1. Technical Field
Embodiments disclosed herein relate to well kill operations in hydrocarbon exploration. In particular, embodiments disclosed herein relate to the development of hydraulic communication between a target and a relief well without the need to intersect the two wells.
2. Description of Related Art
In the field of hydrocarbon exploration and extraction, it is sometimes necessary to drill a relief well to provide a conduit for injecting a fluid, such as mud or cement, into a target well. Such procedures most often occur when the relief well is drilled to kill the target well.
A relief well is typically drilled as a straight hole down to a planned kickoff point, where it is turned toward the target well using conventional directional drilling technology. Drilling is thereafter continued until the relief well intersects the target well, thereby establishing hydraulic communication between the two wells.
Because of the difficulty in intersecting the relief well with the target well, the relief well may be drilled at an incident angle to the target well rather than simply intersecting the target well perpendicularly.
In any event, upon intersection, fluid from the relief well typically U-tubes into the target well. Pumps are used to keep the annulus of the relief well full, followed by pumping at the appropriate kill rates until the blowout is dead.
With reference to
A second or relief wellbore 14 is also shown in the formation 12 extending from a drilling structure 11b. Second wellbore 14 is drilled so that a portion 16 of second wellbore 14 is disposed adjacent a portion 18 of first wellbore 10. Drilling structures 11a, 11b are for illustrative purposes only and may be any type of drilling structure utilized to drill a wellbore, including land deployed drilling structures or marine deployed drilling structures. In this regard, the wellbores may extend from land or may be formed at the bottom of a body of water. Also illustrated is a fluid source 13 for the fluid to be introduced into second wellbore 14.
Preferably, portion 16 of second wellbore 14 is substantially parallel to portion 18 of first wellbore 10. The length of the respective parallel portions may be selected based on the amount of hydraulic communication necessary for a particular procedure. In certain embodiments, the length of the respective parallel portions may be approximately 10 to 40 meters, although other embodiments are not limited by such a distance.
It should be noted that first and second wellbores 10, 14 preferably do not intersect at the adjacent portions 16, 18, but are maintained in a spaced apart relationship from one another. In certain preferred embodiments, the spacing between the two wellbores at the adjacent portions is desirably between zero and 0.25 meters, although other embodiments are not limited by such a distance. It will be appreciated that the closer the second wellbore 14 is to the first wellbore 10, the more effective the method and system for establishing hydraulic communication therebetween.
Although the trajectory of second wellbore 14 need not follow any particular path so long as a portion 16 is positioned relative to a portion 18 of the first wellbore 10, as shown, relief wellbore 10 includes a first substantially vertical leg 20. Kickoff is initiated at point 22 in order to guide second wellbore 14 towards first wellbore 10. Any directional drilling and ranging techniques may be used at this point to guide second wellbore 14 towards first wellbore 10. Once second wellbore 14 has reached a desired offset distance, kickoff to tangent wellbore 10 is initiated at point 24 to form portion 16 of second wellbore 14.
As will be described below, hydraulic communication between second wellbore 14 and first wellbore 10 will be established at the respective adjacent portions 16, 18. First wellbore 10 may be cased or uncased at portion 18. To the extent portion 18 is cased, portion 18 is may be selected to have perforations 26 (shown in
Turning to
Second wellbore 14 includes a casing 28 which preferably incorporates one or more keyed latch couplings 30 at known positions along at least a portion of the length of casing 28. In this regard, latch couplings 30 may be deployed at known spaced-apart intervals along the length of portion 16 of second wellbore 14. More specifically, each latch coupling 30 is carried on a latch coupling casing section 28a. Although not necessary, in certain embodiments, casing 28 may also include a window casing section 28b. Window casing section 28b may include a portion on the interior of casing section 28b with a diminished thickness (relative to the thickness of the overall casing joint) to enhance formation of a window during drilling. Alternatively, a window may be pre-milled in the casing section 28b. In other words, a portion of the window is “preformed” or “pre-milled” in casing section 28b. In this regard, at the point where the window is pre-formed or per-milled, window casing section 28b may include a support sleeve or cladding 29 disposed adjacent the area of the diminished thickness in order to provide structural support to casing section 28b. Sleeve 29 is preferably formed of a material that is easier to mill than the material forming the overall casing joint. For example, sleeve 29 may be formed of a non-ferrous material such as aluminum, fiberglass or similar material.
Disposed within second wellbore 14 is a guided milling system 32 carried on a pipe string 34. Guided milling system 32 includes a mill 36, a guide section 38, and a latch 40. In some embodiments, mill 36 is a milling blade, drill head or other cutting apparatus. Latch 40 is disposed to engage a keyed latch coupling 30 to axially and radially orient milling system 32 within casing 28 in order to establish hydraulic communications by methods described herein. Guided milling system 32 may further include an engagement mechanism 42 used to secure mill 36 to guide section 38 during run-in or deployment within second wellbore 14. In certain embodiments, engagement mechanism 42 may be one or more shear pins, hydraulically actuated locking dogs or the like.
The particular guided milling system 32 illustrated in
As milling blade 36 transitions to the second position, milling blade 36 engages casing 28. Thereafter, when milling blade 36 is in the second position, continued axial movement of milling blade 36 results in the milling of window 50 in casing 28, thereby exposing the interior of casing 28 to formation 12. It will be appreciated that because of the desirability to form window 50 in casing 28 so that the window is best oriented to face casing 24, a track-guided or similar precision milling assembly is preferred. Such a system will establish a known geometric window, prevent roll-off as may be experienced with other types of milling systems, and foreshorten a window aperture.
