concentrically or with a minimum clearance from the inner wall of the main column on one side. The structural connection of the main column and the column back flow to the mast through a flange connection provides the ability to provide changes and control the angle of inclination of the columns. Providing air from below to the main column of air pipes simulates the flow of gas from the reservoir. The installation includes the necessary monitoring equipment, safety equipment and diagnostic algorithms for autonomous long-term experiments.

An advantage of the claimed installation is the possibility of increasing the length of the main pipe string. The increase in the length of the main column and the lift column provides an extension of functionality due to the introduction of a new reagent supply and control unit (SAS), which makes it possible to more fully study the structure of gas-liquid flow, foaming processes at different flow rates and allows you to observe a change in the structure of gas-liquid flow / foam , including the processes of foam decay and liquid runoff in the elevator column, which is not always possible to observe at low column heights, due to that the flow mode does not have time to establish. Fixing the main column and the reverse flow column to the mast, for example using clamps, ensures the safety and reliability of the installation.

Thermostatic control of the fluid inlet allows automatic control and heating of water and oil simulator to the required value, due to which it is possible to achieve a temperature close to the borehole fluids in real gas, gas condensate wells.

The difference between the installation and analogues is to simulate the productivity of a gas well, i.e. automatic regulation of air flow is proportional to the "virtual" pressure drop between the preset (fixed, stored in the memory of the computer system) pressure in the installation when the processes in it are at rest and the changing pressure at the lower point of the main column of transparent pipes. The pre-set (fixed, stored in the memory of the computing system) pressure in the installation, when the processes in it are at rest, simulates a constant pressure in the reservoir (P ₀ ). The variable pressure at the lower point of the main column of transparent pipes (P _zab ) simulates the pressure at the bottom of the well, the difference between P ₀ and P _zb simulates the depression on the formation. A slight decrease in pressure in the installation and, accordingly, a decrease in pressure in the lower part of the main column, causes her air movement. Pressure reduction is achieved by the release of a certain amount of air from the installation.

The air flow rate supplied to the installation varies according to the law: P ₀ ² -P _zab ² = aQ, where coefficient a characterizes the intensity of air flow (analogue of the well productivity coefficient). The range of possible values of a is established empirically when testing the installation. The gas-dynamic characteristic of air injection equipment maximally ensures the implementation of this law, regardless of the pressure at the inlet.

In FIG. 1 schematically shows the installation.

In FIG. 2 shows a vertical arrangement of pipe columns; FIG. 3 shows the inclined position of the pipe columns.

In FIG. 4 schematically shows the operation of the installation in open mode (by air) with connection to an external high-performance compressor;

In FIG. 5 - operation of the installation in the mode of "pushing" the liquid (in a closed mode through the air).

The design of the installation provides the most compact arrangement of its elements (including the receiver and blowers - not shown in Fig. 1) on a single frame, while all elements are available for replacement, maintenance, and observation. The main frame of the installation has the shape of a parallelepiped, the frame can be collapsible.

The installation comprises a main pipe string 11, an internal pipe string 13 simulating an elevator column, and a return pipe string 15. The pipe columns 11 and 15 are mounted on a collapsible supporting structure - mast 1. The base of mast 1 is located approximately in the middle of the rectangular base of the frame. The stability of the mast 1 can be provided by both stretch marks (metal wire) and rigid mounts (to the wall of the building, etc.).

The inclination of the mast 1 is provided by disassembly and rotation of the flanges 22 (Fig. 2, 3). The angle of the mast 1 can be adjusted. At large angles and a long mast 1 additional stops are possible. Possible tilt angles are determined by the number of holes in the flanges 22.

The main pipe string 11 in the upper part is connected to the return flow column 15. The pipe string 13 simulating an elevator string may be provided with a funnel 12 of elevator pipes at the bottom. To ensure the input of the surfactant into the main column 11, a capillary tube 14 is provided. The column of pipes 15 of the return flow is connected to a separator 17, which is equipped with a water supply line for extinguishing the foam 18. The separator 17 is equipped with a filter cartridge 27. The output of the separator 17 is made either in a closed circle through receiver (option B of Fig. 1), or with the release of air into the atmosphere through DICT (option A, Fig. 1).

