Hydrocarbon fluids such as oil and natural gas are obtained from a subterranean geologic formation, referred to as a reservoir, by drilling a well that penetrates the hydrocarbon-bearing formation. Once a wellbore is drilled, various forms of well completion components may be installed in order to control and enhance the efficiency of producing the various fluids from the reservoir. One such component is a flow control valve used to control the amount of fluid permitted to flow upward through the completion to the surface.
Embodiments of the present disclosure are directed to a flow control valve assembly including a plunger containment member and a plunger operatively coupled to the plunger containment member such that moving the plunger toward an uphole side and toward a downhole side opposite the uphole side in the plunger containment member causes the flow control valve to selectively open and close in response to administration of force to the plunger. The uphole side of the plunger and the downhole side of the plunger are exposed to a hydrostatic pressure of substantially equal magnitude. The assembly also includes a first seal between the plunger and the plunger containment member on the uphole side and a second seal between the plunger and the plunger containment member on the downhole side.
The assembly can also include a power module to provide power to move the plunger to selectively open and close the flow control valve. The first and second seals are able to withstand 1,200 psi and the power module is configured to operate with between 8-10 watts.
Further embodiments of the present disclosure are directed to a method for operating a flow control device. The method includes providing a flow control valve in a well, the flow control valve having a plunger containment member, a plunger, and a fluid port. The plunger is configured to travel forward and backward in the plunger containment member to open and close the flow control valve. The plunger has a first side and a second side opposite the first side. Both the first and second sides are exposed to pressure in the well of substantially equal magnitude, and the fluid port is opened or closed by moving the plunger within the plunger containment member. The method also includes providing a first seal for the first side of the plunger and a second seal for the second side of the plunger. The first and second seals are configured to withstand up to 1,200 psi. The method further includes operating a power module to move the plunger in the plunger containment member, wherein the power module consumes no more than 10 watts of power.
Still further embodiments of the present disclosure are directed to a flow control device for use in a downhole completion. The flow control device includes a central fluid bore configured to conduct fluid upward from the well, the central fluid bore having a fluid port in a wall of the bore, and a plurality of sand screens positioned outside the central bore and configured to filter fluid as the fluid passes through the sand screens. The device also includes an annular bore configured to receive fluid after passing through the sand screens. The annular bore is fluidly connected to the fluid port in the central fluid bore. There is also a plunger positioned in the annular bore and configured to selectively block fluid flow from the annular bore into the central bore. The plunger is selectively, continuously movable between a closed position, an intermediate position, and a fully open position, the plunger having a downhole side and an uphole side opposite the downhole side, wherein the uphole side and downhole sides are both exposed to substantially the same hydrostatic pressure in the well. The device also includes a seal assembly between the plunger and the uphole side.
In the following description, numerous details are set forth to provide an understanding of the present disclosure. However, it will be understood by those skilled in the art that the embodiments of the present disclosure may be practiced without these details and that numerous variations or modifications from the described embodiments may be possible.
In the following description, numerous details are set forth to provide an understanding of some embodiments of the present disclosure. However, it will be understood by those of ordinary skill in the art that the system and/or methodology may be practiced without these details and that numerous variations or modifications from the described embodiments may be possible.
The present disclosure generally relates to an electrically controllable, multi-zone control system. The multi-zone control system may be used for controlling the inflow of fluids into a completion, e.g. a lateral completion, at a plurality of well zones. According to an embodiment, hydraulically actuated, flow control devices are distributed along the completion in the various well zones. Additionally, a control module is positioned between the flow control devices, e.g. in a middle region of the completion. For example, the control module may be positioned between well zones and operated downhole for controlling flow control devices uphole and downhole relative to the location of the control module.
The control module is supplied with hydraulic actuating fluid from a source, such as a downhole hydraulic fluid source or a surface source. In operation, the control module is electrically controllable to enable selective distribution of the hydraulic actuating fluid to specific flow control devices, e.g. flow control devices in a specific well zone. The control module may be actuated via electric signals to provide controlled distribution of hydraulic actuating fluid under pressure to selected flow control devices. The hydraulic actuating fluid is used to shift the selected flow control devices to a desired open or closed flow position allowing or blocking flow from the surrounding well zone.
