BR112014021910B1 - METHOD TO RESTRICT FLOW BETWEEN ZONES IN A WELL AND MECHANISM TO RESTRICT FLOW BETWEEN ZONES IN A WELL - Google Patents

Abstract

downhole mechanism. a downhole mechanism comprising a tubular body; first and second ports in a body wall, and a fluid pressure responsive valve arrangement having a first latched configuration associated with a first pressure wherein the first port is open and the second port is closed, a second latched configuration associated with a second pressure greater than the first pressure where the first door is open and the second door is closed, and a third configuration associated with a third pressure less than the second pressure where the second door is open and the first door is closed.

Description

field of invention

[001] The present invention relates to the downhole mechanism and, particularly, but not exclusively, to the flow control mechanism, such as sand screens and associated mechanism and methods.

Invention history

[002] WO 2009/001069 and WO 2009/001073, the disclosures of which are incorporated herein in their entirety, describe arrangements for supporting borehole walls and for applying predetermined stresses to the borehole walls. The inflatable chambers are mounted on a base tube so that inflation of the chambers increases the mounting diameter. The chambers can support a sand control element.

Invention Summary

[003] According to the present invention, the downhole mechanism is provided comprising: - a tubular body; - first and second ports in a body wall, and - a fluid pressure responsive valve arrangement having a first latched configuration associated with a first pressure where the first door is open and the second door is closed, a second latched configuration associated with a second pressure greater than the first pressure where the first door is open and the second door is closed, and a third configuration associated with a third pressure lower than the second pressure where the second door is open.

[004] According to another aspect of the invention, there is provided a flow control method comprising:- applying a first pressure to a fluid pressure responsive valve arrangement controlling the configuration of the first and second ports in a wall of a body tubular, whereby the valve arrangement maintains a first locked configuration in which the first port is open and the second port is closed; - apply a second pressure greater than the first pressure whereby the valve arrangement assumes a second locked configuration in that the first port is open and the second port is closed, and applying a third pressure less than the second pressure whereby the valve arrangement assumes a third configuration where the second port is open.

[005] The valve arrangement configuration can be changed in any appropriate sequence, for example, the first configuration being followed by the second configuration which is then followed by the third configuration. Alternatively, the third configuration can be followed by the second configuration which is then followed by the first configuration.

[006] The first locked configuration can be an initial configuration for the valve arrangement. In this way, for example, the mechanism can be run in a hole in the first configuration.

[007] The first door may be closed in the third configuration.

[008] The first port may include a check valve that closes the first port in the absence of a positive pressure differential across the valve.

[009] The valve arrangement may include a valve member that closes the second port in the first and second configurations. The valve member can close the first port in the third configuration. The valve member may have any suitable shape, and may be a sleeve. The valve member can be tilted toward a position to open the second port.

[0010] The valve arrangement may be locked in the first configuration by a lock arrangement which may comprise a releasable retaining member such as a shear pin. The retaining member may retain a valve member in a first configuration relative to the body.

[0011] The valve arrangement may include more than one locking arrangement, for example the elements of the valve arrangement may be locked into position when the valve arrangement is in the third configuration.

[0012] The valve arrangement can define a differential piston. One piston face may be exposed to internal tube pressure and a second piston face may be exposed to external pressure, eg ring pressure. Correspondingly, a positive pressure differential between the tube and the ring will result in a fluid pressure force acting on the piston.

[0013] The piston can be accommodated in a chamber with a port providing fluid communication with an external pressure. The port can be sized or otherwise configured to induce a pressure drop in the fluid passing through the port.

[0014] A pressure relief arrangement can be associated with the piston, whereby, if the external pressure exceeds the internal tube pressure, which is a negative pressure differential between the tube and the ring, the external pressure can be relieved , thus avoiding inadvertent or reverse activation of the piston. External pressure can be relieved via a check valve or bleed valve which allows the upper external pressure to bleed from the outside of the piston to the inside of the piston. The valve can be sized or otherwise configured to induce a pressure drop in the fluid passing through the valve. The shape of the valve and the number of valves provided can be selected as appropriate. In one configuration, a port extends across the piston and accommodates a ball driven into a sealing fit with a spring-loaded seat. Clearly, those skilled in the art will recognize that such a pressure relief arrangement may have utility in other forms of downhole mechanism, particularly those using differential pistons, by accommodating reverse pressure differentials that might otherwise have a adverse effect on the operation of a pressure actuated tool.

[0015] The first port may provide fluid communication with a first tool or device, for example a fluid deformable device such as a chamber mounted to the body. The fluid deformable device can support a sand screen, so the mechanism can be used to facilitate fluid pressure activation of a sand screen. In one configuration, the first port provides communication between the interior of the body and a chamber that extends axially along the exterior of the body.

[0016] The second port can provide fluid communication between the interior of the tubular body and the exterior of the tubular body and be configured to, for example, allow the flow of production fluid from a formation in the body, or to allow for passing fluid, such as injection, fracturing or treatment fluid, from the body and into the formation. In some embodiments, the second port can be used to pass a fluid from the tubular body in the formation, and at some other time to pass a fluid from the formation in the tubular body. The second port can be configured with an inflow control device (ICD) and as such the mechanism can be used to facilitate the activation of fluid pressure from an ICD.

[0017] In one configuration, the second port comprises an ICD in the form of an insert, for example, an insert of erosion resistant material such as tungsten carbide. A disk or other member can be provided with an insert and the disk can be adapted to be located in a second port. The shape of the insert can be selected to provide a predetermined pressure drop in the fluid flowing through the port. On some discs, an empty insert may be provided, preventing flow through the second ports.

[0018] One or more valve arrangements may be incorporated into a completion and provided that one or more second ports are provided with ICDs. In this way, based on surveys or other well logging information, an operator can configure the ICDs to provide a desired flow profile from adjacent formations and into the well.

