Patent Grant
7699110
1. Field of Invention
The invention is directed to a flow diverter tool assembly, and, in particular, to a flow diverter tool assembly used to clean debris out of a portion of a production tree on an oil or gas well.
2. Description of Art
Subsea production trees with tubing hangers landed therein, referred to as “horizontal” or “spool” trees, are known in the art. Installation of production trees and completion of oil and gas wells prior to running the tubing routinely result in debris collecting in the bore of the production tree in the area where the tubing hanger lands and seals. Debris can also be collected within the bore of the production tree as a result of the production of oil or gas from the well formation. The collection of debris when the tubing hanger is removed or prior to installation may have an adverse impact on sealing the tubing hanger to the bore of the production tree and may clog ports intersecting the bore. Accordingly, it is desirable in the art to provide a tool capable of being placed within the bore of a horizontal production tree to flush out, or clean out, at least some of the debris contained within the bore of the production tree.
Prior devices and methods of cleaning, or flushing, the bore of a production tree include using a jetting sub lowered into the bore. Fluid is pumped through the jetting sub indiscriminately flushing the bore. One drawback to this prior attempt is that it is incapable of accurately directing the flow of fluid through the jetting sub into the ports of the tree. Therefore, it is desired in the art to provide a flow diverter tool assembly and method of flushing a bore of a subsea production tree that can provide directed flow of fluid from the tool to more accurately target debris for removal from the bore and which assures flow through the intersecting ports of the tree.
In one aspect, the invention is directed to a flow diverter tool assembly that is placed within a horizontal production tree of an oil and gas well and used to clean debris out of a portion of the production tree including the lower and upper tubing annulus ports found in the production tree. Broadly, the tool includes a housing having a passageway there-through. The passageway is used to pump fluid down the string, through the tool, and into the bore of the production tree. The passageway is in fluid communication with at least one outlet disposed along the length of the tool, one of which is preferably aligned with the lower tubing annulus port of the production tree so as to facilitate transporting debris within the portion of the production tree into the lower tubing annulus port.
A seal is disposed along the tool such that the bore of the production tree is divided into an upper portion and a lower portion. The seal is disposed within the bore of the production tree such that it rests below the upper tubing annulus port and above the lower tubing annulus port. Therefore, fluid and debris within the lower portion of the bore of the production tree can flow into the upper portion only by flowing into the lower tubing annulus port and out of the upper tubing annulus port.
To facilitate placement of the seal of the tool in the appropriate location, the tool also preferably includes a locator having a flange that is capable of being landed or placed on a shoulder disposed in the bore of the production tree or the wellhead housing below the tree. The length of the locator is determined by the locations of the shoulder, the lower tubing annulus port, and the upper tubing annulus port so that the seal is disposed between the lower tubing annulus port and the upper tubing annulus port.
The flow diverter tool assembly also includes a bypass device located above the seal that allows displaced fluid to flow through the tool, bypassing the seal, when the tool is being retrieved. The bypass device preferably comprises a slip-joint, which includes an inner barrel and an outer barrel. The inner barrel includes an inner port, and the outer barrel includes an outer port. When extended, i.e., when the inner barrel telescopes outward relative to the outer barrel, the inner port and the outer port become aligned with each another. Upon alignment of the inner port with the outer port, the upper portion of the bore of the production tree is placed in fluid communication with the passageway of the flow diverter tool assembly. Lifting the running string to pull the tool from the tree bore causes the inner barrel to slide upward relative to the outer barrel. As a result, a fluid path through the tool is created that bypasses the seal. Therefore, the seal does not have to bear the weight of the column of fluid in the riser as the tool is being retrieved, because the displaced fluid flows through the tool and out of the tool below the seal.
The inner barrel can be connected to the running string so that when running the flow diverter tool assembly into the bore of the production tree, the inner port and outer port are out of alignment. In that instance when running-in, displaced fluid would flow around the sides of the seal.
