OA17794A - Autonomous flow control system and methodology - Google Patents
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- OA17794A OA17794A OA1201600076 OA17794A OA 17794 A OA17794 A OA 17794A OA 1201600076 OA1201600076 OA 1201600076 OA 17794 A OA17794 A OA 17794A
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- 230000004048 modification Effects 0.000 description 5
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- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 4
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Abstract
A technique facilitates regulation of flow through a flow control device to improve a well operation, such as a production operation. The technique utilizes a flow control device which has a valve positioned in a housing for movement between flow positions. The different flow positions allow different levels of flow through a primary flow port. At least one flow regulation element is used in cooperation with and in series with the valve to establish a differential pressure acting on the valve. The differential pressure is a function of fluid properties and is used to autonomously actuate the flow control device to an improved flow position.
Description
AUTONOMOUS FLOW CONTROL SYSTEM AND METHODOLOGY CROSS-REFERENCE TO RELATED APPLICATIONS
The présent document is based on and daims priority to U.S. Provisional Application Serial No.: 61/871,348, filed August 29, 2013, which is incorporated herein by reference in its entirety.
BACKGROUND
Hydrocarbon fluids such as oil and natural gas are obtained from a subterranean géologie formation, referred to as a réservoir, by drilling a well that pénétrâtes the hydrocarbon-bearing formation. Once a wellbore is drilled, various forms of well completion components, e.g. sand control Systems, may be installed in the well. In certain applications, inflow control devices are employed to create flow restrictions through the production tubing. The fluid flow through the inflow control device moves through a port with a fixed setting which provides a controlled pressure drop. However, réservoirs may produce with an unpredictable performance associated with variations in fluid properties that resuit from réservoir changes and fluid changes over time.
SUMMARY
In general, a system and methodology are provided for regulating flow through flow control devices to improve a well operation, such as a production operation. The technique utilizes a flow control device, e.g. an inflow control device, which has a valve positioned in a housing for movement between flow positions. The different flow positions allow different levels of flow through a primary flow port. At least one flow régulation element is used in coopération with the valve to establish a differential pressure acting on the valve. The differential pressure is a function of fluid properties and is used to autonomously actuate the flow control device to an improved flow position.
However, 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 daims.
BRIEF DESCRIPTION OF THE DRAWINGS
Certain embodiments ofthe disclosure will hereafter be described with reference to the accompanying drawings, wherein like reference numerals dénoté like éléments. It should be understood, however, that the accompanying figures illustrate the various implémentations described herein and are not meant to limit the scope of various technologies described herein, and:
Figure 1 is a schematic illustration of an example of a well system deployed in a wellbore and comprising at least one screen assembly in combination with a flow control device, according to an embodiment ofthe disclosure;
Figure 2 is a schematic illustration of an example of a flow control device operated autonomously based on establishing differential pressures associated with changes in fluid properties, according to an embodiment ofthe disclosure;
Figure 3 is a schematic illustration of another example of a flow control device, according to an embodiment ofthe disclosure;
Figure 4 is a schematic illustration similar to that of Figure 3 but showing the flow control device in a different operational position, according to an embodiment ofthe disclosure;
Figure 5 is a schematic illustration of another example of a flow control device, according to an embodiment ofthe disclosure;
Figure 6 is a schematic illustration similar to that of Figure 5 but showing the flow control device in a different operational position, according to an embodiment ofthe disclosure;
Figure 7 is a schematic illustration of another example of a flow control device, according to an embodiment ofthe disclosure;
Figure 8 is a schematic illustration of another example of a flow control device operated autonomously based on establishing differential pressures associated with changes in fluid properties, according to an embodiment of the disclosure; and
Figure 9 is a schematic illustration of another example of a flow control device, according to an embodiment of the disclosure.
DETAILED DESCRIPTION
In the following description, numerous details are setforth to provide an understanding of some embodiments of the présent 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 disclosure herein generally involves a system and methodology forfacilitating a flow control operation, such as a well production operation or a well injection operation. The system and methodology enable an autonomous régulation of flow through a flow control device or flow control devices during the life of the flow control operation. In well applications, the flow control device(s) may be employed to improve the overall well operation by autonomously regulating flow over time at spécifie well zones as fluid properties, flow rates, and differential pressures may change with time.