[0019] The mechanism may include two or more valve arrangements and associated first and second ports. Each valve arrangement can be associated with a respective tool or device, for example each mechanism can be associated with a respective orifice wall support mechanism, wrapper, hanger or sand screen. The valve arrangements and associated tools or devices may be axially spaced along the tubular body. Alternatively, or in addition, the valve arrangements and associated tools or devices may be circumferentially spaced around the tubular body. In this way, multiple valve arrangements can be activated simultaneously.

[0020] The valve arrangement can be arranged in a fourth configuration with the second port closed. The valve arrangement can be adapted for mechanical actuation for the fourth configuration. Thus, for example, in the fourth configuration, the mechanism can impede the flow of production or other fluid from one formation in a completion, or impede the flow of fluid from a completion or other body in a formation.

[0021] The mechanism may comprise fluid deformable members or chambers mounted on a base tube, which members may be adapted to be activated by fluid passing through the first port. Activated members can provide support for filter media, and can be used to locate filter media, such as a sand screen, in contact with an orifice wall, or to increase the diameter described by the filter media. The activated members can be adapted to provide support for an orifice wall, or to load or compress material between the members and an orifice wall, with or without supply of filter medium, thus providing the beneficial effects as described in WO2009/ 001069 and WO2009/001073. A check valve or the like may be associated with the first port to retain fluid in the fluid deformable members. Alternatively, or in addition, relief valves or the like may be associated with fluid deformable members, the valves being configured to release pressure from the members to prevent excessive inflation. Furthermore, the mechanism can be configured to allow deflation or deactivation of the limbs, for example, by providing appropriate valves, thus facilitating the removal or recovery of a mechanism from an orifice, although in most cases it is likely that the mechanism is intended for permanent installation.

[0022] One aspect of the present invention relates to the provision of a tubular body forming part of a completion including one or more sand screens, each screen incorporating a mechanism in accordance with the invention. The first ports can communicate with fluid deformable members or chambers mounted on a base tube, the chambers supporting a filter member. Screens can be drilled in a hole drilled to the desired depth with the valve arrangement in the locked configuration. A first pressure is then applied to the interior of the completion and fluid can pass through the first ports to simultaneously and at least partially inflate the chambers, increasing the diameter of the screens to locate the filter members against the adjacent orifice wall or casing. The applied pressure is then increased to a second higher pressure and the valve arrangement assumes the second locked configuration. This can be achieved by providing a valve member in the form of a sleeve and incorporating a differential piston, the valve member being initially locked into position by a shear pin. The second upper pressure can trim the pin and move the sleeve a short distance, against the action of a spring, keeping the first door open and the second door closed. Pressure can be further increased to fully inflate and activate the chambers; the pressure required to make the pins appear may be less than the pressure required to fully activate the chambers. Maintaining the pressure at this high level for a period of time ensures that all pins are propped and all screens are fully activated against the borehole. Activated screens can thus conform to the wellbore wall, i.e. the screens will tend to follow and maintain contact with the wellbore surface, even if the surface is non-cylindrical or otherwise irregular. Pressure is then bled from completion, the check valves associated with the first ports locking out the elevated pressure within the chambers and keeping the sleeves fully activated. As the pressure continues to bleed, the sleeves are moved by the springs to assume the third configuration where the first doors are closed and the second doors are open. An additional barrier can be provided to close the first ports, for example a selector valve can be provided between the first ports and the valve sleeve and can be positioned to close the first ports. The production fluid can then flow from the formation, through the filter member and the second ports and into completion, and then to the surface. In other embodiments, the mechanism can be used to control fluid flow in the opposite direction, for example, injection, fracturing or treatment flow fluid in formation.

[0023] In this way, the screens can be fully activated by modulating the pressure applied to the internal part of the completion. If desired, the entire completion or a completion section can be pressurized to simultaneously activate all screens or numerous screens provided in the pressurized section, which in the vast majority of cases will be attainable without providing specialist equipment or expertise. Furthermore, no intervention is required, increasing the speed and reliability of the operation. Alternatively, screens can be activated individually or in groups, for example, by using an appropriate tool or device to isolate individual screens or groups of screens. This allows different activation pressures to be used for selected screens and for selected locations in the well.

[0024] Completion will typically be intended as a permanent installation. However, the completion, or indeed any other configuration of the invention, can be configured to be retrievable or removable, typically by allowing for deflation and deactivation of the chambers.

[0025] Where the mechanism comprises fluid deformable members or chambers mounted on a base tube that has been activated by fluid passing through the first port, the activated mechanism can provide a structure with improved resistance to crushing and collapse.

[0026] According to another aspect of the present invention, the downhole mechanism is provided in the form of a fluid pressure deformable chamber for location in a base member, the chamber having a body having a first portion of a first length, width and depth, a second portion having at least one of a second depth and width smaller than the first portion, and a transition portion coupling the first and second portions and configured to provide a progression between the deformation characteristics of the first and second servings.

[0027] The second portion can be used to locate or secure the chamber to the base member.

[0028] The second portion may form one end of the chamber, and a second portion and an associated transition portion may be provided at one or both ends of the chamber. When filling the chamber with fluid, the depth of the chamber may increase. The pressure of the fluid used to deform the chamber can be selected based on a number of criteria. For example, a pressure between 1.4 and 5.5 MPa (200 and 800 psi) can be used to fully activate the chamber, but clearly other pressure variations can be effective in other embodiments.

[0029] A plurality of chambers can be provided around a base member. The chambers may extend axially from the base member and be disposed side by side to provide substantially complete circumferential coverage of the base member. The chambers can support a member or device, for example a filter member such as a sand screen.

[0030] The chamber may have a wall formed to match the profile of an associated base member. Typically, the chamber will have an arched inner wall where the chamber is intended to be mounted externally to a cylindrical base member. As the chamber is filled with fluid, an outer wall moves radially outward, increasing the depth of the chamber and the diameter of the assembly. The chamber may have an arcuate outer wall intended to match the surface of an adjacent hole wall.

[0031] The chamber may include an activation port to provide passage of the chamber strain fluid. The port can be provided at any suitable location in the chamber. The port can be provided in the second portion, at one end of the chamber, which can form a spike. The activation port can be located on a main axis of the chamber. The associated post may initially be at least as deep as the body.

