WO2012142274A2 - Systèmes et procédés de coiffage d'un puits sous-marin - Google Patents

Systèmes et procédés de coiffage d'un puits sous-marin Download PDF

Info

Publication number
WO2012142274A2
WO2012142274A2 PCT/US2012/033305 US2012033305W WO2012142274A2 WO 2012142274 A2 WO2012142274 A2 WO 2012142274A2 US 2012033305 W US2012033305 W US 2012033305W WO 2012142274 A2 WO2012142274 A2 WO 2012142274A2
Authority
WO
WIPO (PCT)
Prior art keywords
bop
subsea
capping stack
spool
stack
Prior art date
Application number
PCT/US2012/033305
Other languages
English (en)
Other versions
WO2012142274A3 (fr
Inventor
Paul Edward ANDERSON
Chase BREIDENTHAL
Mike T. BROWN
Randall CHIASSON
Kevin DEVERS
William Patrick GRAMES
John D. Hughes
Mark Henley NICHOLS
Les OWEN
Trevor Smith
James WELLINGS
Paul TOOMS
Original Assignee
Bp Corporation North America Inc.
Bp Exploration Oeperating Company Limited
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Family has litigation
First worldwide family litigation filed litigation Critical https://patents.darts-ip.com/?family=46022669&utm_source=google_patent&utm_medium=platform_link&utm_campaign=public_patent_search&patent=WO2012142274(A2) "Global patent litigation dataset” by Darts-ip is licensed under a Creative Commons Attribution 4.0 International License.
Application filed by Bp Corporation North America Inc., Bp Exploration Oeperating Company Limited filed Critical Bp Corporation North America Inc.
Publication of WO2012142274A2 publication Critical patent/WO2012142274A2/fr
Publication of WO2012142274A3 publication Critical patent/WO2012142274A3/fr

Links

Classifications

    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B33/00Sealing or packing boreholes or wells
    • E21B33/02Surface sealing or packing
    • E21B33/03Well heads; Setting-up thereof
    • E21B33/035Well heads; Setting-up thereof specially adapted for underwater installations
    • E21B33/038Connectors used on well heads, e.g. for connecting blow-out preventer and riser
    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B33/00Sealing or packing boreholes or wells
    • E21B33/02Surface sealing or packing
    • E21B33/03Well heads; Setting-up thereof
    • E21B33/06Blow-out preventers, i.e. apparatus closing around a drill pipe, e.g. annular blow-out preventers
    • E21B33/064Blow-out preventers, i.e. apparatus closing around a drill pipe, e.g. annular blow-out preventers specially adapted for underwater well heads
    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B41/00Equipment or details not covered by groups E21B15/00 - E21B40/00
    • E21B41/0007Equipment or details not covered by groups E21B15/00 - E21B40/00 for underwater installations
    • E21B41/0014Underwater well locating or reentry systems
    • EFIXED CONSTRUCTIONS
    • E21EARTH OR ROCK DRILLING; MINING
    • E21BEARTH OR ROCK DRILLING; OBTAINING OIL, GAS, WATER, SOLUBLE OR MELTABLE MATERIALS OR A SLURRY OF MINERALS FROM WELLS
    • E21B43/00Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells
    • E21B43/01Methods or apparatus for obtaining oil, gas, water, soluble or meltable materials or a slurry of minerals from wells specially adapted for obtaining from underwater installations
    • E21B43/0122Collecting oil or the like from a submerged leakage

Definitions

  • the invention relates generally to systems and methods for containing fluids being discharged subsea. More particularly, the invention relates to systems and methods for capping a subsea blowout preventer or lower marine riser package and controlling the discharge of hydrocarbons into the surrounding sea.
  • a blowout preventer (BOP) is installed on a wellhead at the sea floor and a lower marine riser package (LMRP) mounted to the BOP.
  • LMRP marine riser package
  • a drilling riser extends from a flex joint at the upper end of LMRP to a drilling vessel or rig at the sea surface.
  • a drill string is then suspended from the rig through the drilling riser, LMRP, and the BOP into the well bore.
  • a choke line and a kill line are also suspended from the rig and coupled to the BOP, usually as part of the drilling riser assembly.
  • drilling fluid or mud
  • drilling fluid is delivered through the drill string, and returned up an annulus between the drill string and casing that lines the well bore.
  • the BOP and/or LMRP may actuate to seal the annulus and control the well.
  • BOPs and LMRPs comprise closure members capable of sealing and closing the well in order to prevent the release of high-pressure gas or liquids from the well.
  • the BOP and LMRP are used as safety devices that close, isolate, and seal the wellbore.
  • Heavier drilling mud may be delivered through the drill string, forcing fluid from the annulus through the choke line or kill line to protect the well equipment disposed above the BOP and LMRP from the high pressures associated with the formation fluid. Assuming the structural integrity of the well has not been compromised, drilling operations may resume. However, if drilling operations cannot be resumed, cement or heavier drilling mud is delivered into the well bore to kill the well.
  • a method for capping a subsea wellbore wherein a wellhead of the subsea wellbore is disposed at the sea floor, a subsea blowout preventer (BOP) is mounted to the wellhead, a lower marine riser package (LMRP) is coupled to the BOP, and a riser extends from the LMRP.
  • the method comprises (a) identifying a subsea landing site on the BOP or LMRP for connection of a capping stack.
  • the method comprises (b) preparing the subsea landing site for connection of the capping stack.
  • the method comprises (c) installing a capping stack on to the subsea landing site.
  • the method comprises (d) shutting in the wellbore with the capping stack after (c).
  • the capping stack for containing a subsea wellbore.
  • the capping stack comprises a body containing a sealing mechanism.
  • the body has a central axis, a first end, a second end opposite the first end, and a main bore extending axially from the lower end to the upper end.
  • the sealing mechanism is configured to seal the main bore.
  • the capping stack comprises a transition spool having a central axis, a first end releasably connected to the second end of the body, a second end opposite the first end, and a flow bore extending axially between the first end and the second end.
  • the flow bore is in fluid communication with the main bore of the body.
  • the transition spool includes an annular flange axially disposed between the first end and the second end of the transition spool and a mule shoe extending axially from the second end of the transition spool.
  • a method for shutting in a subsea wellbore wherein a wellhead of the wellbore is disposed on the sea floor, a subsea BOP is mounted to the wellhead, an LMRP is mounted to the BOP, and a riser extends from the LMRP.
  • the method comprises (a) removing the LMRP from the BOP subsea.
  • the method comprises (b) lowering a second BOP subsea from a surface vessel to a position laterally adjacent the subsea BOP.
  • the second BOP includes a body having a central axis, an upper end, a lower end, and a main bore extending axially from the lower end to the upper end.
  • the method comprises (c) maintaining the second BOP outside of a plume of hydrocarbons formed by the produced hydrocarbons during (b).
  • the method comprises (d) moving the second BOP laterally over the subsea BOP after (b).
  • the method comprises (e) lowering the second BOP axially downward into engagement with the subsea BOP after (d).
  • the method also comprises (f) securing the second BOP to the subsea BOP.
  • the capping stack for containing a subsea wellbore.
  • the capping stack comprises a valve spool containing a valve.
  • the valve spool has a central axis, a first end, a second end opposite the first end, and a main bore extending axially from the lower end to the upper end.
  • the valve is configured to seal the main bore.
  • the capping stack comprises a transition spool having a central axis, a first end releasably connected to the second end of the body, a second end opposite the first end, and a flow bore extending axially between the first end and the second end.
  • the flow bore is in fluid communication with the main bore of the body, and the transition spool includes an annular flange axially disposed between the first end and the second end of the transition spool and a mule shoe extending axially from the second end of the transition spool.
  • the first end of the transition spool comprises a wellhead- type connector.
  • the capping stack further comprises a plurality of side outlets, each side outlet having a first end in fluid communication with the main bore, a second end distal the valve spool, and a side outlet valve disposed between the first end and the second end. Each side outlet valve is configured to control the flow of fluid through the corresponding side outlet.
  • the plurality of side outlets are disposed between the valve spool and the transition spool.
  • the second end of each side outlet comprises a connector hub.
  • a pressure control device is coupled to at least one of the connector hubs.
  • the capping stack comprises a BOP coupled to the valve spool.
  • the BOP comprises one or more sets of opposed rams.
  • the mule shoe has a tapered end in side view and is configured to be inserted into a flex joint.
  • the annular flange of the transition spool includes a plurality of circumferentially spaced holes.
  • a bolt is positioned in each of the plurality of holes in the annular flange, each bolt having a lower end disposed in one hole and an upper end axially above the hole.
  • An annular band is disposed about the upper end of each bolt, wherein the band is configured to bias the upper end of each bolt radially inward.
  • a method for capping a subsea wellbore wherein a wellhead of the subsea wellbore is disposed at the sea floor, a subsea blowout preventer (BOP) is mounted to the wellhead, a lower marine riser package (LMRP) is coupled to the BOP, and a riser extends from the LMRP.
  • BOP subsea blowout preventer
  • LMRP lower marine riser package
  • the method comprises (a) identifying a subsea landing site on the BOP or LMRP for connection of a capping stack.
  • the method comprises (b) preparing the subsea landing site for connection of the capping stack.
  • the method comprises (c) installing a capping stack on to the subsea landing site.
  • the capping stack comprises a valve spool having a central axis, a first end, a second end opposite the first end, a main bore extending axially from the first end to the second end, and a valve configured to seal the main bore.
  • the method comprises (d) closing the valve after (c).
  • the capping stack further comprises a plurality of side outlets, each side outlet having a first end in fluid communication with the main bore, a second end distal the spool body, and a side outlet valve disposed between the first end and the second end. Each side outlet valve is configured to control the flow of fluid through the corresponding side outlet.
  • (d) comprises allowing each side outlet valve to remain in an open position during the actuating of the valve of the valve spool to alleviate pressure on the wellbore. In embodiments, (d) comprises sequentially closing each of the side outlet valves to shut in the wellbore.
