This disclosure relates to multilateral well access systems and associated methods of performing an intervention operation at a multilateral well.
Multilateral well completions can allow for maximum reservoir contact with minimum drilling costs and reduced surface location requirements. For example, multilateral wells may offer higher production indices, the possibility of draining relatively thin formation layers, decreased well requirements, and better sweep efficiencies. Conventionally, through-tubing intervention into laterals may be achieved through a dedicated completion system installed during a drilling phase or through a re-entry guide and an access bottom hole assembly with features for locating a target lateral.
This disclosure relates to a multilateral well access system and a method of performing an intervention operation at a multilateral well using the system. The system includes multiple directional guides and multiple cooperating surface profiles positioned at respective target branches of a multilateral well. Each directional guide includes an upper guide surface that is formed to deflect an intervention tool into a target branch and includes a bypass port that is sized to allow through passage of the intervention tool. Each directional guide also has an exterior key that is formed complementary to the cooperating surface profile to ensure correct positioning of the directional guide at the surface profile. The bypass port may be plugged to prevent the intervention tool from passing through to a lower branch located more deeply within the multilateral well and to ensure that the intervention tool enters the branch located adjacent the directional guide. The bypass port may also be in an open state to allow the intervention tool to pass through the directional guide to access a lower branch.
In one aspect, a multilateral well access system includes a directional guide and a mating surface profile. The directional guide includes a main body and an outer surface profile disposed on the main body. The main body defines a guide surface oriented non-parallelly to an elongate axis of the main body and a bore passing through the main body along the elongate axis. The mating surface profile is formed complementary to the outer surface profile of the directional guide and is engaged with the outer surface profile to secure the directional guide in a fixed position.
Embodiments may provide one or more of the following features.
In some embodiments, the main body has a tapered shape.
In some embodiments, the guide surface is orientated at an obtuse angle with respect to the elongate axis.
In some embodiments, the outer surface profile is positioned on opposite sides of the main body, and the inner surface profile is positioned on the opposite sides of the main body.
In some embodiments, the multilateral well access system further includes a plug that is sized to be positioned within the bore to close the bore.
In some embodiments, the main body defines a landing seat that extends within the bore to prevent through passage of the plug.
In some embodiments, the multilateral well access system further includes an entry guide that is sized to be positioned within the bore to direct a tool into the bore.
In some embodiments, the entry guide includes a tapered portion.
In some embodiments, the directional guide further includes an attraction device for attracting a tool to the bore.
In some embodiments, the attraction device includes one or both of a magnet and an electronic device.
In some embodiments, the directional guide further includes a detection device for detecting the presence of a tool within the bore.
In some embodiments, the detection devices includes an electronic sensor.
In some embodiments, the directional guide further includes a high-pressure seal that surrounds the main body.
In some embodiments, the mating surface profile is arranged on a casing that surrounds the directional guide.
In some embodiments, the directional guide is a first directional guide, the main body is a first main body, the guide surface is a first guide surface, the bore is a first bore having a first diameter, the outer surface profile is a first outer profile, the mating surface profile is a first mating surface profile, the fixed position is a first fixed position, and the multilateral well access system further includes a second directional guide and a second mating surface profile. The second directional guide includes a second main body and a second outer surface profile disposed on the second main body. The second directional guide defines a second guide surface oriented non-parallelly to an elongate axis of the second main body and a second bore passing through the second main body along the elongate axis and having a second diameter. The second mating surface profile is formed complementary to the second outer surface profile and is engaged with the second outer surface profile to secure the second directional guide in a second fixed position.
In some embodiments, the second fixed position is downhole of the first fixed position.
In some embodiments, the first diameter of the first bore is larger than the second diameter of the second bore.
In some embodiments, the second directional guide is spaced axially apart from the first directional guide.
In some embodiments, the first outer surface profile has a first shape and the second outer profile has a second shape that is different from the first shape.
In some embodiments, the first mating surface profile is configured to prevent secure positioning of the second directional guide at the first mating surface profile.
In another aspect, a method of performing an intervention operation at a multilateral well includes deploying a directional guide to an axial position within the multilateral well at which a lateral section of the multilateral well is located, installing a main body of the directional guide to an inner surface profile arranged along a casing that surrounds the directional guide at the axial position, closing a bore that passes through the main body along an elongate axis of the main body, deflecting an intervention assembly along a guide surface of the main body into the lateral section, and controlling the intervention assembly to perform the intervention operation within the lateral section.
Embodiments may provide one or more of the following features.