The lower part of the main pipe string 11 is connected to the storage tank 19 through a sub 20 for a different inclination of the installation, as well as to the radial inlet 7 to provide air supply through the unit of nozzles of the wet gas 8, the connecting block 10 of the water inlet. The main pipe string 11 may be provided with a dispersant 9 with regulation. The storage tank 19 is made transparent, volumetric divisions are applied to it. A device 28, for example a heat exchanger, is used to heat water and the temperature of the supplied air.

The installation contains containers: a container with mineralized water 2, a container with oil simulator 3 (for example, Exxol), a container with a surfactant solution 4, a container with fine sand (dust) 5. The container for supplying sand 5 is made transparent, volumetric divisions are applied to it.

The installation contains a means 23 - a container for separating liquid into water and an oil simulator. Capacity - separator -23, water output lines, oil simulator, output lines from the separator 17 form a hydraulic system for multiple use of water and hydrocarbon liquid (oil simulator) in a vicious circle.

The installation contains electrically controlled hydraulic actuators for opening and closing the main (key) shut-off and control valves: air inlet valve 6, valve 21 for supplying fluid to the test column, valve for venting air 24, valves 25 of nozzle block 8, water supply valve 26. All control equipment made with the ability to provide work both in manual and in computer-controlled automatic modes.

These tanks 2, 3, 4, 5, water lines to the main column 11 with the corresponding shut-off and control valves, pumps, and compressor form a gas supply and control system for gas flow, a thermostatic water supply and control system for water flow and an oil simulator, and a supply and control system for flow reagent.

The installation is equipped with a sub 20, adjusting flanges 22 with holes to ensure installation of the angle.

At several points along the flow of the gas-water mixture, installation of control and measuring means 34, for example, screw-in high-precision pressure / temperature and / or differential pressure sensors, is provided. In FIG. Figure 1 shows five control points (may be more or less), in each of which two sensors are installed (each type) in order to duplicate readings and diagnose sensor malfunctions. Integrated into the flow means of control of density (humidity) are distributed along the diameter of the pipes, since the density of the stream will be unevenly distributed over the cross section of the pipes. Those. each of the four points of extended control should have several density measuring points.

To carry out video monitoring (with backlight) in order to monitor the occupancy of the containers 5, 19, the separator 17, observation inserts 16 are provided for monitoring the flow regime, video cameras 31 (VR) are provided for video surveillance of the installation as a whole (Fig. 1).

At several points along the flow, it is possible to install cameras 29 for high-resolution photocontrol (with backlight) with interval recording of digital photographs for subsequent analysis of the flow structure and foam. To monitor the flow entering the funnel 12 of the elevator pipes 13, a height-adjustable observation point is provided.

All cameras and camcorders 29, 31 are connected to a single receiver with a sufficient depth of information storage. Video from all cameras is broadcast to a separate video monitor.

All instrumentation and A equipment is connected to a separate controller, which, in turn, transmits information and is controlled using a computer or laptop.

The control computer software carries out reception, processing, storage, indication of measuring, signal and control information.

The installation can be placed both indoors (preferably hangar type), and outdoors (in the summer at an air temperature of + 15 ° C). The possibility of placement on the street will increase the height of the mast with pipe columns.

The installation is as follows.

Before the experiment: The installation is clean, the pressure is atmospheric.

Process pipelines in the required areas are filled with liquids to eliminate air congestion.

The level sensor 32 in the separator 17 must be brought to its initial state for which it is filled with water from the tank 2 through line 18 until the level sensor is activated and the water is discharged into the empty separator 23.

In experiments with a small liquid supply, the option of using a measuring column without filling the separator with liquid is possible.

