Embodiments disclosed herein relate to well intervention 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.
In the field of hydrocarbon exploration and extraction, it is sometimes necessary to establish fluid communication between two wells.
One example occurs in the situation where it becomes necessary to drill a relief well to intersect an existing well, as in the case where the casing of the existing well has ruptured and it becomes necessary to plug the existing well at or below the point of the rupture to bring it under control. In order to do this, the relief well must be drilled to intersect the original well at the desired level, thus establishing fluid communication between the two wells. The relief well provides a conduit for injecting a fluid, such as mud or cement, into the existing, or target, well.
Since such ruptures, or blowouts, often produce extremely hazardous conditions at the surface in the vicinity of the original well, the relief well usually must be started a considerable distance away from the original wellhead. A relief well is typically drilled as a generally vertical hole down to a planned kickoff point, where the relief well is turned toward the target well using conventional directional drilling technology and thereafter drilled as a deviated well. Drilling of the deviated portion of the relief well is thereafter continued until the relief well intersects the target well, thereby establishing hydraulic communication between the two wells.
Because the same problems of control of the direction of drilling that were encountered in the original well are also encountered in drilling the relief well, the location of the relief well borehole also cannot be known with precision; accordingly, it is extremely difficult to determine the distance and direction from the end of the relief well to the desired point of intersection on the target well. In addition, the relief well usually is very complex, compounding the problem of knowing exactly where it is located with respect to a target that may be 10 inches in diameter at a distance of thousands of feet below the earth's surface.
Moreover, in order to minimize the risk of bit or mill deflection, whereby the bit or mill of the relief well is deflected by the casing of the target well upon impact, the incident angle, i.e., the angle at intersection of the two wellbores, is commonly kept to no more than 6 degrees. Because of the small size of the intersection point, greater care must be exercised during the final approach and breach, which costs time and tries patience, in order to intersect the two wells to establish fluid communication.
The foregoing disclosure may repeat reference numerals and/or letters in the various examples. This repetition is for the purpose of simplicity and clarity and does not in itself dictate a relationship between the various embodiments and/or configurations discussed. Further, spatially relative terms, such as “beneath,” “below,” “lower,” “above,” “upper,” “uphole,” “downhole,” “upstream,” “downstream,” and the like, may be used herein for ease of description to describe one element or feature's relationship to another element(s) or feature(s) as illustrated in the figures. The spatially relative terms are intended to encompass different orientations of the apparatus in use or operation in addition to the orientation depicted in the figures. For example, if the apparatus in the figures is turned over, elements described as being “below” or “beneath” other elements or features would then be oriented “above” the other elements or features. Thus, the exemplary term “below” can encompass both an orientation of above and below. The apparatus may be otherwise oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein may likewise be interpreted accordingly.
Wellbore fluid communication for relief wells, coalbed methane drilling, wellbore re-entries for remediation, enhanced production, or plug and abandon operations can be achieved by positioning a portion of a relief well to be adjacent, but spaced apart from a target well, and thereafter perforating in the radial direction of the target well. A latch mechanism is disposed in the casing of the relief well to axially and radially orient a perforation tool, thereby allowing discreet, selective discharge of the perforation tool only in the direction of the target well. A non-rotational packer may be utilized in conjunction with the latch mechanism to ensure that engagement of the latch does not affect sealing of the annulus of the relief well.
With reference to
A second or relief wellbore 22 is also shown in the formation 12 extending from a well head 14 associated with a drilling structure 18b. Drilling structure 18b may be the same or a different drilling structure from drilling structure 18a. Drilling structures 18a, 18b 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 10, 22 may extend from land or may be formed at the bottom of a body of water (not shown). In the illustrated embodiment, first wellbore 10 includes a distal or terminus end 24 and second wellbore 22 includes a distal or terminus end 26. Also illustrated is a fluid source 28 for fluid introduced into second wellbore 22.
Although the orientation of the second wellbore is not limited except as disclosed herein, in one or more embodiments, second wellbore 22 is drilled to have a substantially vertical portion 30 extending from surface 16, a kickoff point 32 and a deviated portion 34 extending from the kickoff point 32 along a select trajectory 36 so that second wellbore 22 is drilled so that a portion 38 of second wellbore 22 is disposed adjacent a portion 40 of first wellbore 10.