  • the LMRP has an upper end including a riser flex joint connected to the riser, and wherein the subsea landing site is a riser adapter of the riser flex joint. In embodiments, (b) comprises removing the riser from the riser flex joint before (c).
  • the capping stack includes a mule shoe coupled to the second end of the valve spool, and an annular flange axially disposed between the mule shoe and the valve spool, wherein (c) comprises (cl) inserting the mule shoe into the riser adapter; (c2) axially advancing the mule shoe into the riser adapter until the annular flange of the capping stack engages a mating annular flange on the riser adapter; and (c3) securing the annular flange of the capping stack to the annular flange of the riser adapter.
  • (c) further comprises (cl) connecting a transition spool to the riser adapter, wherein the transition spool comprises a longitudinal axis, a first end configured to be coupled to the body of the capping stack, a second end comprising a mule shoe, and an annular flange positioned axially adjacent the mule shoe; and (c2) connecting the capping stack to the transition spool after (cl).
  • (cl) comprises positioning the transition spool laterally offset from the subsea landing site; moving the transition spool into alignment with the riser adapter; and urging the transition spool into engagement with the riser adapter, wherein (c2) comprises positioning the capping stack laterally offset from the subsea landing site, moving the capping stack into alignment with the transition spool, and urging the capping stack into engagement with the transition spool.
  • the subsea landing site is a wellhead-type coupling at a first end of the BOP.
  • the capping stack comprises a BOP coupled to the valve spool.
  • Figure 1 is a schematic view of an embodiment of an offshore drilling system
  • Figure 2 is an enlarged view of the riser flex joint of the lower marine riser package of
  • Figure 3 is a top view of the flange of the riser adapter of Figure 2;
  • Figure 4 is a schematic view of the offshore drilling system of Figure 1 damaged by a subsea blowout and after removal of the riser;
  • Figure 5 is a side view of an embodiment of a capping stack for containing the wellbore of Figure 4.
  • Figure 6 is a schematic cross-sectional view of the capping stack of Figure 5;
  • Figure 7A-7E are sequential schematic views of the deployment and installation of the capping stack of Figure 5 onto the flex joint of Figure 4;
  • Figure 8 is schematic view of an embodiment of a capping stack for containing a wellbore
  • Figure 9 is cross-sectional view of the blowout preventer of Figure 8.
  • Figure 10 is a perspective view of the transition spool of Figure 8.
  • Figure 1 lA-11H are sequential schematic views of the deployment and installation of the capping stack of Figure 8 onto the flex joint of Figure 4;
  • Figure 12 is a schematic front view of an embodiment of a capping stack for containing the wellbore of Figure 4;
  • Figure 13 is a schematic side view of the capping stack of Figure 12;
  • Figure 14A-14D are sequential schematic views of the deployment and installation of the capping stack of Figure 12 onto the BOP of Figure 4;
  • Figure 15 is a schematic front view of an embodiment of a capping stack for containing the wellbore of Figure 4;
  • Figure 16 is a schematic cross-sectional view of the valve spool of Figure 15;
  • Figure 17A-17H are sequential schematic views of the deployment and installation of the capping stack of Figure 15 onto the BOP of Figure 4;
  • Figure 18 is a schematic front view of an embodiment of a capping stack for containing the wellbore of Figure 4;
  • Figure 19 is a schematic side view of the BOP of Figure 18;
  • Figure 20 is a front view of the BOP of Figure 18;
  • Figure 21 is a side view of the BOP of Figure 18;
  • Figure 22 is a front view of the BOP of Figure 18 configured for deployment subsea;
  • Figure 23 is a side view of the BOP of Figure 18 configured for deployment subsea;
  • Figures 24A-D are sequential schematic views of the deployment and installation of the capping stack of Figure 18 onto the BOP of Figure 4;
  • Figure 25 is a schematic front view of an embodiment of a capping stack for containing the wellbore of Figure 4;
  • Figure 26 is a schematic cross-sectional view of the valve manifold of Figure 25;
  • Figures 27A-D are sequential schematic views of the deployment and installation of the capping stack of Figure 28 onto the BOP of Figure 4.
  • Figure 28 is a flowchart illustrating an embodiment of a method for deploying and installing a capping stack.
  • the terms “including” and “comprising” are used in an open-ended fashion, and thus should be interpreted to mean “including, but not limited to... .”
  • the term “couple” or “couples” is intended to mean either an indirect or direct connection. Thus, if a first device couples to a second device, that connection may be through a direct connection, or through an indirect connection via other devices, components, and connections.
  • the terms “axial” and “axially” generally mean along or parallel to a central axis (e.g., central axis of a body or a port), while the terms “radial” and “radially” generally mean perpendicular to the central axis. For instance, an axial distance refers to a distance measured along or parallel to the central axis, and a radial distance means a distance measured perpendicular to the central axis.
  • system 100 includes an offshore platform 110 at the sea surface 102, a subsea blowout preventer (BOP) 120 mounted to a wellhead 130 at the sea floor 103, and a lower marine riser package (LMRP) 140.
  • Platform 110 is equipped with a derrick 111 that supports a hoist (not shown).
  • a drilling riser 115 extends from platform 110 to LMRP 140.
  • riser 115 is a large-diameter pipe that connects LMRP 140 to the floating platform 110.
  • riser 115 takes mud returns to the platform 110.
  • Casing 131 extends from wellhead 130 into subterranean wellbore 101.
  • Downhole operations are carried out by a tubular string 116 (e.g., drillstring, production tubing string, coiled tubing, etc.) that is supported by derrick 111 and extends from platform 110 through riser 115, LMRP 140, BOP 120, and into cased wellbore 101.
  • a downhole tool 117 is connected to the lower end of tubular string 116.
  • downhole tool 117 may comprise any suitable downhole tool(s) for drilling, completing, evaluating and/or producing wellbore 101 including, without limitation, drill bits, packers, testing equipment, perforating guns, and the like.
  • string 116, and hence tool 117 coupled thereto may move axially, radially, and/or rotationally relative to riser 115, LMRP 140, BOP 120, and casing 131.
  • BOP 120 and LMRP 140 are configured to controllably seal wellbore 101 and contain hydrocarbon fluids therein.
  • BOP 120 has a central or longitudinal axis 125 and includes a body 123 with an upper end 123a releasably secured to LMRP 140, a lower end 123b releasably secured to wellhead 130, and a main bore 124 extending axially between upper and lower ends 123 a, b.
  • Main bore 124 is coaxially aligned with wellbore 101, thereby allowing fluid communication between wellbore 101 and main bore 124.
  • BOP 120 is releasably coupled to LMRP 140 and wellhead 130 with hydraulically actuated, mechanical wellhead-type connectors 150.
  • connectors 150 may comprise any suitable releasable wellhead-type mechanical connector such as, without limitation, the H-4® profile subsea connector available from VetcoGray Inc. of Houston, Texas or the DWHC profile subsea connector available from Cameron International Corporation of Houston, Texas.
  • wellhead-type mechanical connectors e.g., connectors 150
  • such wellhead-type mechanical connectors comprise a male component or coupling, labeled with reference numeral 150a herein, that is inserted into and releasably engages a mating female component or coupling, labeled with reference numeral 150b herein.
  • BOP 120 includes a plurality of axially stacked sets of opposed rams - opposed blind shear rams or blades 127 for severing tubular string 116 and sealing off wellbore 101 from riser 115, opposed blind rams 128 for sealing off wellbore 101 when no string (e.g., string 116) or tubular extends through main bore 124, and opposed pipe rams 129 for engaging string 116 and sealing the annulus around tubular string 116.
  • Each set of rams are a plurality of axially stacked sets of opposed rams - opposed blind shear rams or blades 127 for severing tubular string 116 and sealing off wellbore 101 from riser 115, opposed blind rams 128 for sealing off wellbore 101 when no string (e.g., string 116) or tubular extends through main bore 124, and opposed pipe rams 129 for engaging string 116 and sealing the annulus around tubular string 116.
  • Each set of rams are
  • each set of rams 127, 128, 129 functions as a sealing mechanism.
  • Opposed rams 127, 128, 129 are disposed in cavities that intersect main bore 124 and support rams 127, 128, 129 as they move into and out of main bore 124.
  • each set of rams 127, 128, 129 is actuated and transitioned between the open and closed positions by a pair of actuators 126.
  • each actuator 126 hydraulically moves a piston within a cylinder to move a drive rod coupled to one ram 127, 128, 129.
  • LMRP 140 has a body 141 with an upper end 141a connected to the lower end of riser 115, a lower end 141b releasably secured to upper end 123a with connector 150, and a throughbore 142 extending between upper and lower ends 141a, b.
  • Throughbore 142 is coaxially aligned with main bore 124 of BOP 110, thereby allowing fluid communication between throughbore 142 and main bore 124.
  • LMRP 140 also includes an annular blowout preventer 142a comprising an annular elastomeric sealing element that is mechanically squeezed radially inward to seal on a tubular extending through bore 142 (e.g., string 116, casing, drillpipe, drill collar, etc.) or seal off bore 142.
  • annular BOP 142a has the ability to seal on a variety of pipe sizes and seal off bore 142 when no tubular is extending therethrough.
  • upper end 141a of LMRP 140 comprises a riser flex joint 143 that allows riser 115 to deflect angularly relative to BOP 120 and LMRP 140 while hydrocarbon fluids flow from wellbore 101, BOP 120 and LMRP 140 into riser 115.
  • flex joint 143 includes a cylindrical base 144 rigidly secured to the remainder of LMRP 140 and a riser extension or adapter 145 extending upward from base 144.
  • a fluid flow passage 146 extending through base 144 and adapter 145 defines the upper portion of throughbore 142.
  • a flex element (not shown) disposed within base 144 extends between base 144 and riser adapter 145, and sealingly engages both base 144 and riser adapter 145.