[0032] The first width and depth can be substantially constant along the length of the body.

[0033] A fluid port can be provided at the other end of the chamber. Alternatively, the other end of the chamber may be closed or sealed and may serve primarily to locate the end of the chamber relative to the base member. A door at the end of the chamber may be open, for example, to facilitate filling the chamber during fabrication or assembly to remove air from the chamber, to accommodate a pressure relief valve, or to provide communication with another chamber, for example, a camera on an adjacent device, which device might be a sand screen.

[0034] The edges of the transition portion may depict an inner radius and an outer radius. The inner radius reduces stresses in the transition portion as the chamber is deformed. The outer radius also reduces stresses in the transition portion as the chamber is deformed. Additionally, the outer radius reduces shrinkage of the length and width of the chamber as the chamber is deformed. The outer radius also reduces the potential to damage a filter member extending over the chamber and tends to provide a more even profile in the deformed chamber.

[0035] The transition portion can be configured to cooperate with a chamber block defining a fluid passage. The chamber block can be configured to maintain its shape while the chamber is deformed. The block can define a female port configured to receive the transition portion. The transition portion can be bonded to the block, for example by welding, to provide a pressure-tight seal between the chamber and the block. The block can be configured to be fixed to a base member. The chamber can be attached to the block before the block is attached to the base member. Correspondingly, the transition and block portion can be, for example, welded around the complete periphery to ensure pressure integrity before the assembly is mounted on the base member. The block may include an entrance door in an interior wall. The inlet port may include a check valve. The input port can be configured to communicate with the first port of the first aspect of the invention.

[0036] According to another aspect of the present invention, there is provided a method of connecting a fluid pressure deformable chamber having an activation port at one end of the chamber to a base member, the method comprising forming a sealed connection between the activation port and a chamber block and then mount the chamber block to the base member.

[0037] The block may have any suitable shape and may be relatively rigid with respect to the chamber so that the block substantially retains its shape when the chamber is deformed. The block can include a valve.

[0038] The trigger port can be provided in a transition portion as described above.

[0039] According to a further aspect of the present invention, there is provided a support layer for location between a downhole filter member and an associated base member, the support layer comprising a sheet of material, the sheet being open and formed to provide a fluid path.

[0040] This aspect of the invention allows the support layer to function as a drainage layer.

[0041] The support layer can be formed from a curved sheet.

[0042] The support layer may portray surface protrusions to space the sheet from an adjacent member. Alternatively, or in addition, the layer may have a corrugated shape, for example the layer may be corrugated or otherwise define peaks and valleys, or the layer may be formed of overlapping members, or multiple layers may be provided and adjacent layers superimposed.

[0043] The support layer can be used in a sand screen as used in the production of hydrocarbons from underground formations.

[0044] The support layer may comprise a plurality of members.

[0045] The support layer can be formed from any suitable material. The layer may comprise a solid sheet, for example solid steel plate, although other materials may be used.

[0046] The openings can be of any suitable shape, pattern, shape or size. For example, rows of holes can be punched or pressed from the sheet. In use, openings may allow the passage of oil or gas.

[0047] The openings can be consistently over the support layer. Alternatively, the shape of openings can be varied to control the passage of fluid through the layer and particularly to equalize the flow through the layer over the length of the layer. For example, the number or dimensions of the openings can increase or decrease along the length of the layer depending on the distance between the openings and a valve or flow port in the base support. Typically, openings further spaced from the outflow port will provide a larger area of flow to compensate for the pressure drop that will occur as fluid flows from the openings to the outflow port.

[0048] If the support layer is provided with the protrusions, these may have any suitable shape, pattern, shape, size or depth. The protrusions may lift or space the support layer from the base member, allowing oil or gas to flow down between the layer and the base member. The protrusions can be arranged to allow fluid to flow either or both axially and circumferentially.

[0049] Protrusions can be formed by stamping a pattern onto the sheet of material to create protrusions on the inner surface.

[0050] The support layer can be formed to match the profile or shape of one or both of the filter member and base member. The support layer may be provided in combination with fluid pressure deformable base members or activation chambers, as described in relation to the other aspects of the invention, and a support layer member may be configured to provide a bridge between the adjacent activation chambers, to provide support for the filter member, particularly as the chambers are activated and gaps open between the chambers, and to provide radial support for the adjacent well hole wall. The support layer can also help maintain the circular shape of the canvas as the canvas is activated. In other aspects of the invention, activation chambers may have surfaces formed to provide a fluid path along the surface of the support member.

[0051] According to another aspect of the invention, there is provided a retainer for a sand screen filter member comprising a configurable clip member for securing at least an end portion of a filter member against a clip body configured to attach to a base member.

[0052] According to a still further aspect of the present invention, there is provided a method of retaining a filter member in a sand screen, the method comprising:

[0053] find the filter member around a base member; and

[0054] securing at least the end portions of the filter member against the base member.

[0055] The filter member may be in the form of a weave. The filter member can be wrapped around the base member.

[0056] The clip member may comprise an axially convertible retainer having a clip surface configured to cooperate with an opposing clip surface on the clip body, whereby a portion of the filter member can be secured between the surfaces. Clamp surfaces can define cones.

[0057] The clamp member may be a clamp ring and may be threaded or otherwise attachable to the clamp body. Where a threaded clamp ring is provided, the relative rotation of the clamp ring and clamp body can induce axial movement of the clamp ring in the clamp body.

[0058] The clamp body may be integral with the base member. Alternatively, the clamp body may be detached from the base member, and may float at least axially relative to the base member. This arrangement facilitates to accommodate axial shrinkage of the filter member if the filter member is to be subject to expansion.

[0059] The clamp body may be recessed beyond the clamp surface of the clamp body to accommodate one end of the filter member. If necessary or desirable, the filter member can be tack welded into the recess during assembly to retain the filter member in place before the clip member is secured to the clip body.

[0060] The invention also relates to a sand screen incorporating the retainer, and a method of mounting a sand screen.

