Straddle packer with fluid pressure packer set and automatic stay-set

Abstract

A straddle packer has a floating auto-J sleeve that automatically shifts the straddle packer from a run-in condition to a stay-set condition after pumping of high-pressure fluid into the straddle packer in excess of a predetermined pump rate is terminated. In the stay set condition, packer elements of the straddle packer remain in sealing contact with a well casing or well bore into which the straddle packer has been run.

Claims

1. A straddle packer with fluid pressure packer set and automatic stay-set, comprising: a floating auto-J sleeve that rotates freely on a piston mandrel of a modular pressure cylinder of the straddle packer, the floating auto-J sleeve including a continuous auto-J groove in an outer periphery thereof, the auto-J groove including a plurality of auto-J groove run-in slots and a plurality of auto-J groove stay-set slots; and a plurality of auto-J pins installed in a piston sleeve of the modular pressure cylinder, the piston sleeve reciprocating with respect to the piston mandrel in response to fluid pressure pumped into the straddle packer, and the plurality of auto-J pins being respectively received in and sliding within the continuous auto-J groove as the piston sleeve reciprocates with respect to the piston mandrel and the auto-J sleeve rotates on the piston mandrel.

2. The straddle packer as claimed in claim 1 wherein the auto-J sleeve is restrained from axial movement on the piston mandrel by an auto-J sleeve uphole end that abuts a piston connected to the piston mandrel and an auto-J sleeve downhole end that abuts a lower packer element compression bell connected to the piston mandrel.

3. The straddle packer as claimed in claim 1 wherein when the auto-J pins are in the auto-J run-in slots, first and second packer elements of the straddle packer are in a relaxed condition that permits the straddle packer to be moved within a well casing or a well bore.

4. The straddle packer as claimed in claim 1 further comprising a plurality of auto-J groove pressure-set slots in the continuous auto-J groove.

5. The straddle packer as claimed in claim 4 wherein when the auto-J pins are in the auto-J groove pressure-set slots, first and second packer elements of the straddle packer are in a pressure boosted set condition and provide a high-pressure fluid seal against a well casing or a well bore into which the straddle packer has been run.

6. The straddle packer as claimed in claim 4 wherein respective ones of the plurality of auto-J groove pressure-set slots are between respective ones of the plurality auto-J run-in slots and respective ones of the plurality of auto-J groove stay-set slots.

7. The straddle packer as claimed in claim 1 further comprising a plurality of auto-J groove shift slots in the continuous auto-J groove.

8. The straddle packer as claimed in claim 7 wherein respective ones of the plurality of auto-J groove shift slots are between respective ones of the auto-J groove stay-set slots and respective ones of the auto-J run-in slots.

9. The straddle packer as claimed in claim 1 wherein when the auto-J pins are in the auto-J groove stay-set slots, first and second packers of the straddle packer provide a high-pressure fluid seal with a well casing of a well bore into which the straddle packer has been run.

10. The straddle packer as claimed in claim 1 wherein the plurality of auto-J pins comprises four auto-J, pins.

11. A straddle packer with fluid pressure packer set and automatic stay-set, comprising: a floating auto-J sleeve that rotates freely on a piston mandrel of a modular pressure cylinder of the straddle packer, the floating auto-J sleeve including a continuous auto-J groove in an outer periphery thereof, the auto-J groove including a plurality of auto-J groove run-in slots, a plurality of auto-J groove pressure-set slots, a plurality of auto-J groove stay-set slots and a plurality of auto-J groove shift slots; and a plurality of auto-J pins installed in a piston sleeve of the modular pressure cylinder, the piston sleeve reciprocating with respect to the piston mandrel in response to fluid pressure pumped into the straddle packer, and the plurality of auto-J pins being respectively received in and sliding within the continuous auto-J groove as the piston sleeve reciprocates with respect to the piston mandrel and the auto-J sleeve rotates on the piston mandrel.

12. The straddle packer as claimed in claim 11 wherein the auto-J sleeve is restrained from axial movement on the piston mandrel by an auto-J sleeve uphole end that abuts a piston connected to the piston mandrel and an auto-J sleeve downhole end that abuts a lower packer element compression bell connected to the piston mandrel.

13. The straddle packer as claimed in claim 12 wherein when the auto-J pins are in the auto-J run-in slots, first and second packer elements of the straddle packer are in a relaxed condition that permits the straddle packer to be moved within a well casing or a well bore.

