This disclosure relates to well tools for cementing a portion of a wellbore, for example, in a cement squeeze operation.
Some wells undergo cement squeeze operations to repair, solidify, or generally re-cement a portion of a wellbore or casing. A cement squeeze well tool operates to supply cement to an annulus of a wellbore or casing at a location within a wellbore near a perforation, leak, or other unwanted opening in a wall of a wellbore or casing. For example, cement squeeze well tools are utilized when a cemented casing is perforated, faulty, incomplete, or otherwise unsatisfactory and requires additional cement to repair the cemented casing. Sometimes, a cement squeeze well tool disposed in a well includes a packer element and cementing ports to flow cement into an annulus of the wellbore or casing. The cement squeeze well tool can be left in the wellbore to be drilled out at a later time.
This disclosure describes well tools, such as cement squeeze well tools, for cementing a portion of a well.
In some aspects of the disclosure, a well tool for cementing a portion of a well includes a cement retainer assembly configured to be disposed within a wellbore, the cement retainer assembly including a ported sub, and the ported sub including a port to flow cement out of the cement retainer assembly and into an annulus of the wellbore. The well tool further includes a capsule connected to the cement retainer assembly and including a body defining an interior chamber of the capsule, the interior chamber configured to retain a fluid, and the capsule configured to be disposed at a location within the wellbore and downhole of the cement retainer assembly.
This, and other aspects, can include one or more of the following features. The body of the capsule can include fiberglass. The capsule can include centralizers extending radially outwardly from the body, the centralizers to position the capsule proximate to a radial center of the wellbore. The capsule can include a first connection structure at a first longitudinal end of the capsule and a second connection structure at a second longitudinal end of the capsule opposite the first longitudinal end. The first connection structure can include a threaded pin-type connection or a threaded box-type connection, and the second connection structure can include a threaded pin-type connection or a threaded box-type connection. The first connection structure can directly couple the capsule to the cement retainer assembly. The first connection structure can directly couple the capsule to the ported sub of the cement retainer assembly. The second connection structure can directly couple to a second capsule configured to be disposed at a location within the wellbore and downhole of the first-mentioned capsule, and the second capsule can include a second body defining a second interior chamber of the second capsule. The capsule can include a one-way check valve at a first longitudinal end of the capsule, the one-way check valve configured to allow fluid to enter the interior chamber of the capsule. The one-way check valve can include a spring-loaded check valve. The capsule can include a vent structure at a second longitudinal end of the capsule opposite the first longitudinal end, the vent structure configured to expel gaseous fluid from within the interior chamber out of the interior chamber of the capsule. The vent structure can include a ball member and a ball seat, the ball member having a specific density less than the fluid in the interior chamber. The vent structure can include a one-way check valve. The body can be substantially cylindrical, and an outer diameter of the cylindrical body of the capsule can be between 65 percent and 80 percent of an inner diameter of an inner wall of the wellbore. The cement retainer assembly can include a packer element to seal against an inner wall of the wellbore. The wellbore can be a cased wellbore, and the inner wall of the wellbore can include an inner wall of a casing. The ported sub can include a plurality of ports to flow cement out of the cement retainer assembly, where the plurality of ports includes the port of the ported sub.
Certain aspects of the disclosure encompass a method for cementing a portion of a well. The method includes running a well tool into a wellbore, where the well tool includes a cement retainer assembly including a ported sub, the ported sub including a port, and a capsule connected to the cement retainer assembly and including a body defining an interior chamber of the capsule, the capsule being disposed downhole of the cement retainer assembly. The method further includes receiving well fluid disposed in the wellbore into the interior chamber of the capsule to fill the interior chamber with the well fluid, and flowing cement through the port of the ported sub out of the cement retainer assembly and into an annulus between the capsule and an inner wall of the wellbore.
This, and other aspects, can include one or more of the following features. The cement retainer assembly can include a packer element to seal against an inner wall of the wellbore, and the method can include, prior to flowing cement through the port of the ported sub, engaging the inner wall of the wellbore with the packer element to isolate the wellbore downhole of the packer element. The method can further include positioning the packer element of the cement retainer assembly uphole of a perforation in the inner wall of the wellbore. Receiving well fluid into the interior chamber of the capsule can include flowing well fluid through a one-way check valve at a first longitudinal end of the capsule to fill the interior chamber of the capsule with the well fluid. Receiving well fluid through a one-way check valve at a first longitudinal end of the capsule can include expelling gaseous fluid from within the interior chamber out of the interior chamber through a vent structure at a second longitudinal end of the capsule opposite the first longitudinal end. The wellbore can be a cased wellbore, the inner wall of the wellbore can include an inner wall of a casing, and flowing cement into the annulus between the capsule and the inner wall of the wellbore can include flowing the cement into the annulus between the capsule and the inner wall of the casing.