  • the flex element allows riser adapter 145 to pivot and angularly deflect relative to base 144, LMRP 140, and BOP 120.
  • the upper end of adapter 145 distal base 144 comprises an annular flange 145 a for coupling riser adapter 145 to a mating annular flange 118 at the lower end of riser 115 or to alternative devices.
  • flange 145a includes a plurality of circumferentially- spaced holes 147 that receive bolts for securing flange 145 a to a mating annular flange 118 at the lower end of riser 115.
  • flange 145 a includes a pair of circumferentially spaced guide holes 148, each guide hole 148 having a diameter greater than the diameter of holes 147.
  • flex joint 143 also includes a mud boost line 149 having an inlet (not shown) in fluid communication with flow passages 142, 146, an outlet 149b in flange 145a, and a valve 149c configured to control the flow of fluids through line 149.
  • BOP 120 includes three sets of rams (one set of shear rams 127, and two sets of pipe rams 128, 129), however, in other embodiments, the BOP (e.g., BOP 120) may include a different number of rams (e.g., four sets of rams), different types of rams (e.g., two sets of shear rams or a blind ram), an annular BOP (e.g., annular BOP 142a), or combinations thereof.
  • LMRP 140 is shown and described as including one annular BOP 142a, in other embodiments, the LMRP (e.g., LMRP 140) may include a different number of annular BOPs (e.g., two sets of annular BOPs), different types of rams (e.g., shear rams), or combinations thereof.
  • rams 127, 128, 129 of BOP 120 and/or LMRP 140 are normally actuated to seal in wellbore 101.
  • rams 127, 128, 129 may not seal off wellbore 101, resulting in a blowout. If the preventers of BOP 120 and LMRP 140 do not seal the wellbore, this may result in the uncontrolled discharge of such hydrocarbon fiuids.
  • riser 115 may be severed and removed after a blowout leaving flange 145a of flex joint 143 remaining.
  • Embodiments of capping stacks and methods for deploying same described in more detail below are designed to cap wellbore 101 and stop the subsea emission of hydrocarbon fluid.
  • capping stack 200 for capping wellbore 101 previously described and containing the hydrocarbon fluids therein is shown.
  • capping stack 200 comprises a valve spool 210 and a guidance device 230.
  • Valve spool 210 has a central axis 215, and includes a spool body 211 with a first or upper end 211a, a second or lower end 211b opposite upper end 211a, and a main bore 211c extending axially between ends 21 la, b.
  • Valve spool 210 also includes a sealing mechanism 220 that controls the flow of fluids through main bore 211c.
  • sealing mechanism 220 is an isolation valve - when valve 220 is in an "open” position, valve 220 allows fluid flow through main bore 211c between ends 211a, b, however, when valve 220 is in a "closed” position, valve 220 restricts and/or prevents fluid flow through main bore 211c between ends 21 la, b. Accordingly, valve 220 may also be referred to as a "sealing mechanism.” Valve 220 is transitioned between the open and closed positions with subsea ROVs. Depending on the type of actuator (e.g.
  • valve 220 is a ball valve.
  • valve 220 may comprise any valve suitable for subsea conditions and containing the anticipated pressure of fluids from wellbore 101 including, without limitation, a gate valve or a ball valve.
  • the valve spool e.g., valve spool 210) may include more than one valve (e.g., valve 220).
  • spool 210 is a double- flanged spool, and thus, upper end 211a comprises an annular flange 212 and lower end 211b comprises an annular flange 213.
  • Each flange 212, 213 includes a plurality of circumferentially spaced holes 212a, 213a, respectively, for receiving bolts that secure capping stack 200 to a mating flange of another component.
  • capping stack 200 is configured to be secured to flex joint 143 following removal of riser 115 from flex joint 143.
  • lower flange 213 is sized and configured to mate and engage with flange 145a of flex joint 143.
  • Bolts 214 are predisposed in holes 213a, and a resilient annular band 216 is disposed about the upper ends of bolts 214.
  • Band 216 biases the upper ends of bolts 214 radially inward relative to their lower ends and holes 213a, thereby skewing and angling bolts 214 relative to holes 213a (i.e., bolts 214 are not coaxially aligned with holes 213a). In this manner, band 216 maintains the position of bolts 214 extending into holes 213a during deployment of stack 200, thereby reducing the likelihood of one or more bolts 214 disengaging their corresponding holes 213a and being dropped to the sea floor 103 during deployment and installation of capping stack 200.
  • band 216 may comprise any suitable resilient device for urging and biasing the upper ends of bolts 214 radially inward.
  • band 216 comprises a tensioned annular band.
  • a pair of circumferentially spaced alignment guides or pins 217 extend axially downward from lower flange 213.
  • Pins 217 are sized and positioned to coaxially and rotationally align flange 213 of capping stack 200 relative to flange 145a of flex joint 143 such that holes 213a are coaxially aligned with corresponding holes 147 in flange 145a.
  • pins 217 slidingly engage mating guide holes 148 in flange 145a.
  • the lower ends of pins 217 comprise a frustoconical outer surface for facilitating the alignment and insertion of pins 217 into holes 148.
  • Each pin 217 includes a handle 218 extending axially upward from flange 213.
  • Handles 218, as well as T-handles 219 extending radially from spool body 210, enable subsea manipulation of stack 200 with one or more subsea remotely operated vehicles (ROVs) during deployment and installation of stack 200.
  • Band 216 is disposed about bolts 214 but positioned on the inside or radially inward of handles 218 such that the ROVs can access handles 218 without interference.
  • guidance device 230 is a tubular mule shoe extending axially downward from lower end 21 lb and flange 213 of spool body 210.
  • Mule shoe 230 has a central axis 235 coaxially aligned with axis 215, a first or upper end 230a connected to lower flange 213, a second or lower end 230b distal flange 213, and a cylindrical through bore 232 extending axially between ends 231a, b.
  • Bore 232 is coaxially aligned with and in fluid communication with main bore 21 lc of spool body 210.
  • Shoe 230 also includes a plurality of circumferentially spaced elongate through slots 233 extending radially from the outer cylindrical surface of shoe 230 to bore 232. In the embodiment, slots 233 are oriented parallel to axis 215. In other embodiments, the slots in the mule shoe (e.g., slots 233 in mule shoe 230) may be omitted.
  • mule shoe 230 is coaxially aligned with joint 143 and axially advanced into joint 143 until flanges 145a, 213 axially abut.
  • through slots 233 provide a flow path for hydrocarbon fluids discharged from wellbore 101 through BOP 120 and LMRP 140.
  • lower end 230b is angled or tapered in side view (i.e., when viewed perpendicular to axis 235). Specifically, lower end 230b is oriented at an angle ⁇ relative to axis 235. Angle ⁇ is preferably between 30° and 60°. In this embodiment, angle ⁇ is 45°. Tapered lower end 230b also facilitates the axial advancement of mule shoe 230 into another component (e.g., flex joint 143) that is bent or angled relative to vertical and/or that contain pipes or tubulars disposed therein. For example, mule shoe 230 may be inserted into another component and slowly axially advanced.
  • another component e.g., flex joint 143
  • tapered end 230b slidingly engages the component, thereby guiding shoe 230 into the component.
  • tapered end 230b slidingly engages and guides tubulars within the component into bore 232.
  • tapered end 230b enables shoe 230 to wedge itself radially between the component and the tubulars disposed therein. This may be particularly advantageous in instances where mule shoe 230 is coupled to a component that contains damage tubulars or pipes that cannot be removed.
  • capping stack 200 is shown being deployed and installed subsea on LMRP 140 to cap and contain wellbore 101. More specifically, in Figure 7 A, capping stack 200 is shown being lowered subsea; in Figure 7B, capping stack 200 is shown being moved laterally over flex joint 143; in Figure 7C, capping stack 200 is shown being generally coaxially aligned with flex joint 143 and lowered into engagement with flex joint 143; and in Figures 7D and 7E, capping stack 200 is shown being secured to flex joint 143.
  • riser 115 is removed from flex joint 143, and any tubulars or debris extending upward from flange 145 a are preferably cut off substantially flush with flange 145 a.
  • riser adapter 145 is preferably oriented vertically and locked in the vertical position. This offers the potential to reduce moments experienced by adapter 145 following installation of these components. More specifically, since riser adapter 145 is designed to pivot relative to base 144, the moments exerted on riser adapter 145 following attachment of such components may cause riser adapter 145 to undesirably pivot and/or break.
  • riser adapter 145 may be oriented vertically and locked in the vertical orientation by any suitable systems and/or methods. Examples of suitable systems and methods for orienting riser adapter 145 vertically and locking riser adapter 145 in the vertical orientation are disclosed in U.S. patent application no. 61/482,132 filed May 3, 2011, and entitled "Adjustment and Restraint System for a Subsea Flex Joint," which is hereby incorporated herein by reference in its entirety for all purposes.
  • ROVs remote operated vehicles
  • ROVs 170 are employed to position stack 200, monitor stack 200, BOP 120, and LMRP 140, and actuate valve 220.
  • Each ROV 170 includes an arm 171 having a claw 172, a subsea camera 173 for viewing the subsea operations (e.g., the relative positions of stack 200, plume 160, the positions and movement of arms 170 and claws 172, etc.), and an umbilical 174.
  • Streaming video and/or images from cameras 173 are communicated to the surface or other remote location via umbilical 174 for viewing on a live or periodic basis.
  • Arms 171 and claws 172 are controlled via commands sent from the surface or other remote location to ROV 170 through umbilical 174.
  • stack 200 is shown being controllably lowered subsea with a plurality of cables 180 secured to stack 200 and extending to a surface vessel.
  • cables 180 are preferably relatively strong cables (e.g., steel cables) capable of withstanding the anticipated tensile loads.
  • a winch or crane mounted to a surface vessel is preferably employed to support and lower stack 200 on cables 180.