Effectively, the control module serves as a multi-zone distribution hub. In some embodiments, the control module is supplied with hydraulic actuating fluid via a single hydraulic control line and a pump is used to place the actuating fluid under suitable pressure for actuating the flow control devices. An electric line may be routed downhole to the control module to provide electrical control signals to the control module. Based on those control signals, the control module is actuated to direct hydraulic actuating fluid through relatively short hydraulic lines to specific flow control devices. As a result, electrical signals supplied through, for example, a single electric line may be routed downhole and used to ultimately control operation of flow control devices in a plurality of well zones, e.g. 2-5 well zones. Use of the electric line enables and simplifies active surface control of fluid flow into the completion at a plurality of downhole well zones. The use of electrical control signals also enhances the ability to multi-drop such a system to various other well zones.
Referring generally to
In some applications, the lateral completion 26 is a lower completion initially installed downhole and then coupled with an upper completion 30 (shown in dashed lines) via a connect-disconnect system 32. An artificial lift system, e.g. an electric submersible pumping system, may be deployed as part of or in cooperation with the upper completion 30 to produce fluids received via lateral completion 26. During a production operation, the lateral wellbore section 24 may be isolated via a packer 34, such as a production packer, set against a surrounding casing 35.
Lateral completion 26 comprises an interior flow region or passage 36 which may be along the interior of a base pipe 38. The lateral completion 26 also comprises a plurality of sand screens 40 disposed about the base pipe 38 and located in corresponding well zones 28. Additionally, the lateral completion 26 comprises a plurality of flow control device systems 41. Each flow control device system 41 may comprise a plurality of flow control devices 42 located in each well zone 28, as further illustrated in
Referring generally to
To facilitate an initial gravel packing of lateral wellbore 24 after setting of the packers 46, the completion 26 also may comprise a plurality of shunt tubes 48 which deliver the gravel packing slurry to sequential well zones 28. The shunt tubes extending through sequential well zones 28 may be joined at a shunt tube isolation valve structure 50 having valves for controlling the flow of gravel slurry. The valves in valve structure 50 serve to further isolate adjacent well zones 28 when the valves are closed, e.g. closed after gravel packing. During a gravel packing operation, gravel packing slurry is delivered downhole by a service tool and then diverted from the inside diameter to the annulus surrounding completion 26 via a port closure sleeve 52. The gravel slurry flows along the annulus and shunt tubes 48 to form a uniform gravel pack 54.
In an operational example, the gravel slurry begins packing from the heel of the well and as the gravel/sand settles the dehydration fluid travels along a drainage layer between the first sand screen 40 and a solid section of the base pipe 38. The dehydration fluid travels along this fluid return path until reaching a first sliding sleeve 56 of a plurality of sliding sleeves. In some applications, some of the returning dehydration fluid also flows through the corresponding flow control device system 41, thus reducing or removing the use of additional sliding sleeves 56. The dehydration fluid then flows into interior 36 and back to the surface through the base pipe 38 and corresponding tubing. Upon completion of the heel zone, the gravel slurry pumping operation is continued and this process is repeated at subsequent well zones 28, with the aid of shunt tubes 48, until screen out pressure is reached and the pumps are stopped.
Once the service tool is retrieved, the upper completion 30 is deployed downhole and engaged with the lower completion 26 to establish communication from the surface to the lower completion 26. For example, electrical and/or hydraulic communication may be established through the connect-disconnect 32 which can be in the form of an electrically powered connect-disconnect system. Electrical power and electrical control signals may be provided to the control module 44 via an electric line 58 routed through the connect-disconnect 32. The electric line 58 may be coupled with a control system 60, e.g. a computer-based control system, located at the surface or at another suitable location.
In some applications, hydraulic actuating fluid may be provided to control module 44 via a hydraulic line 62 to enable selective actuation of the flow control devices 42. The hydraulic line 62 may similarly be routed through the connect-disconnect 32 and coupled with a hydraulic pump and control system 64 located at the surface or at another suitable location. In other embodiments, however, the hydraulic line 62 may be routed to control module 44 from a downhole fluid reservoir as described in greater detail below.
It should be noted the electric line 58 may comprise a single or multiple conductive paths for carrying electrical power, control signals, and/or data signals, e.g. data signals from sensors or other downhole equipment. By way of example, the electric line 58 may be in the form of a single line having a plurality of conductors able to independently carry power and/or data signals between, for example, surface control 60 and control module 44. Similarly, the hydraulic line 62 may comprise a single flow path or a plurality of flow paths for carrying hydraulic actuation fluid.