The level sensors in the separator 23 are brought to their initial state, for which they first fill it with an oil substitute from the tank 3 with overflow in the last section until the second level sensor ("condensate-air") operates. Then the first section is gradually filled with water until the first level sensor (“water-condensate”) is triggered. When filling with water, the oil substitute will overflow into the last section, where its surplus is automatically pumped back to tank 3.

When conducting experiments only with water, the last section of the separator 23 is not used, the level sensor in the first section is either reconfigured to a water-air medium (instead of water-condensate), or it is possible to install the sensor on a water-air medium.

Next, the installation creates the necessary pressure by pumping air into it through a receiver with an integrated compressor. When filling, all valves providing air inlet, as well as valve 21, must be open. All other taps must be closed. After air injection, the taps 6 and 21 are closed.

The mode of "pushing" a column of liquid by air flow.

The inner space of the main pipe string 11 through the inlet 10 is filled with liquid (Fig. 1, 4). Liquids (water, oil substitute (simulator)) in the required quantities through an open valve 26 are pumped by metering pumps 33 from tanks 2 and 3. The required amount of water and oil simulator are determined using flowmeters 30.

The filling process is monitored by the liquid level in the transparent column 11.

By bleeding air through the valve 24, the air circulation process is started. The air flow is controlled by the following algorithm: the air movement should stop if the pressure at the lower point of the main column is set equal to the preset value of P ₀ . Air movement may stop due to:

the process of "self-pressing" of the main pipe trunk with accumulating water with a gradual increase in pressure at the lower point;

increasing pressure by injecting additional air into the installation - the pressure increase in the ground gas collection system is simulated;

forced stopping of air circulation simulating well closure at the wellhead. Forced stop of circulation should cause the restoration of pressure in the installation to P ₀ by pumping air.

The pressure at the bottom of the "radial entry" 7 is taken as P _zab .

The air supply to the radial inlet 7 is controlled by a block of regulators. At a low flow rate, a low productivity line is activated.

To create various modes of the expiration of air bubbles (small / large) in the lower part of the main column of transparent pipes is a dispersant 9. The mode of expiration of the bubbles will affect the process of foaming fluid when applying surfactants.

After the appearance of large air bubbles (transition to the "shell" mode), a line of higher air productivity is activated. Each line can be connected to its supercharger. The number of air intake lines and the number of superchargers are calculated preliminarily. One supercharger is also possible.

The inclusion of the line of maximum air capacity is possible only with sufficient cleaning of the space of the radial inlet - manifold 7 from the liquid, which is controlled through the viewing insert 16.

The liquid carried out by the air stream is separated in the centrifugal separator 17. The level sensor 32 controls the opening of the valve at the bottom of the separator 17.

The liquid from the separator 17 enters the first section of the separator 23, which is at atmospheric pressure. The second section of the tank - separator 23 freely communicates with the first section and is separated from it by a grid for damping waves. In the second section, the liquid is finally stratified: a lighter oil substitute is poured into the last section.

The pumping of water from the second section of the tank - separator 23 into the tank 2 is controlled by a water-condensate level sensor, from the last section into a tank 3 - by a condensate-air level sensor. Pumps are used for pumping, the flow rate is fixed by flow meters.

Free air flow with droplet liquid, liquid accumulation

The free air flow mode can be created either immediately, when the air circulation starts without filling the space of the pipes 11 with liquid, or after cleaning this space from the liquid (Fig. 1, 5).

Open the crane 21 to activate the lower storage tank 19 (before the start of the experiment, it is empty, under pressure).

Dispersant 9 is in a fully open state, or it is removed so as not to create additional resistance to flow.

The addition of liquid (in small quantities) to the air stream is carried out through the unit of nozzles 8. To increase the fluid supply, gradually use all nozzles with taps 25, and if necessary, use the tap 26.

At a low air flow rate or at a large water-gas ratio, part of the liquid will not be carried out by the air stream, but will begin to accumulate in the tank 19. There is no need to fully collect the tank 19, it is enough to fix the rate of fluid accumulation in it, and then close the valve 21.