  • cables 180 are employed to lower stack 200 in this embodiment, in other embodiments, capping stack 200 may be deployed subsea on a pipe string.
  • capping stack 200 is lowered subsea under its own weight from a location generally above and laterally offset from wellbore 101, BOP 120, and LMRP 140. More specifically, during deployment, capping stack 200 is preferably maintained outside of plume 160 of hydrocarbon fluids emitted from wellbore 101. Lowering stack 200 subsea in plume 160 may trigger the undesirable formation of hydrates within stack 200, particularly at elevations substantially above sea floor 103 where the temperature of hydrocarbons in plume 160 is relatively low.
  • riser 115 is preferably removed from flex joint 143.
  • flange 118 may be disconnected from flange 145 a subsea by any suitable means (e.g., with subsea ROVs 170).
  • any tubulars or debris extending upward from flange 145 a are preferably cut off slightly above flange 145 a so as to provide initial coarse guidance for engaging lower end 230b of mule shoe 230.
  • one or more ROVs 170 may be equipped with a saw capable of cutting through any tubulars or debris extending from flange 145 a.
  • stack 200 is lowered laterally offset from riser adapter 145 and outside of plume 160 until mule shoe 230 is slightly above flange 145a.
  • ROVs 170 monitor the position of stack 200 relative to flex joint 143.
  • stack 200 is moved laterally into position immediately above riser adapter 145 with mule shoe 230 substantially coaxially aligned with riser adapter 145.
  • stack 200 is rotated about axes 215, 235 to substantially align guide pins 217 with corresponding holes 148 in flange 145a.
  • Guide pins 217 may each have sockets or holes by which additional guide wires or cables (not shown) may be attached. Guide wires may be attached to guide pins 217 and then threaded through pin holes in flange 145 a. The guide wires may be used to guide ROVS due to low visibility due to the presence of hydrocarbons.
  • One or more ROVs 170 may utilize their claws 172 and handles 218, 219 to guide and rotate stack 200 into proper alignment relative to flange 145a. ROVs 170 may tighten or straighten guide wires which have been threaded through pin holes of flange 145a, and guide transition spool and/or stack 200 into engagement with flange 145a.
  • stack 200 Due to its own weight, stack 200 is substantially vertical, whereas riser adapter 145 may be oriented at an angle relative to vertical (e.g., angle a).
  • angle a an angle relative to vertical
  • cables 180 lower stack 200 axially downward, thereby inserting and axially advancing pins 217 into corresponding holes 148 and inserting and axially advancing mule shoe lower end 230b into riser adapter 145 until flange 213 axially abuts and engages flange 145 a as shown in Figure 7D.
  • the frustoconical surface on the lower end of each pin 217 functions to guide each pin 217 into its corresponding hole 148, even if pins 217 are initially slightly misaligned with holes 148.
  • taper on lower end 230b functions to guide the insertion and coaxial alignment of capping stack 200 and riser adapter 145 as stack 200 is lowered from a position immediately above riser adapter 145, even if mule shoe 230 is initially slightly misaligned with riser adapter 145.
  • valve 220 Prior to moving stack 200 laterally over riser adapter 145, valve 220 is transitioned to the open position allowing hydrocarbon fluids emitted by flex joint 143 to flow unrestricted through stack 200. Valve 220 may be transitioned to the open position at the surface 102 prior to deployment, or subsea via one or more ROVs 170.
  • ROVs 170 ROVs 170.
  • open valve 220 and slots 233 offer the potential to reduce the resistance to the axial insertion of mule shoe 230 into riser adapter 145 and coupling of stack 200 thereto.
  • open valve 220 and slots 233 allow the relief of well pressure during installation of stack 200.
  • valve 220 With a sealed, secure connection between stack 200 and riser adapter 145, valve 220 is transitioned to the closed position with an ROV 170, thereby shutting off the flow of hydrocarbons emitted from wellbore 101, BOP 120, and LMRP 140. Cables 180 may be decoupled from stack 200 with ROVs 170 and removed to the surface once stack 200 is securely bolted to flex joint 143.
  • capping stack 300 for capping wellbore 101 previously described ( Figure 4) and containing the hydrocarbon fluids therein is shown.
  • capping stack 300 comprises a BOP 310 and a transition spool 330 coupled to BOP 310.
  • BOP 310 is releasably coupled to transition spool 330 with a mechanical wellhead-type connector 150 as previously described.
  • BOP 310 is similar to BOP 120 previously described. Specifically, BOP 310 has a central or longitudinal axis 315 and includes a body 312 with a first or upper end 312a, a second or lower end 312b releasably secured to transition spool 330, and a main bore 313 extending axially between ends 312a, b.
  • upper end 312a comprises a male coupling 150a of a wellhead-type connector 150 and lower end 312b comprises a female coupling 150b of wellhead-type connector 150.
  • BOP 310 also includes a plurality of axially stacked sets of opposed rams.
  • BOP 310 includes two sets of axially stacked sets of opposed rams - two sets of opposed blind shear rams or blades 127 as previously described, for sealing off wellbore main bore 313.
  • two ram BOP 310 may generally be considered a light weight BOP.
  • the BOP e.g., BOP 310
  • the BOP may comprise other types of opposed rams such as opposed blind rams (e.g., rams 128), pipe rams (e.g., rams 129), or combinations thereof.
  • Opposed rams 127 are disposed in cavities that intersect main bore 313 and support rams 127 as they move into and out of main bore 313. Each set of rams 127 is actuated and transitioned between an open position and a closed position. In the open positions, rams 127 are radially withdrawn from main bore 313 and do not interfere with any hardware that may extend through main bore 313. However, in the closed positions, rams 127 are radially advanced into main bore 313 to close off and seal main bore 313. Each set of rams 127 is actuated and transitioned between the open and closed positions by a pair of actuators 126 as previously described.
  • transition spool 330 has a central or longitudinal axis 335 (coaxially aligned with axis 315 when coupled to BOP 310), a first or upper end 330a releasably coupled to BOP 310, a second or lower end 330b, and a flow bore 331 extending axially between ends 330a, b.
  • Flow bore 331 is coaxially aligned with main bore 313, thereby forming a continuous flow passage extending axially through capping stack 300.
  • upper end 330a comprises the male coupling 150a of wellhead-type connector 150.
  • transition spool 330 includes an annular flange 334 axially between ends 330a, b and a mule shoe 230 as previously described extending axially from flange 334 to lower end 330b.
  • Flange 334 is similar to flange 213 previously described with reference to capping stack 200.
  • flange 334 includes a plurality of circumferentially spaced holes 334a for receiving bolts 214 that secure transition spool 330 and capping stack 300 to a mating flange of another component.
  • capping stack 300 is configured to be secured to flex joint 143 following removal of riser 115 from flex joint 143.
  • flange 334 is sized and configured to mate and engage with flange 145a of flex joint 143.
  • Bolts 214 are pre-disposed in holes 334a, and a resilient annular band 216 as previously described is disposed about the upper ends of bolts 214.
  • Band 216 urges the upper ends of bolts 214 radially inward relative to their lower ends and holes 334a, thereby skewing and angling bolts 214 relative to holes 334a (i.e., bolts 214 are not coaxially aligned with holes 334a).
  • band 216 maintains the position of bolts 214 extending into holes 334a during deployment of stack 300, thereby reducing the likelihood of one or more bolts 214 disengaging their corresponding holes 334a and being dropped to the sea floor 103 during deployment and installation of capping stack 300.
  • a pair of circumferentially spaced alignment guides or pins 217 as previously described extend axially downward from flange 334.
  • Pins 217 are sized and positioned to coaxially and rotationally align flange 334 of transition spool 330 relative to flange 145a of flex joint 143 such that holes 334a are coaxially aligned with corresponding holes in flange 145a ( Figures 2 and 3).
  • Relatively long guide arms with T- handles 219 extend radially from BOP 310 and enable subsea manipulation of stack 300 with one or more subsea ROVs 170 during deployment and installation of stack 300, while simultaneously allowing ROVs 170 to stay outside hydrocarbon plume 160.
  • Transition spool 330 also includes a plug 337 extending axially through flange 334.
  • Plug 337 is positioned and oriented for axial insertion into outlet 149b of mud boost line 149 in flange 145a when flanges 145a, 334 are coupled together.
  • Plug 337 functions to close off and seal outlet 149b, thereby preventing the leakage of hydrocarbon fluids therethrough in the event mud boost valve 149c fails or otherwise leaks.
  • plug 337 is pre-installed in transition spool 330 prior to deployment such that it engages mating outlet 149b as flanges 145a, 334 axially abut.
  • plug 337 may be installed by an ROV 170 after flanges 145a, 334 are secured together.
  • Plug 337 may be fitted with an adapter for coupling a chemical supply line to plug 337 to inject a chemical into outlet 149b in the event it is necessary to flush hydrates from outlet 149b.
  • mule shoe 230 extends axially from flange 334 to lower end 330b.
  • Central axis 235 of mule shoe 230 is coaxially aligned with axes 315, 335, first or upper end 230a of mule shoe 230 is connected to flange 334, second or lower end 230b of mule shoe 230 defines lower end 330b of transition spool 330, and through bore 232 of mule shoe 230 defines the lower portion of flow bore 331 of transition spool 330.
  • mule shoe 230 is coaxially aligned with joint 143 and axially advanced into joint 143 until flanges 145a, 334 axially abut.
  • through slots 233 provide a flow path for hydrocarbon fluids discharged from wellbore 101 through BOP 120 and LMRP 140.
  • capping stack 300 is shown being deployed and installed subsea on LMRP 140 to cap and contain wellbore 101. Unlike capping stack 200 previously described, in this embodiment, capping stack 300 is installed in stages - transition spool 330 is first deployed and installed subsea onto flex joint 143, and then, BOP 310 is deployed and installed subsea onto transition spool 330.
