In the production of hydrocarbons, it is common to drill one or more secondary wellbores from a first wellbore. Typically, the first and secondary wellbores, collectively referred to as a multilateral wellbore, will be drilled and cased using a drilling rig. Thereafter, once completed, the drilling rig will be removed, and the wellbores will produce hydrocarbons.
During any stage of the life of a wellbore, various treatment fluids may be used to stimulate the wellbore. As used herein, the term “treatment,” or “treating,” refers to any subterranean operation that uses a fluid in conjunction with a desired function and/or for a desired purpose. The term “treatment,” or “treating,” does not imply any particular action by the fluid or any particular component of the fluid.
One common stimulation operation that employs a treatment fluid is hydraulic fracturing. Hydraulic fracturing operations generally involve pumping a treatment fluid (e.g., a fracturing fluid) into a wellbore that penetrates a subterranean formation at a sufficient hydraulic pressure to create one or more cracks, or “fractures,” in the subterranean formation through which hydrocarbons will flow more freely. In some cases, hydraulic fracturing can be used to enhance one or more existing fractures. “Enhancing” one or more fractures in a subterranean formation, as that term is used herein, is defined to include the extension or enlargement of one or more natural or previously created fractures in the subterranean formation. “Enhancing” may also include positioning material (e.g., proppant) in the fractures to support (“prop”) them open after the hydraulic fracturing pressure has been decreased (or removed).
During the initial production life of a wellbore—often called the primary phase—primary production of hydrocarbons typically occurs either under natural pressure, or by means of pumps that are deployed within the wellbore. This may include wellbores that have undergone stimulation operations, such a hydraulic fracturing, during a completion process. Unconventional wells typically will not produce economical amounts oil or gas unless they are stimulated via a hydraulic fracturing process to enhance and connect existing fractures. In order to reduce well costs, the hydraulic fracturing process is performed after the drilling rig has been removed from the well. Furthermore, wells may be hydraulically fractured without the aid of a workover rig if the equipment used to fracture a well is light enough to be transported in and out of the wellbore via a coiled tubing unit, wireline, electric line, or other device.
Over the life of a wellbore, the natural driving pressure may decrease to a point where the natural pressure is insufficient to drive the hydrocarbons to the surface given the natural permeability and fluid conductivity of the formation. At this point, the reservoir permeability and/or pressure must be enhanced by external means. In secondary recovery, treatment fluids are injected into the reservoir to supplement the natural permeability. Such treatment fluids may include water, natural gas, air, carbon dioxide or other gas and a proppant to hold the fractures open.
Likewise, in addition to enhancing the natural permeability of the reservoir, it is also common through tertiary recovery, to increase the mobility of the hydrocarbons themselves in order to enhance extraction, again through the use of treatment fluids. Such methods may include steam injection, surfactant injection and carbon dioxide flooding. In both secondary and tertiary recovery, hydraulic fracturing may also be used to enhance production.
Depending on the nature of the secondary or tertiary operation, it may be necessary to redeploy a rig, often referred to as a “workover rig,” to the wellbore to assist in these operations, which may require additional equipment be installed in a wellbore. For example, subjecting a producing wellbore to hydraulic fracturing pressures after it has been producing may damage certain casings, installations, or equipment already in a wellbore. Thus, it may be necessary to install additional equipment to protect the various equipment and tools already in the wellbore before proceeding with such operations. Such additional equipment is typically of sufficient size and weight that requires the use of a workover rig. As the number of secondary wellbores in a multilateral wellbore increases, the difficulty in protecting the various equipment in the first wellbore and the secondary wellbores becomes even more pronounced.
It would be desirable to provide a system that avoids the need for drilling or workover rigs in treatment fluid operations in multilateral wellbores, particularly those subject to stimulation techniques such as hydraulic fracturing.
Reference is now made to the following descriptions taken in conjunction with the accompanying drawings, in which:
In the drawings and descriptions that follow, like parts are typically marked throughout the specification and drawings with the same reference numerals, respectively. The drawn figures are not necessarily to scale. Certain features of the disclosure may be shown exaggerated in scale or in somewhat schematic form and some details of certain elements may not be shown in the interest of clarity and conciseness. The present disclosure may be implemented in embodiments of different forms.
Specific embodiments are described in detail and are shown in the drawings, with the understanding that the present disclosure is to be considered an exemplification of the principles of the disclosure, and is not intended to limit the disclosure to that illustrated and described herein. It is to be fully recognized that the different teachings of the embodiments discussed herein may be employed separately or in any suitable combination to produce desired results.
