Patent Grant
9062530
For purposes of forming a well to extract a hydrocarbon-based fluid (oil or natural gas) from a hydrocarbon-bearing geological formation, a wellbore is first drilled into the formation and completion equipment, which typically includes a complex system of tubes and valves, is installed in the wellbore to regulate the production of well fluid from the well.
The completion equipment may include sand control equipment, such as screens and filtering media, and a production tubing string to communicate well fluid to the Earth surface. Installing the completion equipment, as well as conducting downhole operations associated with completing the well, such as gravel packing and/or fracturing operations, may involve multiple runs, or trips, into the well. In general, each trip into the well may add to the cost and complexity associated with completing the well.
In an example implementation, a technique includes running a lower completion assembly into a well in a single trip. The lower completion assembly includes a screen, a first valve and a second valve. The technique includes performing a gravel packing operation using the lower completion assembly, where performing the gravel packing operation includes running a service assembly into the lower completion assembly to operate the first valve. The technique further includes removing the service assembly from the well and subsequently installing an upper completion assembly in the well. The installation of the upper completion assembly enables remote control of the second valve of the lower completion assembly for purposes of regulating the production of fluid from the well.
In another example implementation, an apparatus includes a lower completion assembly that includes a screen, a first valve and a second valve, which are adapted to be run downhole as a unit. The first valve is adapted to be controlled by a service tool in a downhole operation, and the service tool is run into the lower completion assembly before installation of an upper completion assembly. The second valve is adapted to be controlled in response to one or more stimuli that are communicated downhole via at least one control line of the upper completion assembly.
In yet another example implementation, an apparatus includes a lower completion assembly that includes a plurality of sections that are adapted to be run downhole in a single trip into a well. The lower completion assembly is adapted to be used during a gravel packing phase to deposit gravel about at least one of the sections and mate with an upper completion assembly after the gravel packing phase to regulate production in a production phase. At least one of the sections includes a screen, a packer, a first valve, a second valve and a circulation valve. The lower completion assembly is adapted to receive a service tool during the gravel packing phase to communicate a gravel slurry and operate the first valve to regulate delivery of the gravel; and the second valve is adapted to be regulated in response to one or more stimuli communicated downhole via at least one control line of the upper completion assembly during the production phase.
Advantages and other features will become apparent from the following drawings, description and claims.
In the following description, numerous details are set forth to provide an understanding of embodiments of the present invention. However, it will be understood by those skilled in the art that the present invention may be practiced without these details and that numerous variations or modifications from the described embodiments may be possible.
In the specification and appended claims: the terms “connect”, “connection”, “connected”, “in connection with”, and “connecting” are used to mean “in direct connection with” or “in connection with via another element”; and the term “set” is used to mean “one element” or “more than one element”. As used herein, the terms “up” and “down”, “upper” and “lower”, “upwardly” and downwardly”, “upstream” and “downstream”; “above” and “below”; and other like terms indicating relative positions above or below a given point or element are used in this description to more clearly describe some embodiments of the invention. Moreover, the term “sealing mechanism” includes: packers, bridge plugs, downhole valves, sliding sleeves, baffle-plug combinations, polished bore receptacle (PBR) seals, and all other methods and devices for blocking the flow of fluids through the wellbore.
Running an intelligent completion that includes flow control valves inside a screen in a well that are completed using sand control operations (e.g., gravel packing or frac packing operations) may not be commercially attractive, as it may be challenging to run relatively large flow control valves inside a relatively small internal diameter screen. Because of this reason, flow control valves may be run on a separate trip and placed above the screen. However, this arrangement may limit the number of zones (two zones, for example) that may be controlled from a given flow control valve. Completion systems and techniques are disclosed herein to independently control flow from wells having many zones (more than two zones, for example). More specifically, the completion systems that are disclosed herein integrate the flow control valve with the screen and gravel packing operations, which allows independent control of flow from more than two zones in a well, which uses sand control.
Referring to
For the example that is depicted in
The lower completion assembly 20, in accordance with implementations disclosed herein, includes at least one flow control valve 110 (a cartridge valve, a solenoid-operated valve and/or a control line-operated valve, an electric valve, a hydraulic valve or electro-hydraulic valve as non-limiting examples); one or more circulating, or port control valves 150 (a sleeve valve, as a non-limiting example); one or more return valves 104 (a sleeve valve, as a non-limiting example); and one or more sand production control devices, such as screens 100. As non-limiting examples, the screen 100 may be a wire-wrapped screen, a mesh screen or a sand production control assembly that includes a combination of different filtering media, depending on the particular implementation. Moreover, the screen 100 may be disposed inside a protective shroud (not shown).
