In many well applications, a wellbore is drilled into a subterranean formation and subsequently completed with completion equipment to facilitate production of desired well fluids, e.g. oil and gas, from a reservoir. Sometimes the completion equipment includes tools which are actuated hydraulically via pressure applied downhole. The pressure actuation may involve moving a ball downhole along an interior of well tubing and into sealed engagement with a corresponding ball seat. This allows pressure to be increased along the interior of the tubing for performing desired functions, e.g. actuating a downhole device or conducting a cementing operation. However, when the ball is in a highly deviated section, e.g. a horizontal section, of the wellbore the ball may unseat if pressure uphole of the ball is bled off.
In general, a system and methodology are provided to facilitate pressure application downhole by locking a ball, e.g. a non-deformable ball, in place to prevent it from unseating even if the pressure is bled off. A ball seat is constructed with a locking feature for effectively capturing and retaining the ball once the ball is seated in the ball seat under sufficient pressure. According to an embodiment, the ball seat may be mounted at a desired position along an internal flow passage of a well string component. The ball seat comprises a throat section which is formed of a ductile material arranged in a suitable structure to enable a desired deformation upon receiving the ball under sufficient pressure. As the ball is pressed into the throat section, the material of the throat section deforms but also partially springs back to resist movement of the ball in the uphole direction, thus capturing the ball in both the uphole direction and the downhole direction.
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 claims.
Certain embodiments of the disclosure will hereafter be described with reference to the accompanying drawings, wherein like reference numerals denote like elements. It should be understood, however, that the accompanying figures illustrate the various implementations described herein and are not meant to limit the scope of various technologies described herein, and:
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 disclosure herein generally involves a system and methodology for facilitating pressure application downhole. In well applications, well strings may be deployed downhole into a borehole, e.g. a wellbore, with completion equipment and/or other downhole equipment. The downhole equipment may comprise various types of tools which are selectively actuated hydraulically via pressure applied downhole through the well string. Examples of such hydraulically actuated tools include sliding sleeve devices which may be in the form of stage cementing collar sleeves, circulation port sleeves, fracturing sleeves, and/or other hydraulically actuated devices.
The increased pressure applied to actuate the desired downhole device or devices may be enabled by locking a ball in sealed engagement with a ball seat to prevent it from unseating even if the pressure is bled off. According to an embodiment, the ball seat may be constructed with a locking feature for effectively capturing and retaining the ball once the ball is seated in the ball seat under sufficient pressure. The ball seat may be mounted at a desired position along an internal flow passage of a well string/well string component. Additionally, the ball seat may comprise a throat section which is formed of a ductile material arranged in a suitable structure to enable a desired deformation upon receiving the ball under sufficient pressure. The arrangement of structure and material enables use of a non-deformable ball without detrimentally affecting the locking capability of the ball seat. As the ball is pressed into the throat section, the material of the throat section deforms but also partially springs back to resist movement of the ball in the uphole direction. Consequently, the ball is captured via the ball seat and locked against movement in both the uphole direction and the downhole direction.
As described in greater detail below, the throat section of the ball seat may be mounted between a ball entrance portion and a base portion in some embodiments. The ball entrance portion may have a variety of configurations to help guide the ball into the throat section which is deformed as the ball is moved through the ball entrance portion and forced into the throat section. The throat section has a diameter less than the diameter of the ball. Due to the structure and deformability of the throat section, the ball may be formed of a non-deformable material, such as aluminum alloy, aluminum bronze, phenolic, or other suitable material.
A non-deformable ball may be considered a ball which compresses less than 2% in diameter (and in some embodiments less than 1%) as it is forced into the throat section under pressure applied down through the well string. It also should be noted that the terms “ball” or “non-deformable ball” are used broadly to refer to items able to block flow along an internal passage. References made herein to “ball” or “non-deformable ball” are meant to include many types of devices having a variety of shapes and configurations, e.g. partial balls, darts, and various other plugs which may seal against a ball seat.
Depending on the parameters of a given application, the throat section may be formed of a ductile material which plastically deforms as the ball is forced into the throat section. In other words, the throat section is forced into a radially outward, expanded configuration by the ball to an extent which plastically deforms the material of the throat section. However, the ductile material is selected with sufficient spring back so that a portion of the throat section on an uphole side of the ball effectively springs back after passage of the ball. The spring back allows this portion of the throat section to transition back to a smaller diameter and thus trap the ball between a reduced radius (relative to the ball radius) on both an uphole side and downhole side of the ball. Accordingly, pressure may be released uphole of the ball without concern that the ball will become unseated with respect to the ball seat even in highly deviated, e.g. horizontal, boreholes.
Examples of ductile material which may be used to construct the throat section include aluminum alloys or steel alloys selected to have appropriate plastic deformability and sufficient spring back to capture the ball. In some embodiments, the throat section may be made out of the same material as the ball entrance portion and the base portion. However, the overall ball seat may be formed with multiple materials, e.g. composite materials. Use of certain materials e.g. aluminum alloys, helps ensure that the ball seat is drillable so that it may be drilled out after its use is completed.
Referring generally to
Additionally, a ball seat 46 may be mounted in the well string 34 along the internal flow passage 44 within tubular section 40. By way of example, the ball seat 46 may be generally circular in cross-section extending about the interior of tubular section 40. In some embodiments, the ball seat 46 may comprise a ball entrance portion 48 having a sloped surface 50 which slopes radially inwardly from interior surface 42 and in a generally downhole direction. As illustrated, the ball seat 46 also may comprise a base portion 52. In the example illustrated, the base portion 52 securely mounts and seals the ball seat 46 to the tubular section 40. However, the ball entrance portion 48 and/or other portions of ball seat 46 may be used to secure the ball seat 46 to the tubular section 40.