14. The straddle packer as claimed in claim 12 wherein when the auto-J pins are in the auto-J groove pressure-set slots, first and second packer elements of the straddle packer are in a pressure boosted set condition and provide a high-pressure fluid seal against a well casing or a well bore into which the straddle packer has been run.

15. The straddle packer as claimed in claim 12 wherein respective ones of the plurality of auto-J groove pressure-set slots are between respective ones of the plurality auto-J run-in slots and respective ones of the plurality of auto-J groove stay-set slots.

16. The straddle packer as claimed in claim 12 wherein respective ones of the plurality of auto-J groove shift slots are between respective ones of the auto-J groove stay-set slots and respective ones of the auto-J run-in slots.

17. The straddle packer as claimed in claim 12 wherein when the auto-J pins are in the auto-J groove stay-set slots, first and second packers of the straddle packer provide a high-pressure fluid seal with a well casing of a well bore into which the straddle, packer has been run.

18. The straddle packer as claimed in claim 12 wherein the plurality of auto-J pins comprises four auto-J pins.

19. A straddle packer with fluid pressure packer set and automatic stay-set, comprising: a floating, auto-J sleeve that rotates freely on a piston mandrel of a modular pressure cylinder of the straddle packer but is restrained from axial movement thereon, the floating auto-J sleeve including a continuous auto-J groove in an outer periphery thereof, the auto-J groove including a plurality of auto-J groove run-in slots, a plurality of auto-J groove pressure-set slots, respective ones of the auto-J groove pressure-set slots being adjacent a first side of respective ones of the plurality of auto-J groove run-in slots, a plurality of auto-J groove stay-set slots, respective ones of the plurality of stay-set slots being adjacent respective ones of the respective auto-J groove pressure-set slots, and a plurality of auto-J groove shift slots, the plurality of auto-J groove shift slots being between respective ones of the plurality of auto-J groove stay-set slots and a second side of the respective ones of the auto-J groove run-in slots; and a plurality of auto-J pins installed in a piston sleeve of the modular pressure cylinder, the piston sleeve reciprocating with respect to the piston mandrel in response to high-pressure fluid pumped into the straddle packer, and the plurality of auto-J pins being respectively received in and sliding within the continuous auto-J groove as the piston sleeve reciprocates with respect to the piston mandrel and the auto-J sleeve rotates on the piston mandrel.

20. The straddle packer as claimed in claim 19 wherein four auto-J pins installed in the piston sleeve, four auto-J groove run-in slots, four auto-J groove pressure-set slots, four auto-J groove stay-set slots, and four auto-J groove shift slots.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Having thus generally described the nature of the invention, reference will now be made to the accompanying drawings, in which:

(2) FIG. 1 is a perspective view of an embodiment of a straddle packer with fluid pressure packer set and automatic stay-set in accordance with the invention in a run-in condition;

(3) FIG. 2 is a cross-sectional view taken between lines 2..4-2..4 of FIG. 1, of a modular cylinder portion of the straddle packer in the run-condition;

(4) FIG. 3 is a cross-sectional view taken between lines 2..4-2..4 of FIG. 1, of the modular cylinder portion of the embodiment of the straddle packer in a packer set condition;

(5) FIG. 4 is a cross-sectional view taken between lines 2..4-2..4 of FIG. 1 of the modular cylinder portion of the embodiment of the straddle packer in a stay-set condition;

(6) FIG. 5 is a perspective view of a floating auto-J sleeve with an auto-J groove in accordance with one embodiment of the invention;

(7) FIG. 6 is a side elevational view of the floating auto-J sleeve shown in FIG. 5;

(8) FIG. 7a is an orthographic projection of the auto-J groove of the floating auto-J sleeve shown in FIG. 5, illustrating a location of auto-J pins when the straddle packer is in a run-in condition;

(9) FIG. 7b is an orthographic projection of the auto-J groove of the floating auto-J sleeve shown in FIG. 5, illustrating a location of the auto-J pins when the straddle packer is in a pressure-boosted set condition after moving from the run-in condition shown in FIG. 7a;

(10) FIG. 7c is an orthographic projection of the auto-J groove of the floating auto-J sleeve shown in FIG. 5, illustrating a location of the auto-J pins when the straddle packer is in a stay-set condition after moving from the pressure-boosted set condition shown in FIG. 7b; and