In accordance with exemplary implementations, the lower completion assembly 20 may be longitudinally partitioned into sections (exemplary uppermost 30, intermediate 60 and lower 80 sections, being depicted in
For example, the uppermost section 30 of the lower completion assembly 20 may include such features as a flow control valve 110, a return valve 104, a screen 100 and a port control valve 150. The uppermost section 30 corresponds to a particular segment, or zone, of the wellbore 12 and extends between an upper gravel packing packer 120 of the lower completion assembly 20 and a lower isolation packer 130, which defines the upper boundary of the next zone and the lower boundary of the zone associated with the section 30. Depending on the particular implementation, the packers 120 and/or 130 may be weight-set packers, mechanically-set packers, inflatable packers, swellable packers, hydraulically-set packers, etc. The screen 100 may longitudinally extend along the wellbore 12 for a distance of several feet to several hundred feet (300 feet, as a non-limiting example), depending on the particular implementation.
In general, the return valve 104 is disposed closer to the lower end of the screen 100 than to the upper end of the screen 100, and as depicted in
More specifically, in accordance with some implementations, all of the return valves 104 (i.e., the return valve 104 of the uppermost completion section 30 and the return valves 104 of the other sections 60 and 80) of the lower completion assembly 20 are initially closed when the assembly 20 is run into the well 10; and the return valves 104 are opened one at a time as the zones are sequentially gravel packed/fractured in an uphole direction. Thus, when it is time to gravel pack and/or fracture the zone associated with the uppermost section 30, for example, the return valve 104 of the uppermost section 30 is opened (via a shifting tool on a service string that is run inside the lower completion assembly 20, for example) to open communication between the central passageway of the section 30 and the surrounding annulus.
Moreover, to gravel pack and/or fracture the zone that is associated with the uppermost section 30, the port control valve 150 of the section 30 is opened (via a shifting tool on a service string, for example) so that a gravel slurry may be communicated from the central passageway of the lower completion assembly 20, through one or more radial ports of the port control valve 150 and into the annulus surrounding the screen 100. In the gravel packing operation, fluid from the slurry exits the slurry, thereby leaving a gravel substrate surrounding the screen 100. This fluid, in turn, returns to the central passageway of the uppermost section 30 through the open return valve 104. It is noted that a service tool string inside the lower completion assembly 20 may include at least one crossover tool for purposes of juxtapositioning flows of the slurry and slurry fluid between the central passageway and annulus of the lower completion assembly 20, as can be appreciated by the skilled artisan.
In accordance with some implementations, the gravel packing operation may be combined with a fracturing operation (in a “frac-pack operation”). Moreover, although gravel packing and fracturing are mentioned herein as examples of downhole operations that may be aided by the components of the lower completion assembly 20, other operations, which may include stimulation operations, acidizing operations, and so forth, may be performed using the lower completion assembly 20, in accordance with other implementations.
Unlike the return valve 104, the flow control valve 110 of the uppermost section 30 is used for purposes of controlling production from the zone that is associated with the section 30. Thus, in general, the flow control valve 110 is not used or controlled during the gravel packing phase and is run into the well 10 initially closed. More specifically, in accordance with exemplary implementations, the flow control valve 110 is constructed to be primarily controlled by one or more control lines 200 to regulate production from the associated zone during the production phase of the well 10. In this manner, one or more control stimuli may be communicated downhole from the Earth surface of the well 10 via the control line(s) 200 during the production phase for purposes of controlling the cross-sectional flow area through the flow control valve 110. As non-limiting example, the stimuli used to control the flow control valve 110 may include hydraulic pressure, hydraulic pressure pulses, electrical stimuli, optical stimuli, acoustic stimuli and so forth; and the control valve 110 has the appropriate telemetry interfaces and actuators to respond to the particular stimuli that are used. During the gravel packing phase, however, a control line communication path does not exist between the lower completion assembly 20 and the Earth surface of the well. As further described below, the control line communication path(s) are completed by one or more control lines of an upper completion assembly, which extends to the Earth surface. Thus, during the gravel packing phase (i.e., before the upper completion assembly is installed), control line operation of the flow control valve 110 is disabled.