Certain aspects of the disclosure include a capsule for a cement squeeze well tool. The capsule includes a body defining an interior chamber configured to retain a fluid, a connection structure at a first longitudinal end of the substantially cylindrical body, the connection structure configured to couple to a cement squeeze well tool, and a one-way check valve at a second longitudinal end of the substantially cylindrical body opposite the first longitudinal end and fluidly connected to the interior chamber. The one-way check valve is configured to flow fluid into the interior chamber.
This, and other aspects, can include one or more of the following features. The capsule can include a vent structure at the second longitudinal end of the body and fluidly connected to the interior chamber, the vent structure to expel gaseous fluid out of the interior chamber. The connection structure can include a threaded pin-type connection or a threaded box-type connection. The body can be substantially cylindrical.
The details of one or more implementations of the subject matter described in this disclosure are set forth in the accompanying drawings and the description. Other features, aspects, and advantages of the subject matter will become apparent from the description, the drawings, and the claims.
Like reference numbers and designations in the various drawings indicate like elements.
This disclosure describes a well tool for cementing a portion of a well, such as for a cement squeeze operation. The cement squeeze well tool described here includes a capsule that can be disposed in a wellbore to reduce a cement volume required to fill a portion of the wellbore with cement. The cement squeeze well tool can be utilized in a cased wellbore, such as adjacent to a casing of a wellbore, or in an uncased, open hole portion of the wellbore. The well tool can include one or more of the capsules positioned downhole of a cement retainer or other fluid injection tool. In some implementations, the well tool is positioned adjacent to wellbore perforations, casing perforations, a casing leak, or another fluid loss opening in the wellbore. The capsules can be made of fiberglass, high strength plastic, aluminum, a combination of these materials, or another material that can be drilled through, such as with a drilling bit or mill, following the cement squeeze operation. Generally, the material of the capsule is softer than steel, for example, so that the capsule can be drilled through. The shape of a portion of the capsule can include a generally cylindrical shape with an outer diameter that approaches, but is less than, the inner diameter of the inner wall of the wellbore, such as an inner wall diameter of the casing or open hole portion of the wellbore.
The capsule(s) occupies a volume within the wellbore or casing, thereby decreasing the internal volume in the wellbore available to flow cement. In other words, the capsule(s) decreases a volume of the annulus between the capsule and the inner wall of the wellbore adjacent the capsule such that a cementing operation to fill the annular space between the capsule and the inner wall of the wellbore requires less cement, for example, as compared to a well tool without a capsule or a well tool with a certain well string having a smaller diameter than the capsule. The capsule can connect to a cement retainer via a ported sub, which allows cement to flow through the cement retainer out of the ported sub and around the capsule. The capsule can also include a valve assembly including a check valve and a vent structure, such that as the cement retainer and the capsule are lowered downhole, fluids in the casing enter into the capsule through the check valve, and gaseous fluid is expelled from the capsule through the vent structure. In some implementations, multiple capsules can be connected end-to-end, for example, by threaded pin-and-box connections.
In certain cement squeeze assemblies, a cement retainer is lowered downhole into a cased portion of a wellbore. In these cement squeeze operations, the cement retainer requires the wellbore downhole of the cement retainer to be empty of other tools, such that the wellbore is completely filled with cement in order to squeeze some cement into a perforation or other leak in the casing. In the present disclosure, one or more capsules can attach to a downhole end of the cement retainer and occupy a volume in the wellbore, thereby reducing the amount of cement required in a cement squeeze operation. The cement squeeze operation addresses a loss circulation zone, for example, by plugging a casing leak, casing perforation, wellbore wall perforation, or other fluid loss opening in the wellbore with cement.
In some instances, a string of capsules can connect to the cement retainer and be long enough to partially or entirely cover an open hole section of the wellbore below a casing shoe to the loss circulation zone with the cement retainer set inside the casing. This assembly can allow for addressing a loss circulation zone that is far away from a downhole end of a casing, defined by a casing shoe, where the capsule string is drilled through with a drill string after a cementing operation. The drill string can regain the length previously drilled prior to the cement squeeze operation without the need for a directional bottom hole assembly (BHA), for example, because the drill string can chase the previous wellbore direction by drilling through and following the capsule(s), as opposed to drilling through only cement. In this instance, the capsule or capsules act as a directional guide for a drill bit of a drill string to follow after a cement squeeze operation. The well tools described here utilizing one or more capsules reduce an amount of cement required for a cementing operation, and provide for a faster and more economical cementing operation, for example, compared to completely filling a wellbore with cement without the use of capsules.