Alternatively, the inner barrel can be connected to the string from the surface such that when running the flow diverter tool assembly into the bore of the production tree, the inner port and outer port are in alignment. As a result, displaced fluid below the seal may be permitted to flow upward through the tool to facilitate lowering the tool assembly into the bore of the production tree.
During the flushing and removal of debris from the portion of the bore of the production tree, the inner port and outer port of the bypass device should be out of alignment so that all of the fluid flowing through the tool assembly is injected from the tool assembly below the seal. When the flow diverter tool assembly has completed its task of removing debris from the portion of the bore of the production tree, the pumping of fluid down the passageway of the flow diverter tool assembly is stopped. The string is then lifted, causing the inner barrel to slide out of the outer barrel until the inner port is aligned with the outer port. Upon alignment of the inner port with the outer port, fluid above the seal is permitted to flow through the tool into the lower portion below the seal, thereby permitting the flow diverter tool to be removed from the production tree. Alternatively, after aligning the inner port with the outer port, the inner barrel can be slid downward again and the portion of the production tree can be further flushed to remove additional debris.
In another specific embodiment, the passageway of the flow diverter tool assembly includes at least one additional outlet, the production port flushing outlet, which aligns with the production port on the production tree. Therefore, this additional outlet can be used to flush debris from the production port into a flowline or a cross-over line attached to the production port.
In operation, the flow diverter tool assembly is disposed in the bore of the production tree such that the seal of the tool divides the bore of the production tree into at least two portions, an upper portion above the seal and a lower portion below the seal. After installation, fluid is pumped down the passageway and out of the outlets disposed along the housing of the tool. Debris is flushed into the fluid in the lower portion and ultimately forced into the lower tubing annulus port, out of the upper tubing annulus port, and into the upper portion of the bore, where it is permitted to flow out of the well, such as through the riser.
While the invention will be described in connection with the preferred embodiments, it will be understood that it is not intended to limit the invention to those embodiments. On the contrary, it is intended to cover all alternatives, modifications, and equivalents, as may be included within the spirit and scope of the invention as defined by the appended claims.
Referring now to
Flow diverter tool assembly is disposed in bore 101 of production tree 100 in relation to upper tubing annulus port 102, lower tubing annulus port 104, and production passage 106. Production tree 100 lands on and is connected to a wellhead housing 116 that supports one or more strings of casing 118, 120. Production casing 118 is supported by a casing hanger 119 (
While production tree 100 is only partially shown in
Broadly, flow diverter tool assembly 10 comprises first end 12, second end 14, housing 16 having fluid passageway 18 longitudinally disposed within housing 16 between first end 12 and second end 14, a fluid by-pass assembly, such as slip-joint portion 20, sealing portion 40, and flushing portion 50 having at least one outlet 53. Flow diverter tool assembly 10 preferably also includes locator portion 60. Although slip-joint portion 20 is shown connected to sealing portion 40 by threads 17, sealing portion 40 is shown connected to flushing portion 50 by threads 17, and flushing portion 50 is shown connected to locator portion 60 by threads 17, it is to be understood that flow diverter tool assembly 10 is not required to be formed by four separate pieces. Nor are the different portions required to be connected by threads 17.
Slip-joint portion 20 includes inner barrel 21 having central passageway 22, exterior surface 23, string connector end 24, inner port 25, and slide end 26. Exterior surface 23 includes flange 28 having one or more seals 29 at slide end 26.
Slip-joint portion 20 also includes outer barrel 30 having slide end 31, inner wall surface 32 forming slide chamber 33 and restrictor 36, exterior surface 34, and outer port 35. Flange 28 of inner barrel 21 is slidably engaged with inner wall surface 32 within slide chamber 33. Restrictor 36 limits the distance inner barrel 21 is permitted to slide or telescope within outer barrel 30.
Inner barrel 21 is slidably engaged within outer barrel 30, thereby permitting inner port 25 and outer port 35 to be placed in, and removed from, alignment with each other by movement of inner barrel 21 within outer barrel 30 in the direction of arrows 38 and 39.