Depending on the particular implementation, the flow control valve 110 may have a single open position (associated with a fixed cross-sectional flow area) to permit fluid communication between the central passageway of the section 30 and the annulus; or alternatively, in accordance with other implementations, the flow control valve 110 may have multiple choke positions in which different cross-sectional flow paths may be selected (via the appropriate control line stimuli) between the central passageway and the annulus. Thus, in the former implementation, the flow control valve 110 may be used to permit or isolate a particular zone of the well 10; and in the latter implementation, the flow control valve 110 may be controlled for purposes of isolating flow from the zone if closed or if open, regulating a particular cross-sectional flow area from the associated zone. Moreover, as further described below, in accordance with example implementations, each section of the lower completion assembly 20, such as the section 30, may contain multiple flow control valves 110 that are selectively controlled (some are opened and some are closed, for example) for purposes of regulating the inflow from the associated zone.
As depicted in
In accordance with an exemplary implementation, a wet connect coupler 180 is disposed at the upper end of the lower completion assembly 20 for purposes of coupling the control line(s) 200 to one or more corresponding control lines of the subsequently installed upper completion assembly (not shown in
Referring back to
In accordance with exemplary implementations, at its lower end, the lower completion assembly 20 includes a lowermost completion section 80 that extends between a given isolation packer (not shown) and a sump packer 140 that is disposed at the lower end of the lower completion assembly 20. In general, the lower section 80 contains components similar to the sections 30 and 60, such as port control valve 150, one or more flow control valves 110, a screen 100 and a return valve 104. Moreover, these elements may be disposed relatively to each other and operate similarly to the components of the sections 30 and 60.
In general, in accordance with exemplary implementations, the return valve 104 and the flow control valve 110 control inflow fluid communication between the surrounding annulus outside of the lower completion assembly 20 and an inner tubing string 300 of the assembly 20. More specifically, inflow fluid is communicated through the screen 100 and depending on the open/closed states of the valves 104 and 110, is communicated through the valve 104 and/or valve 110 into a central passageway 320 of the lower completion assembly 20. During the gravel packing of the associated zone, a slurry flow is introduced, which flows into an annular region 302 surrounding the screen 100. Fluid from the slurry flow exits through the screen 100 and into an annular region 304 between the screen 100 and the exterior of the tubing string 300, leaving the gravel substrate surrounding the screen 100. Access to the central passageway 320 of the tubing 300 and thus, access to the central passageway of the lower completion assembly 20 is controlled during the gravel packing phase by the return valve 104. Thus, during the gravel packing/fracturing of the zone associated with the section 80 when the return valve 104 is open, fluid flows from the annular region 304 into the central passageway 320 of the tubing 300. Closure of the return valve 104 (such as when the lower completion assembly 20 is run into the well 10 and possibly after gravel packing of the zone is complete) may be accomplished using, for example, a shifting tool that is run inside the lower completion assembly 20. As a non-limiting example, the return valve 104 may be a sleeve valve that has an inner profile that is engaged by a corresponding outer profile (an outer surface of a collet, for example) of a service tool (not shown) that is run inside the central passageway 302.
For the production phase, the upper completion assembly (not shown in
Referring to
The flow control valve 110 may have a variety of different designs, depending on the particular implementation. As a non-limiting example,
As a non-limiting example, the electrical cable 401 may contain multiple wires for purposes of communicating power and telemetry signals downhole. One or more of the wires of the electrical cable 401 may be used for purposes of communicating telemetry signals uphole. In general, the electrical cable 401 may be coupled (via a wet connect inductive coupler, for example) to control line communication paths of an upper completion assembly. In general, the communication paths of the upper completion assembly may include acoustic paths, wired paths, wireless paths, optical paths, wired pipe paths, electromagnetic communication paths, and so forth, which are coupled to corresponding control line communication paths of the lower completion assembly 20.
In general, signals that are communicated over the electrical cable 401 are received by a power and telemetry module 408 of the flow control valve 400. In this manner, in accordance with some implementations, command-encoded electrical signals may be communicated downhole to the flow control valve 400 via the cable 401 for purposes of selectively actuating the valve 400. This actuation may include, as non-limiting example, fully opening or fully closing the electric flow control valve 400; setting the flow control valve 400 to a particular choke position, closing flow through the electric flow control valve 400; and so forth.