Preferably, portion 38 of second wellbore 22 is substantially parallel to portion 40 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. As noted above, the particular orientation of the parallel portions of the adjacent wellbores are not limited to a particular orientation so long as they are in proximity to one another as described herein.
It should be noted that first and second wellbores 10, 22 preferably do not intersect at the adjacent portions 38, 40, 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 38, 40 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 22 is to the first wellbore 10, the more effective the method and system for establishing hydraulic communication therebetween.
Although the trajectory 36 of second wellbore 22 need not follow any particular path so long as a portion 38 is positioned relative to a portion 40 of the first wellbore 10, as shown, second wellbore 22 includes a first substantially vertical leg 42. Kickoff is initiated at point 32 in order to guide second wellbore 22 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 44 to form portion 38 of second wellbore 22.
As will be described below, hydraulic communication between second wellbore 22 and first wellbore 10 will be established at the respective adjacent portions 38, 40. First wellbore 10 may be cased or uncased at portion 40. To the extent portion 40 is cased, portion 40 may be selected to have perforations 46 (shown in
Finally, disposed within the second wellbore 22 is a perforating system 48 for establishing the fluid communication between the two wellbores 10, 22. Perforating system 48 is carried on a tubing string 50 extending from drilling structure 18b, and generally includes a latch assembly 52, a perforating gun 54, and a firing head 56. In one or more embodiments, perforating system 48 may further include a non-rotational packer 58.
Turning to
In one or more embodiments, second wellbore 22 includes casing 64. Casing 64 may include a milled window 66 disposed between second wellbore 22 and first wellbore 10 and through which perforations 68 are formed in the formation 12 between the two wellbores 10, 22. In one or more other embodiments, rather than a milled window 66, perforations 68 may be formed in casing 64 and extent out into formation 12 towards first wellbore 10. In any event, as described in more detail below, in one or more embodiments, perforations 68 are selectively formed about the radius of second wellbore xx so as to extend only between second wellbore 22 and first wellbore 10 in a select radial direction 69. Not only does this maximize fluid communication with first wellbore 10, it also minimizes inflow of formation fluid and minimizes the risk of damage to, as well as unintended fluid communication with, other wellbores which may be disposed in the formation 12 about first and second wellbores 10, 22.
Turning to
With particular reference to
Latch coupling 72 has a generally tubular body 76 having an internal bore 77, an upper connector 78 and a lower connector 80 suitable for connecting latch coupling 72 to other selections of casing 64 via a threaded connection, a pinned connection or the like. Latch coupling 72 includes an internal latch profile 82, along the internal bore 77, including a plurality of axially spaced apart recessed grooves 84, such as 84a-84h that extend circumferentially about bore 77 of latch coupling 72. Preferably, recessed grooves 84 extend about the entire circumference of internal bore 77 of latch coupling 72. Latch profile 82 also includes an upper groove 86 having a lower square shoulder 88 and an upper angled shoulder 90. Latch profile 82 further includes a lower groove 92 having a lower angled shoulder 94 and an upper angled shoulder 96.
Latch profile 82 also has a plurality of circumferential alignment elements depicted as a plurality of recesses 98 disposed within the inner bore 77 of latch coupling 72. In the illustrated embodiment, there are four sets of two recesses that are disposed in different axial and circumferential positions or locations within the inner bore 77 of latch coupling 72. For example, a first set of two recesses 98a, 98b are disposed along inner bore 77 at substantially the same circumferential positions and different axial positions. A second set of two recesses 98c, 98d are disposed along inner bore 77 at substantially the same circumferential positions and different axial positions. A third set of two recesses 98e, 98f are disposed along inner bore 77 at substantially the same circumferential positions and different axial positions. A fourth set of two recesses 98g, 98h are disposed along inner bore 77 at substantially the same circumferential positions and different axial positions.
As shown, recesses 98a, 98b are disposed within the inner surface of latch coupling 72 at a ninety degree circumferentially interval from recesses 98c, 98d. Likewise, recesses 98c, 98d are disposed within the inner surface of latch coupling 72 at a ninety degree circumferentially interval from recesses 98e, 98f. Finally, recesses 98e, 98f are disposed within the inner surface of latch coupling 72 at a ninety degree circumferentially interval from recesses 98g, 98h. Preferably, recesses 98 only partially extend circumferentially about the internal bore 77 of latch coupling 72.