Referring again to
Based on the control signals received via electric line 58, the controller 68 executes flow control according to the instructions carried by the control signals. For example, the controller 68 may be used to control operation of a hydraulic manifold 70 of control module 44. As described in greater detail below, the hydraulic manifold 70 may comprise a variety of electrically controllable valves which are actuated according to instructions carried by the electrical control signals. The control module 44/manifold 70 are thus selectively controlled to direct flows of actuating fluid to the appropriate flow control system 41 and corresponding control devices 42 via a corresponding hydraulic line or lines 72.
In some embodiments, each hydraulic line 72 is routed to a corresponding well zone 28 and controls the simultaneous opening or closing of the group of flow control devices 42 in that specific corresponding well zone 28. For example, control instructions may be provided by control system 60 to controller 68 of control module 44 via appropriate electrical signals sent along electric line 58. In response to those instructions, the control module 44 controls hydraulic manifold 70 to ensure a flow of hydraulic actuating fluid to the appropriate flow control devices 42 in a given well zone or zones 28. Accordingly, if undesirable fluid, e.g. water or undesirable gas, begins to flow into the interior 36 of lateral completion 26 at a specific well zone 28, the group of flow control devices 42 in that particular well zone 28 may be closed to block further inflow.
Depending on the type of surrounding formation and equipment used to construct lower completion 26, the number and length of well zones 28 may vary. By way of example, the well zones 28 may be approximately 1000 feet in length and control module 44 may be used to control 2-5 well zones 28. However, the lengths of well zones 28 may range from a few feet to thousands of feet, and the length may be the same or dissimilar from one well zone 28 to the next. Accordingly, the number of flow control devices 42 placed in each well zone 28 also may vary according to the parameters of a given application.
In the specific example illustrated, the overall multi-zone control system 66 employs control module 44 to control well fluid flow at five different well zones 28. Sometimes the number of well zones 28 controlled by an individual control module 44 may be selected based on the number of control line feed throughs available at isolation packers 46. For example, if the isolation packers 46 have three control line feed throughs, then the number of well zones 28 serviced by the control module 44 may be selected based on the ability to accommodate the single electrical line 58 and a pair of hydraulic lines 72. If the number of feed throughs in isolation packers 46 is increased, however, the multi-drop to other well zones 28 can also be increased accordingly. Also, the electric line 58 may be routed to additional control modules 44 so as to enable further control over inflow of well fluids at additional well zones 28.
Referring generally to
The downhole reservoir 74 supplies hydraulic actuating fluid to control module 44 via hydraulic line 62. In the embodiment illustrated, control module 44 comprises a hydraulic pump 78 powered by a motor 80 which, in turn, may be coupled to electrical power via electric line 58. In some embodiments, the hydraulic pump 78 and the motor 80 may be combined into a single component. In the illustrated example, the hydraulic manifold 70 works in cooperation with a plurality of electrically actuated valves 82, e.g. solenoid operated valves, to control flow of hydraulic actuating fluid along hydraulic lines 72. An additional electrically actuated valve 84 may be used to enable circulation of hydraulic actuating fluid back to reservoir 74 when the electrically actuated valves 82 are closed to flow. This allows hydraulic pump 78 to continually operate and to simply return the pumped actuating fluid back to reservoir 74 when the electrically actuated valves 82 are in the closed position.
When the control module 44, e.g. controller 68, receives instructions to change the flow position of flow control devices 42 in a given well zone or zones 28, the appropriate valves 82 are shifted electrically to the desired flow or no-flow position. In the embodiment illustrated, the electrically actuated valve 84 has been shifted to the closed or no-flow position and one of the electrically controlled valves 82 has been shifted to the open flow position to enable flow of actuating fluid to the corresponding flow control devices 42. In the illustrated example, the valve 82 shifted to the open flow position has effectively directed actuating fluid under pressure to the flow control devices 42 in the middle well zone 28, thus shifting those flow control devices 42 to the closed flow position. When flow control devices 42 in the middle well zone 28 are closed, well fluids are prevented from flowing from the exterior of completion 26 to interior 36 at that well zone.
Depending on the application, flow control devices 42 may have a variety of configurations. By way of example, the flow control devices 42 may comprise plunger assemblies 86, e.g. hydraulically actuated plungers 86. In some applications, the plungers 86 are spring biased or otherwise biased to an open flow position allowing flow of fluids from an exterior to an interior of lateral completion 26. When hydraulic actuating fluid is allowed to flow to specific hydraulically actuated plungers 86 via manifold 70, those plungers 86 are forced against the spring bias and into corresponding seats 88 to block further flow of fluids therethrough.