The technique utilizes a flow control device, e.g. an inflow control device, which has a valve positioned in a housing for movement between flow positions. The different flow positions allow different levels of flow through a primary flow port. At least one flow régulation element is used in coopération with the valve to establish a differential pressure acting on the valve. The differential pressure is a function of fluid properties and is used to autonomously actuate the flow control device to an improved flow position. In a well-related production operation, for example, a plurality of the flow control devices may be used as inflow control devices in coopération with a sand control system. However, the flow control devices may be used without sand control in various types of well Systems. In a sand control example, the sand control system may hâve a plurality of screen assemblies through which well fluid, e.g. oil, flows from a surrounding réservoir, into a wellbore, into the screen assemblies, through the flow control devices, and into a base pipe for production to a surface location or other desired location. However, the flow control devices also may be used for flow injection operations and other well related operations.
Because réservoir related flow performance can change over time or the réservoir may flow in an unexpected manner, the flow control devices described herein enable an autonomous adjustment ofthe flow rate at individual flow control devices to automatically improve performance ofthe overall system overthe life ofthe operation. With respectto production operations, the unpredictable performance of a given réservoir often is associated with variations in fluid properties resulting from changes in the réservoir and/or changes in the fluid itself over time.
In a spécifie example, a well completion system comprises a flow control device for regulating fluid flow in a vertical wellbore or a deviated wellbore, e.g. a horizontal wellbore. The well completion system may be used in production operations and/or injection operations. In such applications, the flow rate tends to be higher with respect to highly permeable zones of the réservoir. The flow control device comprises at least one autonomously operated valve used in coopération with a screen assembly of the well completion system. For example, the flow control device may be positioned beneath a filter media of the screen assembly at an end of the screen assembly. The autonomously operated valve is opérable within a flow control device housing having a primaryflow port coupled with a corresponding base pipe portthrough a base pipe ofthe well completion system. For example, the flow control device housing may be placed in communication with an interior ofthe base pipe through one or more holes, e.g. nozzles, extending through a wall ofthe base pipe.
The valve ofthe flow control device and thus the operational position ofthe flow control device may be regulated by a plurality of flow paths, e.g. two flow paths, which may hâve similar flow capacities. Based on fluid properties, a differential pressure is developed between the two flow paths even though the flow paths hâve similar flow capacities. The fluid flow moving along the flow paths is guided to the valve, and the valve is actuated to a desired position based on the differential pressure between the flow paths. Thus, the flow control device may be actuated autonomouslyto an improved position based on the fluid properties ofthe fluid flowing into the flow control device.
In some applications, the valve ofthe flow control device and thus the operational position ofthe flow control device also may be regulated by a single flow path. Based on fluid properties, a négative pressure may be developed at a given position in the flow path relative to both an inlet pressure and an outlet pressure. The fluid flow moving along the flow path is guided to the valve, and the valve is actuated to a desired position based on differential pressure between the given position in the flow path and either the inlet pressure or the outlet pressure. Thus, the flow control device may be actuated autonomously to an improved position based on the fluid properties ofthe fluid flowing into the flow control device.
Referring generally to Figure 1, an embodiment of a well completion system 20 is illustrated as comprising at least one and often a plurality of screen assemblies 22. The screen assemblies 22 individually comprise a filter media 24 disposed radially outward of a base pipe 26. For example, the filter media 24 may be in the form of a screen or mesh surrounding the base pipe 26. In this example, the well completion system 20 is disposed in a wellbore 28 of a well. The filter media 24 of each screen assembly 22 filters particulates from well fluid which flows into wellbore 28 from a surrounding formation and réservoir 30. In some applications, a gravel pack may be formed around the screen assemblies 22 to further filter particulates from the inflowing fluid. The well completion system 20 may be located in a deviated wellbore 28, e.g. a horizontal wellbore, located in the réservoir 30 for production of hydrocarbons fluids or other fluids.