(11) FIG. 7d is an orthographic projection of the auto-J groove of the floating auto-J sleeve shown in FIG. 5, illustrating a location of the auto-J pins when the straddle packer is in a pressure-boosted shift condition after moving from the stay-set condition shown in FIG. 7c.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(12) The invention provides a straddle packer with a fluid pressure boosted packer set and automatic stay-set for use in precision well stimulation or remediation treatments in either open hole or cased wellbores (hereinafter referred to collectively as wellbores). The automatic stay-set is enabled by a floating auto-J sleeve that rotates freely on a piston mandrel of a hydraulic piston that sets the straddle packer. A plurality of auto-J pins retained in a piston sleeve that surrounds the floating auto-J sleeve on the piston mandrel respectively engage an auto-J track in the floating auto-J sleeve. The auto-J track is designed to automatically shift the straddle packer from a run-in condition to a stay-set condition, or vice versa, each time the straddle packer is set using pumped fluid pressure. In the run-in condition, the packers of the straddle packer are in a relaxed state and do not provide a fluid seal against a surrounding well casing or well bore. In the set condition, the packers are in fluid sealing contact with the well casing or well bore. In the stay-set condition, the packers remain in sealing contact with the well casing or well bore. When the straddle packer is in the run-in condition, pumping high-pressure fluid into the straddle packer at a rate that exceeds a predetermined threshold pump rate will shift the straddle packer to the set condition. When pumping stops, the straddle packer automatically shifts to the stay-set condition. When the straddle packer is to be moved, the pumps are reactivated to return the straddle packer to operational pressure and then stopped again, which automatically shifts the straddle packer back to the run-in condition.

(13) TABLE-US-00001 Part No. Part Description 10 Straddle packer 11 Multicomponent mandrel 13 Multicomponent mandrel central passage 14 Completion string connection 15 Upper packer element compression shoulder 18 Upper packer element 20 Upper compression bell 23 Upper compression bell shoulder 24 Upper sliding sleeve 26 Upper sliding sleeve coupling 27 Slotted sliding sleeve female coupling end 28 Slotted sliding sleeve 29a, 29b Sliding sleeve finger components 30 Mandrel flow sub 32a-32h Mandrel flow sub nozzles 36 Lower sliding sleeve 38 Slotted sliding sleeve captured end coupling ring 48 Modular pressure cylinder 50 Sleeve/cylinder crossover 54a-54d Pressure cylinder modules 56a-56d Pressure pistons 64 Lower compression bell 74 Lower packer element 76 Lower crossover sub 78 Lower packer element compression shoulder 82 Velocity bypass sub 96 Lower end cap 98 Piston mandrel 100 Floating auto-J sleeve 102 Auto-J sleeve uphole end 104 Auto-J sleeve downhole end 106a-d Auto-J pins 108 Auto-J groove 110 Auto-J groove run-in slots 112 Auto-J groove pressure-set slots 114 Auto-J groove stay-set slots 116 Auto-J groove shift slots

(14) FIG. 1 is a perspective view of one embodiment of the straddle packer 10 with fluid pressure packer set and automatic stay-set in the run-in condition. The straddle packer 10 has a multicomponent mandrel 11, the majority of which can only be seen in a cross-sectional view as explained in Applicant's co-pending patent application referenced above. The multicomponent mandrel 11 extends from the uphole end to the downhole end of the straddle packer 10. On the uphole end of the multicomponent mandrel 11, a completion string connection component 12 includes a completion string connection 14. The completion string connection component 12 has an upper packer element compression shoulder 15 that abuts an upper packer element 18. On a downhole side of the upper packer element 18 is an upper compression bell 20 having an upper compression bell shoulder 23 for compressing the upper packer element 18. An upper sliding sleeve 24 is connected to a downhole side of the upper compression bell 20. The upper sliding sleeve 24 is connected to an upper sliding sleeve coupling 26, which is in turn connected to a female coupling end 27 of a slotted sliding sleeve 28. In one embodiment, the slotted sliding sleeve 28 has four slotted sliding sleeve finger components, two of which, 29a, 29d, can be seen in this view. The slotted sliding sleeve finger components define four slots that respectively expose at least one mandrel flow sub nozzle of a mandrel flow sub 30. In this embodiment, the mandrel flow sub 30 has a plurality of mandrel flow sub nozzles (only 32a and 32b are visible in this view). A downhole end of the sliding sleeve finger components are threadedly connected to a slotted sliding sleeve captured end coupling ring 38 that is connected to a lower sliding sleeve 36. A downhole end of the lower sliding sleeve 36 is connected to a sleeve/cylinder crossover 50 that is in turn connected to a modular pressure cylinder 48 assembled by interconnecting a plurality of pressure cylinder modules, 54a-54d in this embodiment. The pressure cylinder module 54d is connected to a lower compression bell 64 that abuts an elastomeric lower packer element 74. A lower crossover sub 76 having a lower packer element compression shoulder 78 abuts a downhole end of the lower packer element 74. A velocity bypass sub 82 is connected to a downhole side of the lower crossover sub 76. A lower end cap 96, which caps the downhole end of the multicomponent mandrel 11, is connected to the velocity bypass sub 82.

