For various reasons, operators may want to cut into the side of casing in an existing wellbore so a new sidetracked or lateral wellbore can be drilled. For example, the formation adjacent the original wellbore may become depleted or damaged, or a tool or pipe may have become stuck and may have blocked further use of the original wellbore. For whatever reason, the sidetracked wellbore can be drilled and then lined with pipe for additional operational uses.
As illustrated in
The whipstock 20 may be run in by itself on a setting tool, and the mill 42 can be run in after the whipstock 20 has been set. Alternatively, to save a trip, the whipstock 20 can be run in with the mill 42 temporarily attached to its upper edge. In either case, the whipstock 20 uses an anchor 30 on its end so the whipstock 20 can be anchored in the wellbore 10 at the desired location. The anchor 30 sets in the casing 12 and keeps the whipstock 20 in place to resist the downward force placed upon it as the mill 42 moves along its length through the wall of the casing 12.
Various types of anchors can be used with the whipstock 20, and the anchors can be set mechanically or hydraulically. Mechanically-set anchors require a compressive force to shear a pin so the anchor can be set. These mechanical anchors work well when the anchor is to be set at the bottom of a wellbore or when there is some type of restriction that has been placed in the wellbore, like a bridge plug, against which the anchor can rest. In those instances, the stationary surface available in the wellbore allows operators to generate the compressive force needed to set the mechanical anchor.
In other instances, the anchor may be positioned at some point along the wellbore where there is no surface against which to create a compressive force. In these instances, the anchor can be set with pressurized fluid and requires a hydraulic mechanism.
One particular type of hydraulically-set anchor 30 for the whipstock 20 is shown in
With the whipstock 20 positioned in the wellbore 10, the anchor 30 can be set to secure the whip 22 for the milling process. The running string (or mill 42 when used for run-in) can supply hydraulic fluid through a line to communicate with the anchor 30, pressurize the anchor's mechanism, and set the anchor 30 in the casing 12. For example, hydraulic fluid pressure is supplied to the anchor 30 and can expand slip elements 34 on the anchor 30 outwardly to engage the casing 12 and set the anchor 30. With the anchor 30 set, the mill 42 can then mill the wellbore diversion through the wall of the casing 12. After milling, the whipstock 20 may or may not be retrievable depending on its design.
Sometimes, the anchor 30 has a packer 32 that can isolate the lower portion of the wellbore 10 when set. Other times, isolation may not be necessary. Either way, being able to operate the packer 32 on the anchor 30 for the whipstock 20 offers some unique challenges.
One particular type of anchor 30 available in the art is shown in
Although existing whipstocks 20 and anchors 30 used in the art are effective. Operators are continually seeking new tools that can meet the new challenges experienced in the oil and gas industry around the world. For these reasons, the subject matter of the present disclosure is directed to overcoming, or at least reducing the effects of, one or more of the problems set forth above.
A whipstock assembly positions in a wellbore having casing for forming a sidetrack. The assembly includes a whip, a packer, and an anchor. The packer extends from the whip and is mechanically activatable to seal in the casing, and the anchor extends from the packer and is activatable to anchor in the casing. The anchor sets in the casing before the packer is set. A first temporary connection between the packer and the whip releases in response to a mechanical setting force applied to the assembly, and the packer seals in the casing with the mechanical setting force. A second temporary connection between the packer and the whip releases in response to a mechanical releasing force applied to the assembly, and the whip disconnects from the packer with the mechanical releasing force.
In general, the packer has an end ring and a compressible packing element disposed thereon. The end ring is movable on the packer with the mechanical setting force and compresses the compressible packing element outward toward the casing. The packer can have at least one torque screw disposed thereon and engaged in at least one slot in the end ring, and the end ring can have a body lock connection with the packer.
In one embodiment, the anchor is a mechanically-set anchor that is mechanically activatable to anchor in the casing with a mechanical activation force. For the anchor to be set before the packer, the mechanical activation force for the anchor is at least less than the mechanical setting force of the packer.
In another embodiment, the anchor is a hydraulically-set anchor that is hydraulically activatable to anchor in the casing. Therefore, the assembly can include a hydraulic line communicating from the whip to the anchor via the packer. In one arrangement to accommodate the hydraulics, the packer defines an internal passage, and the hydraulic line for activating the anchor passes through the internal passage from the whip to the anchor. The internal passage can have a bulkhead connector disposed therein and through which a portion of the hydraulic line passes so that the internal passage is sealed.
