1. Field of the Disclosure
The disclosure relates generally to apparatus and methods for control of fluid flow from subterranean formations into a production string in a wellbore.
2. Description of the Related Art
Hydrocarbons such as oil and gas are recovered from a subterranean formation using a well or wellbore drilled into the formation. In some cases the wellbore is completed by placing a casing along the wellbore length and perforating the casing adjacent each production zone (hydrocarbon bearing zone) to extract fluids (such as oil and gas) from such a production zone. In other cases, the wellbore may be open hole. One or more inflow control devices are placed in the wellbore to control the flow of fluids into the wellbore. These flow control devices and production zones are generally separated from each other by installing a packer between them. Fluid from each production zone entering the wellbore is drawn into a tubing that runs to the surface. It is desirable to have a substantially even flow of fluid along the production zone. Uneven drainage may result in undesirable conditions such as invasion of a gas cone or water cone. In the instance of an oil-producing well, for example, a gas cone may cause an in-flow of gas into the wellbore that could significantly reduce oil production. In like fashion, a water cone may cause an in-flow of water into the oil production flow that reduces the amount and quality of the produced oil.
A deviated or horizontal wellbore is often drilled into a production zone to extract fluid therefrom. Several inflow control devices are placed spaced apart along such a wellbore to drain formation fluid or to inject a fluid into the formation. Formation fluid often contains a layer of oil, a layer of water below the oil and a layer of gas above the oil. For production wells, the horizontal wellbore is typically placed above the water layer. The boundary layers of oil, water and gas may not be even along the entire length of the horizontal well. Also, certain properties of the formation, such as porosity and permeability, may not be the same along the well length. Therefore, fluid between the formation and the wellbore may not flow evenly through the inflow control devices. For production wellbores, it is desirable to have a relatively even flow of the production fluid into the wellbore and also to inhibit the flow of water and gas through each inflow control device. Active flow control devices have been used to control the fluid from the formation into the wellbores. Such devices are relatively expensive and include moving parts, which require maintenance and may not be very reliable over the life of the wellbore. Passive inflow control devices (“ICDs”) that are able to restrict flow of water and gas into the wellbore are therefore desirable.
The disclosure herein provides passive ICDs that in one aspect restrict the flow of fluids having undesired viscosities or densities and in another aspect maintain a substantially constant flow of fluids having desired viscosities or densities.
In one aspect, the disclosure provides a flow control device for controlling flow of a fluid between a formation and a wellbore. The flow control device in one embodiment may include an inflow region, a flow-through region and an outflow region, wherein the flow-through region is configured to substantially increase pressure drop when viscosity or density of the fluid is in a first range and maintain a substantially constant pressure drop when the viscosity or density of the fluid is in a second. In another embodiment, the flow-through region may include a structural flow area, an inflow opening and an outflow opening, wherein the structural flow area, a fluid flow path in the structural flow area, tortuosity of the fluid flow path and size of the outflow opening are selected so that values of pressure loss coefficient (“K”) are substantially higher for fluids having Reynolds number (“Re)” in a first range compared to fluids having Re in a second range.
In another aspect, a method of making a flow control device for use in a wellbore for controlling flow of a fluid from a formation into the wellbore is provided. The method, in one embodiment, may include: defining a flow rate for the fluid inflow control device; selecting a geometry for a flow-through region of the flow control device sufficient to cause a pressure drop across the flow-through region that is substantially greater for fluids having viscosity or density in a first range compared to fluids having viscosity or density in a second range for the defined flow rate; and forming the flow control device having the selected geometry.
In yet another aspect, the disclosure herein provides a computer-readable medium, accessible to a processor, having embedded thereon a computer program for executing instructions contained in the computer program, the computer program including: (a) instructions to access a flow rate for a flow control device; (b) instructions to access a first geometry for a flow-through region of the flow control device formed on a tubular member, the flow-through region including an inlet, an outlet and a tortuous path between the inlet and the outlet configured to induce turbulence in the flow of the fluid between the inlet and the outlet sufficient to reduce an effective flow area of the outlet to cause a pressure drop across the outlet that is substantially greater for fluids having viscosity or density in a first range compared to fluids having viscosity or density in a second range for the defined flow rate; instructions to compute pressure drops across the outlet based on the first geometry corresponding to a plurality of fluid viscosities or fluid densities; (c) instructions to determine if the computed pressure drops are acceptable; (d) instructions to selected a different geometry when the computed pressure drops are not acceptable and repeating (b) and (c) using the different geometry until the pressure drops are acceptable; and (e) storing the geometry for which the pressure drops are acceptable.
