RU2743285C1 - Autonomous inflow regulator - Google Patents

Abstract

FIELD: oil production.SUBSTANCE: invention relates to equipment used for oil production, specifically to systems for regulating the flow of liquid into the casing pipe coming from outside the casing pipe, for example, from a productive formation. An autonomous inflow regulator installed in the well on the side surface of the pipe between the pipe and annular space contains a housing with holes in the bottom located along the edge of the inner cavity of the housing, a cover with one hole in the center and a movable disk that performs the functions of a valve. The movable disk is installed with a gap relative to the cover and the bottom inside the housing on the projections of the disk axial orientation. A threaded hole is made in the center of the bottom of the housing, in which a threaded insert with axial projections is installed with the possibility of axial movement to adjust the gap between the disc and the housing.EFFECT: increased efficiency of valve closing with decreased viscosity and increased rate of produced passage through it.7 cl, 6 dwg

Description

The invention relates to equipment used for oil production, specifically to systems for controlling the inflow into the casing of the liquid coming from the outside of the casing, for example, from a productive formation.

A known system for controlling the flow of fluid in a well, containing a fluid module with a bridge network for fluid, and a method of using such a system according to the RF patent for invention No. 2568619. The group of inventions relates to methods and systems for controlling fluid flow in a well. The system contains a fluid module with a main flow, valve and bridge network. The valve has a first position in which fluid can flow through the main path and a second position in which fluid flow through the main path is blocked. The bridge network has first and second branch ducts, each of which has an inlet and an outlet communicating with the main duct and each of which includes two hydraulic resistances with a pressure take-off terminal located between them. In operation, the differential pressure between the terminals of the first and second branch ducts moves the valve between the first and second positions. The technical result consists in increasing the efficiency of controlling the fluid flow in the well. The disadvantage of the system for controlling the flow of fluid in the well is the presence of a network of channels, which increases the likelihood of their clogging and system failure.

A device for leveling the inflow of an oil well is known according to the RF patent for utility model No. 173196. The utility model relates to the field of hydrocarbon production and can be used for the operation of wells, in particular for aligning the profile of the fluid flow along the length of a horizontal well. The task of creating a useful model is to provide the ability to adjust the pressure drop in the channel network and on the inflow regulator, as well as to reduce the labor intensity of manufacturing and assembling the device. The solution to these problems is achieved due to the fact that a device for leveling the inflow of an oil well, containing a support pipe, on which a filter element is installed between the fixing rings, connected by a network of channels with an opening in the pipe, the network of channels to ensure high hydraulic resistance is made with multiple changes in the direction of movement the fluid flow and / or with multiple narrowing and expansion of the flow, on the inner surface of the retaining ring holding the filter element on the side of the channel network, grooves are made for the passage of the extracted product, the channel network is made on rings installed on the carrier pipe in the amount necessary to create the required hydraulic resistance , moreover, on the ends of the rings there are protrusions and depressions that provide the radial orientation of the rings relative to each other, and before and after the rings with a network of channels on the pipe there are adapter rings with holes for the passage of the extracted product. Rings with a network of channels are closed with a casing fixed by a stepped ring, on the inner surface of which there are grooves for the passage of the extracted product. Behind the stepped ring in the hole for the passage of the produced product into the carrier pipe, an inflow regulator is installed on the thread, made with a through hole, the diameter of which is selected depending on the inflow rate at the device installation site. The inflow regulator is closed with a cover, which is fixed to the pipe with screws. Cover, casing and inflow regulator are sealed with rubber rings. The disadvantage of the device for leveling the inflow of an oil well is the complexity of its design.

Known autonomous downhole inflow regulator according to RF patent for invention No. 2513570. A valve assembly for regulating fluid flow in a horizontal well is presented. The casing can be connected by a tubing string. The chamber is formed within the housing and can be fluidly communicated with a flow channel with an internal annular gap formed near the wellbore. The piston and biasing member may be located within the chamber, the biasing member being adapted to bias the piston into a first position. A fluid flow path is formed within the housing and is in communication with the tubing and the internal annulus. The flow path may contain one or more nozzles located therein and the piston may be adapted to move between a first position allowing fluid to flow through the flow path to the tubing and a second position to prevent fluid from flowing into the tubing - blocked. The disadvantage of an autonomous inflow regulator is the complexity of the design.