[0061] In one configuration, the filter medium, which may be in the form of a weave, is wrapped around a base member having a clamp body attached to each end. The weave can be held in place for ease of assembly using ratchet straps, spot welds or the like. Spot welds can be provided along the length of the weave and the weave can be welded to the base member or to a support or drainage layer between the base member and the filter member. The ends of the weave are tightly wound around the recesses in the staple bodies. The clamp or retainer rings are then screwed into the clamp bodies. The weave is clamped between the cones on the clamp ring and the clamp body, thus securing the weave in place around the base member.

[0062] According to a still further aspect of the present invention, there is provided a method of restricting flow between zones in a well, the method comprising: providing a layer of deformable material in a sand screen; and activate the sand screen so that the deformable material contacts and seals against the well wall.

[0063] The deformable material may be provided in a portion of the sand screen, for example at one or both ends of a sand screen.

[0064] The deformable material may be arranged in the sand screen so that fluid can pass below the material, for example through or below the sand screen.

[0065] The wall of the well can be coated, for example, with the casing or liner, or it can be uncoated.

[0066] The deformable material can be an elastomer, and can be an expandable material activated by water, oil or some other material.

[0067] A method of increasing the strength of a base member comprising mounting the chambers on the base member and inflating the chambers.

[0068] The member may have any suitable shape, and may be a hollow or solid member, for example a tube or a beam.

[0069] The chambers may be arranged around a surface of the member and may extend axially from the member. Chambers can be provided on an outer surface of the base member, or on an inner surface of the base member.

[0070] The member may be restricted or contained within a hole or other adjacent wall. An external point charge applied to a chamber, and which tends to deform the chamber wall, will tend to increase the internal fluid pressure in the chamber and result in the charge being spread along the length of the chamber. Furthermore, when a load is applied to one side of the member, chambers on the other side of the member can be compressed between the member and the orifice wall and radially distribute the reaction force over the opposite surface of the member. For tubular members, such as downhole structures, providing the chambers thus will improve the collapse strength of the members.

[0071] A method of creating a crush-resistant structure in accordance with an aspect of the present invention comprises: - locating a base tube in a hole; e- inflating the chambers located between the base tube and the orifice with the fluid, thus providing a structure having a high resistance to crushing.

[0072] The frame may conform to the hole, that is, an outer surface of the frame substantially follows the hole wall.

[0073] The structure may comprise a sand screen.

[0074] The structure may be located in a swelling formation or a formation with geomechanical motion.

[0075] According to another aspect of the present invention, a shroud is provided for a sand control mechanism, the shroud having elongated slots and the shroud being configured to be located in a sand control mechanism with the slots inclined to the axis length of the mechanism.

[0076] The shroud can be provided in combination with a sand control mechanism, eg a sand screen. The shroud may be positioned on the outside of the mechanism, adjacent to a sand control element. The sand control mechanism can be radially expandable, that is, at least a portion of the mechanism can be activated to set a larger diameter.

[0077] The slits can be inclined at any suitable angle, eg 15 degrees to the longitudinal axis.

[0078] The inclination of the slits tends to increase the force or pressure required to extend or activate the shroud. In this way, the shroud can be used to control the activation of the mechanism. For example, where activation is achieved by inflating the pressure-deformable chambers below the sand control element, the shroud can serve to control the pressure needed to initiate activation. Sloping the slits can also serve to reduce friction between the shroud and the sand control element as the sand screen activates.

[0079] According to a further aspect of the invention, there is provided a method of controlling the activation of a sand screen having a shroud adjacent to a sand control element, the method comprising selecting the activation characteristics of the shroud, so that the shroud controls the radial force at which sand screen activation is initiated.

[0080] This aspect of the invention has particular utility in sand screens that use fluid pressure to activate the screens. When selecting shroud characteristics, an operator can select the pressure that initiates activation. Therefore, increases in pressure induced during other operations not intended to activate lower screen pressures will not induce premature screen activation.

[0081] The various aspects of the invention as described above may be combined with each other as appropriate. Likewise, the various features described with reference to a particular aspect may be combined, individually or collectively, with the other aspects as appropriate.

Brief description of the drawings

[0082] These and other aspects of the invention will now be described, by way of example, with reference to the accompanying drawings, in which:

[0083] Figure 1 is a schematic illustration of part of a completion including three sand screens in accordance with an embodiment of the present invention;

[0084] Figure 2 is a partial cutaway view of part of one of the screens of Figure 1;

[0085] Figure 3 corresponds to Figure 2, but shows the screen in an activated configuration;

[0086] Figures 4, 5, 6 and 7 are sectional views of a valve arrangement of one of the screens of Figure 1, showing the valve arrangement in the first, second, third and fourth configurations, respectively;

[0087] Figures 4a and 4b are views of an ICD insert assembly;

[0088] Figure 4c is a schematic view of a check valve;

[0089] Figures 8 and 9 are views of the ends of the activation chambers of one of the sand screens of Figure 1;

[0090] Figures 10 and 11 are views of the activation chambers and chamber blocks of one of the sand screens of Figure 1;

[0091] Figures 12a and 12b are views of the elements of a drainage layer of one of the sand screens of Figure 1;

[0092] Figure 13 is a sectional view of a clamp arrangement of one of the sand screens of Figure 1;

[0093] Figure 14 is a plan view of a sheet to be formed into a sand screen shroud;

[0094] Figure 15 is an enlarged view of a portion of the sheet of Figure 14;

[0095] Figures 16 and 17 are views of a sand screen in accordance with an additional embodiment of the present invention; and

[0096] Figures 18, 19, 20 and 21 are schematic sectional views of structures in accordance with the embodiments of the present invention.

Detailed description of drawings

[0097] Reference is first made to Figure 1 of the drawings, which is a schematic illustration of part of a wellbore completion including three sand screens 10 in accordance with an embodiment of the present invention. Clearly, the completion will include many other elements and devices not shown in the drawing, such as a shoe at the head end of the completion, zonal isolation wrappers, hangers, valves, and the like. Typically, a completion will incorporate more than three screens, the number of screens being selected as appropriate.