Lower end 37 of outer barrel 30 is releasably connected to upper end 41 of sealing portion 40 such as by threads 17. Sealing portion 40 includes central passageway 42, seals 43, and lower end 44. Seals 43 are annularly disposed around the exterior surface of sealing portion 40 such as resting on metal support guide 45. Although seals 43 may be of any type known in the art, seals 43 are preferably neoprene cups with upward facing lips. While two seals 43 are shown in
Sealing portion 40 preferably includes production passage flushing outlet 47 aligned with the production passage 106 of the production tree 100 once installed. Preferably, tool assembly 10 has a guide member (not shown) that engages orientation sub 117 to align production passage flushing outlet 47 with production passage 106 when tool assembly 10 lands. Therefore, any debris collected in the production passage 106 can be flushed by fluid flowing through passageway 18 and out of production passage flushing outlet 47. If desired, by using the cross-over arrangement (not shown) the fluid flowing out production passage 106 can be directed through upper tubing annulus port 102 back into bore upper portion 101
Sealing portion 40 may also include junk basket 48 (
Lower end 44 of sealing portion 40 is releasably connected to upper end 51 of flushing portion 50 such as by threads 17. Flushing portion includes central passageway 52, outlets 53, and lower end 54. Outlets 53 are preferably disposed at three different levels, such as upper outlets 55, middle outlets 56, and lower outlets 57. At least one upper outlet 55 is preferably generally aligned with lower tubing annulus port 104 to facilitate transporting fluid, and debris, into lower tubing annulus port 104 so that it can be carried out upper tubing annulus port 102. For example, upper outlet 55 may be disposed relative to central passageway 52 at an upward angle that is generally the same angle as lower tubing annulus port 104 to facilitate alignment of upper outlet 55 with lower tubing annulus port 104. Preferably, each upper outlet 55 is disposed at an upward inclination relative to central passageway 52, each lower outlet 57 is disposed at a downward inclination relative to central passageway 52, and each middle outlet 56 is disposed perpendicular relative to central passageway 52 to facilitate circulation of fluid, and thus, debris, within lower portion 111 of bore 101 and into lower tubing annulus port 104, out of upper tubing annulus port 102 and into upper portion 112 of bore 101. In one specific embodiment, the upward inclination of each upper outlet 55 is 32 degrees and the downward inclination of each lower outlet 57 is 32 degrees.
Lower end 54 of flushing portion 50 is releasably connected to upper end 61 of locator 60 (
Lower end 64 of locator 63 comprises second end 14 of flow diverter tool assembly 10. Lower end 64, or second end 14, may be attached to additional components known to persons skilled in the art, e.g., drill pipe sub 90 (
Alternatively, end 64, or second end 14, may be attached to a cap (not shown) that prevents fluid from flowing out of passageway 18 except through outlets 53 and, preferably, production passage flushing outlet 47. In this other embodiment, locator 60 preferably does not include any passageways 66.
In operation, flow diverter tool assembly 10 is secured to a string of conduit such as drill pipe and lowered into bore 101 of production tree 100 such that seals 43 are disposed below upper tubing annulus port 102 and above lower tubing annulus port 104. As tool assembly 10 is lowered through the riser, slip-joint portion 20 may be in an extended position such that inner port 25 and outer port 35 are aligned, allowing some fluid to flow through outlets 53, up passageway 18, and through inner port 25 and outer port 35. In this specific embodiment, once tool assembly 10 lands, the weight of the running string causes slip-joint portion 40 to move back to the retracted position in which inner port 25 is not aligned with outer port 35. Seals 43 contact inner wall surface 109 of bore 101 to sealingly divide bore 101 into lower portion 111 and upper portion 112. Slip joint portion 40, if not already in its retracted position, is moved to its retracted position after seals 43 contact inner wall surface 109.
While inner port 25 and outer port 35 of slip-joint portion 40 are out of alignment, fluid is pumped down passageway 18 and, thus, down central passageways 22, 42, 52, and 62. Fluid flows through outlets 53 and production passage flushing outlet 47 to force debris within lower portion 111 and production passage 106, respectively, out of lower portion 111 and production passage 106, into lower tubing annulus port 104, out of upper tubing annulus port 102 and into upper portion 112 of bore 101. Some of the debris conveyed into upper portion 112 will settle into junk basket 48, and some of the debris in upper portion 112 may be carried upward from tree 100 into the riser (not shown).