In some embodiments, the method further includes engaging an outer surface profile disposed on the main body with the inner surface profile arranged along the casing to secure the directional guide at the axial position within the multilateral well.
In some embodiments, the outer surface profile is formed complementary to the inner surface profile.
In some embodiments, the main body has a tapered shape.
In some embodiments, the guide surface is orientated at an obtuse angle with respect to the elongate axis.
In some embodiments, the method further includes landing a plug on a landing seat positioned along the bore to close the bore.
In some embodiments, the method further includes withdrawing the plug from the directional guide to reopen the bore.
In some embodiments, the method further includes placing an entry guide within the bore.
In some embodiments, the entry guide includes a tapered portion.
In some embodiments, the directional guide is a first directional guide, the main body is a first main body, the guide surface is a first guide surface, the bore is a first bore having a first diameter, the inner surface profile is a first inner surface profile, the lateral section is a first lateral section, the axial position is a first axial position, and the method further includes passing the intervention assembly through the first bore to access a second directional guide located downhole of the first directional guide.
In some embodiments, the second directional guide is spaced axially apart from the first directional guide.
In some embodiments, the method further includes deflecting the intervention assembly along a second guide surface of a second main body of the second directional guide into a second lateral section located adjacent the second directional guide and controlling the intervention assembly to perform another intervention operation within the second lateral section.
In some embodiments, a first diameter of the first bore is larger than a second diameter of the second bore.
In some embodiments, the first outer surface profile has a first shape and the second directional guide has a second outer profile having a second shape that is different from the first shape.
In some embodiments, the method further includes attracting the intervention assembly into the bore.
In some embodiments, the directional guide further includes a magnet or an electronic attraction device.
In some embodiments, the method further includes detecting a presence of the intervention assembly within the bore.
In some embodiments, the directional guide further includes an electronic sensor for detecting the presence of the intervention assembly.
In some embodiments, the method further includes fluidically isolating the lateral section from another lateral section of the multilateral well.
In some embodiments, the directional guide further includes a high-pressure seal that surrounds the main body.
The details of one or more embodiments are set forth in the accompanying drawings and description. Other features, aspects, and advantages of the embodiments will become apparent from the description, drawings, and claims.
The directional guides 102a, 102b are formed to selectively guide an intervention assembly 117 (for example, a bottom hole assembly (BHA)) into the adjacent lateral section 103, 105 or to allow through passage of the intervention assembly 117 for access to the next successive lateral section 101, 103. Each directional guide 102a, 102b includes a main body 106a, 106b that is equipped with several functional devices. In an xy plane, each main body 106a, 106b has a generally annular shape (for example, a shape of a thick-walled cylinder). Each main body 106a, 106b defines a cylindrical bore 108a, 108b (for example, a bypass port) that allows through passage of an intervention assembly 117 of a permissible size (for example, a permissible diameter). Each bore 108a, 108b is respectively centered about a central axis 126a, 126b of the main body 106a, 106b.
Each directional guide 102a, 102b is also provided with an associated entry guide 110a, 110b (shown in
Each main body 106a, 106b further defines an upper guide surface 116a, 116b that is oriented to guide or direct an intervention assembly 117 into the respective lateral section 103, 105. For example, when the main body 106a, 106b is temporarily plugged, the upper guide surface 116a, 116b can cause an advancing intervention assembly 117 to selectively deflect into the respective adjacent lateral section 103, 105. Each upper guide surface 116a, 116b is oriented at an obtuse angle α, β with respect to a central axis 126a, 126b of the main body 106a, 106b such that the main body 106a, 106b has the general shape of a wedge in an xz plane, as illustrated in
Each directional guide 102a, 102b also has an outer surface profile 118a, 118b that is disposed exteriorly along the main body 106a, 106b. Each outer surface profile 118a, 118b has a shape that is complementary to the respective inner surface profile 104a, 104b of the surrounding casing 109. Accordingly, each outer surface profiles 118a, 118b is formed as a key with a unique shape that allows the directional guide 102a, 102b to securely and correctly mate with the respective inner surface profile 104a, 104b at the vertical position 113, 115. The unique shapes of the inner surface profiles 104a, 104b and the outer surface profiles 118a, 118b thus prevent positioning of the wrong directional guide 102a, 102b at any inner surface profile 104a, 104b along the casing 109. The outer surface profiles 118a, 118b are designed to land the directional guides 102a, 102b and accordingly extend around an entire circumference of the main bodies 106a, 106b. Similarly, the inner surface profiles 104a, 104b extend around an entire inner circumference of the casing 109 to receive the respective outer surface profiles 118a, 118b of the directional guides 102a, 102b.