Latch profile 82 including the circumferential alignment elements creates a unique mating pattern operable to cooperate with the latch key profile associated with a desired latch assembly, such as described below, to axially and circumferentially anchor and orient a perforating gun in a particular desired circumferential orientation relative to the latch coupling 72 during wellbore intervention operations. The specific profile of each latch coupling 72 can be created by varying one or more of the elements or parameters thereof. For example, the thickness, number and relative spacing of the recesses 98 can be altered.
With particular reference to
Each of the latch keys 106 has a unique key profile 112, such as key profiles 112a, that enables the anchoring and orienting functions of latch assembly 52 with a mating latch coupling 72 having the appropriate latch profile 82 (see
With reference to
In one or more alternative embodiments, the shaped charges 118 and scallops 116 may be arranged about the radius of carrier 114, such as in a helical or other configuration. However in such case, the shaped charges are not interconnected by detonating cord, but are selectively and individually detonatable, so that only those shaped charges 118 facing in a limited or discreet select radial direction may be detonated.
Alternatively, in one or more embodiments, perforating gun 54 may include multiple groups 124 of shaped charges 118 and scallops 116 arranged in a linear configuration, wherein each group 124 is spaced apart from the other groups 124 about the radius of carrier 114 and each group faces in only a limited or discreet radial direction that is different from the other groups. In such case, the shaped charges in a group 124 are interconnected by separate lengths of detonating cord 122, each group 124 being selectively and individually detonatable so that only those shaped charges 118 facing in a limited or discreet select radial direction may be detonated.
It will be appreciated that except as to the positioning of a charge or group of charges to fire in a limited or discreet radial direction, the perforating gun 54 described herein is not limited to a particular type of perforating gun assembly, and that the forgoing general components are provided for illustrative purposes only.
A firing head assembly 56 is also illustrated in
Turning to
Although the disclosure is not limited to a particular type of non-rotational packer,
More specifically, the seal elements 136 are slidably mounted onto the external surface of a packer mandrel 138, and are displaced longitudinally and expanded radially as a setting force is applied downward by a force transmission device 140, such as a tube guide. The disclosure is not limited to any particular system for applying the setting force, and as such, the setting force may be actuated mechanically, hydraulically or by some other mechanism.
In any event, the seal elements 136 are confined axially between an upper compression member 142, such as a connecting sub, and a lower compression member 144, such as setting cylinder. As the tube guide 140 is moved downwardly by the axial setting force, the force is transmitted through the tube guide 140 and connecting sub 142 against the seal elements 136. Likewise, the setting force is transmitted to the setting cylinder 144, which engages the anchor slips 134. In one or more embodiments, the setting cylinder 144 has a longitudinal slot 146 in which a guide pin 148 is received. The seal elements 136 are carried by a slidable mandrel 150. The guide pin 148 is secured to the slidable mandrel 150. The guide pin 148 stabilizes and radially confines movement of the setting cylinder 144 relative to the tube guide 140, connecting sub 142 and slidable mandrel 150 as setting force is applied. Additionally, the guide pin 148 rotationally locks the setting cylinder 144 to the outer packer components to accommodate transfer of a rotational force through packer 58.
As mentioned, the setting force is transmitted to the anchor slips 134 through downward movement of the setting cylinder 144. More specifically, the setting cylinder 144 is coupled to a cam assembly 152 of the anchor slip 134. The cam assembly 152 extends between the external surface of the packer mandrel 138 and the cam surface of a slip carrier 154 to which outwardly facing slips 134 are attached. The cam assembly 152 includes a top cam 156, such as a top spreader cone, and a bottom cam 158, such as a bottom spreader cone, each with a cam surface disposed to engage the cam surface of the slip carrier 154. In one or more embodiments, the cam surfaces are frustoconical wedges which are generally complementary to an outwardly sloping, slanted upper cam surface of the slip carrier 154. Upon application of an axial force to the cam assembly 152 by the setting cylinder 144, the slip carrier 154 is forced radial outward, urging the slips 134 into contact with the wall of casing 64. Axial movement of the spreader cone 156 is stabilized by a cap screw 160. The cap screw 105 is slidably received within a longitudinal slot 162 which intersects the slip carrier 154. The shank of the cap screw 160 is fastened in a threaded bore in the top spreader cone 156 and projects radially into the slot 162, thereby preventing rotation of the spreader cone and upper wedge relative to the slip carrier 154.