As further illustrated in Figure 1, a flow control device 32 is used in coopération with the screen assembly 22. In some applications, at least one flow control device 32 may be used in coopération with each ofthe screen assemblies 22 ofthe well completion system 20. By way of example, theflow control device 32 may be positioned radially inward ofthe filtermedia 24 ofthe corresponding screen assembly 22. Additionally, the flow control device 32 may be used to control flow of fluid through a base pipe port 34 (or a plurality of base pipe ports 34) extending through a wall ofthe base pipe 26. Depending on whetherthe well operation is a production operation or an injection operation, the flow control device 32 may be used to control fluid flow into an interior 36 of the base pipe 26 orfluid flow out ofthe base pipe 26 to the surrounding formation 30.
Referring generally to Figure 2, a schematic représentation of an embodiment of flow control device 32 is illustrated. In this example, the flow control device 32 is an autonomous flow control device, e.g. an autonomous inflow control device, comprising at least one autonomously actuated valve. In various operations, the flow control device or devices 32 may be used in the well completion system 20 to regulate flux with respect to fluid flowing from the réservoir 30 or fluid being injected into the réservoir 30. The flow control device or devices 32 may be used to automatically change flow performance ofthe well completion system 20 as fluid properties change. For example, the flow control device or devices 32 may be configured to allow a higher flow rate of viscous oil versus restricting the flow rate of a less viscous fluid, such as water. In some applications, the flow control devices 32 may be configured to optimize a flow of oil versus gas and/or of gas or oil versus water.
The flow control device 32 comprises a set of flow régulation éléments which automatically change the flow performance based on fluid properties, e.g. different fluid properties resulting from different fluid types. The flow régulation éléments may comprise a wide variety of éléments having an effect on fluid flow through the flow control device so as to create a pressure differential in the flow control device which acts autonomously to actuate a flow control device valve. For example, the flow régulation éléments may be constructed to create laminar fluid flow through a thin tube if the fluid has high viscosity versus turbulent flow through a nozzle. When the fluid changes to a less viscous fluid, the flow régulation element créâtes a turbulent flow through the same thin tube. By combining two or more éléments like this, a differential pressure is created that can be used to actuate the valve ofthe flow control device 32 to a desired position.
Referring again to the example illustrated in Figure 2, the flow control device 32 may comprise a housing 38 having a flow channel 40. In production applications, fluid flowing into wellbore 28 and through filter media 24 enters the flow control device 32 through flow channel 40. The fluid, e.g. well fluid, flowing into housing 38 through flow channel 40 is split into a plurality of branches or flow paths 42 and 44 disposed in housing 38. In this example, fluid flowing along flow paths 42, 44 is directed through a plurality of flow régulation éléments 46, 48, 50, 52. However, other numbers of flow régulation éléments may be employed depending on the parameters of a given application. The flow régulation éléments 46, 48, 50, 52 may be selected from a variety of flow restricting éléments including tubes, nozzles, Venturi éléments, porous material, and/or other éléments which affect flow to establish the flow régulation element.
By selecting different types of flow régulation éléments, a différence in pressure occurs at locations 54 and 56 along the flow paths 42 and 44, respectively. In this example, the locations 54 and 56 are positioned between the first set of flow régulation éléments 46, 48 and the second set of flow régulation éléments 50, 52. This differential pressure can be transferred through pressure path segments 58, 60 to a valve 62 ofthe flow control device 32 so as to create a pressure differential which acts on the valve 62. The differential pressure shifts the valve 62 to a corresponding position which régulâtes a total flow of fluid passing along the flow paths 42, 44 to valve 62, through a valve port 64, and then exiting valve 62 through a primary flow port 66 positioned in housing 38. The valve 62 is connected in sériés with the flow paths 42 and 44. In this example, the flow control device 32 may be mounted on base pipe 26 at base pipe port 34 such that primary flow port 66 in housing 38 discharges fluid into and through base pipe port 34.
It should be noted the configuration and layout ofthe autonomous flow control device 32 illustrated in Figure 2 is provided as an example and other configurations and layouts may be used in various applications. For example, the valve 62 may be positioned at the entry to housing 38 or at a different locations along the flow paths 42, 44 through the flow control device 32. Additionally, some ofthe flow régulation éléments 46, 48, 50, 52 may be located at other positions and/or integrated into the flow regulating valve 62. Additionally, the flow control device 32 may be used in applications in which the fluid flow is reversed to enable injection operations or other well treatment operations.