In this case, the liquid begins to accumulate above the valve 21, i.e. at the bottom of the radial inlet 7, and then begins to flow to the block of air flow regulators 6. Thus, the lower regulator of the highest performance should be closed by this moment. The process of moving the gas-water mixture in the region of the block of regulators 6 is visually controlled through the viewing insert 16.

Further, the two-phase flow will work in the "shell" mode. This will begin to increase the pressure P _Zab in the lower part of the radial input 7, where the pressure sensor (s) (differential pressure) are installed (s). Air consumption will begin to decrease until the circulation stops completely, which will correspond to the state of “self-silencing”.

Thus, the whole process can be repeated.

Work with mechanical impurities (sand) in a stream

Dosing of sand occurs from a vertical transparent container 5. The pressure from the installation is transferred to the vessel 5. The feed rate of the sand is monitored and recorded visually (Fig. 1).

Since soluble in water, altering their properties solids, too fine fractions that can leave a layer of “dust” inside the pipes are not used as solids, the installation can be completely cleaned from solids with water.

Large fractions of particles may not be carried away by the air stream, but accumulate in the tank 19. The accumulated volume of sand and liquid in the tank 19 is measured after the experiment, as well as visually during the experiment. Capacity 19 can be disconnected from the installation, incl. during the experiment when closing the valve 21, the discharge of fluid and pressure into the separator 23.

When conducting experiments with the slope of the column, the container 19 is located in a vertical position, for which a set of sub 20 different configurations is provided.

The rest of the solids (sand) accumulates in the separator 17. Their volume can be controlled by calculation as the difference between the flow rate from the tank 5 and the volume in the tank 19. A removable filter is provided in the lower part of the separator 17 in front of the automatic crane. The filter traps sand during the discharge of liquid from the separator when the level sensor is triggered. The separator is cleaned of mechanical impurities after the experiment (s) with the filter removed.

In the upper part of the separator 17, a filter 27 is provided for delaying the drip liquid, sand and foam.

Work with surfactants and other non-aggressive liquid reagents.

The surfactant solution is supplied through a capillary tube 14, which is inserted into the annulus between the columns of transparent pipes 11 and 13. The depth of the descent of the capillary tube can be adjusted, the position of the bottom of the tube 14 can vary along the entire length of the column 11 (Fig. 1).

The surfactant solution in the required quantities is pumped by the metering pump from the tank 4. The required amount of solution is determined using a flow meter.

Surfactant solution can be supplied at any operating mode of the installation.

The process will be accompanied by foaming of the fluid in the barrel. To control the intensity of foam formation and destruction at several points, video and photo monitoring is provided. At these points, means of indirect control of the density (humidity) of the flow are provided.

For complete damping (physical destruction) of the foam in the separator 17 in order to prevent it from entering the circulated air and to the inlet of the blower (in the form of a closed system through the air), intensive irrigation (through nozzles) of the internal cavity of the separator with water supplied from above through line 18 can be used The water flow is controlled by a separate flow meter and metering pump. In the upper part of the separator 17, an inspection window may be provided for controlling foaming.

With the possible onset of critical foaming conditions, it is possible to provide a filter cartridge 27 for temporary containment of the foam (dropping liquid, sand). When it is critically clogged, an emergency stop of circulation.

For research, the necessary substances and / or their substitutes are selected. Components that will be replaced by natural gas (atmospheric air of various humidity and temperature), formation and condensation water (purified tap water reduced to the appropriate mineralization), gas condensate or light oil (Exxol).

The experiments can be carried out both in the vertical position of the installation and in the inclined position, the angle of inclination relative to the vertical varies from 0-85 ° due to the adjusting flanges 22 installed in the frame and configurable mast 1 with supports and braces, as well as a sub 20 for different inclination installation. The flow of components is controlled manually on the control unit of the installation, while the air flow according to the law P ₀ ² -P _Zab ² = aQ is controlled by the automation system in automatic mode. During all types of experiments, the pressure and temperature are automatically measured along the entire flow path, and photo and video are also taken (Fig. 1.)