When it is necessary to transmit a deviated bore, or a tight bend of a horizontal completion, occasionally high amounts of torque are required to be transmitted through the packer and into the lower section of perforating system 48. To enhance the transmission of torque through packer 58, an anti-rotation lug 164 which projects radially from the lower portion of bottom cam 158 is provided. The anti-rotation lug 164 projects into a longitudinal slot 166 of slip carrier 154. Longitudinal travel of the slip carrier 154 relative to the anti-rotation lug 164 is permitted by the slot 166 which is formed in the slip carrier 154. While the longitudinal slot 166 formed in the slip carrier 154 permits relative longitudinal movement of the slip carrier 154 relative to bottom cam 158, the radially projecting head portion of lug 164 provides a rotational lock between the slip carrier 154 and the bottom cam 158, thereby preventing rotation of the slip carrier 154 relative to the bottom cam 158 during running and setting operations.
Turning to
In particular, there is shown a lower tubular 167 separating the latch assembly 52 from the perforating gun 54 a known length or distance “L”. During make-up of perforating system 48, the length “L” of lower tubular 167 may be adjusted as necessary to position the perforating gun 54 adjacent the intended area of perforation. While the latch assembly 52 is preferably positioned below the perforating gun 54, it will be appreciated that in one or more embodiments, the latch assembly 52 could be positioned above the perforating gun 54 on lower tubular 167, so long as the relative axial distance “L” between the latch assembly 52 and the perforating gun 54 is known.
Also illustrated in
With reference to
With the second wellbore drilled, in step 184, at least a portion of the second wellbore is cased in order to position a latch coupling along the length of the second wellbore, preferably in the vicinity of or in proximity to the portion of the second wellbore that is adjacent the target location of the first wellbore. In one or more embodiments, the second wellbore is cased to at least the axial distance “L” below the identified target location of the first wellbore. The casing may be installed and cemented in place as is well known in the industry. The casing at the axial distance “L” includes a latch casing section in which a latch coupling is installed in the casing, as described above. The latch casing is positioned in the second wellbore so that the latch coupling is in a particular orientation, using methods known in the art. While the latch assembly is preferably positioned below the perforating gun in makeup of a perforating system, in cases where the latch assembly is positioned above the perforating gun, then the latch casing section will likewise be positioned in the second wellbore an axial distance “L” above the location desired for establishing fluid communication. This distance “L” corresponds to the separation in a tool string between a perforating gun and a latch assembly, as described above.
In step 186, the perforating system, and in particular the perforating gun, is picked up and run into the second wellbore on a tubing string to a first or measurement position, wherein the perforating system is in the vicinity or proximity of the target location so that a latch assembly run in with the perforating gun is spaced apart from the latch coupling of the casing. It will be appreciated that at this point, when the perforating gun is in the first position, the latch assembly is not engaged with the latch coupling. In one or more embodiments, the perforating system is run into the second wellbore short of, i.e., upstream of, the target location. For example, the perforating system may be run into the second wellbore a distance of approximately 90 feet above or upstream of where the latch casing section is positioned in the second wellbore.
In any event, once the perforating system is positioned in the vicinity of or proximity to the target location, but before the latch assembly is engaged with the latch coupling, i.e., the first position, in step 188, one or more tubing string parameters are determined in order to establish baseline tubing string parameters against which further manipulation of the tool string can be compared. These tubing string parameters may include the weight of the tubing string, the torque required to rotate the tubing string at a select rate, the pick-up weight of the tubing string, the slack-off weight of the tubing string or the axial force need to urge the tubing string forward. Since the axial position of the perforating system in the wellbore effects these parameters, those skilled in the art will appreciate that these parameters cannot be accurately measured at the surface, but must be determined once the perforating system is at the approximate depth where fluid communication is to be established. In any event, as will be explained, thereafter, changes in one or more of these parameters can be utilized to orient the perforating gun. For example, a decrease or slack in the weight of a tubing string being lowered into the second wellbore indicates that the latch assembly on the tubing string may have landed in the latch coupling of the casing.
