NO312734B1 - Sleeve valve and method for establishing adjustable fluid flow - Google Patents

Description

The invention relates to a sleeve valve for regulating fluid flow between a hydrocarbon reservoir and a production pipe in a well in the hydrocarbon reservoir, where the sleeve valve comprises an outer sleeve and an inner sleeve, each of which has at least one opening, where the inner sleeve is movable by means of an actuator or a tool between an open position where the opening of the inner sleeve corresponds to the opening of the outer sleeve, and a closed position where the opening of the inner sleeve does not correspond to the opening of the outer sleeve, and possibly intermediate positions.

The invention also relates to a method for establishing adjustable fluid flow between a hydrocarbon reservoir and a production pipe in a well in the hydrocarbon reservoir, using a sleeve valve.

When extracting hydrocarbons from hydrocarbon reservoirs, wells are drilled from the seabed or the surface of the earth down to and into the reservoir, which is under pressure. The part of the well that extends from the seabed or the surface of the earth to the reservoir is lined with casing to prevent the well collapsing. Inside the casing is placed a production pipe, which extends from the seabed or the surface of the earth, past the end of the casing and into the reservoir.

In order to be able to regulate the inflow of fluids from the reservoir, it is desirable to be able to close and open the inflow to the production pipe at different places along the part of the production pipe which is located in the reservoir.

In order to regulate the flow to or from a production pipe, sleeve valves can be used, which comprise an outer sleeve and an inner sleeve, both of which are provided with openings. The outer sleeve is fixed and can form a part of the production pipe, while the inner sleeve is movable to bring the openings in the two sleeves in and out of correspondence, to open or shut off flow through the sleeve valve.

The production pipe can extend through different production zones, and can have one or more sleeve valves in each production zone. The production zones can have different pressures, and to prevent hydrocarbons from flowing between the production zones on the outside of the pipe, the space between the production pipe and the well wall can be closed off with insulating gaskets or filled with concrete, which is usually called cementing. The concrete can be filled through a valve in the production pipe, and then flows up the outside of the production pipe. In addition to the concrete preventing the flow of hydrocarbons between the production zones, the concrete also prevents the flow of hydrocarbons from the reservoir to the production pipe, and the concrete must therefore be perforated in the areas where inflow to the production pipe is desired. This perforation can be done with a perforating gun, which shoots projectiles into the concrete. However, a perforating cannon cannot easily be combined with a sleeve valve, as the projectiles will destroy the sleeve valve.

In order to maintain the pressure in the reservoir, water or gas injection is used in some places, that is, pressurized water or gas is pressed into the reservoir from the well, and it may then be desirable to regulate the outflow from the well along the production pipe. Sleeve valves can also be used for this purpose, but the use of sleeve valves will also in this case be associated with the above-mentioned issue regarding cementing the well.

GB 2 201 979, US 4 782 896 and US 4 921 044 describe sleeve valves for regulating fluid flow between a hydrocarbon reservoir and a well in the hydrocarbon reservoir, comprising a fixed outer sleeve and an inner sleeve which is movable between positions where openings in the outer sleeve and inner sleeve correspond or not corresponds.

The problem of being able to establish a fluid flow between a hydrocarbon reservoir and a production pipe in the reservoir, where the space between the production pipe and the well wall is filled with concrete, is discussed in US 5,425,424. Here, a device is described which comprises a sliding sleeve valve, where the valves comprise radially movable pistons that can be used to crack the concrete. The pistons simultaneously push out grease, which pushes away concrete and also acts as an anti-hardening agent for the concrete.

US 5 533 570 describes an apparatus for downhole injection and mixing of fluids in a concrete slurry. The fluid is stored in a chamber, and can be injected into external, unhardened concrete via electromagnetic valves.

The purpose of the invention is to produce a solution to the above-mentioned problem associated with the use of sleeve valves in a production pipe where the space between the production pipe and the well wall is filled with concrete. The purpose of the invention is further to provide a method for establishing adjustable fluid flow between a hydrocarbon reservoir and a production pipe in a well in the hydrocarbon reservoir, using a sleeve valve, where the space between the production pipe and the well wall is filled with concrete.