In an alternative arrangement, a first portion of the hydraulic line can communicate from the whip with the internal passage on one side of the packer's compressible packing element, while a second portion of the hydraulic line can communicate with the internal passage on an opposite side of the packing element to the anchor. The packer's internal passage can thereby communicate the first and second portions of the hydraulic lines with one another. In this arrangement, the packer can have seals sealing at least the first portion of the hydraulic line from the internal passage when the first temporary connection is released in response to the mechanical setting force used to set the packer.
The first temporary connection can include an intermediate member connected to the whip and movably disposed adjacent the packer's compressible packing element. One or more first shear elements temporarily affix the intermediate member to the packer. For its part, the second temporary connection can include one or more second shear elements temporarily affixing the intermediate member to the packer's end ring movable against the compressible packing element.
As noted above, the anchor is set before the packer is set in the casing. The set anchor may thereby position the unset packer eccentrically in the casing. At least a portion of the eccentrically-positioned packer acts as a fulcrum point tending to position a tip of the whip against the casing.
A method of forming a sidetrack in a wellbore having casing involves deploying in the casing a whipstock assembly having a whip, a packer extending from the whip, and an anchor extending from the packer. The whipstock assembly anchors in the casing by setting the anchor in the casing, and the packer mechanically sets in the casing with a mechanical setting force after setting the anchor. At this point, various operations can be performed, namely forming the sidetrack in the wellbore with the assembly set in the casing.
Setting the anchor in the casing before setting the packer can involve positioning the unset packer eccentrically in the casing. In this way, at least a portion of the eccentrically-positioned packer can be used as a fulcrum point to urge a tip of the whip against the casing, which can have advantages disclosed herein.
Setting the anchor can involve mechanically setting the anchor with a mechanical activation force at least less than the mechanical setting force used for the packer. Alternatively, setting the anchor can involve communicating hydraulics from the whip to the anchor through the packer. To do this, a hydraulic line can communicate from the whip to the anchor through an internal passage of the packer.
In another arrangement, a first portion of a hydraulic line from the whip communicates to an internal passage of the packer on one side of a compressible packing element, while a second portion of the hydraulic line communicates from internal passage of the packer on an opposite side of the compressible packing element to the anchor. When the first temporary connection is released in response to the mechanical setting force, at least the first portion of the hydraulic line can seal from the internal passage.
Mechanically setting the packer in the casing involves moving an end ring on the packer with the mechanical setting force against a compressible packing element on the packer and compressing the compressible packing element outward toward the casing. This is done by freeing a first temporary connection of the assembly with the mechanical setting force applied to the assembly.
For the first temporary connection, an intermediate member connected to the whip is provided that is movably disposed adjacent the packer's compressible packing element. A temporarily affixing of this intermediate member to the packer can then be sheared so that the mechanical setting force can be applied to the packer's compressible packing element.
Eventually, the whip of the assembly can mechanically disconnect from the packer by freeing a second temporary connection between the packer and the whip with a mechanical releasing force applied to the assembly. Disconnecting the whip by freeing the second temporary connection between the packer and the whip with the mechanical releasing force can then involve shearing another temporarily affixing of the intermediate member to the packer's end ring, which is movable against the compressible packing element.
The foregoing summary is not intended to summarize each potential embodiment or every aspect of the present disclosure.
The whip 60 is a wedge-shaped member with a concave face 62 that can steer a mill or a cutter (not shown) to the side of casing where a window can be formed. The intermediate member 70 connects the packer 80 to the lower end of the whip 60. The packer 80 is a permanent, compression-set packer that is run below the whip 60 and above the anchor 90 on the assembly 50. As will be discussed later, the packer 80 is set after the anchor 90 has been set.
The anchor 90 can be set with hydraulic pressure using a hydraulic line 75, or the anchor 90 can be activated with set-down weight so no hydraulic line is required. For the hydraulically-set anchor 90, the hydraulic line 75 extends from a coupling (66:
In one arrangement, the packer 80 has an internal bypass for the transmission of hydraulic pressure to set the anchor 90. Alternatively, the hydraulic line 75 is run inside the packer 80 so the hydraulic line 75 can pass to the anchor 90. Further details of these features are discussed later.
For a mechanically-set anchor 90, use of the control line 75 is not necessary. In this case, the packer's internal dimension can be plugged with a small fitting to seal a fluid passage that would be present in the packer 80 for communicating with the hydraulically-set anchor 90. For example, the packer 80 can be filled with fluid and can have a mechanism that seals off the inside of the packer 80 as the packer 80 is set.