Furthermore, the ball seat 46 may comprise a throat section 54 extending between the ball entrance portion 48 and the base portion 52. An interior surface 56 of the throat section 54 defines an internal throat passage 58 which has a diameter smaller than the diameter of interior surface 42 and smaller than the diameter of a ball used to block flow along internal flow passage 44, as explained in greater detail below. In some embodiments, the throat section 54 is constructed with a wall 60 which extends from ball entrance portion 48 to base portion 52 at a radially inward position from interior surface 42 so as to form a space 62 between the interior surface 42 and the throat section 54.
According to some examples, the throat section 54 may be constructed such that interior surface 56 is cylindrical. In other applications, however, the throat section 54 may be constructed such that interior surface 56 has other profiles. For example, the interior surface 56 may be constructed with a sloped profile which tapers to a smaller diameter in a downhole direction as indicated by angle 64. By way of example, the angle 64 may be less than 10°, e.g. in the range of 1-3°. It should be noted that throat section 54 may be constructed in a variety of configurations and may be utilized with various types of support structures, e.g. various types of base portions 52, and with various types of entrance portions 48. As explained in greater detail below, the throat section 54 is constructed to effectively serve as a locking feature which locks a ball in sealing engagement with the ball seat 46.
Referring generally to
As the ball 66 enters internal throat passage 58, flow along internal flow passage 44 is blocked so that the pressure uphole of ball 66 may be increased. The increased pressure is used to force ball 66 along internal throat passage 58 and into throat section 54 as illustrated in
By way of example, the pressure applied to shift ball 66 into throat section 54, as illustrated in
In the illustrated example, ball 66 is constructed from a non-deformable material and throat section 54 is constructed from a ductile material, e.g. an aluminum alloy, which deforms as ball 66 moves into throat section 54 to create a region of deformation 67 (see also
In various embodiments, the material of throat section 54 is selected to undergo plastic deformation as ball 66 is forced along internal throat passage 58 into throat section 54. The plastic deformation in, for example, deformation region 67 is useful in ensuring retention of the ball 66. However, the material of throat section 54 retains sufficient spring back to enable creation of uphole portion 68 after passage of ball 66, thus trapping the ball 66.
In a specific example, movement of a non-deformable ball 66 into throat section 54 causes radial expansion of the throat section wall 60 into space 62 to a sufficient degree that the material of throat section 54 undergoes plastic deformation. At the same time, however, the downhole portion 72 remains and the uphole portion 68 is created via the spring back of the throat material. Consequently, the ball 66 becomes trapped and effectively locked against movement downhole via portion 72 or uphole via portion 68 even when pressure in well string 34 is released. In some embodiments, the base portion 52 of ball seat 46 is formed as a non-expandable section having a smaller inside diameter than the diameter 70 of ball 66 so as to ensure downhole portion 72 remains to resist movement of ball 66 past the ball seat 46.
Referring generally to
With this type of throat section 54, the interior surface 56 may be constructed with a stepped profile 74 which has a plurality of steps 76 to establish appropriate diameters for capturing balls of different diameters. According to the example illustrated, the steps 76 are constructed to capture two differently sized balls 66, but additional steps 76 may be added for capturing additional balls 66. The plurality of differently sized balls 66 which may be seated enables a plurality of sequential pressure applications separated by flow through capability.
Accordingly, the throat section 54 may be constructed to enable application of sufficient pressure to force at least the initial ball through the ball seat 46 to enable flow along internal flow passage 44. Subsequently, the flow along passage 44 may again be blocked by dropping another ball 66 (a larger diameter ball) for engagement with a larger diameter step 76. Each step 76 is able to deform, e.g. plastically deform, and form its own deformation region 67 for locking in place the corresponding ball 66.
Referring generally to
In the illustrated example, however, the ball seat 46 is mounted to the sliding sleeve 80 along the interior of sliding sleeve 80. When ball 66 is seated and locked in throat section 54, pressure may be increased along the interior of the well string 34 to enable shifting of the sliding sleeve 80 in a downhole direction. The ball seat 46 and ball 66 are simply shifted along with the sliding sleeve 80. For example, the sliding sleeve 80 may be shifted from a closed position (see
Referring generally to
Referring generally to
Depending on the parameters of a given application, environment, and equipment utilized, the ball seat 46 may be used as part of various types of completion equipment or other downhole equipment. In a variety of applications, the ball seat 46 is constructed to plastically deform as a non-deformable ball 66 is forced into the ball seat throat section 54 while allowing sufficient spring back to capture the ball. This allows the use of a conventional, non-deformable ball 66. However, various other types of balls, including deformable balls, can be used with the ball seat 46 for at least some applications.
The ball seat 46 may be a fixed element in a tubular section, e.g. a liner, or it may be mounted as part of a sliding sleeve or other shiftable component. Additionally, the ball seat 46 may be constructed from various aluminum alloys, composite materials, and/or other materials which provide the capability for plastic deformation and sufficient spring back. The specific alloys/materials selected may vary depending on the environment in which the ball seat 46 is used, the type of corresponding equipment, and the pressures to be applied for a given operation
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 | Kind |
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20305260.0 | Mar 2020 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/US2021/021030 | 3/5/2021 | WO |