To conduct the first type of experiments (table 1) to study the flow of gas with water with the accumulation of a liquid column and then killing the well, at the beginning there is a continuous supply of air through the air inlet 6 with a flow regulator, then the supply of water of a certain salinity from tank 2 begins, which further through the pipeline passes through the flow meter and is fed into the unit of nozzles 8 of wet gas through the valve 25 and / or into the connecting unit 10 through the valve for the liquid inlet 26. Due to the fact that the flow passes through the dispersant 9, located in the lower part of the main pipe string 11, various modes of the expiration of air bubbles in the installation are provided. To achieve the studied flow regime, there is a gradual increase in fluid flow and its accumulation, due to this there is an automatic decrease in gas flow simulating well killing due to counteraction of the accumulated fluid column. The change in air flow occurs according to the law P ₀ ² -P _Zab ² = aQ, which simulates the influx of gas from the reservoir, with equalization of the pressures P _Zab and P ₀ there is a process of auto-damping ("self-jamming"). With this type of experiment, the accumulation rate of the liquid column is studied at different flow rates of water and air, the time of accumulation of liquid in the main pipe string 11 is recorded, and the volume of accumulated liquid is measured at the end of the experiment. To stop the installation, the air supply is cut off, air is vented through the air discharge valve 24 located on the separator 17, and liquid is removed from the separator. The study of this mode is due to changes in the flow rate of liquid and water using a system for supplying and controlling the flow of air and water.

To conduct the second type of experiments (table 1) to study the gas flow with the removal of a liquid column by a surfactant solution (foaming), a certain volume of water is filled in the main column of transparent pipes 11 from the tank 2 through the connecting block 10 with the liquid inlet cock 26 open, after which air is supplied through input 6 with flow controllers, then through the supply and control system the flow of surfactants begins (if necessary, the flow rate of the solution increases) from the tank 4 through a capillary tube 14, the surfactant is fed to this interval by adjusting the height of the descent-rise of the capillary tube 14 at the upper point of the column of the main pipes. After surfactant is supplied, the liquid column is foamed and removed from the main column 11 along the column of elevator pipes 13 and return pipes 15 to the separator 17 with the foam extinguished along the path of the foam, photofixation and pressure and temperature are measured. As the well is cleaned of the liquid column, the air flow automatically increases according to the law P ₀ ² -P _zab ² = aQ, which simulates the cleaning of the well by reducing the back pressure of the liquid column. With this type of experiment, the rate of removal of the liquid column is visually determined, that is, the time during which the liquid is removed at different flow rates of the surfactant solution, the structure of the foam is fixed using photo-video shooting along the entire flow path, the tensile capacity of the surfactant is determined at different temperatures of the liquid, and surfactant solution. Further study of the properties of the foam (quality, decay rate, etc.) is also not ruled out. After cleaning the well from the liquid, the installation stops, the air supply stops, the foam in the separator 17 is extinguished and the liquid enters the separator 23, and then back to the water tank 2.

To conduct the third type of experiments (table 1) to study the flow of gas with condensate with a gradual accumulation of a column of condensate in the well and its subsequent auto-damping, air is first supplied through inlet 6 with flow controllers and then dosed from tank 3 with a simulator of light oil using a flow meter 30, supplying an oil simulator and / or through a block of nozzles 8 of wet gas with the open taps 25 of the block of nozzles and / or through the connecting block 10 with the open tap 26 of the liquid inlet. The flow passes through a dispersant 9 located at the bottom of the main pipe string 11. Gradually, an oil / condensate simulator begins to accumulate in the main pipe string 11 and the air flow automatically starts to decrease, simulating well killing, with an Exxol column. Air flow is regulated according to the law P ₀ ² -P _Zab ² = aQ, self-suppression of the well by condensate is fixed when a column creates condensate backpressure on the air flow. With this type of experiment, the condensate column accumulation rate is studied at various Exxol and air flow rates, the condensate accumulation time in the main pipe string 11 is recorded, and the volume of condensed condensate measured at the end of the experiment. After the auto-silencing of the well, the installation is turned off, air is vented when the tap 24 is opened to discharge air and accumulated condensate from the separator 17 and the main column of transparent pipes through the storage tank 19 and enters the separator 23, and then into the tank 3.