As noted above, the anchor 90 can be mechanically-set or hydraulically-set. Shown here, the anchor 90 is actuated hydraulically so the hydraulic line 75 runs from the whip 60, through the packer 80, and to the mechanisms of the anchor 90 so hydraulic fluid from a running tool or the like affixed at the whip 60 can communicate to the anchor 90 and set it in the casing 12.
As shown, the anchor 90 is similar to that shown in
Discussion now turns to
As best shown in
To communicate hydraulics from the whip 60 to the anchor 90, the hydraulic line 75 as shown in
Communicated inside the mandrel's bore 83, the hydraulic fluid is held therein by end caps or seals 85a-b disposed at each end of the bore 83. The end caps 85a-b can be welded or otherwise affixed in place. This creates a fluid-filled chamber through packer 80. The hydraulic fluid from the bore 83 can pass through another mandrel port 83b to a fitting 74b on the lower end of the mandrel 82. From this fitting 74b, the hydraulic line 75 can run along the anchor 90 to then communicate with the anchor's trigger components 98.
Although the anchor 90 is operated hydraulically, the packer 80 is operated mechanically by the interaction of the whip 60, intermediate member 70, and upper end ring 84a. Turning to the operation of the packer 80, discussion turns to
The upper (movable) end ring 84a is disposed on the packer mandrel 82 and is affixed with shear screws 78a-b, pins, elements, or other temporary fixture. A first set of shear screws 78a affixes the end ring 84a to the intermediate member 70. A second set of the shear screws 78b affixes the end ring 84a to the mandrel 82.
To set the packer 80 by moving the upper end ring 84a against the packing elements 86 and against the lower (fixed) end ring 84b, the intermediate member 70 as discussed below pushes the upper end ring 84a. The first shear screws 78a do not shear free when the intermediate member 70 is forced downward along the mandrel 82 during setting procedures discussed below. The second shear screws 78b, however, do shear free when the intermediate member 70 is forced downward along the mandrel 82 at a mechanical setting force. The first shear screws 78a can be sheared free when the intermediate member 70 is forced upward during release procedures discussed below.
The shear values for set down with the second set of shear screws 78b may be lower than the shear valves for release with the first set of shear screws 78a. Moreover, if the anchor 90 is mechanically set, then any shear value associated with the anchor's setting would be lower than setting shear values for the packer 80.
Torque screws 87b on the mandrel 82 can ride in guide slots 87a on the end ring 84a. The torque screws 87b transmit torque from the whip 60 to the anchor 90, and the torque screws 87b can slide in the slots 87a during packer setting. To hold the upper end ring 84a in a set state compressed against the packing elements 86, a body lock ring 89b on the end ring 84a can lockably engage teeth 89a disposed on the mandrel 82, allowing movement toward the packing elements 86a-b and preventing reverse movement.
Overall, the assembly 50 mechanically sets the packer 80 after the anchor 90 has been set either mechanically or hydraulically. Operation of the packer 80 on the assembly 50 is shown in
As shown more specifically in
During run in, the upper end ring 84a is held affixed to the intermediate member 70, and the intermediate member 70 is held affixed to the packer mandrel 82 by the shear screws 78a-b. In this position, the torque screws 87b are disposed in the lower end of the guide slots 87a on the end ring 84a. Of course, during run in, the anchor 90 is not set, and hydraulic pressure is not yet communicated through the line 75 and mandrel bore 83 to activate the anchor 90.
As shown in
Once the anchor 90 is set as shown in
To actually set the packer 80 after the anchor 90 is set, operators put weight on the assembly 50 using the running tool (not shown), which is affixed to the whip 60. Weight is applied by the whip 60 and the intermediate member 70 to shear the screws 78b. Freed from the mandrel 82, the end ring 84a moves along the mandrel 82 and compresses against the packing elements 86. For example, the weight required to initiate setting may be about 20-25K lb. Then, the minimum weight required to set the packer 80 in the casing 12 can be about 40K lb, and the maximum weight to sustain without losing seal can be about 65K lb. These values are merely exemplary.
As shown in
When shifted to set the packer 80, the intermediate member 70 eventually seals off the hydraulics. In particular, O-ring seals are disposed on the packer mandrel 82 adjacent the port 83a for the hydraulic fitting 74a. As the intermediate member 70 slides along the mandrel 82 during setting of the packer 80, the fitting 74a slides past the hydraulic port 83a. This seals off the fluid path and can be useful if the hydraulic line 75 below the packer 80 leaks.