Known adjustable flow restrictor for use in an underground well under the RF patent for invention No. 2532410. The group of inventions relates to mining and can be used to control the flow of fluid into a well. The system contains a flow chamber through which a multicomponent fluid flows, and this chamber contains at least one inlet, an outlet and at least one structure located in a spiral relative to the outlet, contributing to swirling the multicomponent fluid flow in a spiral around the outlet. Another version of the system comprises a flow chamber having an outlet, at least one structure that helps to swirl the multicomponent fluid in a spiral around the outlet, and at least one more structure that prevents the flow of the multicomponent fluid from being redirected to a radial path going to the outlet. The technical result consists in preventing the formation of a gas cone and / or a water cone around the well. The disadvantage of an adjustable flow restrictor is the low separation efficiency of the well fluid with a lower viscosity.

Known electrohydraulic inflow control valve according to RF patent for utility model No. 181704. The utility model relates to the field of hydrocarbon production and can be used for the operation of wells, in particular, for aligning the profile of the fluid flow along the length of a horizontal well. The task of the utility model is to create a new device - an electro-hydraulic inflow control valve with the achievement of the following technical result: ensuring the flow of liquid from the production formation into the supporting pipe with the possibility of limiting the flow of undesired liquid or gas through the valve and the possibility of adjusting the pressure drop in the channel network from the wellhead. The electro-hydraulic inflow control valve includes a housing containing a main channel with an actuator that closes the channel, and a secondary channel with flow restrictors to create the required pressure drop. The actuator is driven by a piston, the position of which is determined by a displacement sensor; in the secondary channel there is a network of flow limiters made in the form of throttling packets and nozzles; a differential pressure sensor is installed, while the secondary channel is limited by a damper and an electromagnetic valve actuated from the surface of the well. In addition, the electro-hydraulic inflow control valve contains a buffer tank for the liquid displaced by the valve. The disadvantage of the electro-hydraulic inflow control valve is that it is operated from the surface.

Known flow control device according to the RF patent for invention No. 2600401. The invention relates to equipment for completing oil and gas wells, in particular for regulating the inflow of well fluid in a separate section of the wellbore. The device contains a housing consisting of upper and lower parts connected by a threaded connection, an axial entrance to the housing and radially located outlets, an entrance to a secondary channel in the upper part of the housing, made in the form of a groove in which a porous element is located, a system of capillary channels in axial direction, made in the walls of the housing, a movable element, a collet and a small-diameter nozzle. In the lower part of the housing, the capillary channels are combined into a cavity between the movable element and the lower part of the housing. The disadvantage of the flow control device is low reliability associated with the presence of capillary channels in the secondary flow, passing through which the flow repeatedly turns, which in the presence of mechanical impurities will lead to clogging of the secondary channel and a rapid failure of the device.

A device and method for passive control of a fluid medium in a well is known according to the RF patent for invention No. 2540764. The group of inventions relates to the oil and gas industry and, in particular, to the field of selective control of the flow of fluids - fluids entering the production string of the well. The technical result is to limit the flow of water in the flow of hydrocarbons. The method of manufacturing the device for controlling the flow of fluid from the formation involves the use of a material with an adaptable shape and with an open cell structure. A flow control element is formed by injecting a material with an adaptable shape - a hydrophilic polymer - into the openings of the open-cell structure. The amount of hydrophilic polymer is provided in a volume sufficient for the flow control element to restrict the flow of water flowing through it. The hydrophilic polymer is placed in the openings of the open cell structure to restrict the flow of water through them. At the same time, the adhesion of the hydrophilic polymer to the walls of the cells of the material with the adaptable shape is provided. The disadvantage of the device and method for passive control of the fluid in the well is the low efficiency when changing the operating modes of the well.