Examples of the more important features of the disclosure have been summarized rather broadly in order that detailed description thereof that follows may be better understood, and in order that the contributions to the art may be appreciated. There are, of course, additional features of the disclosure that will be described hereinafter and which will form the subject of the claims appended hereto.
The advantages and further aspects of the disclosure will be readily appreciated by those of ordinary skill in the art as the same becomes better understood by reference to the following detailed description when considered in conjunction with the accompanying drawings, in which like reference characters designate like or similar elements throughout the several figures of the drawing, and wherein:
The present disclosure relates to apparatus and methods for controlling flow of formation fluids in a well. The present disclosure provides certain drawings and describes certain embodiments of the apparatus and methods, which are to be considered exemplification of the principles described herein and are not intended to limit the disclosure to the illustrated and described embodiments.
Referring initially to
Each production device 134 features a production control device (or flow control device) 138 used to govern one or more aspects of flow of one or more fluids from the production zones into the production string 120. As used herein, the term “fluid” or “fluids” includes liquids, gases, hydrocarbons, multi-phase fluids, mixtures of two of more fluids, water and fluids injected from the surface, such as water. Additionally, references to water should be construed to also include water-based fluids; e.g., brine or salt water. In accordance with embodiments of the present disclosure, the flow control device 138 may have a number of alternative structural features that provide selective operation and controlled fluid flow therethrough.
Subsurface formations typically contain water or brine along with oil and gas. Water may be present below an oil-bearing zone and gas may be present above such a zone. A horizontal wellbore, such as section 110b, is typically drilled through a production zone, such as production zone 116, and may extend to more than 5,000 feet in length. Once the wellbore has been in production for a period of time, water flow into some of the flow control devices 138. The amount and timing of water inflow can vary along the length of the production zone. It is desirable to have flow control devices that will restrict the flow of fluids when a selected amount of water is present in the production fluid. In an aspect, by restricting the flow of production fluid containing water, the flow control device enables more oil to be produced over the production life of the production zone.
Still referring to
Re=Inertia forces/viscous force
Re=(ρ·V·dv/dx)/μ·d2v/dx2
Re=ρVD/μ, wherein
ρ is density of the fluid, V is flow volume, v is the fluid velocity, D is a dimension of the flow area, such as diameter of an opening, and μ is the viscosity of the fluid. The Reynolds number for low viscosity fluids, such as water is relatively high compared to the high viscosity fluids, such as oils. Therefore, Re may also be expressed as:
Re=f(density, viscosity, fluid velocity and surface dimension(s))
Pressure drop Dp across a flow area A may be expressed as:
Dp=K·(ρ/A2)·v2,
where A is the flow area. The pressure loss coefficient K is a function of Reynolds number Re (K=f (Re)). The inventors have determined that K also is a function of the geometry of the flow path of the fluid through the flow control device and in particular the tortuosity of the flow path within the flow control device, and that therefore inducing turbulence in the flow of a fluid affects the pressure drop of fluids of different viscosities, as described in more detail later. The pressure loss coefficient K may be expressed as:
K=f(Re, opening size, tortuosity).