To carry out the fourth type of experiments (table 1) to study the flow of gas with water and condensate with the gradual accumulation of a column with subsequent auto-damping, air is first supplied through inlet 6 with flow controllers, then a certain amount is added to the flow (if necessary, the flow rate increases) Exxol from the tank 3 and water of a certain mineralization from the tank 2 using the nozzle block 8 with the open taps 25 of the nozzle block and / or through the connecting block 10 with the open tap 26 of the connecting block. The flow passes through a dispersant 9, located in the lower part of the main pipe string 11. Gradually, a column of liquid consisting of Exxol and water begins to accumulate in the main pipe string. The air flow rate is regulated by the law P ₀ ² -P _Zab ² = aQ, as the column accumulates in the column of the main transparent pipes 11, the gas flow automatically decreases, simulating well killing, due to counter-pressure of the liquid column. Stopping air supply means auto-capping. The installation is stopped, the air supply is stopped, the air is vented when the tap 24 is opened to discharge air, the condensate and water from the separator 17 and the main column of transparent pipes 11 pass through the storage tank 19 to the separator 23, and after separation to the tank 3 and tank 2, respectively . With this type of experiment, the rate of accumulation of a liquid column (water + condensate) is studied at various flow rates of water and air, the time of accumulation of liquid in the main pipe string 11 is recorded, the volume of accumulated liquid is measured at the end of the experiment, and the flux density is also measured.

To carry out the fifth type of experiments (table 1) to study the flow of gas with dust (the study of vortices) and sand (accumulation of cork), at the beginning, air is supplied through inlet 6 with flow controllers, then from a transparent container 5 with fine sand (dust), under pressure, with the function of dosing and visual level control with the help of a video camera 31, they start supplying sand (dust) to the air inlet, after air with sand (dust) moves through the main column of transparent pipes 11, the flow enters the column of transparent lift pipes 13, at the end which is equipped with a funnel of elevator pipes 12 of various geometries, on which the flow swirls and then flows through the return flow pipes 15 to the separator 17. As the sand (dust) dosage increases, transparent pipes 11 accumulate in the main column, as a result, a sandy hole forms bung. With this type of experiment, the accumulation of a column of sand cork and its movement along the elevator 13 and the main 11 columns are visually determined, the change in the flow velocity depending on the various configurations of the funnels 12 of the elevator pipes is measured.

To conduct the sixth type of experiments (table 1) to study the flow of gas with water, condensate and sand with gradual accumulation, air is first supplied through inlet 6 with flow controllers, then a certain amount is added to the flow (if necessary, the flow rate increases) Exxol from the tank 3, water of a certain salinity from the tank 2 using the nozzle block 8 with the open taps 25 of the nozzle block and / or through the connecting block 10 with the open tap 26 of the connecting block, sand (dust) from a transparent container with Kim sand (dust) 5, which is under pressure, with the function of dosing and visual level control using the video camera 31 starts supply of sand (dust) to the air inlet. Gradually, a column of liquid and sand (dust) consisting of Exxol, water and sand (dust) begins to accumulate in the main column of transparent pipes. Air flow is regulated according to the law P ₀ ² -P _Zab ² = aQ, as the column accumulates in the column of the main transparent pipes 11, the gas flow automatically simulates well killing due to counter-pressure of the column of liquid and sand (dust). With this type of experiment, the accumulation rate of a column of liquid (water + condensate) and sand is studied at various flows of water, Exxol, sand and air, the time of accumulation of a column of liquid and sand plug in the main pipe string 11 is recorded, and the volume of accumulated liquid and sand plug at the end is measured experiment, the flux density is also measured. Stopping the air supply means the auto-capping of the well, then the installation stops, the air supply stops, the air is bleed when the tap is opened to discharge air 24 and the accumulated condensate and water from the separator 17 and the main column of transparent pipes through the lower storage tank 19 enter the separator 23, and after tank for Exxol 3 and water tank 2, sand from the unit and separator is removed separately.

