The present invention relates to a downhole completion system for isolating several zones in a well having a top. The invention also relates to a downhole completion method for completing a downhole completion system.
Annular barriers are used downhole to provide isolation of one zone from another in an annulus in a borehole of a well between a well tubular metal structure and the borehole wall or another well tubular metal structure. When expanding annular barriers, it is important that the annular barriers are expanded to abut the inner face of the borehole or other well tubular metal structure to provide proper zonal isolation.
It is an object of the present invention to wholly or partly overcome the above disadvantages and drawbacks of the prior art. More specifically, it is an object to provide an improved downhole completion system ensuring that all annular barriers are expanded to abut the inner face of the borehole or other well tubular metal structure to provide proper zonal isolation.
The above objects, together with numerous other objects, advantages and features, which will become evident from the below description, are accomplished by a solution in accordance with the present invention by a downhole completion system for isolating several zones in a well having a top, comprising:
wherein the second annular barrier is arranged in between the first annular barrier and the third annular barrier, and the second annular barrier is configured to expand at a lower pressure than the first and third annular barriers.
Additionally, the above objects, together with numerous other objects, advantages and features, which will become evident from the below description, are accomplished by a solution in accordance with the present invention by a downhole completion system for isolating several zones in a well having a top, comprising:
wherein the second annular barrier is arranged in between the first annular barrier and the third annular barrier, and the second annular barrier is arranged in between the first annular barrier and the third annular barrier, and the second annular barrier expands at a first pressure, the first annular barrier expands at a second pressure, the third annular barrier expands at a third pressure, the first pressure barrier is lower than the second pressure and/or third pressure.
In addition, the second annular barrier may expand prior to expansion of the first and third annular barriers in that:
Furthermore, the second pressure may be equal to or the same as the third pressure.
When expanding three or more annular barriers simultaneously against an inner face of an impermeable part of the borehole formation or against another well tubular metal structure, there is a risk that the middle annular barrier cannot be fully expanded. If the well tubular metal structure comprises three annular barriers, and there is a risk that the second middle annular barrier between the first annular barrier and the third annular barrier will be unable to fully expand if the expandable metal sleeve of the first and third annular barriers abut the inner face first, then the first and third annular barriers will enclose a volume of liquid, and the expandable metal sleeve of the second middle annular barrier will not be able to fully expand since the liquid in the volume cannot be displaced through the impermeable formation or the other well tubular metal structure. By having the second annular barrier arranged in between the first annular barrier and the third annular barrier and by it being configured to expand at a lower pressure than the first and third annular barriers, it is ensured that all three annular barriers are able to fully expand. This is of special importance if the first and second annular barriers isolate a production zone, and the second and third annular barriers isolate a water-producing zone. Also when the three annular barriers are to carry a certain load when used for hanging off a liner, it is important that all the annular barriers are carrying the intended load, and in such situation, the expandable metal sleeves of the annular barriers are expanded to abut the inner face of another well tubular metal structure.
Moreover, the expandable metal sleeve of the second annular barrier may expand at a lower pressure than the expandable metal sleeve of the first and third annular barriers.
Furthermore, the expandable metal sleeve of the second annular barrier may have a first thickness being smaller than a second thickness of the expandable metal sleeve of the first and third annular barriers.
In addition, the expandable metal sleeve of the second annular barrier may be made of a metal material being more ductile than the metal material of the expandable metal sleeve of the first and third annular barriers.
Also, the expandable metal sleeve of the second annular barrier may be more flexible than the expandable metal sleeve of the first and third annular barriers.
Further, the expandable metal sleeve of the second annular barrier may be made of a metal material being more flexible than the metal material of the expandable metal sleeve of the first and third annular barriers.
Moreover, the second annular barrier may comprise means for expanding the second annular barrier before the first and third annular barriers.
Furthermore, the means may be that the expandable metal sleeve of the second annular barrier has a first thickness being smaller than a second thickness of the expandable metal sleeve of the first and third annular barriers.
In addition, the means may be that the expandable metal sleeve of the second annular barrier is made of a metal material being more ductile than the metal material of the expandable metal sleeve of the first and third annular barriers.