Unless otherwise specified, use of the terms “connect,” “engage,” “couple,” “attach,” or any other like term describing an interaction between elements is not meant to limit the interaction to direct interaction between the elements and may also include indirect interaction between the elements described. Unless otherwise specified, use of the terms “up,” “upper,” “upward,” “uphole,” “upstream,” or other like terms shall be construed as generally away from the bottom, terminal end of a well; likewise, use of the terms “down,” “lower,” “downward,” “downhole,” or other like terms shall be construed as generally toward the bottom, terminal end of a well, regardless of the wellbore orientation. Use of any one or more of the foregoing terms shall not be construed as denoting positions along a perfectly vertical axis. Unless otherwise specified, use of the term “subterranean formation” shall be construed as encompassing both areas below exposed earth and areas below earth covered by water such as ocean or fresh water.
As used herein, “first wellbore” shall mean a wellbore from which another wellbore extends (or is desired to be drilled, as the case may be). Likewise, a “second” or “secondary wellbore” shall mean a wellbore extending from another wellbore. The first wellbore may be a primary, main or parent wellbore, in which case, the secondary wellbore is a lateral or branch wellbore. In other instances, the first wellbore may be a lateral or branch wellbore, in which case the secondary wellbore is a “twig” or a “tertiary” wellbore.
Generally, in one or more embodiments, an isolation system (e.g., as might be used to complete a main wellbore or lateral wellbore, fracture a main wellbore or lateral wellbore, drill a main wellbore or lateral wellbore, workover a main wellbore or lateral wellbore, etc.) is provided in a multilateral wellbore with a secondary wellbore extending from a first wellbore. The isolation system includes a tubular having an opening therein that aligns with a secondary wellbore window formed in the casing string of the first wellbore. The isolation system may include annular seals along the outer surface of the tubular above and below the opening, and may further include an orientation device carried within the tubular. In one or more embodiments, a main bore isolation sleeve is positioned within the isolation system to seal the opening in the isolation system and the secondary wellbore window in the first wellbore casing to isolate the secondary wellbore from high pressure fluid directed farther down the first wellbore casing. In one or more embodiments, a whipstock seats on the orientation device so that a surface of the whipstock is aligned with the secondary wellbore window of the first wellbore casing string. In one or more embodiments, a straddle stimulation tool abuts the surface of the whipstock and extends through the isolation system opening from the first wellbore into the secondary wellbore.
Turning to
The well system 100 illustrated in
The well system 100 illustrated in
The well system 100 illustrated in
In accordance with one embodiment of the disclosure, the one or more annular seals 190 in the well system 100 (e.g., in the isolation system 180) are I-shaped seals. The term I-shaped seal, as used herein, means that the annular seal includes a pair of opposing members separated by a central member (e.g., central rigid member), the central member defining first and second fluid cavities on opposing sides thereof. In certain embodiments, the I-shaped seal may also be referred to as H-shaped seals, for example depending on their orientation. Accordingly, the term I-shaped seal and H-shaped seal are synonymous.
Turning to
In one or more embodiments, the I-shaped seal 200 may additionally include one or more engagement features 215, 225 along a radially exterior surface of the first member 210 and a radially interior surface of the second member 220, respectively. The one or more engagement features 215, 225, at least in one embodiment, may be pushed radially outward and radially inward, respectively, as the first fluid pressure 245 engages with the first fluid chamber 240 and the second fluid pressure 255 engages with the second fluid chamber 250. Accordingly, the one or more engagement features 215, 225 may be employed to provide increased sealing.
In at least one embodiment, the I-shaped seal 200 is a metal I-shaped seal. For example, the metal I-shaped seal could be a steel I-shaped seal. In yet other embodiments, the I-shaped seal might include one or more of the following metals or alloys: 316 Stainless, C-276 alloy, 718 alloy, tungsten carbide, cemented carbide, brass, and/or bronze, etc., among other metals and/or alloys and/or composites. Thus, when placed between two metal tubulars, such as that shown in
Turning to
Likewise, with regard to secondary wellbore 110b, which is formed at a junction 340 with first wellbore 110, a transition joint 345 may extend from the casing window 165 formed along the inner annulus of the casing 160. Transition joint 345 may be made of steel, fiberglass, or any material capable of supporting itself under the pressure of fluids, cement, or solid objects such as rock in a downhole environment. A casing hanger 350 may be deployed from which a secondary wellbore casing 360 hangs. Secondary wellbore casing 360 has a proximal end, a distal end and an interior surface. The distal end may include perforations 365 or a sliding sleeve. The proximal end may include a shoulder for supporting the secondary wellbore casing 360 on the casing hanger 350. Secondary wellbore casing 360 is illustrated as cemented in place within secondary wellbore 110b. In other embodiments (not shown) the transition joint 345 may be threaded directly to a PBR 370, which in turn is threaded to the secondary wellbore casing 360, and no casing hanger 350 is necessary.