A perforation tool may be included on pipe string 34 above or below guided milling system 32, or may be separately conveyed into wellbore 14 once guided milling system 32 has been removed. For purposes of the description, a perforation tool 52 will be illustrated as carried on pipe string 34 below guided milling system 32. However, the disclosure is not limited to this particular configuration. Moreover, it should be understood that perforating tool 52 is not necessary for all embodiments, but may be utilized to enhance fluid flow through the formation 12 between first wellbore 10 and second wellbore 14 in some cases.
Thus, in
Preferably, the perforating tool 52 is positioned, sealed and secured in the casing 28 by a packer 58. The packer 58 seals off an annulus formed radially between the tubular string 52 and the wellbore 14. A firing head 60 is used to initiate firing or detonation of charges 62 of perforating tool 52 (e.g., in response to a mechanical, hydraulic, electrical, optical or other type of signal, passage of time, etc.), when it is desired to form the perforations 56. Although the firing head 60 is depicted in
In any event, it will be appreciated that perforating tool 52 is disposed to discharge or ignite charges 62 arranged only along a select portion of the radius of tool 52 so that the charges 62 form perforations 56 only through window 50. Moreover, due to the close proximity of wellbore 14 to wellbore 10, perforating tool 52 can also form perforations 26 (see
Turning to
The particular guided milling system 32 illustrated in
With reference to
It will be appreciated that the latch coupling 30 and latch 40 assembly descried herein eliminates the need for a conventional milling anchor device and maintains full bore access to the lower main bore.
In step 130, a window is milled in the casing of the second well at the portion of the second well adjacent the selected portion of the first well. The window is milled so as to be facing the first well. To accomplish this step, a guided milling system is deployed in the second well. The guided milling system is preferably oriented by engaging a latch of the guided milling system with a latch coupling carried by the casing of the second well. Thus, during drilling and casing of the second well, the casing may be include one or more latch couplings disposed along or adjacent to the relevant portion of the second well. Additionally, the deployed casing may include an aluminum sheath or portion at the area to be milled.
In certain embodiments, the milling system may be a track guided milling system, so that the method includes guiding the mill along a track or constrained path in order to more precisely form the window. In such system, the mill, such as a blade, is often supported by a bearing that moves along the track. In other embodiments, rather than a guide section having a track or constrained path, a whipstock may be deployed to guide the mill into contact with the casing of the second well.
Typically, during run-in, a release mechanism may be used to lock the guide of the guided milling system to the mill. Once in position, the release mechanism can be actuated, sheared or ruptured, as the case may be, to disengage the guide from the mill so that milling can proceed.
In step 140, a fluid is introduced into the second well and pumped or otherwise driven through the milled window, through the formation between the first and second wells and into the first well. Typically, such a procedure may be used to control pressure within the first well, such as when it is desired to kill the first well. Thus, the fluid is typically pumped under pressure. The fluid may be a drilling mud, cement or other gas, foam or fluid weighted material.
An additional step 150 may be performed after the window is milled in order to promote or enhance fluid flow from the second well through the formation to the first well. In step 150, the formation may be perforated by discharging a perforating tool through the window. To the extent the casing of the target wellbore is not perforated, in addition to perforating the formation, the discharged perforating tool may be used to also perforate the casing of the target wellbore. In other words, the casing of the target wellbore is perforated externally.
In addition to perforating the casing of the target wellbore, or alternatively thereto, in step 150, the casing of the target wellbore may be milled or drilled using a mill as described herein. It will be appreciated that any of the perforating, milling or drilling of the target casing from the second wellbore is enhanced by ensuring that the second wellbore is in close proximity and axially parallel with the first wellbore. As with the milling of the window itself, proper orientation of the perforating tool, and hence the charges thereon, is desirable so that the discharge is limited to discharge in the radial direction of the milled window. Therefore, the latch coupling may be used to engage a latch on the perforating tool. Alternatively, the latch carried by the guided milling system can be engaged with a second latch (such as 30′ in
Because of the need for precision in performing the steps recited above, the latch and latch coupling as utilized are important in certain embodiments of the invention. A latch may be included on any of the components of the system as described herein, such as the guide or the perforating tool. To further ensure proper axial positioning and radial orientation of the milling system in the second wellbore, a hydraulic locking tool may be utilized to transport and deploy a guide section in the second wellbore. The hydraulic locking system extends at least partially into the guide section and secures thereto. The hydraulic locking system includes pistons or other engagement mechanism for coupling the hydraulic locking system to the guide section for deployment and/or retrieval. Once the latch of the guide section engages the latch coupling, the hydraulic locking tool is disengaged from the guide section so that milling operations can proceed.
To further ensure proper radial orientation of the milling system in the second wellbore, an alignment sub may be deployed in the second wellbore casing between a latch coupling casing and the window casing. The alignment sub permits the window casing to be axially rotated relative to the latch coupling casing in order to adjust for misalignment between the two. Thus, an actual make-up position of the latch coupling casing is determined relative to the window casing. An adjustment ring on the alignment sub may then be utilized to compensate for the difference between the actual and desired positions of the two casing sections so that when the latch of the guided milling system and/or the latch of the perforating tool engages the latch coupling, the guided milling system and/or perforating tool, as the case may be, is properly oriented for the hydraulic communication procedures described herein.
Moreover, while it is desirable to mill a suitable window 50 with only a first pass of a milling system as described herein, it will be appreciated that multiple passes may be necessary to sufficiently enlarge window 50 or excavate formation 12 in order to establish a desired level of hydraulic communication between first wellbore 10 and second wellbore 14. Thus, for example, the milling system illustrated in
Filing Document | Filing Date | Country | Kind |
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PCT/US13/57104 | 8/28/2013 | WO | 00 |