In some embodiments, individual electrically actuated valves 82 may be coupled with flow control devices 42 in more than one well zone 28. In the embodiment illustrated in
A sensor system 90 also may be used to optimize control over fluid flow in each of the well zones 28. By way of example, the sensor system 90 may comprise a plurality of sensors 92 positioned along completion 26 and/or at other suitable locations within well zones 28. The sensors 92 may be in the form of pressure sensors, temperature sensors, or other sensors distributed throughout the well zones 28. The sensor data, e.g. pressure and temperature data, may be sent along electric line 58 to at least one of the controller 68 or control system 60 for processing. The processed data provides information that can be used for controlling flow into completion 26 at each well zone 28. For example, if the sensor data indicates the presence of water and/or gas, the flow control devices 42 for that well zone 28 may be closed to block further inflow of fluid.
Depending on the reservoir and surrounding formation, the lateral completion 26 may be constructed in various lengths and configurations. In
The overall zonal flow control system 66 may be adapted to a variety of applications and may be used to provide a low-cost, active control of multiple well zones 28, e.g. five well zones, from a single distribution hub/module 44. With additional feed throughs in packers 46 and in shunt tube isolation valve structures 50, additional well zones 28 may be controlled via module 44. The control module 44 serves as a distribution hub which can be multi-dropped to provide flow control in a plurality of well zones based on control signals through the simple electric line 58. In some applications, the hydraulic actuating fluid may be selectively diverted by the control module 44 to actuate other components in the lower completion 26, e.g. packers, sliding sleeves, or zonal isolation valves. The flow control devices 42 also may comprise various types of plunger assemblies which facilitate return flow through the sand screen assembly joints 43.
Depending on parameters of a given application, the control module 44 may be constructed in a variety of configurations and may comprise various features. Examples of such features include the integral pump 78 and the motor 80 used for hydraulic power generation. The control module 44 also may incorporate or work in cooperation with a pressure compensation system, e.g. compensators 76. In some applications, the control module may comprise or work in cooperation with an accumulator used for storing hydraulic energy. Additionally, electronics 68 may comprise various types of controllers and telemetry systems utilized for communication and for controlling the components of control module 44 and overall flow control system 66.
Other components of the overall well system and multi-zone flow control system 66 also may be adjusted according to the parameters of a given application. The electric line 58 may comprise separate lines for power and data or a combined power/data line. The control system 60 and electric line 58 may be used for carrying a variety of signals along a wholly hardwired electrical communication line or a partially wireless communication line. Such adjustments to the well system may be made according to equipment, environmental, and/or other considerations.
The plunger 112 has a downhole side 118 and an uphole side 120. In previous designs, the plunger 112 was exposed to pressure on the downhole side 180 which was counter balanced by a force applied to the plunger 112 to the uphole side 120 to maintain the plunger 120 in the desired position. Depending on the installation, the pressure and counter balancing forces were large. The flow control valve assembly 100 also includes a power module 124 (shown schematically) that provides power to move the plunger up and down to open and close the valve assembly 100. The present disclosure is directed to embodiments in which the pressure is balanced between the uphole side 120 and downhole side 180.
The assembly 100 includes a series of seals 122 which will permit the pressure to be applied to the uphole side 120 without contaminating the fluid flow through the fluid port 116. The uphole side 120 and downhole side 180 can both be in communication with hydrostatic pressure in the wellbore mitigating and even eliminating the need to force the plunger 112 toward the closed position. The forces required to move the plunger 112 from the closed position toward any intermediate position or a fully-open position are also very low. In some embodiments the required power is 10 watts or less. The power consumption is related to the flow rates and the pressure rating. For a lower pressure and flow rate configuration, the power can be as low as 5 watts. The balanced design allows for a greater amount of pressure to be held. In some embodiments, the pressure can be as high as 5,000 psi. The seals 122 can be made of a different material and configuration than the interface between the plunger 112 and the downhole side 118 of the plunger containment member 114, resulting in a differential force urging the plunger 112 in either direction, depending on the characteristics of the seals. The balanced design results in this resultant force being no greater than 50 pound-feet. In some embodiments the force is as much as 100 pound-feet, or as little as 20 pound-feet. Such an installation in a complex multi-zonal well installation as shown in the present disclosure was previously difficult and required power quantities greater than what was easily available.
Although a few embodiments of the disclosure have been described in detail above, those of ordinary skill in the art will readily appreciate that many modifications are possible without materially departing from the teachings of this disclosure. Accordingly, such modifications are intended to be included within the scope of this disclosure as defined in the claims.
Number | Date | Country | |
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62204732 | Aug 2015 | US |