After some or all of the wellbore 102 is drilled, a portion of the wellbore 102 extending from the wellhead 104 to the subterranean zone 106 can be lined with lengths of tubing, called casing or liner. The wellbore 102 can be drilled in stages, the casing may be installed between stages, and cementing operations can be performed to inject cement in stages between the casing and a cylindrical wall positioned radially outward from the casing. The cylindrical wall can be an inner wall of the wellbore 102 such that the cement is disposed between the casing and the wellbore wall, the cylindrical wall can be a second casing such that the cement is disposed between the two tubular casings, or the cylindrical wall can be a different substantially tubular or cylindrical surface radially outward of the casing. In the example well system 100 of
The wellhead 104 defines an attachment point for other equipment of the well system 100 to attach to the well 102. For example, the wellhead 104 can include a Christmas tree structure including valves used to regulate flow into or out of the wellbore 102, or other structures incorporated in the wellhead 104. In the example well system 100 of
The well string 112 can include a number of different well tools that can drill, test, produce, intervene, or otherwise engage the wellbore 102. In the example well system 100 of
The well tool 114 includes a cement retainer 202, a ported sub 206 having one or more ports 208 (one shown), and a capsule 210 disposed downhole of the cement retainer 202. The capsule 210, ported sub 206, and cement retainer 202 are connected to each other at the surface of the well (for example, at the rig floor) before the well tool 114 is deployed, or lowered, into the wellbore 102. The well tool 114 acts to receive a flow of cement from an uphole location, for example, via a work string connected to the well tool 114, and to direct the cement into the wellbore 102 downhole of the cement retainer 202. The cement retainer 202 is shown in
The capsule 210 occupies a volume of space downhole of the cement retainer 202 to reduce a volume of cement used to fill the wellbore 102, for example, during a cement squeeze operation or other cementing operation.
The size of the capsule 210 can vary. For example, a longitudinal length of the capsule 210 can range from 10 feet to 40 feet, such as a 30 foot length, and an outer diameter of the capsule 210 can range from 3 inches to 16 inches, for example, depending on the size of the wellbore 102. In some implementations, the body 212 has an outer diameter that approaches but is less than the inner diameter of the inner wall 200. For example, the body 212 can have an outer diameter that is between 65 percent and 80 percent of the diameter of the inner wall 200, such as 75 percent of the diameter of the inner wall 200. In some examples, the outer diameter of the body 212 is greater than an outer diameter of the well string supporting the well tool 114 in the wellbore 102.
The body 212 of the capsule 210 includes a valve system that allows for the flow of fluid through the interior chamber 214 in a selective manner. For example, the example capsule 210 is shown in
The one-way check valve 220 of the valve system can take a variety of different forms. For example, the one-way check valve 220 can include a ball check valve, diaphragm check valve, tilting disc check valve, a lift-check valve, a combination of these, or another type of one-way check valve. In the example capsule 210 of
In some implementations, as the capsule 210 is lowered downhole, fluid residing in the wellbore 102 applies a force on the plug element 224 greater than a minimum threshold force to open the check valve 220. The minimum threshold force to open the check valve 220 is a force equal to or greater than an opposite force applied by the spring 226 (for example, the spring bias of spring 226) on the plug element 224. When the well fluid applies at least the minimum threshold force on the plug element 224, the spring 226 compresses and the check valve 220 allows the well fluid to flow into the interior chamber 214 of the capsule 210. The spring characteristics can vary, for example, based on expected well fluid pressures and well applications. In some examples, the spring 226 has a stiffness that is based on a desired opening force of the check valve 220, based on the area of the face of the plug element 224, the size or volume of the interior chamber 214 of the capsule 210, a combination of these features, or other parameters. Of course, as the interior chamber 214 fills with fluid, the minimum threshold force to open the check valve 220 increases, as the minimum threshold force includes the spring bias combined with an applied force on the plug element 224 in a downhole direction from fluid within the interior chamber 214. In some examples, the check valve 220 has a pressure rating of 100 psi, such that a pressure differential at or greater than 100 psi between pressure in the interior chamber 214 and the pressure exterior to the capsule 210 (such as the hydrostatic pressure of wellbore 102) opens the check valve 220, and a pressure differential less than 100 psi closes the check valve 220. In other words, when the pressure in the wellbore 102 exterior to the capsule 210 is at least 100 psi greater than the pressure within the interior chamber 214 of the capsule 210, the check valve 220 opens.