In step 190, the tubing string is urged forward in the second wellbore under a first axial force so that the latch assembly of the perforating tool 48 approaches the latch coupling mounted on the casing. In vertical wellbores, first axial force may be the weight of the tubing string and which may be sufficient to move the tubing string forward. In deviated wellbores, the first axial force may be an applied forced as required to move the tubing string forward. In any case, the tubing string is urged forward until a change is observed or identified in the tubing string parameters previously determined. In the case of a tubing string being lowered into a wellbore, such a change may be a decrease in weight or slack off in weight of the tubing string. In the case of a tubing string being pushed into the wellbore under an axial force, such a change may be an increase in the force needed to urge the tubing string forward. In any event, such a change signifies that the latch assembly of the perforating tool has engaged, is abutting or is otherwise adjacent the latch coupling of the casing.
In step 192, a rotational force is applied to the tubing string thereby causing the tubing string, and in particular the latch assembly carried by the tubing string, to rotate. In or or more embodiments, the rotational force is applied at the select rotational rate utilized during determination of tubing string parameters and the torque is observed. In one or more embodiments, the rotational force is applied at the same time or contemporaneously with, the tubing string is urged axially forward. In one or more embodiments, the tubing string is rotated at a comparatively slow rate, such as for example, in the approximate range of 5-10 revolutions per minute. Those skilled the art will appreciate that a rotational speed that is comparatively slow will allow a change in the tubing string parameters, and particularly, a change in the torque required to maintain the select rotational speed, to be readily identified.
As stated, in one or more embodiments, the tubing string is rotated and moved forward at the same time. As such, an operator may observe two changes in the tubing string parameters which together are indicative that the latch coupling has fully engaged the latch coupling. To the extent the wellbore is vertical, an operator may observe a slack off in weight, i.e., a change in the first axial force, coupled with an increase in torque, indicating that the latch assembly has landed in the latch coupling and that the latch assembly has rotated in the latch coupling until the spring loaded keys have engaged a radial recess, thereby rotationally securing the latch assembly to the latch coupling. The slack off in weight is due to the fact that the latch coupling is at least partially supporting the downward weight of the tubing string, while the increase in torque indicates that the keys of the latch assembly have engaged the radial recesses of the latch coupling. To the extent the latch is positioned in a horizontal or deviated portion of the second wellbore, an operator may observe an increase in the axial forced required to urge the tool string forward coupled with an increase in torque, indicating that the latch assembly has landed in the latch coupling and that the latch assembly has rotated in the latch coupling until the keys have engaged a radial recess, thereby rotationally securing the latch assembly to the latch coupling.
In either case, it will be appreciated that thereafter, an additional change in the tubing string parameters may be observed to indicate that the latch assembly has fully engaged the latch coupling as desired. Specifically, the pick-up weight will increase, the tubing string being constrained from upward or upstream axial movement by the engagement of the latch assembly with the coupling.
In any event, it will be appreciated that because a non-rotating packer is utilized in one or more embodiments, the rotational force is passed through the non-rotating packer to the latch assembly so as not to prematurely set the packer, thus allowing the latch assembly to be manipulated as described herein. Moreover, it will be appreciated that the latch system allows the charges of a perforating gun to be radially aligned so that only a select charge or set of charges are facing the target wellbore. In one or more embodiments, the perforating gun may have different sets of charges, such as for example, charges set for different depth or with different detonation characteristics, and the application of the axial and rotational forces can be manipulated to position or re-position a particular set of charges to face the target wellbore.
Thus, in one or more embodiments, once the latch system is engaged and a first set of charges is facing the target wellbore, based on one or more measured or observed parameters in the wellbore, the tubing string may be picked up or set down and rotated until the latch assembly has a different orientation in the latch coupling, and a second set of charges is facing the target wellbore.
In step 194, once the latch assembly has been seated in the latch coupling to the desired radial position, a packer is actuated. In one or more embodiments, the packer is actuated by applying a second axial force in order to actuate a non-rotational packer. Specifically, the second axial force is utilized to set the slips and expand the sealing element of the packer. In one or more embodiments, the weight of the tubing string is applied to the packer, shearing shear pins and thereby actuating the packer.