Under the compression, the packer element 86 extends outward to engage inside the casing 12 to create a fluid seal. As noted above, the set anchor 90 causes the packer 80 to be forced against one side of the casing 12 as a portion of the packer 80 is used as a fulcrum point for pushing the tip of the whip 60 against the casing 12. Because the packer 80 is forced against the casing 12, a very large extrusion gap is formed on one side. The other side of the packer 80 has a very small or no extrusion gap. Therefore, the packing elements' material is preferably capable of moving both circumferentially and radially to pack off in the casing 12. The packing element 86 may also be preconfigured with more material on one side to accommodate the expected extrusion gap relative to the casing 12 when the anchor 90 is set.
With the anchor 90 and packer set 80, operations can continue. For instance, the setting tool (not shown) is disengaged from the whip 60, and milling of a sidetrack wellbore is performed according to standard procedures. The packer 80 transmits torque generated by the milling operation through it to the anchor 90 below.
Once the sidetrack wellbore is completed (i.e., drilled, lined with pipe, perforated, etc.), the whip 60 can be removed from the assembly 50, leaving the packer 80 and the anchor 90 in place. To do this, operators engage the whip 60 with a pulling tool (not shown) at a profile (e.g., 64) and pull up on the whip 60 against the packer 80 and anchor 90 set in the casing 12. As shown in
The packer 80 and anchor 90 can then be removed according to conventional practices. For example, a milling operation can free the packer 80 from engagement with the surrounding casing 12 so the packer 80 can be washed out. Also, the exposed end of the packer mandrel 82 acts a fishing neck for retrieval.
In addition to shearing of the whip 60 followed by the milling/washover of the packer 80, there are other contingency retrieval operations that can be implemented. For example, retrieval may need to be performed while the assembly 50 is being run in the well to depth and being oriented. If the assembly 50 sets prematurely, the operators will want to remove the entire assembly 50 and bring it to surface. Should the assembly 50 pre-set, the operators can shear the whip 60 from the assembly 50 and can also retrieve the packer 80 and anchor 90 as a unit. This presupposes that the friction of the anchor 90 in the casing is less than the shear value. This retrieval operation can also be used if the operators want to retrieve the assembly 50 even if set properly to depth and after the desired window has been milled.
In the previous version of the packer 80, the inner bore 83 of the packer 80 is used for communicating high-pressure hydraulic fluid to the anchor 90. The bore 83 is filled with fluid and has a mechanism that seals off the inside of the packer 80 as the packer 80 is set. In another version, the hydraulic line 75 can be run through a bulkhead type connector inside the packer 80 to communicate fluid to the anchor 90.
In particular,
As shown, the line 75a from the whip 60 terminates and connects to an intermediate line 75c with tubing union fittings. The intermediate line 75c then passes through an opening 79a and into the intermediate member 70. The intermediate line 75c affixes with fittings (e.g., two Swagelok straight connectors) to the end cap 85c in the mandrel 82, and the intermediate line 75c continues and passes through the mandrel's bore 83 to an opening 79b downhole on the packer 80. Here, the intermediate line 75c connects with tubing union fittings to the lower line 75b, which extends to the anchor 90.
The end cap 85c is a bulkhead connector sealed and affixed in the mandrel's bore 83. The hydraulic line 75c is sealed with fittings to the bulkhead connector 85c so the line 75c can pass through the connector 85c. In this way, the bulkhead connector 85c prevents fluid from bypassing the packer 80 through the mandrel's bore 83.
Setting of the anchor 90 and packer 80 can be performed as before. The setting shear screws 78b affixing the intermediate member 70 to the mandrel 82 can be disposed as before or can be positioned as shown in
In
In another alternative shown in
The foregoing description of preferred and other embodiments is not intended to limit or restrict the scope or applicability of the inventive concepts conceived of by the Applicants. It will be appreciated with the benefit of the present disclosure that features described above in accordance with any embodiment or aspect of the disclosed subject matter can be utilized, either alone or in combination, with any other described feature, in any other embodiment or aspect of the disclosed subject matter.
In exchange for disclosing the inventive concepts contained herein, the Applicants desire all patent rights afforded by the appended claims. Therefore, it is intended that the appended claims include all modifications and alterations to the full extent that they come within the scope of the following claims or the equivalents thereof.
This is non-provisional of U.S. patent application Ser. No. 62/004,383, filed 29, May 2014, which is incorporated herein by reference in its entirety and to which priority is claimed.
Number | Date | Country | |
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62004383 | May 2014 | US |