After a sufficient amount of time has elapsed to remove debris from lower portion 111 of bore 101, the pumping of fluid down passageway 18 is stopped. Flow diverter tool assembly 10 is lifted, causing inner barrel 21 to slide upwardly within outer barrel 30 in the direction of arrow 38. As result of inner barrel 21 sliding upwardly within outer barrel 30, inner port 25 becomes aligned with outer port 35. The alignment of inner port 25 with outer port 35 permits fluid in upper portion 112 of bore 101 to flow into passageway 18 and out of outlets 53 and production passage flushing outlet 47 while tool assembly 10 is pulled upward (arrow 39). As a result, the fluid in the riser bypasses seals 43 while tool assembly 10 moves upwards. Therefore, seals 43 do not have to lift the entire column of fluid in the riser. As tool assembly 10 is pulled upward debris will collect on top of seals 43 and in junk basket 48. This movement of fluid also results in the pressure within bore 101 above seals 43, i.e., in upper portion 112, and the pressure within bore 101 below seals 43, i.e., in lower portion 111, to move toward equilibrium as tool 10 is being pulled upward, facilitating removal of flow diverter tool assembly 10 from bore 101.
In one specific embodiment, flow diverter tool assembly 10 is not removed after a first cleaning of debris from bore 101, but instead, inner barrel 21 is slid back into outer barrel 30 causing inner port 25 to no longer be aligned with outer port 35. Thereafter, fluid is again pumped down passageway 18 and, thus, central passageways 22, 42, 52, and 62, and out of outlets 53 and production passage flushing outlet 47 to remove additional debris from lower portion 111 of bore 101. These steps can be repeated as many times as desired or necessary to sufficiently remove as much debris as possible or desired from lower portion 111 of bore 101.
After removal, the well is completed conventionally. A tubing hanger (not shown) is connected to a string of tubing and lowered into the well. The tubing hanger lands on shoulder 108 in bore 101 and has a production outlet that aligns with production passage 106 with the assistance of orientation sub 117. Circulation between the tubing annulus surrounding the tubing and the interior of the tubing is achieved via upper tubing annulus port 102 and lower tubing annulus port 104 in a conventional manner.
In one specific embodiment, seals 43 can be inflated and deflated such as by placing seals 43 in fluid communication with hydraulic fluid pressure delivered from the surface. Seals 43 could also be inflated or energized from retracted to sealed positions using the pressure of the fluid being pumped down passageway 18 to outlets 53. For example, pressure relief valves (not shown) could be located in outlets 53 to assure that seals 43 inflate or are energized before fluid is allowed to be discharged from outlets 53. If seals 43 are of that type, seals 43 would be recessed when flow diverter tool assembly 10 is placed within bore 101 of production tree 100. After properly locating flow diverter tool 10 within bore 101, seals 43 are inflated or energized. Flow diverter tool assembly 10 is then operated in the same manner as described above. After flow diverter tool assembly 10 removes the debris from bore 101, seals 43 are would be recessed, causing the release of pressure by seals 43 and, thus, release of flow diverter tool assembly 10, from inner walls surface 109 of bore 101, allowing flow diverter tool assembly 10 to be removed from bore 101. The bypass device comprising slip joint 20 might not be required if seals 43 were of a type that inflated or energized.
It is to be understood that the invention is not limited to the exact details of construction, operation, exact materials, or embodiments shown and described, as modifications and equivalents will be apparent to one skilled in the art. For example, as mentioned above, the flow diverter tool assembly is described herein as being formed by four separate portions releasably connected by threads. However, the flow diverter tool assembly may be formed out of one, two, three, five, or any other number of portions as desired or necessary, such as to facilitate fabrication, transportation, and installation within the bore of the production tree. Accordingly, the invention is therefore to be limited only by the scope of the appended claims.
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