In one or more embodiments, the well system 100 may further include the one or more I-shaped seals 190. As shown in
In at least one embodiment, one or more of the I-shaped seals 190 are located near the junction 340. The term “near”, as that term is used with regard to the placement of the one or more I-shaped seals 190 relative to the junction 340, means that the one or more I-shaped seals 190 are located less than 100 meters from the junction 340. In at least one other embodiment, one or more of the I-shaped seals 190 are located in close proximity with the junction 340. The term “in close proximity”, as that term is used with regard to the placement of the one or more I-shaped seals 190 relative to the junction 340, means that the one or more I-shaped seals 190 are located less than 5 meters from the junction 340. In at least one other embodiment, one or more of the I-shaped seals 190 are located proximate the junction 340. The term “proximate”, as that term is used with regard to the placement of the one or more I-shaped seals 190 relative to the junction 340, means that the one or more I-shaped seals 190 are located less than 1 meter from the junction 340.
Turning to
In one or more embodiments, the well system 100 additionally includes a pair of I-shaped seals 420 disposed along an inner surface of the isolation system 180. In at least one embodiment, the pair of I-shaped seals 420 are spaced apart to seal above and below the opening 185 when another tubular is positioned therein. The I-shaped seals 420 may be similar in one or more respects to the I-shaped seals 200 described with regard to
Turning to
The pair of I-shaped seals 420 are spaced apart, as described above, to seal above and below the opening 185 defined in the wall of the elongated tubular 410 when the main bore isolation sleeve 510 is deployed within isolation system 180. Accordingly, when the pair of I-shaped seals 420 are properly placed, the first wellbore 110 is isolated from the secondary wellbore 110b. In other words, fluid communication between the first wellbore 110 and the secondary wellbore 110b is blocked by main bore isolation sleeve 510, allowing various operations, such as high-pressure pumping, in the first wellbore 110 or secondary wellbore 110a to occur without impacting secondary wellbore 110b. In those embodiments wherein access, whether physical or fluid access, to the secondary wellbore 110b is desired, the main bore isolation sleeve 510 may be removed entirely from the main wellbore 110, or alternatively slid to a location where the pair of I-shaped seals 420 are not straddling the opening 185.
Turning to
Turning now to
The downhole tool 700 of
In the illustrated embodiment of
Turning now to
In at least one or more embodiments, the slot 810 has an uphole no-go profile 820 and a downhole no-go profile 830, the uphole no-go profile 820 and the downhole no-go profile 830 preventing the main bore isolation sleeve 850 from being removed (e.g., easily removed) and withdrawn uphole from the isolation system 710. Moreover, the uphole no-go profile 820 and the downhole no-go profile 830 may act as alignment features, such that when the main bore isolation sleeve 850 abuts the uphole no-go profile 820 it is known that the opening 730 is fully isolated, and that when the main bore isolation sleeve 850 abuts the downhole no-go profile 830 it is known that the opening 730 is fully accessible. This configuration assumes that the main bore isolation sleeve 850 is configured to slide uphole to fully isolate the opening 730. Nevertheless, the configuration could be reversed, such that the main bore isolation sleeve 850 is configured to slide downhole to fully isolate the opening 730.
In one or more embodiments, the elongated tubular 720 includes one or more profiles 840 that are configured to engage with a collet 855 in the main bore isolation sleeve 850. In one or more embodiments, the one or more profiles 840 and the collect 855 may act as a latching mechanism, for example to hold the main bore isolation sleeve 850 in place, as well as act as a secondary alignment feature.