For the example that is depicted in
Among its other features, in accordance with an exemplary implementation, the flow control valve 400 may include at least one sensor for purposes of acquiring information pertaining to sensed downhole conditions. This information, in turn, may be communicated uphole via the power and telemetry module 408 using one or more wires of the electrical cable 401 (as a non-limiting example). As non-limiting examples, the flow control valve 400 may include one or more of the following sensors: a pressure sensor, a temperature sensor, a viscosity sensor, and so forth.
By monitoring the data acquired by the sensor(s), an operator at the Earth surface of the well 10 may determine various parameters and control production for a given zone. As a more specific non-limiting example, depicted in
Referring to
Referring to
Next, according to the technique 600, a service string is run into the lower completion assembly, pursuant to block 616. In further implementations, the service string may also be the string that is used to run the lower completion assembly 20 into the well 10 and may be released from the lower completion assembly 20 to allow the service tool(s) of the service tool assembly 20 to perform downhole operations, manipulate valves of the assembly 20, and so forth. In general, each service tool of the service tool string may include one or more collets that have predefined profiles for purposes of engaging the return valves 104 and port control valves 150 to selectively control the opening and closing of these valves, in accordance with some implementations. The service string may further include a tubular string that extends uphole to the Earth surface of the well for purposes of communicating fluids and/or gravel-laden slurry downhole for purposes of using the lower completion assembly 20 to perform such operations as a gravel packing operation, a fracturing operation, a combined gravel packing and fracturing operation, a stimulation operation, an acidizing operation, and so forth.
As an example, the technique 600 next includes performing the gravel packing phase in which the zones are gravel packed (or concurrently fractured and gravel packed, depending on the implementation), beginning with the lowermost zone and proceeding uphole in a sequential fashion. In this manner, the service tool string is positioned (block 620) in the next zone to be gravel packed/fractured and used to open the return valve 104 and port control valve 150 associated with the zone. Next, the gravel packing operation is performed (block 624) in the zone. In other words, the gravel slurry is communicated through the service string and via the appropriate port control valve 150 into the annular region that surrounds the screen 100 such that excess fluid is communicated through the screen 100 and returns to the Earth surface. In accordance with some implementations, the gravel packing operation may be associated with a fracturing operation in which an increased fluid pressure is used for purposes of fracturing the zone.
According to the technique 600, if, pursuant to decision block 628 another zone is to be gravel packed/fractured, then control returns to block 620 in which the service tool is re-positioned and manipulated accordingly to open and close the appropriate valves and deliver the slurry flow. Referring to
As a more specific example,
For the example that is depicted in
In this manner, as depicted in
The tubing string 660 of the lower completion assembly 650 further includes a port control valve 664 (a sleeve valve, for example) for the upper zone 654, which may be operated by a shifting tool (not shown in
In general, the lower completion assembly 650 has a similar design and employs similar components (denoted by similar reference numerals) for the lower zone 656, in accordance with example implementations.
During gravel packing, fracturing operations or stimulation operations, and so forth, the port control valves 664 may be selectively opened and closed for purposes of communicating a flow between the central passageway of the tubing string 660 and an annular region in the appropriate zone 654, 656. After these operations are complete and the port control valves 664 are closed, it may be particularly challenging to maintain seals through the closed port control valves 664. Therefore, referring to
The isolation straddle seal assembly 700 includes sections, such as exemplary sections 704 and 706, which form corresponding seals to seal off the port control valves 664 from the central passageway of the tubing string 660. Thus, as shown in
The isolation straddle seal assembly 700 also includes, in accordance with exemplary implementations, radial ports 710, 712, 714 and 716 (depicted as examples), which align with the corresponding outlets of the flow control valves 668 to thereby permit fluid communication through the flow control valves 664 and the central passageway of the tubing string 660, as selectively controlled by the states of the flow control valve 664.
In accordance with exemplary implementations, the isolation straddle seal assembly 700 may further include valves 720, 724, 726 and 728 (depicted as non-limiting examples), such as sleeve valves, which provides backup control in case one or more of the flow control valves 664 stop properly functioning (fail closed, for example). In this regard, as depicted in
For the example implementation that is depicted in
Initially, the valves 720, 724, 726 and 728 are closed, if the corresponding flow control valves 668 operate properly. However, if a particular flow control valve 668 should fail and not be able to be opened or adjusted to the proper setting, the corresponding valve 720, 724, 726 or 728 may be opened (shifted open by a corresponding shifting tool, for example) to establish communication in an alternative path.