The flow régulation éléments, e.g. flow régulation éléments 46, 48, 50, 52, may comprise a variety of features including tubes, nozzles, Venturi éléments, porous materials, and/or other features having different flow characteristics for different fiuids. For example, the different flow régulation éléments may each hâve a different Reynolds number. With respect to high Reynolds numbers, the flow tends to be more turbulent and the pressure drop dépends largely on fluid density and is proportional to velocity squared. For laminar fluid flow, the pressure drop is more dépendent on viscosity and is proportional to velocity. For the various flow régulation éléments 46, 48, 50, 52, the transition between turbulent and laminar flow behaves differently. Thus, the flow régulation éléments can be constructed to hâve a different Reynolds number for a given flow rate by adjusting flow régulation element related properties such as velocity and diameter. By way of example, the Reynolds number for a nozzle type flow régulation element can be modified by using several smaller nozzles in parallel or several larger nozzles in sériés instead of a single physical nozzle, thus providing different flow régulation éléments for a given, similar flow area along flow paths 42, 44. In another example, the flow régulation element 48 may comprise a long thin tube or a porous material and flow régulation element 52 may comprise a diffuser or Venturi type element. Various other types and arrangements of flow régulation éléments may be employed to create the desired pressure differential based on the different flow characteristics of a given fluid passing through the flow régulation éléments. The different types of flow régulation éléments disposed in flow control device 32 enable pressure differentials to be established so as to automatically actuate the valve 62 to a desired flow position.
Referring generally to Figures 3 and 4, another embodiment of flow control device 32 is illustrated. In this example, fluid flow, e.g. production fluid flow, again enters flow control device housing 38 via flow channel 40 and exits at primary flow port 66. However, the flow direction may be reversed for some applications such that fluid enters at port 66 and exits through flow channel 40. After entering the flow control device 32 through flow channel 40, the fluid is diverted into flow paths 42 and 44. In this example, fluid moving along flow path 42 is subjected to flow régulation element 46, which is in the form of a nozzle 68, and also to flow régulation element 50, which is in the form of a thin tube 70. The pressure path segment 58 extends from a location between the flow régulation éléments 46, 50 to one side of valve 62. The fluid moving along flow path 44 is subjected to flow régulation element 48, which is in the form of a thin tube 72, and also to flow régulation element 52, which is in the form of a nozzle 74. The pressure path segment 60 extends from a location between the flow régulation éléments 48, 52 to an opposite side of valve 62, as illustrated. In this example, the same types of flow régulation éléments are used along each flow path 42 and 44 but the types are positioned in an opposite order.
In the embodiment illustrated, the thin tubes 70, 72 and the nozzles 68, 74 are sized such that for viscous oil the tube 70 or 72 provides a higher pressure than the corresponding nozzle 68 or 74. This characteristic results because the flow in the thin tubes 70, 72 is mainly affected by fluid viscosity. As a resuit, a flow of viscous oil créâtes a higher pressure along segment 58 than along segment 60 and this differential pressure is transferred to the flow regulating valve 62. The differential pressure causes the valve 62 to be actuated to an appropriate valve position by moving a valve piston 76 toward, for example, a fully open position 78, as illustrated in Figure 3. The fully open position 78 allows maximum fluid flow through the valve 62 from valve port 64 and out through primary flow port 66 into base pipe 26 via base pipe port 34. In this example, the valve piston 76 may be equipped with seals 80 or with a gap having sufficiently narrow tolérances which ensure minimal leakage flow past piston 76.
Referring again to Figure 4, in the case of a low viscosity fluid entering the flow control device 32 via flow channel 40, the tube pressure drop along thin tubes 70, 72 is less. As a resuit, a different pressure balance in the control segments 58, 60 occurs. In fact, the flow of low viscosity fluid, e.g. water, through flow control device 32 créâtes a higher pressure along control segment 60 than along control segment 58 and this differential pressure is transferred to the flow regulating valve 62. This differential pressure causes the valve 62 to be actuated to an appropriate valve position by moving the valve piston 76 toward a choked position 82, e.g. a restricted flow or no flow position, as illustrated in Figure 4. The choked position 82 blocks or reduces fluid flow through the valve 62 from valve port 64 and out through primary flow port 66.
