This invention relates in general to subsea wellhead assemblies, and in particular to a tieback connector that has a sleeve located on its lower end that serves as a stab guide, a seal protector, and a lockdown member for the casing hanger.
A subsea wellhead assembly installed at the sea floor may be in water thousands of feet deep. During completion and certain production operations, components from a floating platform are lowered from the platform to engage the subsea wellhead assembly. Often, the components will have seals that are subject to being damaged while lowering through openings in the floating platform and also while being stabbed into the wellhead assembly. A remote operated vehicle (“ROV”) may be used to help stab and guide the component being lowered from the surface vessel.
For example, one component comprises a tieback connector. A tieback connector connects a production riser between a subsea wellhead housing and the surface production platform. Typically a surface production tree locates at the upper end of the production riser on the production platform. A tieback connector normally has an tubular body with a lower end that stabs into the bore of a casing hanger. A seal on the lower end of the tieback body engages a seal surface in the casing hanger. The tieback connector has locking elements that lock into a profile in the wellhead housing. Care must be taken during running of the tieback connector to avoid damage to the seal, particularly while entering the bore of the wellhead housing. It is known to install a sleeve over the seal prior to lowering the tieback connector through the platform. However, an ROV must be employed to remove the sleeve prior to stabbing the tieback connector into the wellhead housing.
Casing hangers in subsea wells often will have a lockdown mechanism to resist upward movement of the casing hanger that may occur due to thermal growth during production. The lockdown member engages an upper end of the casing hanger and a grooved profile in the bore of the wellhead housing. Normally, installing the lockdown member requires an extra trip to be made with a running tool, costing valuable rig time.
In this invention, a sleeve is installed on the tubular body of a component to be lowered from a surface vessel into a wellhead member. In the preferred embodiment, the component comprises a tieback connector. The sleeve has a lower position with a lower end adjacent to the seal to prevent damage. The exterior of the sleeve is configured to serve as a stab guide to facilitate entry of the tieback connector into the wellhead housing. The sleeve lands on an upward facing shoulder in the wellhead housing, which is typically the upper end of a casing hanger. Continued downward movement of the connector body causes the connector body to move downward relative to the sleeve. This downward movement results in the seal sliding into engagement with the sealing surface in the casing hanger.
The tieback connector has a latch member that moves into engagement with a locking profile in the bore of the wellhead housing. The upper end of the sleeve contacts the lower end of the latch member as the latch member engages the locking profile. As a result, any upward force exerted on the sleeve due to the casing hanger tending to move upward transmits through the sleeve, latch member and into the wellhead housing. This load path prevents upward movement of the casing hanger, which could otherwise cause damage to the seal.
Referring to
Casing hanger 17 has a bore 19 with an enlarged inner diameter in the upper portion containing a cylindrical seal surface 21. A packoff 23 seals between an exterior wall surface of casing hanger 17 and wellhead housing bore 14. It is not uncommon for a number of closely spaced wells to be drilled and installed with casing hangers 15, 17, then left for a period of time until a production platform is installed above for completing and producing the wells.
In this example, the well is to be completed with a surface Christmas or production tree (not shown) at the production platform. In the completion process, the operator lowers a production riser (not shown) into the sea with a tieback connector 25 on its lower end. Tieback connector 25 has an inner body 27 that is tubular and has a central axial passage 26 extending through it. A seal 29 is located on the lower end of tieback connector 25. Seal 29 may be of a variety of types and is adapted to seal against upper casing hanger seal surface 21. In this example, seal 29 is a metal U-shaped seal located near the lower end of inner body 27 and on the exterior of inner body 27. A threaded retainer ring 38 holds seal 29 in place.
A protector sleeve 31 is slidably carried on the lower exterior portion of inner body 27. Protector sleeve 31 has a lower end 33 that is located radially outward of seal 29 while protector sleeve 31 is in the lower position. In this lower position, protective sleeve 31 surrounds seal 29 to prevent damage in case inner body 27 is accidentally bumped against some other structure, such as part of the floating platform or the upper portion of wellhead housing 13.
Protector sleeve 31 is releasably retained in the lower position shown in
A split retainer ring 39 is carried within a recess in the inner diameter of protective sleeve 31 above trigger sleeve 35. Retainer ring 39 releasably engages a groove 40 on the outer diameter of inner body 27. A thin upper section of trigger sleeve 35 extends upward into engagement with the inner side of retainer ring 39, which is inclined. Shear pins 37 are selected to shear upon the application of a pre-selected weight. In this embodiment, retainer ring 39 will not release protector sleeve 31 until shear pins 37 shear. In the point of initial contact of trigger sleeve 35 with the upper end of casing hanger 17, as shown in
Protector sleeve 31 has an exterior with a reduced diameter portion 41a at its lower end. The outer diameter at lower portion 41a is substantially the same as the outer diameter of the upper end of casing hanger 17, which is smaller than the inner diameter of bore 14. A tapered transition area 41b extends from lower portion 41a upward. Transition portion 41b joins an enlarged diameter portion 41c that is only slightly smaller than the inner diameter of bore 14. A recessed portion 41d extends upward from enlarged diameter portion 41c. In this embodiment, recessed portion 41d is generally concave and joins a full diameter portion at upper end 42, which has the same outer diameter as enlarged diameter portion 41c. In this embodiment, recessed portion 41d has an axial length that is greater than the axial distance from lower end 33 to the upper edge of enlarged diameter portion 41c. Exterior portions 41a, 41b, 41c and 41d serve as a stab guide to assist in stabbing tieback connector 25 into bore 14. Recessed portion 41d increases the maximum permissible stabbing angle relative to the axis of wellhead housing 13.