  • the two stage installation approach is preferred since it allows the relatively light weight, stand alone transition spool 330 suspended on wires 180 to be more precisely and easily manipulated subsea with ROVs 170 to achieve sufficient engagement with riser adapter 145.
  • transition spool 330 due to the relatively light weight of transition spool 330, ROVs 170 are more adept at maintaining the position of spool 330 and engagement of flanges 145a, 334 while bolting flanges 145a, 334 together.
  • transition spool 330 is secured to riser adapter 145, the upward facing wellhead connector coupling 150a is available for landing and connecting BOP 310, which is typically a more straight forward procedure similar to conventional subsea BOP installation operations.
  • transition spool 330 is shown being controllably lowered subsea and secured to flex joint 143; and in Figures 11E-H, BOP 310 is shown being controllably lowered subsea and secured to transition spool 330.
  • riser 115 is removed from flex joint 143, and any tubulars or debris extending upward from flange 145a are preferably cut off substantially flush with flange 145 a.
  • riser adapter 145 is preferably oriented vertically and locked in the vertical position. Examples of suitable systems and methods for orienting riser adapter 145 vertically and locking riser adapter 145 in the vertical orientation are disclosed in U.S. patent application no. 61/482,132 filed May 3, 2011, and entitled "Adjustment and Restraint System for a Subsea Flex Joint," which is hereby incorporated herein by reference in its entirety for all purposes.
  • transition spool 330 is shown being controllably lowered subsea with a plurality of cables 180 secured to spool 330 and extending to a surface vessel.
  • cables 180 are preferably relatively strong cables (e.g., steel cables) capable of withstanding the anticipated tensile loads.
  • a winch or crane mounted to a surface vessel is preferably employed to support and lower spool 330 on cables 180.
  • cables 180 are employed to lower spool 330 in this embodiment, in other embodiments, spool 330 may be deployed subsea on a pipe string.
  • spool 330 is lowered subsea under its own weight from a location generally above and laterally offset from wellbore 101, BOP 120, and LMRP 140 and outside of plume 160 to reduce the potential for hydrate formation within spool 330.
  • spool 330 is lowered laterally offset from riser adapter 145 (outside of plume 160) until mule shoe 230 is slightly above flange 145a.
  • ROVs 170 monitor the position of spool 330 relative to flex joint 143.
  • spool 330 is moved laterally into position immediately above riser adapter 145 with mule shoe 230 substantially coaxially aligned with riser adapter 145.
  • spool 330 is rotated about axis 335 to substantially align guide pins 217 with corresponding holes 148 in flange 145a ( Figure 3).
  • One or more ROVs 170 may utilize their claws 172 and handles 218 to guide and rotate spool 330 into the proper alignment relative to flange 145a.
  • spool 330 Due to its own weight, spool 330 is substantially vertical, whereas riser adapter 145 may be oriented at an angle relative to vertical (e.g., angle a).
  • angle a an angle relative to vertical
  • guide wires are secured to the lower tips of the pins. The free ends of such guide wires are threaded through the mating holes in the flange, and are pulled to urge the pins into alignment with the mating holes and the mule shoe into alignment with the flex joint.
  • cables 180 lower spool 330 axially downward, thereby inserting and axially advancing pins 217 into corresponding holes 148 and inserting and axially advancing mule shoe lower end 230b into riser adapter 145 until flange 334 axially abuts and engages flange 145a as shown in Figure 1 ID.
  • the frustoconical surface on the lower end of each pin 217 functions to guide each pin 217 into its corresponding hole 148, even if pins 217 are initially slightly misaligned with holes 148.
  • taper on lower end 230b functions to guide the insertion and coaxial alignment of spool 330 and riser adapter 145 as stack 200 is lowered from a position immediately above riser adapter 145, even if mule shoe 230 is initially slightly misaligned with riser adapter 145.
  • emitted hydrocarbons flow freely through spool 330 and slots 233 in mule shoe 230, thereby relieving well pressure and offering the potential to reduce the resistance to the axial insertion of mule shoe 230 into riser adapter 145 and coupling of transition spool 330 thereto.
  • ROVs 170 decouple cables 180 from spool 330
  • BOP 310 is controllably lowered subsea and coupled to upper end 330a of transition spool 330 with connector 150.
  • BOP 310 is shown being lowered subsea with cables 180 secured thereto and extending to a winch or crane mounted to a surface vessel. Due to the weight of BOP 310, cables 180 are preferably relatively strong cables (e.g., steel cables) capable of withstanding the anticipated tensile loads. Although cables 180 are employed to lower BOP 310 in this embodiment, in other embodiments, BOP 310 may be deployed subsea on a pipe string.
  • cables 180 are employed to lower BOP 310 in this embodiment, in other embodiments, BOP 310 may be deployed subsea on a pipe string.
  • BOP 310 is lowered subsea under its own weight from a location generally above and laterally offset from wellbore 101, BOP 120, LMRP 140, and spool 330, and outside of plume 160 to reduce the potential for hydrate formation within BOP 310.
  • BOP 310 is lowered laterally offset from transition spool 330 and outside of plume 160 until lower end 312b is slightly above spool 330.
  • ROVs 170 monitor the position of BOP 310 relative to spool 330.
  • BOP 310 is moved laterally into position immediately above spool 330 with female coupling 150b at lower end 312b generally coaxially aligned with male coupling 150a at upper end 330a of spool 330.
  • One or more ROVs 170 may utilize their claws 172 and handles 219 to guide and position BOP 310 relative to spool 330.
  • BOP 310 Due to its own weight, BOP 310 is substantially vertical, whereas spool 330 may be oriented at an angle relative to vertical (e.g., angle a). Thus, it is to be understood that perfect coaxial alignment of BOP 310 and spool 330 may be difficult. With BOP 310 positioned immediately above and couplings 150a, b generally coaxially aligned, cables 180 lower BOP 310 axially downward. Due to the weight of BOP 310, compressive loads between BOP 310 and spool 330 urge the male coupling 150a at upper end 310a into the female coupling 150b at lower end 330b. Once the male coupling 150a is sufficiently seated in the female coupling 150b to form wellhead-type connector 150, connector 150 is hydraulically actuated to securely connect BOP 310 to spool 330 and form stack 300 as shown in Figure 11H.
  • rams 127 Prior to moving BOP 310 laterally over riser adapter 145 and spool 330, rams 127 are transitioned to the open position allowing hydrocarbon fluids emitted by flex joint 143 and spool 330 to flow unrestricted through BOP 310, thereby relieving well pressure and offering the potential to reduce the resistance to the coupling of BOP 310 to spool 330.
  • Rams 127 may be transitioned to the open position at the surface 102 prior to deployment, or subsea via one or more ROVs 170.
  • capping stack 400 for capping wellbore 101 previously described ( Figure 4) and containing the hydrocarbon fluids therein is shown.
  • capping stack 400 comprises a drilling BOP 410 similar to BOP 110 previously described.
  • BOP 410 has a central or longitudinal axis 415, and includes a body 412 with a first or upper end 412a, a second or lower end 412b, and a main bore 413 extending axially between ends 412a, b.
  • Upper end 412a comprises a male coupling 150a of a wellhead-type connector 150 and lower end 412b comprises the female coupling 150b of a wellhead-type connector 150.
  • BOP 410 includes a plurality of axially stacked sets of opposed rams - one set of opposed blind shear rams or blades 127, one set of opposed blind rams 128, and one set of opposed pipe rams 129, each as previously described.
  • Opposed rams 127, 128, 129 are disposed in cavities that intersect main bore 413 and support rams 127, 128, 129 as they move into and out of main bore 413.
  • Each set of rams 127, 128, 129 is actuated and transitioned between an open position and a closed position.
  • rams 127, 128, 129 are radially withdrawn from main bore 413, and in the closed positions, rams 127, 128, 129 are radially advanced into main bore 413 to close off and seal main bore 413.
  • Each set of rams 127, 128, 129 is actuated and transitioned between the open and closed positions by a pair of actuators 126 as previously described.
  • a plurality of T-handles 219 extend radially from body 412.
  • handles 219 are used by ROVs 170 to manipulate, rotate, and position stack 400.
  • capping stacks described herein preferably include temperature and pressure transducers to measure the temperature and pressure of the hydrocarbon fluids within the capping stack, and a means for relieving wellbore pressure to avoid a potential blowout.
  • capping stack 400 includes a temperature transducer 421 and a pressure transducer 422 positioned along main bore 413 to measure the temperature and pressure, respectively, of the fluids within main bore 413.
  • Transducers 421, 422 are positioned axially below the lowermost set of rams 127 such that transducers 421 , 422 can continue to measure the temperature and pressure, respectively, of the wellbore fluids even if rams 127 are closed.
  • Transducers 421, 422 communicate the temperature and pressure measurements to a transmitter 423, which then communicates the temperature and pressure measurements to the surface where they may be continuously or periodically monitored.
  • transmitter 423 may comprise any suitable device for communicating a signal subsea.
  • transmitter 423 is an acoustic telemetry transmitter.
  • stack 400 also includes a plurality of side outlets 414 extending from main bore 413 through body 412.
  • Each side outlet 414 has a first end 414a in fluid communication with main bore 413, a second end 414b distal main bore 413 and extending from body 412, and a sealing mechanism 414c that controls the flow of fluids through the side outlet 414.
  • each sealing mechanism 414c is an isolation valve.
  • side outlets 414 provide a means for relieving the pressure of fluids in main bore 413.
  • Each second end 414b preferably comprises a connector hub for connecting other devices to end 414a to aid in managing the fluid pressure within main bore 413.
  • Such other devices may include, without limitation, chokes, pressure relief assemblies (e.g., burst disk assembly), pressure caps, flexible jumpers, etc.
  • one or more side outlets 414 may be coupled to a containment and/or disposal system such that outlets 414 produce to the containment and/or disposal system once stack 400 is coupled to BOP 120. Although side outlets 414 are shown and described as outlets, they may also be used as inlets to inject fluids into main bore 413.