The purposes are achieved according to the invention with a sleeve valve and a method of the type mentioned at the outset which is characterized by the features specified in the claims.

The invention thus relates to a sleeve valve for regulating fluid flow between a hydrocarbon reservoir and a production pipe in a well in the hydrocarbon reservoir, where the sleeve valve comprises an outer sleeve and an inner sleeve each of which has at least one opening, where the inner sleeve is movable by means of an actuator or a tool between a open position where the opening of the inner sleeve corresponds to the opening of the outer sleeve, and a closed position where the opening of the inner sleeve does not correspond to the opening of the outer sleeve, and possibly intermediate positions. The sleeve valve comprises at least one chamber for concrete hardening agent, and at least one passage from the chamber for concrete hardening agent to at least one injection outlet on the outside of the inner sleeve, the injection outlet corresponding to the opening of the outer sleeve when the inner sleeve is moved to an injection position. The sleeve valve further comprises at least one actuator for extruding concrete hardening agent from the chamber, through the passage, the injection outlet and the opening of the outer sleeve, for injecting concrete hardening agent into unhardened concrete outside the outer sleeve.

The injection of the concrete hardening inhibitor into the unhardened concrete will take place during cementing of the space between the production pipe and the well wall. An area is thus established outside the opening of the outer sleeve where the concrete does not harden or only hardens to a limited extent, and fluids are thus allowed to flow between the reservoir and the sleeve valve, i.e. the openings of the outer sleeve.

The invention also relates to a method for establishing adjustable fluid flow between a hydrocarbon reservoir and a production pipe in a well in the hydrocarbon reservoir, using a sleeve valve according to the invention. According to the method according to the invention, the following steps are carried out: the sleeve valve is integrated into a production pipe, and the production pipe is placed in the well in the hydrocarbon reservoir, in a manner known in and of itself, the sleeve valve's chamber for concrete hardening agent is filled with concrete hardening agent, and the inner sleeve is in an injection position,

the space between the production pipe with the sleeve valve and the wall of the well is filled with liquid, unhardened concrete,

the actuator for extruding concrete curing agent from the chamber is activated, so that the concrete curing agent is injected into the concrete and forms open areas that allow fluid flow between the reservoir and the opening of the outer sleeve,

the inner sleeve is moved to the open position, to establish initial fluid flow between the reservoir and the opening of the outer sleeve, after which the inner sleeve can be moved to the desired position, to establish the desired fluid flow.

During the initial fluid flow, uncured concrete that has been affected by the concrete hardening inhibitor is flushed out of the area outside the opening of the outer sleeve, into through the opening of the outer sleeve and out of the well. By subsequent regulation of the sleeve valve, the inner sleeve can be brought to a position where the opening of the inner sleeve fully or partially corresponds to the opening of the outer sleeve, for regulation of the fluid flow to the desired value.

The outer sleeve and the inner sleeve can have one or more openings which correspond to corresponding openings in the inner sleeve and the outer sleeve respectively. The sleeves' openings can be arranged in rows along the sleeves, and can be arranged symmetrically around the sleeves. The inner sleeve can be movable in that it can be rotated about the longitudinal direction of the production pipe, the inner sleeve can be slidable in the longitudinal direction of the production pipe, or the inner sleeve can be movable along a helical line in the longitudinal direction of the production pipe. The inner sleeve can be moved using a remote-controlled tool that is driven by an electric or hydraulic motor, for example via coiled tubing or electric cables, or the inner sleeve can be moved via a drill string. In both cases, the movement can be transferred to the inner sleeve via a gripping tool with clamping jaws that are activated electrically or hydraulically. The mobility of the inner sleeve can also be realized with devices that are integrated into the sleeve valve, for example hydraulic cylinders. In addition to the fact that the inner sleeve can be movable between positions where the two sleeve openings correspond or do not correspond, the inner sleeve can also be movable to intermediate positions, so that the fluid flow can be set to intermediate positions between closed and fully open flow.

The invention will now be explained in more detail in connection with descriptions of specific embodiments, and with reference to the drawings, where:

fig. 1 shows a sleeve valve according to the invention in a hydrocarbon reservoir,

fig. 2 shows the sleeve valve in fig. 1 with part of the inner sleeve and the outer sleeve

cut away,

fig. 3 shows an enlarged section of fig. 2,

fig. 4 shows a cross-section through the sleeve valve, laid along the section line IV-IV in fig.