Referring to
Referring to
Moreover, in addition to the sections 762 and 768, an inner tubing string 761 of the isolation straddle seal assembly 760 has ports 764 and 770, which are aligned with the flow control valve 664. Additionally, similar to the isolation straddle seal assembly 700, the isolation straddle seal assembly 760 includes valves 766 and 770 (sliding sleeve valves, for example), which are used as backup valves to selectively provide alternative paths for the return valves 756 of the upper 654 and lower 656 zones, respectively. In this manner, the isolation straddle seal assembly 760 includes a return valve shifting tool 780 at the lower end of the tubing string 761 for purposes of opening the port control valve 664 when the assembly 750 is run into the lower completion assembly 760.
Referring to
Among its other features, the upper completion assembly 800 includes an inductive coupler 816, which is constructed to inductively couple wires of an electric cable 811 that is in communication with the Earth surface to the corresponding wires of the electrical cable 670. For implementations in which the electrical cable is not employed (one or more hydraulic control lines, for example, are alternatively used), the upper completion assembly 800 may not include the inductive coupler 816. When used, the inductive coupler 816 inductively couples the electrical signals to a corresponding inductive coupler 790 located at the upper end of the lower completion assembly 750, as depicted in
In addition to or in replacement of the inductive couplers 816 and 790, in accordance with some implementations, the lower end of the upper completion assembly 800 includes a hydraulic wet connect coupler 820 that is disposed below the inductive coupler 816 (if used) to connect one or more hydraulic lines that extend to the Earth surface to one or more hydraulic lines that extend downhole to components of the lower completion assembly 750. As non-limiting examples, these components may include one or more flow control valves 668. As depicted in
Referring to
In general, the inner tubing string 856 may include an inductive coupler assembly 858 for purposes of communicating signals from an electrical cable 854 to downhole components of the lower completion assembly 850, such as flow control valves 862. In general, each zone may include multiple flow control valves 862, which, in accordance with some implementations, are arranged around the periphery, as depicted in
Inside a given zone, the tubing string 856 may further include a return valve 864 (a sleeve valve, for example), which provides an alternative path to regulate flow communication (via a shifting tool, for example), should the flow control valves 862 of the zone fail or not operate properly. With the standalone screen assembly arrangement, it is noted that a gravel packing operation may not be performed. In general, the packers 872 and 874 may be open hole isolation packers, such as swellable packers, hydraulically-set packers, mechanically-set packers and so forth. In further implementations, electric power may be used to activate swelling of the packers 872 and 874. Thus, many variations are contemplated, which are within the scope of the appended claims.
Referring to
In general, the lower completion assembly 900 is used to pack gravel around all of the screens in one operation. In this regard, initially, after the gravel pack packer 852 is set, the open hole isolation packer 861 remains unset, so that gravel pack slurry that is communicated inside an inner washpipe 950 via a gravel pack service tool 954 may be communicated through the port control valve 910 and into the annular region between the borehole segment wall 851 and the screen assemblies. Slurry fluid from the gravel packing operation returns through the sleeves and corresponding flow control valves 862 into the central passageway of the washpipe 950.
As depicted in
As a non-limiting example, the formation isolation valve 924 may be a mechanically-control valve (controlled via a shifting tool, for example), in accordance with some implementations. In this manner, referring to
Referring to
While a limited number of examples have been disclosed herein, those skilled in the art, having the benefit of this disclosure, will appreciate numerous modifications and variations therefrom. It is intended that the appended claims cover all such modifications and variations.
This application claims the benefit under 35 U.S.C. §119(e) to U.S. Provisional Patent Application Ser. No. 61/441,096 entitled, “SAND CONTROL WITH INTEGRATED INTELLIGENT COMPLETION AND FLOW CONTROL VALVES,” which was filed on Feb. 9, 2011, and U.S. Provisional Patent Application Ser. No. 61/441,032, entitled, “INTEGRATED SINGLE TRIP MULTIZONE FRAC PACK AND INTELLIGENT COMPLETION SYSTEM,” which was filed on Feb. 9, 2011. Each of these applications is hereby incorporated by reference in its entirety.
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