Known autonomous inflow control valve AUKP-FLOWREG AICD according to the technical passport of the company Weatherford (prototype). An autonomous inflow control valve is installed in the well on the lateral surface of the pipe between the pipe and annular space. It includes a body with holes in the bottom located along the edge of the inner cavity of the body, a lid with one hole in the center and a movable disk that acts as a valve installed with a gap relative to the lid and the bottom inside the body on the protrusions of the axial orientation of the disk. The disadvantage of an autonomous inflow control valve is the inability to adjust the well flow rate, as well as to adjust the hydraulic resistance formed by the gap between the cover and the disc to select the optimal gap that ensures the valve closure when the viscosity and the rate of passage of the produced product through it changes.

The objective of the invention is to adjust the hydraulic resistance formed by the gap between the cover and the disk, with the achievement of the following technical result: increasing the efficiency of valve closure while decreasing the viscosity and increasing the rate of passage of the produced product through it, as well as adjusting the optimal ratio of flow rate and water cut of the produced product.

The solution to these problems is achieved due to the fact that an autonomous inflow regulator installed in the well on the lateral surface of the pipe between the tubular and annular space includes a body with holes in the bottom located along the edge of the inner cavity of the body, a cover with one hole in the center and a movable disk, acting as a valve, installed with a gap relative to the cover and the bottom inside the body on the protrusions of the axial orientation of the disc, and in the center of the bottom of the body there is a threaded hole, in which a threaded insert with protrusions of axial orientation is installed with the possibility of axial movement to adjust the gap between the disc and the cover. At the upper end of the threaded insert there are at least three protrusions of axial orientation, located evenly around the circumference. At the bottom end of the threaded insert there is a polygonal hole or a slotted groove for a key. The threaded insert is installed in the body on a thread seal or sealant. The threaded insert is cold-welded into the body. In the threaded hole of the body and on the threaded insert, the thread pitch is made small for smooth adjustment. At the maximum lateral displacement of the disc, its edges do not go beyond the protrusions of the axial orientation of the disc.

The conducted patent studies have shown that the proposed technical solution has novelty, industrial applicability and an inventive step, i.e. meets all the criteria of the invention. The inventive level is confirmed by the fact that a new set of essential features provides a new technical result. Industrial applicability is due to the fact that in the manufacture of an autonomous inflow regulator, non-scarce materials and known technologies are used.

The essence of the invention is illustrated in FIG. 1 ... 6, where:

FIG. 1 shows an autonomous inflow regulator installed on a pipe in a well.

FIG. 2 shows a longitudinal section of an autonomous inflow regulator and a diagram of the movement of well fluid in it.

FIG. 3 shows section A-A. The disc that acts as a valve is not shown in section.

FIG. 4 Shown is a top view of a six axially oriented threaded insert.

FIG. 5 Shows a threaded insert, section B-B.

FIG. 6 shows a view "B" of a hexagonal key hole made from below in a threaded insert.

An autonomous inflow regulator 1 is installed in the well 2 on the side surface of the pipe 3 between the pipe 4 and the annular space 5, includes a body 6 with holes 7 in the bottom 8 located along the edge of the inner cavity 9 of the body 6, a cover 10 with one hole 11 in the center and movable disc 12, performing the functions of a valve, installed with a gap relative to the cover 10 and the bottom 8 inside the body 6 on the protrusions of the axial orientation 13 of the disc 12, and in the center of the bottom of the body 8 there is a threaded hole 14, in which the axial movement to adjust the gap "S" Between the disc 12 and the cover 10, a threaded insert 15 with protrusions of axial orientation 13 is installed. At the upper end 16 of the threaded insert 15 there are at least three protrusions of axial orientation 13, which are evenly spaced around the circumference. On a circle. On the lower end 17 of the threaded insert 15, a polygonal hole 18 or a slotted groove for a key is made. The threaded insert 15 is installed in the body 6 on the thread seal or sealant. The threaded insert 15 is fixed in the body by cold welding. In the threaded hole 14 of the body 6 and on the threaded insert 15, the pitch of the thread, for smooth adjustment, is made small. With the maximum lateral displacement of the disc 12, its edges do not go beyond the protrusions of the axial orientation 13 of the disc.