[0098] As will be described in greater detail below, the screens 10 are run through the hole in a retracted or smaller diameter configuration and subsequently activated to assume a larger diameter configuration, where the outer surface of the screens fits the orifice wall, if this is formed by case, liner, or an unlined hole section.

[0099] Figure 2 of the drawings illustrates a partial cross-sectional view of part of one of the screens in Figure 1, showing the screen 10 in an initial configuration. The screen 10 comprises a base tube 12 providing mounting for six activation chambers 14 which extend axially along the outer surface of the base tube 12. The chambers 14 are disposed side by side around the base tube 12 and, as will be described, can be inflated or deformed by filling chambers 14 with high pressure fluid so that chambers 14 assume an activated configuration as illustrated in Figure 3 of the drawings.

[00100] A drainage layer is located externally of the chambers 14, the layer comprising six strips 18 of open sheet steel. Like chambers 14, tapes 18 are arranged side by side and extend axially along web 10, but are circumferentially offset relative to chambers 14, as illustrated in the drawings, so that when chambers 14 are extended, the tapes 18 join the gaps 20 formed between the chambers 14. Additional detail related to the drainage layer will be provided below.

[00101] The drainage layer supports a filter medium in the form of a weave 22, the weave shape being selected so that the opening size of weave 22 does not vary as weave 22 is extended to accommodate deformation of the weave chambers. activation 14. The weave 22 may comprise a single length of material wrapped around the drainage layer with the longitudinal edges overlapping, or it may comprise two or more lengths or strands of material. A protective shroud 24 is provided over weave 22.

[00102] Reference is now also made to Figures 4, 5, 6 and 7 of the drawings, which are sectional views of a valve arrangement 30 of one of the screens 10 of Figure 1, showing the valve arrangement in the first, second , third and fourth configurations, respectively. In use, a valve arrangement 30 will be provided at the lower end of each screen 10 between the lower end of the activation chambers 14 and a stump apex connection 32 and a special connection (not shown) at the end of the screen 10. Will be noted that Figures 4, 5, 6 and 7 omit drainage layer 16, weave 22 and shroud 24.

[00103] The valve arrangement 30 comprises a body 34 comprising a number of interconnected cylindrical portions 34a, 34b which also form the lower end of the screen body. As will be described, the valve arrangement 30 also includes a number of generally cylindrical internal parts that are configurable to control the passage of fluid through the first and second ports 36, 38 in the body portion 34a. First ports 36 provide communication with activation chambers 14 via respective chamber blocks 40 which each incorporate a check valve 42 including a ball 44. The ball 44 can be formed of any suitable material, eg PTFE, ceramic , steel, rubber, brass or aluminum. Second ports 38 also extend through body portion 34a and, when open, allow production fluid to flow from the outside of screen 10 to base tube 12, and subsequently to the surface.

The second ports 38 may be sized or otherwise configured to provide a predetermined pressure drop in the production fluid flowing to the base tube. In this way, over the length of completion, the operator can configure the second ports to provide a desired flow profile considering local formation conditions. In one configuration, each second port 38 is provided with an inflow control device (ICD) assembly in the form of a disc 39 for location in port 38, the disc having a central flow port accommodating a suitably tungsten carbide insert. measured 41 as illustrated in Figures 4a and 4b of the drawings (the skilled person will note that the ports 38 as illustrated in the figures are non-circular and thus ICDs in the form of disks 39 are intended for use in combination with an alternative configuration depicting the second circular doors). Insert 41 is selected to provide the desired area of flow or pressure drop and is pressed into disc 39, which is then screwed into port 38 from the outside of body portion 34a, the outer face of the disc being provided with a screw thread configured to mate with a mating screw thread provided on port 38. Disc 39 is also provided with an O-ring seal. If appropriate, some ports 38 of a valve arrangement 30 can be fitted with a disc , including an empty insert, preventing flow through selected ports.

The valve arrangement 30 includes a primary valve sleeve 46. A central portion of the sleeve 46 defines production ports 48 which, when the valve arrangement 30 is in the third configuration, are aligned with the second ports 38. In the first configuration, as illustrated in Figure 4, the production ports 48 are offset from the second ports 38, and isolated from the outside of the valve sleeve 46 by seals 50, 51. An additional seal 52 also serves to insulate the second port 38. The lower portion of valve sleeve 46 defines an internal profile 55 for engaging an intervention tool, as will be described. The upper end of sleeve 46 includes collet fingers 49 which have outer profiles for engaging with locating recesses 45 formed in the inner diameter of body 34. Collet fingers 49 also define profiles 43 which allow mechanical engagement with an intervention tool, if required, as will be described.

[00106] A secondary valve or shuttle sleeve 47 is located externally of the primary valve sleeve 46 and carries the external seals 54 for isolation of the first port 36 when the valve arrangement is in the third and fourth configurations, as illustrated in Figures 6 and 7. Sleeves 46, 47 are initially secured together by shear pins 59. In the first and second configurations, shuttle sleeve 47 is located down and clear of first ports 36, and activation ports 56 on primary valve sleeve 46 , which may include a filter member 57, are aligned with the first ports 36, providing fluid communication between the interior of the screen 10 and the activation chambers 14.

[00107] A valve drive sleeve 58 is also located within the body 34 and depicts an external recess 60 that provides sealing contact with the body portion 34b. The shear pins 62 initially lock the sleeve 58 relative to the sleeve body against the action of a compression spring 63 contained in a chamber 67 between the sleeve 58 and the body portion 34b. While the upper face of recess 60 is exposed to internal or tube pressure, the lower face of recess 60 is exposed to external or ring pressure via a port 61 in the sleeve body, so that the recess 60 acts as a piston. differential.