To conduct the seventh type of experiments (table 1) to study the removal of a condensate column (foaming), the Exxol volume of the main column of transparent pipes 11 is filled with a certain volume 11 from the tank 3 through the connecting block 10 with the liquid inlet cock 26 open, after which air is supplied through the inlet 6 with regulators flow rate, then through the supply and regulation system the flow of surfactants begins (if necessary, the flow rate of the solution increases) from the tank 4 through a capillary tube 14, the surfactant is supplied for a predetermined interval using p adjusting the descent height of the capillary tube 14 at the upper point of the column of the main pipes 11. After the surfactant is fed, the Exxol column is foamed and removed from the main column 11 through the column of elevator pipes 13 and the return pipe 15 to the separator 17 with the foam extinguished along the path of the foam Photofixation and measurement of pressure and flow temperature occur. As the well is cleansed of the Exxol column, an automatic increase in air flow occurs according to the law P ₀ ² -P _Zab ² = aQ, simulating well cleaning by reducing the back pressure of the Exxol column. With this type of experiment, the rate of removal of a column of liquid (Exxol + water) and sand is measured, that is, how long does it take to remove liquids (Exxol + water) and sand at a different flow rate (different concentration) of a surfactant solution, the foam structure is recorded using photo and video shooting throughout flow path, the carrying capacity of the surfactant is determined at different temperatures of both the liquid and the surfactant solution. After the well is cleaned of liquid, the installation stops, the air supply stops, the foam in the separator 17 is extinguished and Exxol enters the separator 23 and then back to the Exxol tank 3.

To carry out the eighth type of experiments (table 1) to study the removal of a column of water and condensate (foaming), a certain volume of Exxol and water of a certain mineralization are filled with a certain mineralization of the main column of transparent pipes 11 from vessel 3 and vessel 2 through the connecting block 10 with the liquid inlet cock 26 open, after there is air supply through inlet 6 with flow controllers, then through the supply and control system the flow of surfactants begins (if necessary, the flow rate of the solution increases) from the tank 4 by capillary ke 14 surfactant is supplied at a predetermined interval by adjusting the height of the descent raising of the capillary tube 14 at the upper point of the column of the main pipes 11. After the surfactant is supplied, the Exxol column and water are foamed and removed from the main column 11 along the lift pipe string 13 and return flow pipes 15 into the separator 17 with the extinguishing foam. Along the way the foam moves, photofixation and measurement of pressure and flow temperature take place. As the well is cleansed of the Exxol column and water, the air flow automatically increases according to the law P ₀ ² -P _Zab ² = aQ, simulating the well cleaning due to the decrease in back pressure of the column. With this type of experiment, the rate of removal of the Exxol column and water is visually determined, that is, how long does Exxol and water remove at a different flow rate of the surfactant solution, the foam structure is fixed using photo-video shooting along the entire flow path, and the surfactant capacity at different temperatures is determined as liquid and surfactant solution. After the well is cleaned of water-condensate liquid, the installation stops, the air supply stops, the foam in the separator 17 is extinguished and the liquid enters the separator 23 and then back to the Exxol 3 tank and the saline water tank 2.