  • capping stack 400 is shown being deployed and installed subsea on BOP 120 to cap and contain wellbore 101. More specifically, in Figure 14 A, capping stack 400 is shown being controllably lowered subsea; in Figure 14B, capping stack 400 is shown being move laterally over BOP 120; in Figure 14C, capping stack 400 is shown being generally coaxially aligned with BOP 120 and lowered into engagement with BOP 120; and in Figure 14D, capping stack 400 is shown being secured to BOP 120. As previously described, capping stack 400 is configured to be secured to BOP 120.
  • LMRP 140 is removed from BOP 120 by decoupling connector 150 between BOP 120 and LMRP 140, and then lifting LMRP 140 from BOP 120 with one or more ROVs 170.
  • any tubulars or debris extending from upper end 123 a of BOP 120 are cut off substantially flush with upper end 123b with one or more ROVs 170.
  • stack 400 is shown being controllably lowered subsea with a plurality of cables 180 secured to stack 400 and extending to a surface vessel.
  • cables 180 are preferably relatively strong cables (e.g., steel cables) capable of withstanding the anticipated tensile loads.
  • a winch or crane mounted to a surface vessel is preferably employed to support and lower stack 400 on cables 180.
  • cables 180 are employed to lower stack 400 in this embodiment, in other embodiments, stack 400 may be deployed subsea on a pipe string. Using cables 180, stack 400 is lowered subsea under its own weight from a location generally above and laterally offset from wellbore 101 and BOP 120, and outside of plume 160 to reduce the potential for hydrate formation within stack 400.
  • stack 400 is lowered laterally offset from BOP 120 and outside of plume 160 until lower end 412b is slightly above upper end 123 a.
  • ROVs 170 monitor the position of stack 400 relative to BOP 120.
  • stack 400 is moved laterally into position immediately above BOP 120 with female coupling 150b at lower end 412b of BOP 410 generally coaxially aligned with male coupling 150a at upper end 123a of BOP 120.
  • One or more ROVs 170 may utilize their claws 172 and handles 219 to guide and rotate stack 400 into the proper alignment relative to BOP 120.
  • stack 400 Due to its own weight, stack 400 is substantially vertical, whereas BOP 120 may be oriented at an angle relative to vertical (e.g., angle a). Thus, it is to be understood that perfect coaxial alignment of couplings 150a, b may be difficult. With lower end 412b of BOP 410 positioned immediately above upper end 123a of BOP 120 and couplings 150a, b generally coaxially aligned, cables 180 lower stack 400 axially downward. Due to the weight of BOP 410, compressive loads between BOP 410 and BOP 120 urge the male coupling 150a at upper end 123 a into the female coupling 150b at lower end 412b. Once the male coupling 150a is sufficiently seated in the female coupling 150b to form wellhead-type connector 150, connector 150 is hydraulically actuated to securely connect BOP 410 to BOP 120 as shown in Figure 14D.
  • valves 414c and rams 127, 128, 129 Prior to moving BOP 410 laterally over riser adapter 145, valves 414c and rams 127, 128, 129 are transitioned to the open position allowing hydrocarbon fluids emitted by BOP 120 to flow unrestricted through main bore 413 and flow passages 414. Valves 414c and rams 127, 128, 129 may be transitioned to the open position at the surface 102 prior to deployment, or subsea via one or more ROVs 170.
  • BOP 410 As BOP 410 is moved laterally over BOP 120 and lowered into engagement with BOP 120, emitted hydrocarbon fluids flow freely through BOP 410, thereby relieving well pressure and offering the potential to reduce the resistance to the coupling of BOP 410 to BOP 120.
  • wellbore 101 With a sealed, secure connection between BOP 410 and BOP 120, wellbore 101 is shut in by closing one or more rams 127, 128, 129, valves 414c, or combinations thereof with ROVs 170. It should be appreciated that closure of one or both rams 129, 128 shuts off the flow of hydrocarbons through main bore 413 to upper end 412a, but does not impede the flow of emitted hydrocarbons through passages 414. Thus, if rams 127 and valves 414c are open, hydrocarbons emitted from wellbore 101 may pass through a portion of main bore 413 and passages 414 into the surrounding sea water, regardless of whether one or both rams 129, 128 are closed.
  • pressure transducer 422 continuously measures the pressure of wellbore fluids in main bore 413. The measured pressure is communicated to the surface with transmitter 423. If the measured pressure approaches an undesirable level during or after shutting in wellbore 101, rams 127, 128, 129, valves 414c, or combinations thereof can be opened to relieve wellbore pressure. Chokes or pressure relief assemblies may also be coupled to second ends 414b to help manage wellbore pressure during and after installation of stack 400. For example, ends 414b of side outlets 414 may be closed with a burst disk assembly that prevents fluid flow through ends 414b below a predetermined pressure and allows fluid flow through ends 414b above the predetermined pressure that causes one or more bust disks to rupture.
  • the assembly is preferably designed such that the predetermined pressure is below the pressure at which a blowout may occur such that wellbore pressure is relieved prior to reaching an undesirable level.
  • capping stack 500 for capping wellbore 101 previously described ( Figure 4) and containing the hydrocarbon fluids therein is shown.
  • capping stack 500 comprises BOP 310 as previously described coupled to a valve spool 510 including sealing mechanism 220 (i.e., isolation valve 220) as previously described.
  • BOP 310 is releasably coupled to spool 510 with a mechanical wellhead-type connector 150 as previously described.
  • spool 510 includes a spool body 511 having a central axis 515 (coaxially aligned with axis 315 when coupled to BOP 310), a first or upper end 510a releasably coupled to BOP 310, and a second or lower end 510b opposite upper end 510a, and a main bore 512 extending axially between ends 510a, b.
  • Valve 220 controls the flow of fluids through main bore 512 - when valve 220 is in an "open” position, valve 220 allows fluid flow through main bore 512 between ends 510a, b, however, when valve 220 is in a "closed” position, valve 220 restricts and/or prevents fluid flow through main bore 512 between ends 510a, b.
  • valve 220 is a ball valve.
  • valve 220 may comprise any valve suitable for subsea conditions and containing the anticipated pressure of fluids from wellbore 101 including, without limitation, a butterfly valve, a gate valve, or a ball valve.
  • spool 510 is not a flanged spool.
  • upper end 510a comprises a male coupling 150a of a wellhead-type connector 150 and lower end 510b comprises a female coupling 150b of a wellhead-type connector 150.
  • capping stack 500 is configured to be secured to BOP 120 following removal of LMRP 140.
  • T-handles 219 extending radially from spool body 511, enable subsea manipulation of body 511 with one or more subsea ROVs 170 during deployment and installation of body 511.
  • capping stack 500 is shown being deployed and installed subsea on BOP 120 to cap and contain wellbore 101. Similar to capping stack 300 previously described, in this embodiment, capping stack 500 is installed in stages - valve spool 510 is first deployed and installed subsea onto BOP 120, and then, BOP 310 is deployed and installed subsea onto valve spool 510. In Figures 17A-D, valve spool 510 is shown being controllably lowered subsea and secured to BOP 120; and in Figures 17E-H, BOP 310 is shown being controllably lowered subsea and secured to valve spool 510.
  • capping stack 500 is configured to be secured directly to BOP 120
  • LMRP 140 is removed from BOP 120 before connecting valve spool 510 to BOP 120.
  • LMRP 140 is removed from BOP 120 by decoupling connector 150 between BOP 120 and LMRP 140, and then lifting LMRP 140 from BOP 120 with one or more ROVs 170.
  • any tubulars or debris extending from upper end 123 a of BOP 120 are cut off substantially flush with upper end 123b with one or more ROVs 170.
  • valve spool 510 is shown being controllably lowered subsea with a plurality of cables 180 secured to spool 510 and extending to a surface vessel. Due to the weight of spool 510, cables 180 are preferably relatively strong cables (e.g., steel cables) capable of withstanding the anticipated tensile loads. A winch or crane mounted to a surface vessel is preferably employed to support and lower spool 510 on cables 180. Although cables 180 are employed to lower spool 510 in this embodiment, in other embodiments, spool 510 may be deployed subsea on a pipe string. Using cables 180, spool 510 is lowered subsea under its own weight from a location generally above and laterally offset from wellbore 101 and BOP 120, and outside of plume 160 to reduce the potential for hydrate formation within spool 510.
  • cables 180 are employed to lower spool 510 in this embodiment, in other embodiments, spool 510 may be deployed subsea on a pipe string.
  • spool 510 is lowered laterally offset from BOP 120 and outside of plume 160 until lower end 510b is slightly above BOP 120.
  • ROVs 170 monitor the position of spool 510 relative to BOP 120.
  • spool 510 is moved laterally into position immediately above BOP 120 with female coupling 150b substantially coaxially aligned with male coupling 150a. Due to its own weight, spool 510 is substantially vertical, whereas BOP 120 may be oriented at an angle relative to vertical (e.g., angle a).
  • angle a angle relative to vertical
  • cables 180 With lower end 510b positioned immediately above upper end 123a of BOP 120 and couplings 150a, b generally coaxially aligned, cables 180 lower spool 510 axially downward. Due to the weight of spool 510, compressive loads between spool 510 and BOP 120 urge male coupling 150a at upper end 123 a into the female coupling 150b at lower end 412b. Once the male coupling 150a is sufficiently seated in the female coupling 150b to form wellhead-type connector 150, connector 150 is hydraulically actuated to securely connect spool 510 to BOP 120 as shown in Figure 17D. With a sealed, secure connection between BOP 120 and spool 510, cables 180 may be decoupled from spool 510 with ROVs 170 and removed to the surface.