Also, the means may be that the expandable metal sleeve of the second annular barrier is made of a metal material being more flexible than the metal material of the expandable metal sleeve of the first and third annular barriers.
Further, the downhole completion system may comprise a fourth annular barrier arranged next to the first annular barrier closer to the top and a fifth annular barrier next to the third annular barrier furthest away from the top, the second thickness of the expandable metal sleeve of the first and third annular barriers being smaller than a third thickness of the expandable metal sleeve of the fourth and fifth annular barriers.
Moreover, the expandable metal sleeve of the first and third annular barriers may have several sections having a greater thickness than other sections of the expandable metal sleeve of the first and third annular barriers, and the expandable metal sleeve of the second annular barrier may have fewer sections having a greater thickness than other sections of the expandable metal sleeve of the second annular barrier.
Furthermore, the expandable metal sleeve of the first and third annular barriers may have several sections having a greater thickness than other sections of the expandable metal sleeve of the first and third annular barriers, and the expandable metal sleeve of the second annular barrier may not have any sections having a greater thickness than other sections of the expandable metal sleeve of the second annular barrier.
In addition, the first and third annular barriers may be provided with a dissolvable disc in the fluid channel between the expansion opening and the annular barrier space.
Also, the first and third annular barriers may be provided with a dissolvable disc in the fluid channel between the expansion opening and the annular barrier space, and the second annular barrier may have no dissolvable disc in the fluid channel between the expansion opening and the annular barrier space.
Further, the dissolvable disc may be designed so that the second annular barrier is fully expanded before the first and third annular barriers initiate expansion.
Moreover, the first and third annular barriers may be provided with a shear disc in the fluid channel between the expansion opening and the annular barrier space.
Furthermore, the second annular barrier may be fully expanded at a predetermined pressure, and the shear disc is sheared at a differential pressure matching the predetermined pressure so that the second annular barrier is fully expanded before the first and third annular barriers initiate expansion.
In addition, the first and third annular barriers may be provided with a shear disc in the fluid channel between the expansion opening and the annular barrier space, the second annular barrier having no shear disc in the fluid channel between the expansion opening and the annular barrier space.
Furthermore, the second annular barrier may be provided with a shear disc in the fluid channel between the expansion opening and the annular barrier space, the shear disc of the second annular barrier being designed to break at a lower pressure than that of the shear disc of the first and third annular barriers.
Also, the first and third annular barriers may be provided with a shear pin valve having a piston in a bore maintained in a first position by a shear pin which breaks at a predetermined pressure, shifting the piston to a second position in which fluid is allowed to flow from the expansion opening to the annular barrier space.
Further, the piston may have seals.
Moreover, the second annular barrier may comprise a pressure intensifier configured to increase the pressure entering the expansion opening before entering the annular barrier space.
Furthermore, the first and third annular barriers may have no pressure intensifier or a pressure intensifier which increases the pressure less than the pressure intensifier of the second annular barrier.
In addition, the second annular barrier may comprise a first pressure intensifier configured to increase the pressure entering the expansion opening before entering the annular barrier space, and the second annular barrier may comprise a second pressure intensifier configured to increase the pressure entering the expansion opening of the second annular barrier before entering the annular barrier space of the second annular barrier by 10-20 bars more than the first pressure intensifier.
Moreover, the first and third annular barriers may comprise a first pressure intensifier configured to increase the pressure entering the expansion opening before entering the annular barrier space, and the second annular barrier may comprise a second pressure intensifier configured to increase the pressure entering the expansion opening of the second annular barrier before entering the annular barrier space of the second annular barrier by 10-20 bars more than the first pressure intensifier.
Also, the first and third annular barriers may comprise a pressure relief valve in the fluid channel.
Further, the first and third annular barriers may comprise a sequence valve which is activated to open for fluid communication to the annular barrier spaces of the first and third annular barriers at a predetermined pressure in the annular barrier space of the second annular barrier.
Moreover, the first and third annular barriers may each comprise a throttle valve in the fluid channel.
Furthermore, the first and third annular barriers may each comprise a throttle valve in the fluid channel, and the second annular barrier may have no throttle valve in the fluid channel.
In addition, the first and third annular barriers may each comprise an activation unit for bringing a valve from a closed position to an open position when the pressure in the annular barrier space of the second annular barrier is above a predetermined pressure.