1, where the inner sleeve is in the injection position,

fig. 5 shows a cross-section through the sleeve valve, laid along the section line IV-IV in fig.

1, where the inner sleeve is in the open position, and

fig. 6 shows a cross-section through the sleeve valve, laid along the section line IV-IV in fig.

1, where the inner sleeve is in the closed position.

Fig. 1 shows a sleeve valve 1 according to the invention in a well 4 in a hydrocarbon reservoir 2. The sleeve valve 1 comprises an outer sleeve 5 with openings 7. The outer sleeve 5 has at each end a threaded portion 27 which is screwed into the ends of two sections of a production pipe 3 , one of which is shown in section. The sleeve valve 1 is

thus integrated into the production pipe 3. The production pipe 3 with the sleeve valve 1 has been led through an unshown casing in the well 4, through an unshown gasket at the end of the casing, and into the reservoir 2. During the production of hydrocarbons, the hydrocarbons will flow from the reservoir 2 and into the outer sleeve openings 7. In order to prevent hydrocarbons from flowing along the outside of the sleeve valve 1 and the production pipe 3, the space between the sleeve valve 1 and the well wall 21 has been filled

with concrete 11, which has been pumped down through the production pipe 3 and pushed up on the outside of the production pipe 3 and sleeve valve 1.

A centralizing unit 28, which is part of the sleeve valve 1, ensures that on all sides of the sleeve valve there is a certain distance to the well wall 21, so that the concrete 11 fills the space between the sleeve valve 1 and the well wall 21 completely. In addition to the fact that the concrete 11 prevents the flow of hydrocarbons along the sleeve valve, the concrete also prevents the inflow of hydrocarbons to the sleeve valve. In the following, it will be explained how, with the help of the sleeve valve 1 according to the invention, an open area is established between the outer sleeve openings 7 and the well wall 21, so that hydrocarbons can flow into the sleeve valve 1 from the reservoir 2.

Fig. 2 shows the sleeve valve 1 in fig. 1 with part of the outer sleeve 5 cut away, while fig. 3 shows an enlarged section of fig. 2. An inner sleeve 6 is seen, which is also shown partially cut away, and which is provided with openings 8. It can be seen that the inner sleeve 6 is much shorter than the outer sleeve 5, and extends approximately from the centralization unit 28 on one side of the outer sleeve's openings 7 , past the outer sleeve's openings 7, to approximately midway between the outer sleeve's openings 7 and where the outer sleeve 5 is provided with chambers 9, which will be discussed in more detail later.

The sleeve valve shown is a rotary sleeve valve, where the inner sleeve 6 can be rotated by means of an actuator or a tool between an open position where the inner sleeve openings 8 correspond to the outer sleeve openings 7, and fluids can flow between the outside of the outer sleeve 5 and the inside of the inner sleeve 6, and a closed position where the inner sleeve's openings 8 do not correspond with the outer sleeve's openings 7, and fluid flow is prevented. The inner sleeve 6 will also optionally be able to be turned to intermediate positions, where the fluid flow assumes a value between full inflow and no inflow. The inside of the inner sleeve 6 is in communication with the production pipe 3, and the sleeve valve can thus be used to regulate fluid flow between the hydrocarbon reservoir 2 and the production pipe 3. The rotation of the inner sleeve can be performed with an electric or hydraulic actuator or by turning with a tool, for example using of a drill string, which by means of gripping devices grips the inner sleeve and turns it.

The sleeve valve according to the invention comprises at least one chamber 9 for concrete hardening agent, and at least one passage from the chamber 9 for concrete hardening agent to at least one injection outlet 10 on the outside of the inner sleeve 6. The injection outlet 10 corresponds to the opening 7 of the outer sleeve when the inner sleeve 6 has been moved to a specific position, referred to as the injection position. In the embodiment shown, several injection outlets 10 are used, each corresponding to an opening 7 in the outer sleeve 5.