While the check valve 220 is shown at the first longitudinal end 216 of the capsule 210 and centered along the central longitudinal axis A-A, the position of the check valve and the number of check valves can be different. For example, the capsule 210 can include one, two, or more check valves positioned anywhere along the periphery of the body 212 of the capsule 210.
The vent structure 222 of the valve system can also take a variety of different forms. For example, the vent structure 222 can include a vent flap, a ball-and-seat structure, a one-way check valve, a combination of these, or another type of vent structure. In the example capsule 210 of
In some implementations, as the capsule 210 is lowered downhole and the interior chamber 214 fills with fluid entering through the check valve 220, trapped air or other gaseous fluid residing in the interior chamber 214 is expelled out of the interior chamber 214 through the vent structure 222. As the interior chamber fills completely with the well fluid, the vent structure 222 closes. The specific density of the ball member 230 can vary, for example, based on expected well fluid types and well applications. In some examples, the ball member 230 has a specific density less than or equal to that of the lightest expected wellbore fluid, such as water. For example, the ball member 230 can have a specific gravity of 0.8.
While the vent structure 222 is shown in
The capsule 210 includes centralizers 234 that extend radially outward from the body 212. In the example capsule 210 of
The body 212 of the capsule 210 is made of a material that can be drilled through with a drilling tool in a drilling operation following a cementing operation. For example, the body of the capsule 210 can comprise, or be made of, fiberglass or another drillable material. Fiberglass is lightweight and easily drilled through, for example, as compared to metal and other materials, and fiberglass has sufficient burst and collapse pressure ratings, for example, to survive a wellbore run-in and a cement squeeze operation. The material of the body 212 is rigid enough to connect to the cement retainer 202, ported sub 206, or both, and support the weight and contain the pressures of fluid that resides in the interior chamber 214, while also brittle enough to be drilled through in a subsequent drilling operation following the completion of a cementing operation. Both the check valve 220 and the vent structure 222 of the capsule 210 allow pressure equalization between the interior chamber 214 and the wellbore 102 during high pressure cement squeeze operations to avoid the capsule 210 from collapsing or bursting. In addition, the centralizers 234 promote even distribution of cement during the cement squeeze operation by centering the body 212 of the capsule 210 in the wellbore 102.
The cement retainer 202, the ported sub 206, and the capsule 210 can connect to each other in a variety of ways. For example, one or more of the cement retainer 202, ported sub 206, or capsule 210 can be integrally connected, directly coupled (for example, threaded, welded, or otherwise coupled to each other), indirectly connected (for example, via an intermediate sub or other structure), a combination of these connections, or another type of connection. In the example well tool 114 of
The capsule 210 includes a first connection structure at the first longitudinal end 216 of the capsule 210, and includes a second connection structure at the second longitudinal end 218 of the capsule 210. These connection structures allow the capsule 210 to connect to other structures, such as the ported sub 206, the cement retainer 202, another capsule, or a combination of these structures. Referring to
In some implementations, the well tool 114 can include more than one capsule 210. For example,
The first capsule 210′, second capsule 210″, and third capsule 210′″ are connected in series, and connect to each other with threaded connection structures, such as pin-type connections and corresponding box-type connections. Each of the capsules 210′, 210″, and 210′″ have a check valve (like check valve 220 of capsule 210, described earlier) and a vent structure (like vent structure 222 of capsule 210, described earlier), to allow the first capsule 210′, second capsule 210″, and third capsule 210′″ to be filled with well fluid, brine, or other fluid as they are lowered into the wellbore 102, and the vent structures allow for venting of trapped air and gaseous fluid out of the first capsule 210′, second capsule 210″, and third capsule 210′″ to reduce a buoyancy effect of the first capsule 210′, second capsule 210″, and third capsule 210′″ as the well tool 114′ is run into the wellbore 102.
In some implementations, for a string of multiple capsules (210′, 210″ and 210′″) that are lowered in the wellbore like demonstrated in
A number of implementations have been described. Nevertheless, it will be understood that various modifications may be made without departing from the spirit and scope of the disclosure.
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20190368292 A1 | Dec 2019 | US |