Also, the first and third annular barriers may each comprise an activation unit for bringing a valve from a closed position to an open position, the activation unit being activated by a pressure increase in the annular barrier space of the second annular barrier.
Further, each end section of the expandable metal sleeve of the second annular barrier may be connected to the tubular metal part by means of a connection part, each connection part being slidably connected to the tubular metal part.
Moreover, the first and third annular barriers may each comprise an orifice in the fluid channel, the fluid channel being fluidly connected to the annular barrier space upstream of the orifice so that a pressure increase upstream of the orifice activates a valve opening for fluid communication to the annular barrier space when the pressure increase is above a certain level.
Furthermore, the first and third annular barriers may each comprise an orifice in the fluid channel, the fluid channel being fluidly connected to the annular barrier space upstream of the orifice, the inner diameter of the fluid channel of the second annular barrier being larger than the inner diameter of the orifice.
In addition, when the inner diameter of the fluid channel of the second annular barrier is larger than the inner diameter of the orifice, the second annular barrier may be expanded at a lower flow rate than the first and third annular barriers.
Also, the well tubular metal structure may be connected with the drill pipe or coiled tubing closer to the top of the well than the first annular barrier.
Further, the well tubular metal structure may have a first end closest to the top and a second end, the downhole completion system further comprising a drill pipe or coiled tubing connected at a first end with the well tubular metal structure at the first end of the well tubular metal structure.
Moreover, the annular barrier space of the second annular barrier may comprise a compound such as a swellable material increasing the expansion rate of the second annular barrier compared to that of the first and third annular barriers.
The invention also relates to a downhole completion method for completing a downhole completion system according to any of the preceding claims, comprising:
Moreover, during the pressurising of the well tubular metal structure to a first pressure and expansion of the second annular barrier, the first and third annular barriers may remain unexpanded.
Furthermore, the expansion of the first and third annular barriers may be initiated after the expansion of the second annular barrier has been initiated.
In addition, the completion method may comprise increasing the pressure to a second pressure to also expand the first and third annular barriers.
Further, before lowering the well tubular metal structure, the downhole completion method may comprise connecting a drill pipe to a first end of the well tubular metal structure, and lowering the well tubular metal structure may also comprise lowering the drill pipe into the borehole until the well tubular metal structure is arranged in a predetermined position, the pressurising of the well tubular metal structure also comprising pressurising the drill pipe.
Finally, the pressurising of the well tubular metal structure to a first pressure may be performed at a predetermined first flow rate, the downhole completion method further comprising increasing the flow rate to a second flow rate to also expand the first and third annular barriers.
The invention and its many advantages will be described in more detail below with reference to the accompanying schematic drawings, which for the purpose of illustration show some non-limiting embodiments and in which:
All the figures are highly schematic and not necessarily to scale, and they show only those parts which are necessary in order to elucidate the invention, other parts being omitted or merely suggested.
When expanding three or more annular barriers 1 simultaneously against an inner face of an impermeable part of the borehole formation or against another well tubular metal structure, there is a risk that the middle annular barrier cannot be fully expanded. If the well tubular metal structure comprises three annular barriers, and there is a risk that the second middle annular barrier between the first annular barrier and the third annular barrier will be unable to fully expand if the expandable metal sleeve of the first and third annular barriers abut the inner face first, the first and third annular barriers will enclose a volume of liquid, and the expandable metal sleeve of the second middle annular barrier then cannot fully expand since the liquid in the volume cannot be displaced through the impermeable formation or the other well tubular metal structure.
In
Thus in
In
In another aspect, the second annular barrier 1b is configured to expand at a lower pressure than the first and third annular barriers 1a, 1c in that the expandable metal sleeve 14 of the second annular barrier 1b is made of a metal material being more ductile than that of the metal material of the expandable metal sleeve 14 of the first and third annular barriers 1a, 1c.
In another aspect, the second annular barrier 1b is configured to expand at a lower pressure than the first and third annular barriers 1a, 1c in that the expandable metal sleeve 14 of the second annular barrier 1b is more flexible than the expandable metal sleeve 14 of the first and third annular barriers 1a, 1c.