Autonomous inflow regulator 1 works as follows. Before installation in well 2, the position of the disc 12 is adjusted relative to the hole 11 in the cover 10 of the regulator, for which the threaded insert 15 is unscrewed with a key from the body 6, its threads and threads in the threaded hole 14 of the bottom 8 of the body 6 are lubricated with a thread sealant. The threaded insert 15 is again installed in the housing 6, maintaining the gap "S" which, with a known thickness of the cover 10, is controlled by a depth gauge through the hole in the cover 11. The regulator 1 is installed on the side surface of the pipe 3 and is lowered into the well with the casing string 2. The produced product from the annular space 5 enters through hole 11 in the cover 10 inside the regulator 1, then bends around the disc 12 and through the holes 7 in the bottom of the housing 8 passes into the tube space 4. The disc 12 has the ability to axially move between the projections of the axial orientation 13 of the disc 12 and the cover 10. The position of the disc 12 depends on the viscosity of the produced product and the speed of its passage through the regulator 1. In accordance with Bernoulli's law, the sum of static pressure, dynamic pressure and friction pressure losses along the flow line is constant. During the passage of a viscous product, for example oil, the disk 12 is pressed against the axially oriented projections 13 of the disk and provides the maximum flow area. If less viscous fluids, such as water and gas, pass through the regulator 1 at a high speed, a pressure difference arises inside the device, under the influence of which, the disk 12 moves towards the hole 11 in the cover 10 and closes it. Due to this, the flow of water and gas into the pipe space 4 is limited, in the event of a breakthrough. Oil production and water cut of the produced product depends on the size of the gap "S". With an excessive decrease in the gap "S", the well flow rate decreases and the rate of movement of the produced product through the hydraulic resistance increases, which leads to early closure of the hole 11 in the cover 10 by the disk 12 and reduces the productivity of the well. With an excessive increase in the clearance "S", the well flow rate increases, while the water cut of the produced product also increases, since the pressure drop across the hydraulic resistance is not enough to timely close the disk 12.

Application of the invention allowed:

1. Provide an adjustment of the hydraulic resistance formed by the gap between the cover and the disc for the optimal ratio of flow rate and water cut of the produced product.

2. Ensure that the valve is closed when the viscosity decreases and the rate of passage of the produced product through it increases.

3. Prevent the formation of water and gas cones.

4. Reduce the water cut of the produced product.

Claims (7)

1. An autonomous inflow regulator installed in the well on the lateral surface of the pipe between the tubular and annular space, including a body with holes in the bottom located along the edge of the inner cavity of the body, a cover with one hole in the center and a movable disk that acts as a valve, installed with a clearance with respect to the cover and the bottom inside the body on the axial projections of the disc, characterized in that a threaded hole is made in the center of the bottom of the body, in which a threaded insert with axial projections is installed for axial movement to adjust the gap between the disc and the lid. 2. The autonomous inflow regulator according to claim 1, characterized in that at least three axial projections are made on the upper end of the threaded insert, which are evenly spaced around the circumference. 3. An autonomous inflow regulator according to claim 1, characterized in that a polygonal hole or a slotted groove is made at the bottom end of the threaded insert. 4. The autonomous inflow regulator according to claim 1, characterized in that the threaded insert is installed in the body on the threaded seal or sealant. 5. An autonomous inflow regulator according to claim 1, characterized in that the threaded insert is fixed in the body by cold welding. 6. An autonomous inflow regulator according to claim 1, characterized in that the thread pitch in the threaded hole of the body and on the threaded insert is small for smooth adjustment. 7. The autonomous inflow regulator according to claim 1, characterized in that at the maximum lateral displacement of the disc, its edges do not go beyond the protrusions of the axial orientation of the disc.

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