Referring generally to Figures 5 and 6, another embodiment of flow control device 32 is illustrated. In this example, fluid flow, e.g. production fluid flow, enters flow control device housing 38 from a région 84. By way of example, région 84 may be a région adjacent the flow control device 32 and between the base pipe 26 and the filter media 24 of a given screen assembly 22. In this embodiment, the fluid flows from région 84 and moves through flow control device 32 before exiting at primary flow port 66. However, the flow direction may be reversed for some applications, e.g. injection applications, such that fluid enters at port 66 and exits into région 84.
Fluid flowing from réservoir 30 moves through filter media 24 and into région 84. The flow is then diverted into the two flow paths 42 and 44. In this embodiment, flow régulation element 46 is in the form of a tube element 86 and flow régulation element 48 is in the form of a nozzle 88. The tube element 86 tends to be more dominated by a pressure drop than nozzle 88 when a viscous fluid is flowing along flow paths 42, 44.
In this embodiment, the flow paths 42, 44 continue to valve 62 to deliver fluid to the valve 62 and the actuation position of valve 62 is regulated by a différence in pressure at pressure path segments 58 and 60 as a resuit ofthe fluid flow through the first set of flow régulation éléments 46 and 48. In this example, the flow regulating valve 62 has the second set of flow regulating éléments 50, 52 formed into valve piston 76 in the form of flow ports 90, 92, respectively. The flow ports 90, 92 extend to an interior94 ofthe piston 76. The fluid flow along the two flow paths 42, 44 meets at piston interior 94 before exiting through a piston port 96 and flowing out through primary flow port 66 of housing 38 before entering interior 36 of base pipe 26 via base pipe port 34.
lf a fluid with different properties, e.g. less viscous water as compared to viscous oil, flows to région 84 and into flow paths 42, 44, the flow régulation éléments 46, 48, 50, 52 establish a different pressure differential acting on piston 76 of valve 62. In this example, the piston 76 is shifted to a choked flow position, as illustrated in Figure 6. The movement of piston 76 restricts or blocks the flow of fluid exiting piston interior 94 through piston port 96 and thus chokes off the flow of fluid to base pipe interior 36 via base pipe port 34.
Referring generally to Figure 7, another embodiment of flow control device 32 is illustrated. In this example, fluid flow, e.g. production fluid flow, again enters flow control device housing 38 via flow channel 40 and exits at primary flow port 66. As discussed above, the flow direction may be reversed for some applications such that fluid enters at port 66 and exits through flow channel 40. After entering the flow control device 32 through flow channel 40, the fluid is diverted into flow paths and 44. In this example, fluid moving along flow path 42 is subjected to flow régulation element 46, which is in the form of nozzle 68, and also to flow régulation element 50, which is in the form of thin tube 70. The pressure path segment 58 extends from a location between the flow régulation éléments 46, 50 to one side of valve 62. The fluid moving along flow path 44 is subjected to flow régulation element 48, which is in the form of thin tube 72, and also to flow régulation element 52, which is in the form of a diffuser 98. The pressure path segment 60 extends from a location joining thin tube 72 and is routed to an opposite side of valve 62, as illustrated. In this example, the flow régulation éléments 48 and 52 could be considered cooperating features of a single flow régulation element. In some applications, an additional flow régulation element 100, e.g. a nozzle or other io suitable flow régulation element, may be placed in the flow path directing fluid through valve port 64.
Similarto the embodiments discussed above, the flow régulation éléments 46, 48, 50, 52 establish a differential pressure at locations 54, 56 as a function of fluid properties. This differential 15 pressure acts on valve 62 to autonomously actuate the valve 62 and thus the flow control device 32 to an improved flow position based on the fluid properties of fluid flowing through the flow control device 32.
Referring generally to Figure 8, a schematic représentation of another embodiment of flow control device 32 is illustrated. In this embodiment, fluid enters flow control device 32 via flow channel 40 and flows through a flow régulation element 102, which may be in the form of a Venturi element 104, connected in sériés with valve 62. Pressure path segment 58 may be connected between valve 62 and the Venturi element 104 at, for example, the point of its smallest crosssectional area or relatively close to this point of smallest cross-sectional area. The pressure path segment 60 may be connected between an opposite side of valve 62 and a région along a flow path 106 between Venturi element 104 and valve 62. In another layout, the pressure path segment, e.g. pressure path segment 60, may be connected to the primary flow port 66.