Thus, the expandable metal sleeve 14 of the second annular barrier 1b may be made of a metal material being more flexible than that of the metal material of the expandable metal sleeve 14 of the first and third annular barriers 1a, 1c so that the second annular barrier is configured to expand at a lower pressure than the first and third annular barriers.
In the downhole completion system 100, the second annular barrier 1b thus comprises means for expanding the second annular barrier 1b before the first and third annular barriers 1a, 1c. The means may be one of several means where one is that the expandable metal sleeve 14 of the second annular barrier 1b has a first thickness t1 being smaller than a second thickness t2 of the expandable metal sleeve 14 of the first and third annular barriers 1a, 1c. Another means may be that the expandable metal sleeve 14 of the second annular barrier 1b is made of a metal material being more ductile than the metal material of the expandable metal sleeve 14 of the first and third annular barriers 1a, 1c. Yet another means may be that the expandable metal sleeve 14 of the second annular barrier 1b is made of a metal material being more flexible than the metal material of the expandable metal sleeve 14 of the first and third annular barriers 1a, 1c.
As shown in
The annular barrier of
In
In order for the second annular barrier 1b to expand at a lower pressure than the first and third annular barriers 1a, 1c, the first and third annular barriers 1a, 1c may be provided with a shear disc 18 in the fluid channel 17 between the expansion opening 16 and the annular barrier space 15, as shown in
Instead of a shear disc, the first and third annular barriers 1a, 1c may be provided with a dissolvable disc (not shown) in the fluid channel 17 between the expansion opening 16 and the annular barrier space 15. The first and third annular barriers 1a, 1c are provided with the dissolvable disc (not shown) in the fluid channel 17 between the expansion opening 16 and the annular barrier space 15, and the second annular barrier 1b has no dissolvable disc in the fluid channel 17 between the expansion opening 16 and the annular barrier space 15. The dissolvable disc is designed so that the second annular barrier 1b is fully expanded before it is dissolved and the first and third annular barriers initiate expansion.
In another aspect, the first and third annular barriers 1a, 1c comprise a sequence valve 24, as shown in
In
In yet another aspect, the first and third annular barriers is, 1c are provided with a shear pin valve 130, as shown in
In order for the second annular barrier 1b to expand at a lower pressure than the first and third annular barriers 1a, 1c, the first and third annular barriers 1a, 1c may in another aspect each comprise a throttle valve in the fluid channel 17. The first and third annular barriers 1a, 1c each comprise a throttle valve in the fluid channel 17, and the second annular barrier 1b has no throttle valve in the fluid channel 17. In this way, the second annular barrier 1b is expanded before the first and third annular barriers 1a, 1c.
In yet another aspect, the first and third annular barriers 1a, 1c each comprise an activation unit for bringing a valve from a closed position to an open position when the pressure in the annular barrier space 15 of the second annular barrier 1b is above a predetermined pressure. The activation unit may be activated by a pressure increase in the annular barrier space 15 of the second annular barrier 1b. This may be measured by a sensor communicating with the activation unit through an electric wire or wirelessly.
Even though not shown, each end section 31, 32 of the expandable metal sleeve 14 of the second annular barrier 1b may be connected to the tubular metal part 12 by means of a connection part 30, where each connection part is slidably connected to the tubular metal part 12 so that the expandable metal sleeve 14 of the second annular barrier 1b is more easily expanded radially outwards than the expandable metal sleeve 14 of the first and third annular barriers 1a, 1c having expandable metal sleeves 14 that are fixedly fastened to the tubular metal part 12, either by welding, bite fitting or a crimped connection.