(15) The internal components and operation of Applicant's straddle packer with fluid pressure packer set and velocity bypass are described in detail in the above-identified co-pending U.S. patent application Ser. No. 15/961,947, and that description will not be repeated here.

(16) FIG. 2 is a cross-sectional view taken between lines 2..4-2..4 of FIG. 1 of the modular pressure cylinder 48 of the straddle packer 10 in the run-condition. In accordance with the invention, the straddle packer 10 is provided with a floating auto-J sleeve 100, having, an auto-J sleeve uphole end 102 and an auto-J sleeve downhole end 104. The straddle packer 10 is further provided with a plurality of auto-J pins 106 that are installed in the piston sleeve 55d adjacent the lower compression bell 64. In one embodiment there are 4 auto-J pins 106a, 106b, 106c and 106d, only two of which, 106a and 106c, are visible in this cross-sectional view. The floating auto-J sleeve 100 is mounted on a piston mandrel 98 of pressure piston 56d, and rotates freely on the piston mandrel 98, but is restrained from any axial movement by the pressure piston 56d which abuts the auto-J sleeve uphole end 102 and the upper compression bell 20 which abuts the auto-J sleeve downhole end 104. A continuous auto-J groove 108 is machined in an outer periphery of the floating auto-J sleeve 100. One embodiment of the continuous auto-J groove 108 will be described below in detail with reference to FIGS. 7a-7d. The auto-J pins 106a-106d have inner ends that respectively slide within the auto-J groove 108, as will also be explained below in detail. In the run-in condition, the auto-J pins 106a-106d are respectively in auto-J groove run-in slots 110, as better seen in FIG. 7a.

(17) FIG. 3 is a cross-sectional view, taken between lines 2..4-2..4 of FIG. 1, of the modular pressure cylinder 48 of one embodiment of the straddle packer 10 in a packer set condition. As explained in Applicant's above-referenced co-pending patent application, when high pressure fluid is pumped into the straddle packer 10, the modular pressure cylinder 48 compresses the upper packer element 18 and the lower packer element 74 to pressure isolate a section of the wellbore between the respective packer elements 18, 74 after a pumped fluid rate exceeds a predetermined pump, rate threshold. Activation of the modular pressure cylinder 48 induces movement of the pressure cylinder module 54d relative to the pressure piston 56d, which in turn slides the auto-J pins 106a-106d within the auto-j groove 108 towards the uphole end 102 of the floating auto-J sleeve 100. At full pressure-boosted compression of the packer elements 18, 74, the auto-J pins 106a-106d respectively slide into auto-J groove pressure-set slots 112, as best seen in FIG. 7b, effecting a slight rotation of the floating auto-J sleeve 100 on the piston mandrel 98 as the auto-J pins 106a-106d shift to the new location.