[00108] To prevent accidental unlocking of sleeve 58 due to reverse differential pressure, for example an increase in ring pressure relative to internal pressure, check valves 65 (one shown) extend through recess 60, allowing the fluid bleeds from the chamber between the sleeve 58 and the body portion 34b and into the valve, thus releasing any excess reverse pressure. A schematic of a check valve 65 is shown in Figure 4c of the drawings. Correspondingly if, for example, during installation or recovery from completion, fluid is being circulated through completion and into the adjacent ring, there may be circumstances where ring pressure (P1) increases above internal pressure (P3) . In this situation, fluid from the ring can bleed through port 61 and into spring chamber 67, being subjected to a pressure drop at a lower pressure (P2) in the process. This reduces the pressure differential across the recess 60. However, if sufficient, the pressure differential remaining between the chamber 67 and the interior of the completion can then lift the check valve ball 69 from its seat 71, against the action. of a spring 73, allowing fluid to bleed from chamber 67 and on completion. In this way, an operator can employ the relatively high circulation rates, secure in the knowledge that higher ring pressure will not result in premature shearing of pins 62, and premature release of sleeves 58, 46, 47. The number and configuration of valves hold 65 may be selected as appropriate for the completion setting and anticipated operating conditions.

[00109] An upper end of sleeve 58 extends outwardly from the lower end of primary valve sleeve 46, and meets the lower end of shuttle sleeve 47.

[00110] As noted above, in the first configuration, enabling ports 56 are aligned with first ports 36, while second ports 38 are closed due to misalignment between ports 38 and production ports 48; screens 10 are drilled into the hole in this configuration. A positive pressure differential between the interior of the screens 10 and the chambers 14 will open the check valve 42 and allow fluid to flow from the interior of the completion into the activation chambers 14, via the chamber blocks 40. Thus, in use , when completion is pressurized to a first pressure, chambers 14 will be subjected to an initial degree of inflation or deformation with valve arrangement 30 in this first configuration. Tube pressure can be maintained at this first pressure for a period to provide an initial degree of inflation of the chambers 14. Clearly, rather than pressurizing the entire completion, an operator can run a flush tube or the like within the completion to communicate the pressure from surface to screens 10.

[00111] After a predetermined interval, the internal tube pressure can be increased to a second higher level to bring the differential pressure experienced through the recess 60 to a level sufficient to trim the pins 62, as illustrated in Figure 5. This pressure differential causes check valve balls 69 to seat, ensuring that check valves 65 remain closed. This results in a slight downward movement of sleeve 58, against spring action 63, until the lower end of sleeve 58 engages a stop 64. However, this movement is not transferred to primary valve sleeve 46, or shuttle sleeve 47 In this way, the first port 36 remains open while the second upper pressure fully inflates and activates the chambers 14.

[00112] After an additional predetermined interval, after which the operator can be confident that all screens 10 have been fully activated, pressure can be bled from completion, allowing spring 63 to move sleeve 58 upward relative to body 34 as illustrated in Figure 6. After an initial degree of movement, that movement of sleeve 58 is also converted to valve sleeves 46, 47 by moving sleeves 46, 47 upward to close first ports 36 and open the second ports 38, particularly aligning ports 38 with production ports 48 in sleeve 46. This requires collet fingers 49 to be displaced from lower recess 45a and moved to engage with upper recess 45b. Furthermore, the alignment of the ports 38, 48 is ensured by the provision of the timing pins 31, which prevent relative rotation of the body portion 34a and sleeves 46, 47.

[00113] In this third valve configuration, high pressure fluid is locked in the inflated chambers 14 by check valves 42 and shuttle sleeve 47, while production fluid can flow into the screen through inline ports 38, 48.

[00114] If any of the valve sleeves 46, 47 do not move to the third configuration when the pressure is bled, then the intervention tool can be employed to engage the collet profile 43 and mechanically shift the sleeves 46, 47 upward . Furthermore, if, at any point in the future, an operator wishes to shut down production from a particular screen 10, an intervening power tool can be run through the hole to engage the sleeve profile 55. The primary valve sleeve 46 can is thus pushed downwardly, displacing the tweezer fingers 49 from the upper recess 45b to the lower recess 45a, so that the ports 38, 48 are moved out of alignment, as illustrated in Figure 7 of the drawings. However, a split ring 66 located in a recess 68 in the body portion 34a fits with an outer recess 70 in the upper end of the drive sleeve 58 preventing downward movement of the sleeve 58 and also locking the shuttle sleeve 47 in position. door closing; if sufficient force is applied by the intervention tool, the connecting shear pins 59 between the sleeves 46, 47 will drop, allowing the relative movement of the sleeves 46, 47 so that the first port 36 remains isolated.

[00115] Reference is now made to figures 8, 9, 10 and 11 of the drawings, which illustrate the details of activation chambers 14 and chamber blocks 40. In particular, Figure 8 shows the lower end of an activation chamber 14 , while Figure 9 shows the upper end of an activation chamber 14. Activation chambers 14 are elongated and have a width W and depth D. In one configuration, the chambers 14 are formed by bending a long narrow sheet of metal into a series of steps to provide the desired profile, the joint edges then being joined by a suitable method, eg being laser or high frequency welded. However, both ends of the chambers are cut to provide a narrow tab or spigot 72. The cut metal edges defining the lower spigot 72a are welded to leave a hole for fluid passage while the top spigot 72b is welded closed. Thus, the hole 74 in the lower spike 72a is of a width w, less than the width of the chamber W. Likewise, the edges defining the transition from the full-width chamber to the spikes 72 have radius, particularly being formed with an outer radius 76 and an inner radius 78. On inflation or deformation of the chambers 14, the outer radius 76 reduces the stresses at the end of the chambers 14, reduces shrinkage in length during activation, reduces the potential to damage the weave 22, and smoothes the end profile of the deformed chamber 14. The inner radius 78 reduces stresses in the transition area during activation.

[00116] The open spigot 72a allows fluid communication between the activation chamber 14 and the interior of the completion, via the chamber block 40 which includes a hole 80 in an end face to receive the spigot 72a. Spike 72a and chamber block 40 are assembled while separate from the screen body, and the components are then bonded together around the full perimeter of hole 80 to provide pressure integrity, connection 82 being perhaps more clearly visible in the Figure 11 of the drawings. Connection 82 may be provided by any suitable method, typically welding, for example TIG, laser or robotic welding.