In order for the second annular barrier 1b to expand at a lower flow rate instead of at a lower pressure than the first and third annular barriers 1a, 1c, the first and third annular barriers 1a, 1c may in another aspect each comprise an orifice in the fluid channel 17. The fluid channel 17 is fluidly connected to the annular barrier space 15 upstream of the orifice so that a pressure-increase upstream of the orifice due to a high flow of fluid activates a valve which opens for fluid communication to the annular barrier space 15 when the pressure increase is above a certain level. The inner diameter of the fluid channel 17 of the second annular barrier 1b is larger than the inner diameter of the orifice of the first and third annular barriers 1a, 1c. When the inner diameter of the fluid channel 17 of the second annular barrier 1b is larger than the inner diameter of the orifice, the second annular barrier 1b is expanded at a lower flow rate than the first and third annular barriers 1a, 1c. In this way, the second annular barrier 1b can be expanded at one flow rate before the flow rate is increased, and the first and third annular barriers 1a, 1c are then expanded. In order to be able to vary the flow rate of the pressurised fluid, the well tubular metal structure 3 is connected with the drill pipe or coiled tubing closer to the top of the well than the first annular barrier 1a so that the flow rate can be changed, e.g., from one barrel per minute for expanding the second annular barrier 1b to two barrels per minute for expanding the first and third annular barriers 1a, 1c. The well tubular metal structure 3 has a first end closest to the top of the well and a second end. The downhole completion system further comprises a drill pipe or coiled tubing connected at a first end with the well tubular metal structure 3 at the first end of the well tubular metal structure 3.
The downhole completion method for completing a downhole completion system 100 as described above comprises mounting tubular sections with tubular metal parts 12 of the well tubular metal structure 3 having the first, second and third annular barriers 1a, 1b, 1c, and the second annular barrier 1b being mounted to be arranged in between the first annular barrier and the third annular barrier 1a, 1c. The downhole completion method further comprises lowering the well tubular metal structure 3 in the well until the well tubular metal structure 3 is arranged in a predetermined position, and pressurising the well tubular metal structure 3 to a first pressure and expanding the second annular barrier 1b. During the pressurising of the well tubular metal structure 3 from within to a first pressure and expansion of the second annular barrier 1b, the first and third annular barriers 1a, 1c remain unexpanded. The expansion of the first and third annular barriers 1a, 1c is initiated after the expansion of the second annular barrier 1b has been initiated, and for some aspects described above, the expansion of the first and third annular barriers 1a, 1c is initiated after the expansion of the second annular barrier 1b has ended.
The downhole completion method further comprises increasing the pressure to a second pressure to expand also the first and/or third annular barriers 1a, 1c or increasing the flow rate to a second flow rate to expand also the first and third annular barriers 1a, 1c.
The downhole completion method further comprises increasing the pressure to a third pressure to also expand the other of the first and third annular barriers 1a, 1c.
The downhole completion method where the flow rate has to be increased in order for the second annular barrier 1b to expand before the first and third annular barriers 1a, 1c comprises connecting a drill pipe to a first end of the well tubular metal structure 3 before lowering the well tubular metal structure 3, and then lowering the well tubular metal structure 3 also comprises lowering the drill pipe into the borehole 5 until the well tubular metal structure 3 is arranged in a predetermined position, the pressurising of the well tubular metal structure 3 also comprising pressurising the drill pipe. Then, the pressurising of the well tubular metal structure 3 to a first pressure is performed at a predetermined first flow rate, the downhole completion method further comprising increasing the flow rate to a second flow rate to expand also the first and third annular barriers 1a, 1c.
By “fluid” or “well fluid” is meant any kind of fluid that may be present in oil or gas wells downhole, such as natural gas, oil, oil mud, crude oil, water, etc. By “gas” is meant any kind of gas composition present in a well, completion or open hole, and by “oil” is meant any kind of oil composition, such as crude oil, an oil-containing fluid, etc. Gas, oil and water fluids may thus all comprise other elements or substances than gas, oil and/or water, respectively.
By “casing” or “well tubular metal structure” is meant any kind of pipe, tubing, tubular, liner, string, etc., used downhole in relation to oil or natural gas production.
In the event that the tool is not submergible all the way into the casing, a downhole tractor can be used to push the tool all the way into position in the well. The downhole tractor may have projectable arms having wheels, wherein the wheels contact the inner surface of the casing for propelling the tractor and the tool forward in the casing. A downhole tractor is any kind of driving tool capable of pushing or pulling tools in a well downhole, such as a Well Tractor®.
Although the invention has been described above in connection with preferred embodiments of the invention, it will be evident to a person skilled in the art that several modifications are conceivable without departing from the invention as defined by the following claims.
Number | Date | Country | Kind |
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20215501.6 | Dec 2020 | EP | regional |