  • valve 220 Prior to moving spool 510 laterally over BOP 120, valve 220 is transitioned to the open position allowing hydrocarbon fluids emitted by BOP 120 to flow unrestricted through spool 510, thereby relieving well pressure and offering the potential to reduce the resistance to the coupling of spool 510 to BOP 120. Valve 220 may be transitioned to the open position at the surface 102 prior to deployment, or subsea via one or more ROVs 170.
  • BOP 310 is shown being controllably lowered subsea with cables 180 secured thereto and extending to a winch or crane mounted to a surface vessel. Due to the weight of BOP 310, cables 180 are preferably relatively strong cables (e.g., steel cables) capable of withstanding the anticipated tensile loads. Although cables 180 are employed to lower BOP 310 in this embodiment, in other embodiments, BOP 310 may be deployed subsea on a pipe string.
  • cables 180 are employed to lower BOP 310 in this embodiment, in other embodiments, BOP 310 may be deployed subsea on a pipe string.
  • BOP 310 is lowered subsea under its own weight from a location generally above and laterally offset from wellbore 101, BOP 120, and spool 510, and outside of plume 160 to reduce the potential for hydrate formation within BOP 310.
  • BOP 310 is lowered laterally offset from spool 510 and outside of plume 160 until lower end 312b is slightly above spool 510.
  • ROVs 170 monitor the position of BOP 310 relative to spool 510.
  • BOP 310 is moved laterally into position immediately above spool 510 with couplings 150a, b substantially coaxially aligned with spool 510.
  • One or more ROVs 170 may utilize their claws 172 and handles 219 to guide and position BOP 310 relative to spool 510.
  • BOP 310 Due to its own weight, BOP 310 is substantially vertical, whereas spool 510 may be oriented at an angle relative to vertical (e.g., angle a). Thus, it is to be understood that perfect coaxial alignment of couplings 150a, b may be difficult. With BOP 310 positioned immediately above and couplings 150a, b generally coaxially aligned, cables 180 lower BOP 310 axially downward. Due to the weight of BOP 310, compressive loads between BOP 310 and spool 510 urge the male coupling 150a at upper end 510a into the female coupling 150b at lower end 312b. Once the male coupling 150a is sufficiently seated in the female coupling 150b to form wellhead-type connector 150, connector 150 is hydraulically actuated to securely connect BOP 310 to spool 510 and form stack 500 as shown in Figure 17H.
  • rams 127 Prior to moving BOP 310 laterally over spool 510, rams 127 are transitioned to the open position allowing hydrocarbon fluids emitted by BOP 120 and spool 330 to flow unrestricted therethrough. Rams 127 may be transitioned to the open position at the surface 102 prior to deployment, or subsea via one or more ROVs 170.
  • emitted hydrocarbon fluids flow freely through BOP 120, spool 510, and BOP 310.
  • capping stack 600 for capping wellbore 101 previously described ( Figure 4) and containing the hydrocarbon fluids therein is shown.
  • capping stack 600 comprises a BOP 610 and transition spool 330 as previously described coupled to BOP 310.
  • BOP 610 is releasably coupled to transition spool 330 with a mechanical wellhead-type connector 150 as previously described.
  • BOP 610 is similar to BOP 410 previously described.
  • BOP 610 has a central or longitudinal axis 615, and includes a body 612 with a first or upper end 612a, a second or lower end 612b, and a main bore 613 extending axially between ends 612a, b.
  • Upper end 612a comprises a wellhead-type connector male coupling 150a
  • lower end 612b comprises a wellhead-type connector female coupling 150b.
  • BOP 610 includes a plurality of axially stacked sets of opposed rams - two sets of opposed upper blind shear rams or blades 127, and one set of opposed blind rams 128, each as previously described.
  • Opposed rams 127, 128 are disposed in cavities that intersect main bore 613 and support rams 127, 128 as they move into and out of main bore 613.
  • Each set of rams 127, 128 is actuated and transitioned between an open position and a closed position. In the open positions, rams 127, 128 are radially withdrawn from main bore 613, and in the closed positions, rams 127, 128 are radially advanced into main bore 613 to close off and seal main bore 613.
  • Each set of rams 127, 128 is actuated and transitioned between the open and closed positions by a pair of actuators 126 as previously described.
  • a frame 616 is connected to body 612 and extends around rams 127. As will be described in more detail below, frame 616 may be used by ROVs 170 to manipulate, rotate, and position BOP 610.
  • BOP 610 includes a temperature transducer 421 and a pressure transducer 422, each as previously described, positioned along main bore 613 to measure the temperature and pressure, respectively, of the fluids within main bore 613.
  • Transducers 421, 422 are positioned axially below the lowermost set of rams 128 such that transducers 421, 422 can continue to measure the temperature and pressure, respectively, of the wellbore fluids even if rams 127, 128 are closed.
  • Transducers 421, 422 communicate the temperature and pressure measurements to a transmitter 423 as previously described, which then communicates the temperature and pressure measurements to the surface where they may be continuously or periodically monitored.
  • BOP 610 also includes a plurality of side outlets 614 extending from main bore 613 through body 612.
  • Each side outlet 614 has a first end 614a in fluid communication with main bore 613, a second end 614b distal main bore 613 and extending from body 612, and a pair of gate valves 614c that controls the flow of fluids through the side outlet 614.
  • side outlets 614 provide a means for injecting fluids into main bore 613 as well as relieving the pressure of fluids in main bore 613.
  • side outlets 614 provide passages for introducing fluids into main bore 613 and removing fluids from main bore 613.
  • each second end 614b comprises a connector hub 617 for connecting other devices thereto.
  • Such other devices may include, without limitation, chokes, pressure relief assemblies (e.g., burst disk assembly), pressure caps, flexible jumpers, etc.
  • one or more side outlets 614 may be coupled to a containment and/or disposal system such that outlets 614 produce to the containment and/or disposal system once stack 600 is coupled to BOP 120.
  • capping stack 600 is installed in stages - transition spool 330 is first deployed and installed subsea onto flex joint 143 as previously described and shown in Figures 11A-D, and then, BOP 610 is deployed and installed subsea onto transition spool 330 as described below.
  • riser 115 is removed from flex joint 143, and any tubulars or debris extending upward from flange 145 a are preferably cut off substantially flush with flange 145 a as previously described.
  • BOP 610 is shown configured for subsea deployment using a deployment assembly 601.
  • deployment assembly 601 includes a hydrate inhibitor injection system 630 and a running tool 640 which are coupled to BOP 610 for subsea deployment.
  • System 630 includes a perforated riser joint 631 and an injection line 635.
  • Riser joint 631 is a tubular having a first or upper end 631a, a second or lower end 631b, and a plurality of holes 632 along its length.
  • Upper end 631a comprises an annular mounting flange 633 connecting riser joint 631 to running tool 650.
  • Lower end 631b comprises an annular flange 634 connected to a wellhead-type connector female coupling 150b that engages male coupling 150a at upper end 612a, thereby releasably coupling riser joint 631 to BOP 610.
  • Injection line 635 comprises an elongate fluid flow line having a first or inlet end 635 a coupled to running tool 640 and a second or outlet end 635b coupled to connector hub 617 of one side outlet 614.
  • Running tool 640 has a first or upper end 640a removably coupled to a tubular pipe string 650 and a second or lower end 640b comprising an annular flange 641 coupled to flange 633 of riser joint 631.
  • Upper end 640a includes a fluid passage 642 having a first or inlet end 642a in fluid communication with tubing string 650 and a second or outlet end 642b in fluid communication with inlet 635a.
  • a hydrate inhibiting fluid such as glycol may be pumped down string 650, through passage 642, line 635, and side outlet 614 into main bore 613 to reduce the potential for hydrate formation within BOP 610.
  • Lower end 640b of running tool 640 occludes and completely closes off riser joint 631.
  • any fluids flowing axially upward through main bore 613 e.g., hydrocarbon fluids, hydrate inhibitors, etc.
  • riser joint 631 are blocked by running tool 640 and are forced radially outward through holes 632.
  • running tool 640, perforated riser joint 631, and hydrate inhibitor injection system 630 are shown in conjunction with BOP 610 of capping stack 600, running tool 640, perforated riser joint 631, injection system 630, or combinations thereof may be employed during deployment of other embodiments of BOPs, capping stacks, valve spools, and valve manifolds described herein.
  • the BOP, capping stack, valve spool, or valve manifold is preferably deployed with a pipe string (e.g., string 650) to enable communication of hydrate inhibiting chemicals to system 630.
  • BOP 610 is shown being lowered subsea and secured to transition spool 330, which has already been deployed and installed subsea onto flex joint 143 as previously described and shown in Figures 11A-D.
  • BOP 610 is controllably lowered subsea with tubular string 650, which extends from running tool 640 to a surface vessel.
  • a derrick or other suitable device mounted to the surface vessel is preferably employed to support and lower BOP 610 on string 650.
  • string 650 is employed to lower BOP 610 in this embodiment, in other embodiments, BOP 610 may be deployed subsea on cables (e.g., cables 180).
  • BOP 610 is lowered subsea under its own weight from a location generally above and laterally offset from wellbore 101, BOP 120, and transition spool 330 and outside of plume 160 to reduce the potential for hydrate formation within BOP 610.
  • a hydrate inhibitor such as glycol is pumped down tubing string 650, through passage 642, line 635, and side outlet 614 into main bore 613.
  • the injected inhibitor is free to flow upward within main bore 613 into riser joint 631 and out holes 632.
  • hydrate inhibitor injection system 630 offers the potential to reduce and/or eliminate hydrate formation during deployment of BOP 610.
  • BOP 610 is lowered laterally offset from transition spool 330 and outside of plume 160 until lower end 612b is slightly above spool 330.
  • ROVs 170 monitor the position of BOP 610 relative to spool 330.
  • BOP 610 is moved laterally into position immediately above spool 330 with female coupling 150b at lower end 612b substantially coaxially aligned with male coupling 150a at upper end 330a of spool 330.