Graph 300 shows demonstrates that it is desirable to have a flow control device that exhibits a high value of pressure loss coefficient K for fluids with a Reynolds number higher than the Reynolds number for water 301, as shown by the curve segment 302. Graph 300 also shows that it desirable to have a relatively constant pressure loss coefficient K for Reynolds numbers less than the Reynolds number for water 301, as shown by the curve segment 306. The overall behavior of a fluid through an ICD depends upon the rheology of the fluid. Rheology is a function of several parameters, including, but not limited to, flow area, tortuosity, friction, fluid velocity, fluid viscosity and fluid density. In aspects, rheology parameters may be calculated or assumed to provide flow control devices that will inhibit water flow. The disclosure herein utilizes fluid rheology principles and other factors noted above to provide flow control devices that inhibit flow of fluids with viscosity or density in one range and allow a substantially constant flow of fluids with viscosity or density in another range. Exemplary flow control devices and methods of making such devices are described in reference to
Referring now to
In aspects, the first stage 530a may have a width or axial flow distance x1 and a height or radial distance y1. The offset or misalignment between the inlet port 532a and the outlet port 532b for stage 530a is denoted by h1. Similarly, the axial flow distance, radial distance, and outlet ports for subsequent stages 530b and 530c are respectively denoted by x2, h2 and d3, and x3, h3 and d4. The fluid path through such stages is denoted by Fp1, Fp2 and Fp3. The first substantial pressure drop Dp1 occurs at the port 532a. The fluid 501 then flows along a tortuous path Fpi and exits through port 532b. The second pressure drop Δp2 occurs at port 532b. Similarly, subsequent pressure drops occur at ports 532c and 532d. In an embodiment, the majority of the pressure drops occur at the ports. The pressure drop across the device 500 is approximately the sum of the pressure drops at each stage, namely Δp1, Δp2 and Δp3. As noted earlier, for a given fluid type (viscosity, density, etc.) and a flow rate, the pressure drop depends upon the flow areas, tortuosity of flow path, etc. In one aspect, each stage in the flow control device 500 may have same physical dimensions. In another aspect, the radial distance, port offset and port size may be chosen to provide a desired tortuosity so that the pressure drop will be a function of the fluid viscosity or density. In other aspect, the dimension of such stages may be different. It has been determined that an flow control device made according to the aspects shown in
Still referring to
In embodiments, the channel 920a may be arranged as a maze or labyrinth structure that forms a tortuous or circuitous flow path for the fluid flowing therethrough. In one embodiment, each stage 932a-932d of channel 922a may respectively include a chamber 942a-942d. Openings 944a-944d hydraulically connect chambers 942a-942d in a serial fashion. In the exemplary configuration of channel 920a, formation fluid enters into the inflow region 910 and discharges into the first chamber 942a via port or opening 944a. The fluid then travels along a tortuous path 952a and discharges into the second chamber 942b via port 944b and so on. Each of the ports 944a-944d exhibit a certain pressure drop across the port that is function of the configuration of the chambers on each side of the port, the offset between the ports associated therewith and the size of each port. The stage configuration and structure within determines the tortuosity and friction of the fluid flow in each particular chamber, as described herein. Different stages in a particular channel may be configured to provide different pressure drops. The chambers may be configured in any desired configuration based on the principles, methods and other embodiments described herein.
Additionally, in embodiments, some or all of the surfaces of the channels 920a-920d may be constructed to have a specific frictional resistance to flow. In some embodiments, the friction may be increased using textures, roughened surfaces, or other such surface features. Alternatively, friction may be reduced by using polished or smoothed surfaces. In embodiments, the surfaces may be coated with a material that increases or decreases surface friction. Moreover, the coating may be configured to vary the friction based on the nature of the flowing material (e.g., water or oil). For example, the surface may be coated with a hydrophilic material that absorbs water to increase frictional resistance to water flow or a hydrophobic material that repels water to decrease frictional resistance to water flow.
In another aspect, the disclosure herein provides a method of determining the configuration of one or more flow channels for inflow devices that may provide substantially high pressure drop for fluids having viscosities or densities in a first range compared to the pressure drop for fluids having viscosities or densities in a second range. A set of fluid parameters is defined for a particular application, which parameters may include the flow rate or bulk volume desired for the inflow device, fluid viscosity and/or density ranges, etc. An initial set of parameters for an inflow device may then be selected or defined, which parameters, for example, may include one or more of: number of stages, surface area for each stage, stage geometries, offset between flow ports, axial travel distance for the fluid in each stage, angle of bend for the flow path, curvature of the flow paths, etc. A behavior of pressure drop versus viscosity of the fluid flowing through the specified ICD is determined using a computer system and a simulation model. The simulation may also be performed to provide pressure drops through each stage, fluid flow velocity patterns, reduction in effective flow areas along the fluid paths, etc. The results of the simulated or calculated pressure drops for different ranges of viscosities or densities may be compared to desired pressure drops. If the results differ more than an acceptable value, one or more initial parameters for the flow control device are altered and the simulation process repeated. This iterative process may be continued using new values of one or more inflow device parameters until a satisfactory pressure drop relationship is obtained. Alternatively, the relation ship between Reynolds number (Re) and coefficient of friction (K) may be determined at end of each simulation run to determine an inflow device configuration that will provide higher pressure drop for unwanted fluids, such as water, and a relatively constant pressure or laminar flow for certain other fluids, such as oils. The amount of turbulence induced along the fluid path in the inflow device, reduction in the effective flow areas along at ports or along bends, etc may be determined from flow velocity patterns and utilized to select parameters of the inflow device prior to each simulation run. The exemplary channels for flow control devices are described herein as axially placed channels in a tubular. However, such and other channels made according the teachings herein may be placed radially, helically or along any other angle. Additionally, such flow control devices may utilize different types of channels in a single device.