[00117] Within the chamber block 40 is a drilled hole 84 (Figure 7) that extends to intercept a radial recess 85 that accommodates the check valve 42.

[00118] The closed post 72b is constrained by an alternative clamp body (not shown). The upper end of the chambers 14 can be secured to the respective upper clamp body or be mounted to allow a degree of axial movement, for example, to allow axial shrinkage of the chamber 14 upon inflation. In other embodiments, spike 72b may be provided with a relief valve to protect against over-pressurization of chambers 14, or may provide fluid communication with other activation chambers in the same or adjacent assembly.

[00119] The chamber blocks 40 are held in place on the screen body 34a by clamps 88 (Figure 7) which are bolted to the body 34a and engage with the recesses 90 formed in the edges of the blocks 40.

[00120] As noted above, drainage tapes 18 are mounted externally from mounted chambers 14, and portions of a drainage layer tape 18 are illustrated in Figure 12a and 12b of the drawings. In use, the drainage layer formed by the tapes 18 lifts the weave 22 from the activation chambers 14, maximizing inflow through and around the fabric. Tapes 18 are solid steel plate provided with perforations 92 that allow oil or gas to flow through weave 22 and fabric 10. The tapes are produced by punching and stamping the flat plate to provide the required pattern, before the roll form on the required radius and then cut it to length. The perforations 92 can be any suitable shape or size, and in the configuration illustrated, each strip 18 includes four axial rows of round holes. As noted above, the tapes 18 are also stamped to form protrusions on the inner surface of the tapes 18 to lift the drainage layer from the activation chambers 14 to allow flow under the layer and between the activation chambers 14 and tapes. 18. Again, the stamps 94 can be of any suitable shape, size or depth and, in the configuration illustrated, the stamps 94 are formed as four axial rows, axially and circumferentially offset from the perforations 92. The tapes 18 are formed with an inner radius to match the outer radius of the activation chambers 14 to ensure that the outer diameter of the screen 10 is minimized and that the drainage layer formed by the tapes 18 provides optimal support across the activation chambers 14.

[00121] The ends of the tapes 18 are tapered and are fixed to the screen 10 by welding to the recesses 91 (Figure 7) provided in the chamber block clamps 88. The tape ends are also notched to facilitate deformation; tape ends should bend and extend to accommodate activation of chambers 14.

[00122] After the activation and deformation of the chambers 14, the drainage layer tapes 18 provide support to the weave 22 as the gaps 20 (Figure 3) between the activation chambers 14 increase. Likewise, 18 spoke tapes help maintain a substantially circular shape during the activation process. In the absence of such support, the screen would assume a hexagonal shape due to the weave 22 and the outer shroud 24 forming the straight lines between each outer diameter of the activation chamber.

[00123] Reference is now also made to Figure 13 of the drawings, which illustrates a clamp arrangement for use in securing the weave 22 in place on fabric 10. The Figure shows the body portion 34a serving as a clamp body and a retainer ring 96 that can be threaded to the body 34a. Clamp body 34a defines a recess 100 above thread 97, and a tapered surface 98 leading downward into recess 100. Ring 96 includes a corresponding tapered surface 102 at its upper end, so that when ring 96 is clamped onto body 34a, surfaces 98, 102 mate and secure a portion of weave 22 therebetween.

[00124] During the manufacturing process, weave 22 is wrapped around the fabric body, over the drainage layer formed by tapes 18, with the upper and lower ends of weave 22 positioned in recesses 100 (a similar fastening arrangement is provided at the top edge of the screen).

[00125] Weave 22 can be held in place using ratchet handles, spot welding or the like and, if desired, weave 22 can be spot welded into recess 100. Spot welds can also be provided along the length of the fabric 10, to secure the weave 22 to the ribbons 18. The clamp ring 96 is then screwed onto the clamp body 34a and the cone surfaces 98, 102 to secure and secure the weave 22. The shroud 24 is then located over the tight weave 22.

[00126] Reference is now made to Figures 14 and 15 of the drawings, which illustrate the details of the open sheet or plate 23 used to form the wrapping 24. Conventional wrappings are formed with overlapping slits elongated longitudinally, and by expanding the web. of sand, the cracks open to accommodate the increase in circumference described by the shroud; the shroud is intended to provide a degree of protection for the weave, however it is intended to be readily extensible so that expansion of the weave is not restricted. Screen 10 can be provided with such a conventional shroud. However, the shroud 24 of the illustrated configuration of the present invention depicts the 30mm long slits 25 which are slanted 15 degrees along the length of the plate. This results in a shroud 24 that will require higher pressure to expand, thus providing greater control of the activation pressure required to initiate fabric 10 expansion. The angled slots 25 also result in less friction between the outer surface of the weave 22 and the inner surface of the fabric. shroud 24 as slots 25 open and weave 22 slides under shroud 24.

[00127] For most applications, it is contemplated that shroud 24 will form the outer surface of the screen. However, in some embodiments, a portion of the fabric may be covered with an elastomer, as illustrated in Figures 16 and 17 of the drawings. In this configuration, a neoprene elastomer coating 104 was wrapped around a portion of the outer diameter of the fabric. Such a screen has been activated, the rubber liner 104 will be pushed against the adjacent casing or formation and will provide a restriction or deflector to the flow of production fluids between the zones; liner 104 may provide a low pressure seal or restriction of fluid flow past the screen, but may allow fluid to flow below liner 104 and into or along the screen. Clearly in other embodiments, different grades of material can be used to provide a superior pressure seal.