(18) FIG. 4 is a cross-sectional view of the modular cylinder portion 48 of the embodiment of the straddle packer 10 taken between lines 2..4-2..4 of FIG. 1, in a stay-set condition. When pumping of high-pressure fluid into the straddle packer 10 is terminated, pressure within a central passage 13 of the straddle packer 10 begins to bleed off and the packer elements 18, 74 start returning to the relaxed, run-in position. This induces relative movement between the pressure cylinder module 54d and the piston mandrel 98, forcing the auto-J pins 106a-106d through the continuous auto-J groove 108 to auto-J groove stay-set slots 114, best seen in FIG. 7c, effecting a further rotation of the floating auto-J sleeve 100 on the piston mandrel 98. In the stay-set condition, the respective packer elements 18, 74 are slightly relaxed from the pressure-boosted condition, but continue to provide a secure high-pressure fluid seal with a well bore or well casing in which the straddle packer 10 is packed off. This permits, as one example, the monitoring of downhole pressure versus time to determine a fracture closure of adjacent geology.

(19) FIG. 5 is a perspective view of the floating auto-J sleeve 100 with the auto-J groove 108 in accordance with one embodiment of the invention. As explained above, the floating auto-J sleeve 100 has the uphole end 102 and the downhole end 104. As further explained above, the auto-J groove 108 is a continuous groove machined around a periphery of the floating auto-J sleeve 100. The continuous auto-J groove 108 includes auto-J groove run-in slots 110, auto-J groove pressure-set slots 112, auto-J groove stay-set slots 114, and auto-J groove shift slots 116, all of which are best seen in FIGS. 7a-7d. FIG. 6 is a side-elevational view of the floating auto-J sleeve 100 shown in FIG. 5.

(20) FIG. 7a is an orthographic projection of the auto-J groove 108 of the floating auto-J sleeve 100 shown in FIG. 5, illustrating a location of the auto-J pins 106a-106d when the straddle packer 10 is in the run-in condition in which the respective packer elements 18, 74 are in a relaxed condition that permits the straddle packer 10 to be run into a well casing or a well bore, or moved freely within the well casing or a well bore. In the run-in condition of the straddle packer 10, the respective auto-j pins 106a-106d are located at or near a downhole end of the respective auto-J run-in slots 110.

(21) FIG. 7b is an orthographic projection of the auto-J groove 108 of the floating auto-J sleeve 100 shown in FIG. 5, illustrating the auto-J pins 106a-106d in auto-J groove pressure-set slots 112. As explained above, the auto-J pins 106a-106d shift automatically from the auto-J run-in slots 110 to the auto-J pressure-set slots 112 when high-pressure fluid is pumped at a sufficient rate into the straddle packer 10. When the auto-J pins 106a-106d are in the auto-J pressure-set slots 112, the respective packer elements 18, 74 are in maximum compression and provide a very high-pressure fluid seal against a well casing or well bore in which the straddle packer 10 is located.

(22) FIG. 7c is an orthographic projection of the auto-J groove 108 of the floating auto-J sleeve 100 shown in FIG. 5, illustrating the auto-J pins 106a-106d in the auto-J groove stay-set slots 114, which keeps the straddle packer 10 in the stay-set condition. As explained above, when the straddle packer 10 is in the stay-set condition, the respective packer elements 18, 74 are slightly relaxed from the pressure-boosted set condition, but still provide a secure high-pressure fluid seal with the well casing or the well bore,

(23) FIG. 7d is an orthographic projection of the auto-J groove 108 of the floating auto-J sleeve 100 shown in FIG. 5, illustrating a location of the auto-J pins 106a-106d in the auto-J groove shift slots 116 when the straddle packer 10 is in a pressure-boosted shift condition after being in the stay-set condition. In this condition, pumping of high-pressure stimulation fluid into a section of a production formation isolated by the respective packer elements 18, 74 may be performed, or pumping may be terminated as soon as operational fluid pressure is achieved.

(24) In either case, the relaxation of the packer elements 18, 74 after pumping is terminated will automatically move the auto-J pins 106a-106d from the auto-J shift slots 116 to the auto-J run-in slots 110, which shifts the straddle packer 10 back to the run-in condition shown in FIG. 7a.

(25) As will be understood by those skilled in the art, shifting of the straddle packer 10 from the run-in condition to the stay-set condition and back again to the run-in condition is exclusively dependent of fluid pressure and fluid flow control and is independent of work string manipulation of any sort. This is particularly advantageous in very long lateral bores, where precise work string manipulations may be difficult, if not impossible, to due frictional drag on the work string.

(26) It should be further understood that the shape and configuration of the auto-J groove 108 is illustrative only.

(27) The explicit embodiments of the invention described above have been presented by way of example only. The scope of the invention is therefore intended to be limited solely by the scope of the appended claims.