The axial length of protector sleeve 31 is dimensioned so that it slightly exceeds the distance from the upper end of upper casing hanger 17 to the lower edge of a locking profile 45. Casing hanger 17 lands within wellhead housing 13 within a selected tolerance, and the length of protector sleeve 31 is selected so that upper end 42 will protrude slightly above the lower edge of locking profile 45 as long as casing hanger 17 is set within tolerances. Locking profile 45 comprises one or more grooves formed in wellhead housing bore 14.
Protector sleeve 31 has a central bore portion 43a above trigger sleeve 35 that substantially equals the adjacent outer diameter of inner body 27. An upper bore portion 43b extends upward from central bore portion 43a and has two or more conical transitions to a largest inner diameter at upper end 42. The wall thickness at upper end 42 is much thinner than the wall thickness of protector sleeve 31 at any other point in this example.
A latch 47 is carried by inner body 27 for engaging locking profile 45. Latch 47 may be of a variety of types. In this embodiment, latch 47 comprises a plurality of separate segments, defining a lower end that will radially expand from the position shown in
A cam sleeve 57 is slidably carried on the exterior of inner body 27. Cam sleeve 57 has an exterior surface that is inclined for moving a split lock ring or locking member 59 inward while in the lower position. Locking ring 59 engages an upper grooved profile 61 formed on the exterior of inner body 27. A hydraulic fluid chamber 61 is formed between cam sleeve 57 and inner body 27 for causing downward movement of cam sleeve 57 when supplied with fluid pressure.
In operation, initially the well will be drilled to a first depth and low pressure wellhead 11 installed. A conductor pipe secured to the lower end of wellhead 11 extends into the well to a first depth. The operator drills the well to a greater depth and runs a string of casing, with the upper end of the casing being secured to the lower end of high pressure wellhead housing 13. The operator drills even greater depths and installs additional strings of casing 18, each on a casing hanger 15, 17 that lands in bore 14 of wellhead housing 13.
When the operator wishes to tieback the well to a surface production facility, he will lower tieback connector 25 on a string of production riser (not shown). Protector sleeve 31 will be in the lower position shown in
As shown in
The operator then supplies hydraulic fluid pressure to chamber 61 (
The operator completes the well in a conventional manner. Typically, this includes running a string of tubing (not shown) from the floating production platform through the riser and tieback connector passage 26 into the well. The operator perforates the well and installs a Christmas tree (not shown) at the upper end of the riser. The well fluid flows upward through the tubing to the Christmas tree.
During production, thermal growth may tend to cause casing hanger 17 to move upward in wellhead housing 13. This upward movement will be resisted by protector sleeve 31 since upper end 42 of protector sleeve 31 is in firm contact with the lower end of latch member 47. Any upward force will transmit through protector sleeve 31 to the lower end of latch member 47 and from there into locking profile 45 and wellhead housing 13.
The invention has significant advantages. The protector sleeve serves as a stab guide for the tieback connector while entering the bore of the wellhead housing. The protector sleeve provides protection to the seal located on the lower end of the inner body of the tieback connector. The seal is exposed only after it is safely within the bore of the wellhead housing. The protector sleeve also serves as a lockdown to resist upward movement of the casing hanger due to thermal growth.
While the invention has been shown in only one of its forms, it should be apparent to those skilled in the art that it is not so limited but susceptible to various changes without departing from the scope of the invention. For example, although the protector sleeve is shown in connection with a tieback connector, it could be utilized with other components lowered into engagement with subsea wellhead members. The latching of the tieback connector could be accomplished with other types of locking members. The lower end of the protector sleeve need not completely surround the seal in order to provide adequate protection.
Number | Name | Date | Kind |
---|---|---|---|
5255743 | Adam et al. | Oct 1993 | A |
5299642 | Nelson et al. | Apr 1994 | A |
5368335 | Dinnes | Nov 1994 | A |
5450904 | Galle | Sep 1995 | A |
5566761 | Pallini et al. | Oct 1996 | A |
6260624 | Pallini, Jr. et al. | Jul 2001 | B1 |
6536527 | Munk et al. | Mar 2003 | B2 |
6540024 | Pallini et al. | Apr 2003 | B2 |
7025145 | Emmerson | Apr 2006 | B2 |
Number | Date | Country |
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0338154 | Oct 1989 | EP |
Number | Date | Country | |
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20060196673 A1 | Sep 2006 | US |