To carry out the ninth type of experiments (table 1) to study the removal of a sand plug by a surfactant solution, a certain volume of water is filled with a certain mineralization of the main column of transparent pipes 11 from the tank 2 through the connecting block 10 with the liquid inlet tap 26 open and the column of the main transparent pipes 11 is filled from the top a certain volume of sand (dust), after which air is supplied through inlet 6 with flow controllers, then surfactant supply begins through the flow supply and control system (if necessary the flow rate of the solution increases) from the tank 4 through the capillary tube 14, the surfactant is supplied for a predetermined interval by adjusting the descent height of the capillary tube 14 at the top of the column of the main pipes 11. After supplying the surfactant, a column of water and sand (dust) is foamed and removed from the main column 11 along the column of elevator pipes 13 and return pipe 15 to a separator with foam extinguishing 17. As the well cleans from a column of water and sand (dust), the air flow automatically increases according to the law P _o ² -P _zab ² = aQ, imitate its hole cleaning by reducing the back pressure column. With this type of experiment, the rate of removal of the water-sandy plug is visually determined, that is, for how long the plug is removed at different flow rates of the surfactant solution, the structure of the foam is fixed using photo-video shooting along the entire flow path, and the tensile capacity of the surfactant is determined at different temperatures of both liquid and surfactant solution. After the well is cleaned of a column of water and sand (dust), the installation stops, the air supply stops, the foam in the separator 17 is extinguished and the liquid enters the separator 23 and then back to the tank for mineralized water 2, sand (dust) is separately removed from the installation and the separator .

It is possible to conduct closed-loop experiments using a unit with a connected receiver, which allows the use of real natural gas from fields, in which case the experimental results will be as close as possible to the conditions of real fields.

Thus, the claimed experimental setup for simulating a gas-liquid mixture and dynamic processes in a gas wellbore provides an extension of the range of tools (stands, devices) intended for modeling and researching processes in a well.

Legend to table 1:

+ ↑ - gradual increase in consumption as necessary;

+ ↓ а - automatic reduction of gas flow simulating well killing due to counter-pressure of a liquid column;

+ ↑ a - automatic increase in gas flow, simulating well cleaning due to lower back pressure of the liquid column;

+ f - initial barrel filling volume is fixed;

+ - constant gas flow rate.

Claims (10)

1. An experimental setup for simulating the movement of a gas-liquid mixture and dynamic processes in a gas wellbore, characterized in that it contains the main and inner columns of transparent pipes, a reverse flow column, a gas supply and control system for gas flow, a thermostatic water supply and control system for water flow and an oil simulator , a system for supplying and controlling the flow rate of the reagent, the main column in the upper part is connected to the return flow column, the output of which is connected to a separator equipped with an output for liquid and gas, a hydraulic system for the repeated use of water and hydrocarbon liquid, the installation is equipped with instrumentation, video and photo recording devices, while the main pipe string and the reverse flow column are fixed to the mast, and to allow reagent to be fed into the annulus a capillary tube is introduced into the space with the possibility of changing the position along the entire length of the main pipe string. 2. Installation according to claim 1, characterized in that the pipe columns are inclined. 3. Installation according to claim 1, characterized in that it contains a funnel to allow swirling of the flow. 4. Installation according to claim 1, characterized in that the separator output is either in a closed circle through the receiver, or with the release of air into the atmosphere through a critical flow diaphragm meter (DICT). 5. Installation according to claim 1, characterized in that it contains a controller for automatically controlling the air flow, which is changed according to the law P ₀ ² -P _zab ² = aQ, where P ₀ is the preset pressure in the installation when the processes in it are at rest , P _zab - variable pressure at the lower point of the main column, a - coefficient of air flow rate, Q - air flow rate, to ensure the process of simulating gas flow from the wellbore. 6. Installation according to claim 1, characterized in that it contains a dispersant located in the lower part of the main pipe string to provide various modes for the expiration of air bubbles in the installation. 7. Installation according to claim 1, characterized in that the high-resolution photo and video surveillance devices with backlight are installed at several points along the flow to ensure registration and subsequent analysis of the flow structure and foam. 8. Installation according to claim 1, characterized in that, as control and measuring devices, it contains high-precision pressure / temperature and / or differential pressure sensors. 9. Installation according to claim 1, characterized in that the control and measuring devices are installed at several points along the flow direction, with two sensors installed at each point to ensure accurate readings, their duplication and diagnostics of sensor malfunctions. 10. Installation according to claim 1, characterized in that it contains at several points in the direction of flow the means of density control distributed over the diameter of the pipes to provide control of the density of the stream over the cross section of the pipes.

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