The at least one chamber 9 for concrete hardening inhibitor is realized by several elongated chambers 9 for concrete hardening inhibitor, of which only two chambers 9 are seen in figures 2 and 3, are arranged in the outer sleeve 5. The chambers 9 extend in the longitudinal direction of the sleeve valve 1, and are arranged at side of each other in the 5 circumference of the outer sleeve.

The at least one passage from the chamber 9 for concrete hardening inhibitor to the injection outlet 10 is realized by channels 12, 12' in the outer sleeve 5 and channels 14 in the inner sleeve 6. The outer sleeve's channels 12, 12' have an outlet 13 on the inside of the outer sleeve 5, while the inner sleeve's channels 14 have inlet 15 on the outside of the inner sleeve 6. The outlets 13 from the outer sleeve's channels 12, 12' and the inlets 15 to the inner sleeve's channels 14 are positioned so that they correspond when the inner sleeve 6 is in the injection position. O-rings 29 prevent leakage from the outlets 13 from the outer sleeve's channels and the inlets 15 to the inner sleeve's channels.

The sleeve valve 1 further comprises at least one actuator for extruding concrete hardening agent from the chambers 9, through the channels 12, 12', 14, the injection outlets 10 and the outer sleeve openings 7, for injecting concrete hardening agent into unhardened concrete 11 outside the outer sleeve 5. In the embodiment shown, the actuator realized in that each chamber 9 is provided with a piston 16, which is permanently connected to a common actuator for simultaneous extrusion of concrete hardening inhibitor from all chambers 9. The common actuator consists of a ring piston 17 which is movable in a ring cylinder 18, and which are connected via piston rods 31 to the pistons 16. O-rings 30 prevent leakage past the ring piston

17 in the ring cylinder 18.

The ring cylinder 18 is provided with an inlet 19 which is open to the inside of the sleeve valve, that is the inside of the outer sleeve 5, for pressurizing the ring cylinder 18 with a pressure on the inside of the sleeve valve. The inlet 19 could instead have been open to the outside of the sleeve valve, that is, the outside of the outer sleeve, for pressurizing the ring cylinder with a pressure on the outside of the sleeve valve. The ring piston 17 is held in a retracted position in the ring cylinder 18 by a shear pin 20, which is adapted to break and release the ring piston 17 at a predetermined pressure in the ring cylinder 18.

The concrete hardening inhibitor must be injected into the concrete after the concrete has settled during cementing, but before the concrete hardens. The concrete hardening inhibitor can for example be a hydrocarbon, but other concrete hardening inhibitors can also be used. Before injecting the concrete hardening inhibitor, it is ensured that the inner sleeve 6 is turned to the injection position. The injection of concrete hardening inhibitor into the concrete 11 is carried out by pressurizing the inside or outside of the sleeve valve, which can be controlled from the surface, either by means of a coiled pipe or by pressurizing the well. The pressure propagates through the inlet 19 to the ring cylinder 18, and when the pressure exceeds the pressure necessary to break the shear pin 20, it breaks, and the ring piston 17 moves into the ring cylinder 18. The movement of the ring piston propagates via the piston rods 31 to the pistons 16, which pushes concrete hardening inhibitor out of the chambers 9, through the channels 12, 12' and 14 and out into the injection outlets 10 which are located in the openings 7 of the outer sleeve.

The chambers 9 for concrete hardening agent and the injection outlets 10 are preferably connected via the channels 12, 12', 14 in a one to one configuration. It is thus ensured that the same amount of concrete hardening inhibitor, i.e. the contents of one chamber 9, is injected into the concrete from each injection outlet 10.

The ring cylinder 18 is made up of a cylindrical cavity which runs around the circumference of the outer sleeve 5, while the chambers 9 are made up of cylindrical bores that are drilled in the longitudinal direction of the outer sleeve and extend from the bottom of the ring cylinder 18 and further into the outer sleeve. The outer sleeve's channels 12 are made up of holes drilled in extension of the chambers 9, while radially drilled holes form the transverse channels 12' that lead from the channels 12 to the outlets 13. The inner sleeve's channels 14 are made up of holes drilled in the lengthwise direction of the inner sleeve 6, while radially drilled holes forms the inlets 15 and the injection outlets 10.