When fluid of relatively low viscosity or relatively high Reynolds number flows into flow channel 40 and through Venturi element 104, the pressure along pressure path segment 58 tends to be less than both the inlet and exit pressures of the Venturi element 104. However, when fluid of relatively high viscosity or lower Reynolds number flows into channel 40 and through Venturi element 104, the pressure along pressure path segment 58 will not be less than at least the exit pressure of the Venturi element 104. The exit pressure (or in some cases the inlet pressure) is applied to the opposite side of valve 62 via pressure path segment 60. Thus, the variation or différence in pressure in pressure path segment 58 versus the outlet pressure in pressure path segment 60 can be used to autonomously regulate the valve position of valve 62 based on changes in the viscosity (or other characteristic) of fluid flowing through the flow control device 32.
Referring generally to Figure 9, an embodiment of flow control device 32 is illustrated in which the flow régulation element 102 comprises Venturi element 104 and valve 62 utilizes valve piston 76. In this example, the fluid entering into flow channel 40 flows into a smooth entry région 108 of Venturi element 104 which increases the velocity of the fluid. As a resuit of the Bernoulli effect, a réduction in pressure is achieved in a reduced cross-sectional area région 110, e.g. the région of smallest cross-sectional area, of the Venturi element 104. A diffuser région 112 of Venturi element 104 helps regain kinetic energy ofthe flowing fluid and, as a resuit, the pressure increases in this région. In this example, pressure path segment 58 is connected between reduced crosssectional area région 110 and one side of piston 76 of valve 62. The other pressure path segment 60 is connected between diffuser région 112 and the other side of piston 76 of valve 62.
In the case of a more viscous fluid flowing through flow control device 32, the viscous frictional pressure loss tends to dominate over the Bernoulli effect, thus resulting in a shift in differential pressure acting on piston 76 across valve 62. The Venturi element 104 is constructed to create a desired shift in differential pressure as the type of fluid flowing through flow control device 32 changes, e.g. as fluid flow changes from desired to undesired fluids or vice versa. In some applications, the Venturi element 104 may be constructed in a manner which deviates from conventional design rules which tend to optimize certain functions ofthe Venturi for conventional applications. In some applications, for example, the Venturi element 104 may be constructed with a sharper corner or corners 114 at the Venturi entrance. In some applications, the inlet tube section leading into the Venturi may be longer and the diffuser région 112 may hâve various features, e.g. sudden diameter changes in outlet diameterto create a rapid expansion ofthe fluid flow area. These features may be selected to enable création of desired differential pressures based on the different fluid types flowing through the flow control device 32.
The well completion system 20 may be used in a variety of applications, including numerous types of well production applications and injection applications. Depending on the spécifies of a given well application and environment, the construction of the overall completion system 20, and the construction, number, and configuration of screen assemblies 22 and flow control devices 32 may vary. For example, various numbers of screen assemblies 22 may be employed and one or more flow control devices 32 may be used with the individual screen assemblies. Additionally, the system 20 may be designed for use in many types of wells, e.g. horizontal wells and other types of deviated wells. The wells may be drilled in a variety of formations with single or multiple production zones and with many types of gravel packs. The wells also may be drilled as open hole wellbores used in combination with annular packers.
Depending on the application, many types of flow control devices 32 may be employed in the overall system 20. For example, the flow control devices 32 may be constructed as inflow control devices for controlling the inflow of production fluid and/or other well fluid. However, the flow control devices 32 also may be constructed to accommodate outflow of fluid during, for w example, fluid injection operations. Additionally, the individual flow control devices 32 may hâve various types of housings, passages, pistons, and flow régulation éléments arranged to regulate flow based on differential pressures established as a resuit of the different fluid properties of fluid flowing through the individual flow control devices 32. Additionally, many types and arrangements of flow régulation éléments may be employed to establish the changing pressure differential according to the changing properties of fluids flowing through the flow control device 32. Similarly, various materials may be used in constructing the flow control device housing, piston, and/or other features and éléments of the flow control devices.
Although a few embodiments of the disclosure hâve been described in detail above, those 20 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.