In step 196, with the latch system engaged and the packer set, the perforating gun is discharged. In one or more embodiments, only those perforating gun charges radially positioned to face the target wellbore are discharged. In one or more embodiments, where multiple sets of perforating gun charges may be carried by a perforating gun, only the set of charges facing in a desired direction of discharged. The perforations between the relief wellbore and the target wellbore establish fluid communication between the two wellbores. Moreover, in one or more embodiments where the perforations are radially oriented to extent only between the relief and target wellbores, inflow of wellbores fluids from the greater formation about the relief wellbore are minimized while maximizing fluid communication with the target wellbore. To the extent the target wellbore is cased, appropriate charges may be selected and utilized in the perforating gun in order to perforate the casing of the target wellbore. Moreover, if it is determined that sufficient fluid communication is not established by the first shot, the packer may be disengaged and the latch assembly re-oriented in the latch coupling in order to select a different set of charges for additional perforations. Once the perforating gun is re-oriented, the packer may be set as described herein and the perforating gun may be once again discharged to enhance the fluid communication between the relief wellbore and the target wellbore.
Finally in step 198, a fluid is introduced into the relief or second well and pumped or otherwise driven through the perforated area 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 disable 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.
Thus, a system for establishing hydraulic flow from a relief wellbore to a target wellbore has been described. Embodiments of the system may generally include a latch assembly carried by a tubular string; a non-rotational packer carried by the tubular string; and a perforating gun carried by the tubular string. In other embodiments, a system for establishing hydraulic flow from a relief wellbore to a target wellbore may generally include a first well; a second well adjacent the first well along a portion of the length of the second well, the second well having casing disposed along said portion with a latch coupling carried by the casing of the second well, the latch coupling comprises a tubular casing section having a latch profile formed along an inner surface of the tubular casing; a latch assembly carried by a tubular string disposed in the second well, the latch assembly comprises a key housing having at least one circumferentially distributed, axially extending key window through which a spring operated latch key is radially outwardly biased, each latch key having an outward facing key profile; a non-rotational packer carried by the tubular string, the non-rotational packer comprises a packer mandrel having a seal element slidingly disposed thereon between an upper compression member and a lower compression member; a radially movable slip assembly having a cam surface and an axially movable cam assembly having a cam surface generally disposed to cooperate with the cam surface of the slip assembly; a radially extending lug carried by the packer and extending through at least one slot longitudinally formed in the packer, thereby constraining actuation of the packer to axial movement; and a perforating gun carried by the tubular string, the perforating gun comprises a tubular body disposed along an axis of the tubing tool string; and a plurality of charges longitudinally aligned along a portion of an axial length of the tubular body, the plurality of charges oriented to face outward from the body along a select radius, wherein the latch assembly is carried at a distal end of the tubular string; the perforating gun is disposed above the latch assembly along the tubular string; and the non-rotational packer is disposed on the tubular string above the perforating gun, and wherein the portion of the second well is drilled to be axially offset from and substantially parallel to a portion of the first well.
For any of the foregoing embodiments, the system may include any one of the following elements, alone or in combination with each other:
Thus, a method for establishing fluid communication between a first wellbore and a second wellbore in a formation has been described. Embodiments of the method may generally include positioning a perforating gun in the second wellbore upstream of a target location for perforation; determining at least one tubing string parameter associated with the perforating gun while in the upstream position; urging the tubing string downstream in the second wellbore until a change in the tubing string parameter is identified; applying torque to the tubing string until an increase in torque is identified thereby securing the perforating gun in a radial position; setting a non-rotating packer by applying an axial force to the non-rotating packer; and discharging the perforating gun in the direction of the first wellbore. In other embodiments, a method for establishing fluid communication may generally include drilling the second wellbore in the formation so that at least a portion of the length of the second wellbore is adjacent a portion of the length of the first wellbore; orienting a perforating gun in the second wellbore by engaging a latch coupling so that one or more charges of the perforating gun are facing the first wellbore; and actuating the perforating gun to discharge the charges and perforate the formation.
For any of the foregoing embodiments, the method may include any one of the following, alone or in combination with each other:
It should be understood by those skilled in the art that the illustrative embodiments described herein are not intended to be construed in a limiting sense. Various modifications and combinations of the illustrative embodiments as well as other embodiments will be apparent to persons skilled in the art upon reference to this disclosure. It is, therefore, intended that the appended claims encompass any such modifications or embodiments.
Filing Document | Filing Date | Country | Kind |
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PCT/US2014/063220 | 10/30/2014 | WO | 00 |