Fig. 4 shows a cross-section through the sleeve valve 1, laid along the section line IV-IV in fig. 1. The openings 7 of the outer sleeve 5 are provided with sealing elements 26 with through openings 24 for the fluid flow. The sealing elements have greasing surfaces 25 that rest against the outside of the inner sleeve 6. It can be seen that the inner sleeve's channels 14 open into the injection outlets 10. The inner sleeve 6 is in the injection position, and the injection outlets 10 correspond to the outer sleeve's openings 7, or actually the sealing elements' openings 24. When injecting concrete curing agent in the concrete 11, as mentioned above, streams 33 of concrete curing agent flow out through the injection outlets 10, out through the openings 7 of the outer sleeves (actually the openings 24 of the sealing elements) and into the concrete 11. Here the concrete hardening agent is mixed with the concrete 11 in areas 22 between the outer sleeves' openings 7 and the well wall 21. After a while, the concrete hardens around the areas 22, while the concrete in the areas 22 remains unhardened.

After the concrete around the areas 22 has hardened, the inner sleeve 6 is turned in the direction 23, until the inner sleeve reaches the open position, which is shown in fig. 5. The openings 8 of the inner sleeve here correspond with the openings 7 of the outer sleeves (actually the openings 24 of the sealing elements). The pressure in the sleeve valve is then lowered, which is done by opening a valve that releases fluids from the well at the surface. The reservoir is pressurized, and a fluid flow 34 of hydrocarbons occurs from the reservoir 2 to the outer sleeve openings 7, through the sealing element openings 24, through the inner sleeve openings 8, into the interior of the inner sleeve 6, and into the production pipe 3. The fluid flow 34 washes it away unhardened concrete from areas 22, and the sleeve valve is now fully installed.

The inner sleeve 6 can now be turned to the desired position, for example the closed position, which is shown in fig. 6, where the inner sleeve's openings 8 and the outer sleeve's openings 7 (actually the sealing elements' openings 24) do not correspond, or an intermediate position between the open and closed position, as previously mentioned.

Injection position of the sleeve valve, see fig. 4, may possibly coincide with the closed position of the sleeve valve, see fig. 6. The injection outlets 10 can then be placed in the middle between the inner sleeve openings 8. The inner sleeve and the outer sleeve can also be provided with corresponding stops not shown, positioned so that the open position is at one end of a turning area for the inner sleeve 6, while the combined injection position and .closed position is at the other end of the turning range. Simple operation of the inner sleeve is thus achieved.

In the method for establishing adjustable fluid flow 34 between a hydrocarbon reservoir 2 and a production pipe 3 in a well 4 in the hydrocarbon reservoir 2, according to the invention, a sleeve valve 1 according to the invention is used. The procedure includes the following steps: a) the sleeve valve 1 is integrated into a production pipe 3, and the production pipe is placed in the well 4 in the hydrocarbon reservoir 2, in a manner known per se, with the sleeve valve's chamber 9 for concrete hardening agent being filled with concrete hardening agent, and the inner sleeve 6 being located himself in an injection position, see fig. 4, b) the space between the production pipe 3 with the sleeve valve 1 and the wall 21 of the well is filled with liquid, unhardened concrete 11, c) the actuator 17 for squeezing out the concrete hardening inhibitor from the chamber

9 is activated, so that the concrete hardening inhibitor is injected into the concrete 11 and

form open areas 22 that allow fluid flow 34 between the reservoir 2 and the opening 7 of the outer sleeve, and

d) the inner sleeve 6 is moved to the open position, see fig. 5, for the establishment of initial fluid flow 34 between the reservoir 2 and the opening 7 of the outer sleeve, after which the inner sleeve

6 can be moved to the desired position, to establish the desired fluid flow 34.

For a more detailed explanation of the various steps included in the method according to the invention, reference is made to the above description of the sleeve valve according to the invention.