Claims (20)
- What is claimed is:1. A system for controlling flow, comprising:a completion system deployed in a wellbore, the completion system comprising an autonomous flow control device to regulate fluid flow through a port, the autonomous flow control device comprising:a housing having at least one flow path;a valve disposed in the housing and exposed to the at least one flow path such that the valve is connected in sériés with the at least one flow path; and a flow régulation element disposed along the at least one flow path, the flow régulation element establishing a differential pressure as a function of fluid properties of a fluid flowing along the at least one flow path, the differential pressure being used to actuate the valve to regulate the fluid flow through the port.
- 2. The system as recited in claim 1, wherein the flow régulation element comprises a plurality offlow régulation éléments and at least one ofthe flow régulation éléments comprises a thin tube or a porous element.
- 3. The system as recited in claim 1, wherein the flow régulation element comprises a plurality offlow régulation éléments and at least one ofthe flow régulation éléments comprises a nozzle or an orifice.
- 4. The system as recited in claim 1, wherein the flow régulation element comprises a Venturi element.
- 5. The system as recited in claim 1, wherein the flow régulation element comprises a plurality offlow régulation éléments and at least one ofthe flow régulation éléments comprises a Venturi element.
- 6. The system as recited in claim 1, wherein the flow régulation element comprises a plurality of flow régulation éléments which include a combination of thin tubes and nozzles.
- 7. The system as recited in claim 1, wherein the completion system comprises at least one screen assembly having a base pipe and a filter media positioned radially outward of the base pipe, the port being disposed through a wall of the base pipe, further wherein the at least one flow path comprises a plurality of flow paths and the flow régulation element comprises a plurality of flow régulation éléments disposed along the plurality of flow paths.
- 8. The system as recited in claim 1, wherein the valve comprises a piston and the flow régulation element comprises a plurality of flow régulation éléments with at least some of the flow régulation éléments disposed on the piston.
- 9. The system as recited in claim 7, wherein the flow control device is positioned between the filter media and the base pipe.
- 10. A device for controlling flow, comprising:a housing having a primary flow port;a valve positioned in the housing to control a fluid flow through the primary flow port; a flow path in communication with the valve such that the valve is connected in sériés with the flow path; and a flow régulation element positioned along the flow path, the flow régulation element establishing a differential pressure acting on the valve, the differential pressure being a function of fluid properties of a fluid flowing along the flow path, the differential pressure being used to autonomously actuate the valve to regulate fluid flow through the primary flow port.
- 11. The device as recited in claim 10, wherein the flow régulation element comprises a plurality of flow regulating éléments which include a combination of different types of flow régulation éléments.
- 12. The device as recited in claim 11, wherein the valve comprises a valve piston which is shifted by the differential pressure to control fluid flow through the primary flow port.
- 13. The device as recited in claim 12, wherein the valve piston comprises at least some flow régulation éléments of the plurality of flow régulation éléments.
- 14. The device as recited in claim 13, wherein the flow régulation éléments ofthe valve piston restrictflow along the plurality of flow paths as the fluid flow moves to an interior ofthe valve piston.
- 15. The device as recited in claim 11, wherein the plurality of flow régulation éléments comprises a tube element, a nozzle, and a pair of flow ports.
- 16. The device as recited in claim 10, wherein the flow régulation element comprises a Venturi element.
- 17. A method for controlling flow, comprising:positioning a valve in a housing such that the valve is shiftable between flow positions which allow different levels of flow through a primary flow port; and using a flow régulation element to establish a differential pressure acting on the valve as a function of fluid properties of a fluid flowing into the housing, the valve being actuated to a flow position based on the differential pressure.
- 18. The method as recited in claim 17, wherein using the flow régulation element comprises using four flow régulation éléments.
- 19. The method as recited in claim 17, wherein using the flow régulation element comprises using different types of flow régulation éléments which restrict flow differently depending on the viscosity of the fluid flowing through the flow régulation éléments.
- 20. The method as recited in claim 17, further comprising mounting the housing in a screen assembly of a sand control completion to regulate flow of fluids to an interior of a base pipe ofthe sand control completion.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US61/871,348 | 2013-08-29 |
Publications (1)
Publication Number | Publication Date |
---|---|
OA17794A true OA17794A (en) | 2017-12-18 |
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