Aspects disclosed herein include:
Aspects A, B, C, D, E and F may have one or more of the following additional elements in combination: Element 1: wherein the tubular forms at least a portion of an isolation system. Element 2: further including an isolation sleeve located within the isolation system, the isolation sleeve straddling the first and second I-shaped seals to isolate the interior of the tubular and the exterior of the tubular. Element 3: wherein the isolation sleeve is not a permanent fixture within the isolation system. Element 4: wherein the isolation sleeve is a permanent fixture within the isolation system. Element 5: wherein the tubular includes a slot for the isolation sleeve to slide within the isolation system when accessing or closing the opening. Element 6: wherein the tubular includes an uphole no-go profile and a downhole no-go profile, the uphole no-go profile and the downhole no-go profile preventing the isolation sleeve from sliding out of the isolation system. Element 7: wherein the isolation sleeve is configured to abut the uphole no-go profile when the isolation sleeve is isolating the interior of the tubular and the exterior of the tubular, and configured to abut the downhole no-go profile when the isolation sleeve is providing access between the interior of the tubular and the exterior of the tubular. Element 8: wherein the isolation sleeve is configured to abut the downhole no-go profile when the isolation sleeve is isolating the interior of the tubular and the exterior of the tubular, and configured to abut the uphole no-go profile when the isolation sleeve is providing access between the interior of the tubular and the exterior of the tubular. Element 9: wherein the tubular is a metal tubular, and the first and second I-shaped seals are first and second metal I-shaped seals, and further wherein the first and second metal I-shapes seals provide a metal-to-metal seal. Element 10: further including an isolation system positioned within the wellbore casing, the isolation system including an opening that at least partially aligns with the casing window. Element 11: wherein the first and second I-shaped seals are located in an annulus between the wellbore casing and the isolation system. Element 12: wherein the isolation system includes a slot for the isolation sleeve to slide to either isolate an interior of the isolation system from an exterior of the isolation system or provide access between the interior of the isolation system and the exterior of the isolation system. Element 13: wherein the isolation system includes an uphole no-go profile and a downhole no-go profile, the uphole no-go profile and the downhole no-go profile preventing the isolation sleeve from siding out of the isolation system. Element 14: wherein the isolation sleeve is configured to abut the uphole no-go profile when the isolation sleeve is isolating the opening, and configured to abut the downhole no-go profile when the isolation sleeve is providing access through the opening. Element 15: wherein the isolation sleeve is configured to abut the downhole no-go profile when the isolation sleeve is isolating the opening, and configured to abut the uphole no-go profile when the isolation sleeve is providing access through the opening. Element 16: wherein the isolation system is a metal isolation system, and the first and second I-shaped seals are first and second metal I-shaped seals, and further wherein the first and second metal I-shapes seals provide a metal-to-metal seal. Element 17: further including an isolation system positioned within the wellbore casing, the isolation system including an opening that at least partially aligns with the casing window. Element 18: wherein at least one of the one or more I-shaped seals is located in an annulus between the wellbore casing and the isolation system. Element 19: further including an isolation sleeve positioned within the isolation system, and wherein at least one of the one or more I-shaped seals is located in an annulus between the isolation system and the isolation sleeve. Element 20: further including an isolation sleeve positioned within the wellbore casing, and wherein at least one of the one or more I-shaped seals is located in an annulus between the wellbore casing and the isolation sleeve. Element 21: further including a secondary wellbore casing extending from the junction into the secondary wellbore, the secondary wellbore casing having a polished bore receptacle at the junction. Element 22: further including a straddle stimulation tool engaged within the polished bore receptacle, and further wherein at least one of the one or more I-shaped seals is located in an annulus between the polished bore receptacle and the straddle stimulation tool. Element 23: wherein the isolation sleeve is a permanent fixture within the isolation system. Element 24: wherein the elongated tubular includes an uphole no-go profile and a downhole no-go profile, the uphole no-go profile and the downhole no-go profile preventing the isolation sleeve from sliding out of the isolation system. Element 25: wherein the isolation sleeve is configured to abut the uphole no-go profile when the isolation sleeve is isolating the interior of the elongated tubular from the exterior of the elongated tubular, and configured to abut the downhole no-go profile when the isolation sleeve is providing access between the interior of the elongated tubular and the exterior of the elongated tubular. Element 26: wherein the isolation sleeve is configured to abut the downhole no-go profile when the isolation sleeve is isolating the interior of the elongated tubular from the exterior of the elongated tubular, and configured to abut the uphole no-go profile when the isolation sleeve is providing access between the interior of the elongated tubular and the exterior of the elongated tubular. Element 27: wherein the elongated tubular includes one or more profiles configured to engage with a collet in the isolation sleeve. Element 28: wherein the one or more profiles are configured to hold the isolation sleeve in place as well as act as an alignment feature. Element 29: wherein the I-shaped seal is a first I-shaped seal, and further including a second I-shaped seals located in the annulus between the elongated tubular and the isolation sleeve, the first and second I-shaped seals located on opposing sides of the opening, each of the first and second I-shaped seals including: the first and second opposing members; and the central member separating the first and second opposing members, the central member defining the first and second fluid cavities. Element 30: wherein the elongated tubular includes an uphole no-go profile and a downhole no-go profile, the uphole no-go profile and the downhole no-go profile preventing the isolation sleeve from sliding out of the isolation system. Element 31: wherein the isolation sleeve is configured to abut the uphole no-go profile when the isolation sleeve is isolating the interior of the elongated tubular from the exterior of the elongated tubular, and configured to abut the downhole no-go profile when the isolation sleeve is providing access between the interior of the elongated tubular and the exterior of the elongated tubular. Element 32: wherein the isolation sleeve is configured to abut the downhole no-go profile when the isolation sleeve is isolating the interior of the elongated tubular from the exterior of the elongated tubular, and configured to abut the uphole no-go profile when the isolation sleeve is providing access between the interior of the elongated tubular and the exterior of the elongated tubular.
Those skilled in the art to which this application relates will appreciate that other and further additions, deletions, substitutions and modifications may be made to the described embodiments.
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