Example features that may define the geometries of the inner and outer surface profiles 104a, 104b, 118a, 118c include projections, protrusions, teeth, recesses, detents, pockets, and the like. The features may have a variety of shapes, such as circular, curved, round, wave-like, rectangular, triangular, linear, etc. In some embodiments, the outer surface profiles 118a, 118b are embodied as separate, thin components that are respectively assembled with the main bodies 106a, 106b. In some embodiments, the outer surface profiles 118a, 118b are formed integrally with the main bodies 106a, 106b. The directional guides 106a, 106b are further secured to the casing 109 with packing elements (not shown). The directional guides 106a, 106b are centered about a central axis 119 of the casing 109, which coincides with the central axes 126a, 126b of the main bodies 106a, 106b.
Each main body 106a, 106b is equipped with a surrounding high-pressure seal 122a, 122b that fluidically isolates regions of the casing 109 above and below the main body 106a, 106b to effectively isolate consecutive lateral sections 101, 103, 105 from one another. Additionally, each main body 106a, 106b is interiorly equipped with one or more attraction devices 124a, 124b (for example a magnet or an electronic device) that attract the intervention assembly 117. In some embodiments, an intervention assembly 117 may be meant to bypass a non-selected directional guide 102a, 102b (for example, to run through the directional guide 102a, 102b) that is equipped with a magnetic sleeve. The intervention assembly 117 may be equipped with magnets that are of the same polarity as those installed to the non-selected directional guide 102a, 102b to produce a repulsive force that would cause the intervention assembly 117 to bypass the non-selected directional guide 102a, 102b, but to produce an attractive force that would force the intervention assembly 117 into the appropriate lateral that is adjacent to a selected directional guide 102a, 102b. Each main body 106a, 106b is further equipped interiorly with a sensing mechanism 122a, 122b (for example, an electronic sensor) that can detect entry of an intervention assembly 117 into the bore 108a, 108b.
The main bodies 106a, 106b and the outer surface profiles 118a, 118b of the directional guides 102a, 102b are typically made of steel, while the plugs 112a, 112b are typically made of cast iron or aluminum. The main bodies 106a, 106b of the directional guides 102a, 102b typically have an outer diameter that is associated with a size of the intervention assembly 117. In some embodiments, a ratio of a diameter of a main body 106a, 106b of a directional guide 102a, 102b to a diameter of a corresponding intervention assembly 117 is about 7:2. The bore 108b of the upper directional guide 102b has a larger diameter than that of the bore 108a of the lower directional guide 102a. While the example depiction of
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As described and illustrated above, the directional guides 102a, 102b are provided as modified whipstocks (for example, hollow whipstocks) that can advantageously allow through-tubing intervention with bypass of the directional guides 102a, 102b for access to lower lateral sections within a multilateral well 111 in a rig-less manner that does not require removal of the directional guides 102a, 102b. Furthermore, the directional guides 102a, 102b still retain a conventional function of guiding an intervention assembly to target lateral sections of the well 111 that are adjacent the directional guides 102a, 102b along the upper guide surfaces 116a, 116b. Such improved accessibility can facilitate the acidizing and cleaning out of underperforming laterals, better control of production at selected lateral sections, and the running of logs for understanding performance within a lateral section or a main bore and performing corrective actions via selective shifting to ICD intervals within a lateral section.
Accordingly, utilization of the multilateral well access system 100 can avoid costs and time that would otherwise be associated with removal of the directional guides 102a, 102b for lower access to provide maximum surveillance and productivity in a cost-effective manner. For example, the multilateral well access system 100 addresses size limitation challenges of deploying re-entry guide tools, avoids upfront installation of sophisticated completion hardware (for example, lateral access systems), avoids the need to add sophisticated tools to wireline or coil tubing (for example, a gamma reader, a casing collar locater, a caliper, or other sensors) to identify a lateral section, and avoids the need to perform random angle changes, as are often required for conventional re-entry tools.
While the multilateral well access system 100 has been described and illustrated with respect to certain dimensions, sizes, shapes, arrangements, materials, and methods 200, in some embodiments, any component of a multilateral well access system that is otherwise substantially similar in construction and function to the multilateral well access system 100 may include one or more different dimensions, sizes, shapes, arrangements, configurations, and materials or may be utilized according to different methods.
Accordingly, other embodiments are also within the scope of the following claims.