Claims (10)

1. Sleeve valve (1) for regulating fluid flow (34) between a hydrocarbon reservoir (2) and a production pipe (3) in a well (4) in the hydrocarbon reservoir (2), where the sleeve valve (1) comprises an outer sleeve (5) and a inner sleeve (6) each of which has at least one opening (7, 8), where the inner sleeve (6) is movable by means of an actuator or a tool between an open position (fig. 5) where the inner sleeve's opening (8) corresponds to the outer sleeve's opening (7), and a closed position (fig. 6) where the inner sleeve opening (8) does not correspond to the outer sleeve opening (7), and possibly intermediate positions, characterized in that it includes at least one chamber (9) for concrete curing agent, at least one passage from the chamber (9) for concrete curing agent to at least one injection outlet (10) on the outside of the inner sleeve (6), the injection outlet (10) corresponding to the opening (7) of the outer sleeve when the inner sleeve (6) is moved to an injection position (fig. 4), at least one actuator for extruding concrete hardening agent from the chamber (9), through the passage, the injection outlet (10) and the opening of the outer sleeve (7), for injecting concrete hardening agent into unhardened concrete (11) outside the outer sleeve (5). 2. Sleeve valve according to claim 1, characterized in that the chamber (9) for concrete hardening agent is arranged in the outer sleeve (5), that the passage from the chamber (9) for concrete hardening agent to the injection outlet (10) consists of at least one channel (12, 12') in the outer sleeve (5) with a outlet (13) on the inside of the outer sleeve, and at least one channel (14) in the inner sleeve (6) with an inlet (15) on the outside of the inner sleeve, and that the outlet (13) from the outer sleeve's channel and the inlet (15) to the inner sleeve's channel correspond when the inner sleeve (6) is in the injection position (fig. 4). 3. Sleeve valve according to claim 1 or 2, characterized in that the at least one chamber (9) for concrete curing agent consists of several elongated chambers (9) which extend in the longitudinal direction of the sleeve valve, and that each chamber (9) is provided with a piston (16) for squeezing concrete hardening agent through the passage (12 , 12', 14). 4. Sleeve valve according to claim 3, characterized in that the pistons (16) are firmly connected to a common actuator for simultaneous extrusion of concrete hardening inhibitor from the chambers (9). 5. Sleeve valve according to claim 4, characterized in that the actuator consists of a ring piston (17) which is movable in a ring cylinder (18). 6. Sleeve valve according to claim 5, characterized in that the ring cylinder (18) is provided with an inlet (19) which is open to the inside or outside of the sleeve valve, for pressurizing the ring cylinder (18) with a pressure on the inside or outside of the sleeve valve. 7. Sleeve valve according to claim 5 or 6, characterized in that the ring piston (17) is held in a retracted position in the ring cylinder (18) by a shear pin (20), and that the shear pin is adapted to break and release the ring piston (17) at a predetermined pressure in the ring cylinder (18). 8. Sleeve valve according to one of the preceding claims, characterized in that chambers (9) for concrete curing agent and injection outlet (10) are connected via the passages (12, 12', 14) in a one-to-one configuration. 9. Sleeve valve according to one of the preceding claims, characterized in that the sleeve valve's injection position (fig. 4) coincides with the sleeve valve's closed position (fig. 6). 10. Method for establishing adjustable fluid flow (34) between a hydrocarbon reservoir (2) and a production pipe (3) in a well (4) in the hydrocarbon reservoir (2), using a sleeve valve (1) according to one of the preceding claims, characterized by the following steps: a) the sleeve valve (1) is integrated into a production pipe (3), and the production pipe is placed in the well (4) in the hydrocarbon reservoir (2), in a manner known in and of itself, the sleeve valve's chamber (9) for concrete curing agent being filled with concrete hardening inhibitor, and the inner sleeve (6) is in an injection position (fig. 4), b) the space between the production pipe (3) with the sleeve valve (1) and the wall of the well (21) is filled with liquid, unhardened concrete (11), c) the actuator (17) for extruding concrete hardening agent from the chamber (9) is activated, so that the concrete hardening agent is injected into the concrete (11) and forms open areas (22) that allow fluid flow (34) between the reservoir (2) and the opening of the outer sleeve (7), d) the inner sleeve (6) is moved to the open position (fig. 5), to establish an initial fluid flow (34) between the reservoir (2) and the outer sleeve opening (7), after which the inner sleeve (6) can be moved to the desired position , for establishing the desired fluid flow (34).