Thus, in one aspect, the disclosure herein provides an apparatus for controlling flow of fluid between a reservoir and a wellbore, which apparatus in one embodiment may include a flow-through region configured to substantially increase value of a selected parameter relating to the flow flow-through region when a selected property of the fluid is in a first range and maintain a substantially constant value of the selected parameter when the selected property of the fluid is in a second range.
In another aspect, the flow control device may include a flow-through region configured to substantially increase pressure drop across the flow-through region when a selected property of the fluid is in a first range and maintain a substantially constant pressure drop across the flow-through region when the selected property of the fluid is in a second range.
In another embodiment, the flow control device may include an inflow region, a flow-through and an outflow region, wherein the flow-through region is configured to substantially increase pressure drop when viscosity or density of the fluid is in a first range and maintain a substantially constant pressure drop when the viscosity or density of the fluid is in a second range. In one aspect, the first range may include viscosities less than 10 cP and the second range may include viscosities above 10 cP. Alternatively, the first range may include densities more than 8.33 lbs per gallon and the second range include densities less than 8.33 lbs per gallon. In one aspect, the flow-through region may be configured to induce selected amounts of turbulences in fluids having viscosities or densities in the first range to provide a desired pressure drop across the flow-through region for a given fluid flow rate through flow-through area. In another aspect, the flow-through region may include a structural area configured to receive the fluid via a first port and discharge the received fluid via a second port having a dimension “d”, the structural area having an axial distance “x”, there being an offset “h” between the first port and the second port. In one embodiment, h may be between 4 to 6 times d. In another embodiment h/x is greater than d/h. In another embodiment, the flow-through region may be configured to include a tortuous path.
In anther aspect, the disclosure provides a flow control device that may include: a flow-through region including a structural flow area, an inflow opening and an outflow opening, wherein the structural flow area, a fluid flow path in the structural flow area between the inflow opening and the outflow opening, tortuosity of the fluid flow path and size of the outflow opening are selected so that value of a fluid performance co-efficient (“K”) is substantially greater for fluids having low Reynolds number (“Re)” in a first range compared to fluids having high Re in a second range.
In another aspect, a method is provided that may include: defining a flow rate for the fluid flow-through the inflow control device; selecting a geometry for the flow-through region formed on a tubular member, the flow-through region including an inlet, an outlet and a flow path between the inlet and the outlet configured to induce turbulence in the flow of the fluid between the inlet and the outlet sufficient to reduce an effective flow area through the outlet to cause a pressure drop across the outlet that is substantially greater for fluids having viscosity or density in a first range compared to fluids having a viscosity or density in a second range for the defined flow rate; and forming the tubular member having the selected geometry.
In yet another aspect, a computer-readable medium is provided that is accessible to a processor for executing instruction in a program embedded in the computer-readable medium, which program may include: (a) instructions to access a flow rate for a fluid flow control device; (b) instructions to access a first geometry for a flow-through region of the inflow control device formed on a tubular member, the flow-through section including an inlet, an outlet and a tortuous path between the inlet and the outlet configured to induce turbulence in the flow of the fluid between the inlet and the outlet sufficient to reduce the effective flow area through the outlet to cause a pressure drop across the outlet that is substantially greater for fluids having viscosity or density in a first range compared to fluids having a viscosity or density in a second range for the defined flow rate; (c) instructions to compute pressure drops across the outlet based on the first geometry corresponding to a plurality of fluid viscosities or fluid densities; (d) instructions to compare the computed pressure drops corresponding to the first range and the second range to desired values; (e) instructions to repeat steps c and d using one or more additional geometries until the computed pressure drops are within acceptable values; and (e) instructions to store a geometry having pressure drops that meet the desired values.
It should be understood that
This application takes priority from U.S. Provisional Application Ser. No. 61/248,346, filed on Oct. 2, 2009.
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