[00128] Reference is now made to Figures 18, 19, 20 and 21 of the drawings which are schematic sectional views of structures in accordance with several additional embodiments of the present invention. In the screens described above, and as illustrated in Figure 18, the activation chambers 14 are arranged around a circular base tube 12. The test demonstrated that the provision of the inflated activation chambers 14 in the outer diameter of the contained base tube 12 inside a hole creates a structure with significantly improved crush resistance when compared to a structure consisting essentially of a 12 base tube alone. This is believed to be due, at least partially, to the dampening effect of the activation chambers 14, compression of an inflated activation chamber 14 by an externally applied mechanical load leading to an increase in internal fluid pressure which results in the load being spread along the length of chamber 14 and radially around the screen. Likewise, when such a structure is subjected to a high load on one side of the structure, the pressure increases in the chambers on the other side of the structure: for example, if a high load is applied in the region of chamber 14(6), a pressure high is measured in the opposite chamber 14(3) and, to a lesser extent, in the adjacent chambers 14(4) and 14(2). The test further demonstrated that the chambers 14 tend to absorb at least the initial deformation of the structure, so that the inner diameter of the base tube 12 remains substantially unobstructed. Likewise, the deformed chambers 14 tend to recover, typically around 50%, when the applied force is reduced.

[00129] The test also identified that the sand integrity of the sand screens incorporating the inflated chambers 14 as described herein, when subjected to crushing or squeezing loads, the loads were kept at very high loading, as was the integrity of the chambers 14 In one test, the pressure in chambers 14 increased from 6.90 MPa (1000 psi) initial to almost 8.27 MPa (1200 psi), corresponding to a 2.54 cm (1 inch) strain of a sand screen with an activated outside diameter of 21.59 cm (8/inch). Thus, a sand screen conforming to an embodiment of the present invention will withstand significant crush loading, for example, from a swelling or partially collapse formation, and will accommodate a degree of deformation without adversely affecting the base tube 12. Clearly, this effect is not limited to sand screen, and inflatable chambers can be mounted in an impermeable section of an intended completion to cross a non-production problem section. Correspondingly, an operator may be able to use significantly lighter and less expensive base tube 12, and may be able to drill and then hold holes through difficult formations, for example swelling formations that would otherwise be expected to crush the orifice lining pipe located in the orifices.

[00130] Figures 19, 20 and 21 illustrate that this principle can be employed to increase the collapse and crush strength of other tubular shapes, such as rectangular and triangular base tubes 106, 108 of Figures 19 and 20, and also to provide protection against internal loads as illustrated in Figure 21.

[00131] It will be apparent to those skilled in the art that the above described embodiments are merely exemplary of the present invention, and that various modifications and improvements can be made to these embodiments without departing from the scope of the invention.

Claims (19)

1. Method for restricting flow between zones in a well, the method characterized in that it comprises: - providing a layer of the deformable material (104) in a sand screen (10); - activating the sand screen using sand chambers deformable fluid (14) mounted in a base tube (12) so that the chambers increase the diameter of the sand screen (10), and the layer of deformable material (104) deforms to contact and seal against the well wall ; and - providing a plurality of support layer members (18), each support layer member disposed to provide a bridge between adjacent deformable fluid chambers (14). 2. Method according to claim 1, characterized in that it comprises at least one of:- providing the deformable material (104) on a portion of the sand screen (10) to provide a seal to restrict the flow of past liquid on the screen; - supplying the deformable material (104) at at least one end of the sand screen (10); and - supplying the deformable material (104) circumferentially around the sand screen and axially along the sand screen (10). 3. Method according to claims 1 or 2, characterized in that it comprises wrapping the deformable material (104) around a portion of a diameter on the outside of the sand screen (10). 4. Method according to claim 3, characterized in that the deformable material is an elastomer. 5. Method according to any one of claims 1 to 4, characterized in that the deformable material (104) is a swellable material, and the swellable material is activated upon exposure to oil or water. 6. Method according to any one of claims 1 to 5, characterized in that it comprises activating the deformable chambers (14) by passing fluid inside the deformable chambers, the activated chambers providing support for at least one sand screen ( 10). 7. Method according to claim 1, characterized in that the deformable material (104) is arranged in the sand screen (10) so that, in use, the fluid passes under the material, and the fluid passes through or below the sand screen (10). 8. Method according to claim 1, characterized in that the production fluid is allowed to flow from an outer portion of the screen (10), into the base tube (12), and subsequently to the surface. 9. Mechanism for restricting flow between zones in a well, the mechanism being characterized in that it comprises:- deformable fluid chambers (14) mounted on a tube base (12); - a sand screen (10) provided by the chambers; - a layer of deformable material (104) provided in the sand screen (10), whereby after activation, the chambers (14) increase the diameter of the sand screen (10 ), and the layer of deformable material (104) is deformed by the sand screen (10) to contact and seal against the wall of the well; and - a plurality of support layer members (18), each support layer member (18) arranged to provide a bridge between adjacent deformable fluid chambers (14). 10. Mechanism according to claim 9, characterized in that at least one of the support layer members (18) comprises a plate of material, the plate is perforated and formed to provide a fluid path. 11. Mechanism according to claims 9 or 10, characterized in that the deformable material (104) is provided to a part of the sand screen (10) to provide a seal, and in use, the flow is prevented of fluid pass the screen. 12. Mechanism according to claim 11, characterized in that the deformable material (104) is provided in at least one end of the sand screen (10). 13. Mechanism according to claim 12, characterized in that the deformable material (104) is provided circumferentially around the sand screen and axially along the sand screen (10). 14. Mechanism according to any one of claims 9 to 13, characterized in that the deformable material (104) is an elastomer. 15. Mechanism according to any one of claims 9 to 14, characterized in that the deformable material (104) is wrapped around a portion of an outer diameter of the sand screen (10). 16. Mechanism according to any one of claims 9 to 15, characterized in that the deformable material (104) is a swellable material, and the swellable material activates upon exposure to oil or water. 17. Mechanism according to any one of claims 9 to 16, characterized in that the deformable chambers (14) are adapted to be activated by the passage of fluid within the deformable chambers (14), and in use, the activated chambers provide support for at least one sand screen (10). 18. Mechanism according to claim 9 or 10, characterized in that the deformable material (104) is arranged in the sand screen (10) so that, in use, the fluid passes under the material, and where the fluid passes through or below the sand screen (10). 19. Mechanism according to claim 9 or 10, characterized in that the production fluid is allowed to flow from an outer portion of the screen (10), into the base tube (12), and subsequently to the surface.

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