  • One or more ROVs 170 may utilize their claws 172 and frame 616 to guide and position BOP 610 relative to spool 330.
  • BOP 610 Due to its own weight, BOP 610 is substantially vertical, whereas spool 330 may be oriented at an angle relative to vertical (e.g., angle a). Thus, it is to be understood that perfect coaxial alignment of couplings 150a, b may be difficult. With BOP 610 positioned immediately above spool 330 with couplings 150a, b generally coaxially aligned, string 650 lowers BOP 610 axially downward. Due to the weight of BOP 610, compressive loads between BOP 610 and spool 330 urge the male coupling 150a at upper end 330a into the female coupling 150b at lower end 612b.
  • connector 150 is hydraulically actuated to securely connect BOP 610 to spool 330 and form stack 600 as shown in Figure 24D. Injection of hydrate inhibiting fluids into main bore 613 may continue, as desired, after BOP 610 securely connected to spool 330.
  • rams 127, 128 and valves 614c Prior to moving BOP 610 laterally over spool 330, rams 127, 128 and valves 614c are transitioned to the open position allowing hydrocarbon fluids emitted by spool 330 to flow unrestricted through BOP 610 and passages 614 that are not being used for hydrate inhibitor injection, thereby relieving well pressure and offering the potential to reduce the resistance to the coupling of BOP 610 to spool 330.
  • Rams 127, 128 and valves 614c may be transitioned to the open position at the surface 102 prior to deployment, or subsea via one or more ROVs 170.
  • wellbore 101 With a sealed, secure connection between BOP 610 and spool 330, wellbore 101 is shut in by closing one or more rams 127, 128, valves 614c, or combinations thereof with ROVs 170. Hydrate inhibitor fluid injection is preferably ceased before shutting in wellbore 101. It should be appreciated that closure of one or both sets of rams 127 shuts off the flow of hydrocarbons through main bore 613 to upper end 612a, but does not impede the flow of emitted hydrocarbons through passages 614.
  • lower rams 128 and valves 614c are open, hydrocarbons emitted from wellbore 101 may pass through a portion of main bore 613 and passages 614 into the surrounding sea water, regardless of whether one or both sets of upper rams 127 are closed. Therefore, to completely shut in wellbore 101, lower rams 128 must be closed or valves 414c and at least one set of upper rams 127 must be closed.
  • Transducers 421, 422 and side outlets 614 offer the potential to reduce the likelihood of an undesirable blowout during and after shutting in wellbore 101.
  • pressure transducer 422 continuously measures the pressure of wellbore fluids in main bore 413. The measured pressure is communicated to the surface with transmitter 423. If the measured pressure approaches an undesirable level during or after shutting in wellbore 101, rams 127 128, valves 614c, or combinations thereof can be opened to relieve wellbore pressure. Chokes or pressure relief assemblies may also be coupled to connector hubs 617 (with corresponding valves 614c open) to help manage wellbore pressure during and after installation of stack 600.
  • ends 614b of side outlets 614 may be closed with a burst disk assembly that prevents fluid flow through ends 614b below a predetermined pressure and allows fluid flow through ends 614b above the predetermined pressure that causes one or more bust disks to rupture.
  • the assembly is preferably designed such that the predetermined pressure is below the pressure at which a blowout may occur such that wellbore pressure is relieved prior to reaching an undesirable level.
  • tubular string 650, running tool 650, and riser joint 631 may be disconnected from BOP 610 and removed to the surface by disconnecting wellhead-type connector 150 between riser joint 631 and BOP 610.
  • injection line 635 is disconnected from connector hub 617 so that it can be removed to the surface along with running tool 650.
  • ROVs 170 may be employed to perform these procedures.
  • capping stack 600 has been shown and described as including BOP 610 and transition spool 330, it should be appreciated that BOP 610 itself may function as a capping stack that is directly connected to BOP 120 in a similar manner as capping stack 400 previously described.
  • BOP 610 would be configured as shown in Figures 22 and 23, and deployed as shown in Figures 24A-E, with the exception that female coupling 150b at lower end 612b is directly coupled to male coupling 150a at upper end 123a of BOP 120 following removal of LMRP 140 from BOP 120.
  • capping stack 700 for capping wellbore 101 previously described ( Figure 4) and containing the hydrocarbon fluids therein is shown.
  • capping stack 700 comprises a valve spool 710 and transition spool 330 as previously described coupled to spool 710.
  • spool 710 is releasably coupled to transition spool 330 with a mechanical wellhead-type connector 150 as previously described.
  • valve spool 710 has a central or longitudinal axis 715, and includes a body 712 with a first or upper end 712a, a second or lower end 712b, and a main bore 713 extending axially between ends 712a, b.
  • valve spool 710 includes sealing mechanism 220 (i.e., isolation valve 220) as previously described, which controls the flow of fluids through main bore 713 - when valve 220 is in an "open” position, valve 220 allows fluid flow through main bore 713 between ends 712a, b, however, when valve 220 is in a "closed” position, valve 220 restricts and/or prevents fluid flow through main bore 713 between ends 712a, b. Valve 220 is transitioned between the open and closed positions with subsea ROVs 170.
  • type of actuator e.g.
  • valve 220 is a ball valve.
  • valve 220 may comprise any valve suitable for subsea conditions and containing the anticipated pressure of fluids from wellbore 101 including, without limitation, a gate valve or a ball valve.
  • the valve spool e.g., valve spool 710) may include more than one valve (e.g., valve 220) that controls the flow of fluid through the main bore (e.g., bore 713).
  • spool 710 is not a flanged spool. Rather, upper end 712a of spool body 712 comprises a wellhead-type connector male coupling 150a, and lower end 612b comprises a wellhead-type connector female coupling 150b. As will be described in more detail below, capping stack 700 is configured to be secured to flex joint 143. T-handles 219 extending radially from spool body 712, enable subsea manipulation of spool 710 with one or more subsea ROVs 170 during deployment and installation of spool 710.
  • spool 710 includes a temperature transducer 421 and a pressure transducer 422, each as previously described, positioned along main bore 713 to measure the temperature and pressure, respectively, of the fluids within main bore 713.
  • Transducers 421, 422 are positioned axially below isolation valve 220 such that transducers 421, 422 can continue to measure the temperature and pressure, respectively, of the wellbore fluids even if valve 220 is closed.
  • Transducers 421, 422 communicate the temperature and pressure measurements to a transmitter 423 as previously described, which then communicates the temperature and pressure measurements to the surface where they may be continuously or periodically monitored.
  • valve spool 710 also includes a plurality of side outlets 714 extending from main bore 713 through body 712.
  • Each side outlet 714 has a first end 714a in fluid communication with main bore 713, a second end 714b distal main bore 713 and extending from body 712, and a sealing mechanism 714c that controls the flow of fluids through the side outlet 714.
  • each sealing mechanism 714c is a valve.
  • valve spool 710 may also be described as a "valve manifold.”
  • side outlets 714 provide a means for injecting fluids into main bore 713 as well as relieving the pressure of fluids in main bore 713.
  • each second end 714b comprises a connector hub 617 as previously described for connecting other devices thereto.
  • Such other devices may include, without limitation, chokes, pressure relief assemblies (e.g., burst disk assembly), pressure caps, flexible jumpers, etc.
  • one or more side outlets 714 may be coupled to a containment and/or disposal system such that outlets 714 produce to the containment and/or disposal system once stack 700 is coupled to BOP 120.
  • capping stack 700 is installed in stages - transition spool 330 is first deployed and installed subsea onto flex joint 143 as previously described and shown in Figures 11A-D, and then, valve manifold 710 is deployed and installed subsea onto transition spool 330 as described below.
  • riser 115 is removed from flex joint 143, and any tubulars or debris extending upward from flange 145 a are preferably cut off substantially flush with flange 145 a as previously described.
  • valve manifold 710 is shown being lowered subsea and secured to transition spool 330, which has already been deployed and installed subsea onto flex joint 143 as previously described and shown in Figures 11A-D.
  • valve manifold 710 is shown being controllably lowered subsea with a plurality of cables 180 secured to stack 700 and extending to a surface vessel. Due to the weight of valve manifold 710, cables 180 are preferably relatively strong cables (e.g., steel cables) capable of withstanding the anticipated tensile loads.
  • a winch or crane mounted to a surface vessel is preferably employed to support and lower valve manifold 710 on cables 180.
  • cables 180 are employed to lower stack 200 in this embodiment, in other embodiments, valve manifold 710 may be deployed subsea on a pipe string.
  • valve manifold 710 is lowered laterally offset from transition spool 330 and outside of plume 160 until lower end 712b is slightly above spool 330.
  • ROVs 170 monitor the position of valve manifold 710 relative to spool 330.
  • valve manifold 710 is moved laterally into position immediately above spool 330 with female coupling 150b at lower end 712b substantially coaxially aligned with male coupling 150a at upper end 330a of spool 330.
  • One or more ROVs 170 may utilize their claws 172 and handles 219 to guide and position valve manifold 710 relative to spool 330.
  • valve manifold 710 Due to its own weight, valve manifold 710 is substantially vertical, whereas spool 330 may be oriented at an angle relative to vertical (e.g., angle a). Thus, it is to be understood that perfect coaxial alignment of couplings 150a, b may be difficult. With valve manifold 710 positioned immediately above spool 330 with couplings 150a, b generally coaxially aligned, cables 180 lower valve manifold 710 axially downward. Due to the weight of valve manifold 710, compressive loads between valve manifold 710 and spool 330 urge the male coupling 150a at upper end 330a into the female coupling 150b at lower end 712b.
  • connector 150 is hydraulically actuated to securely connect valve manifold 710 to spool 330 and form stack 700 as shown in Figure 27D.
  • a hydrate inhibitor injection system similar to system 630 previously described may be used to inject hydrate inhibiting fluids into main bore 713 via one or more side outlets 714.
  • valve 220 and valves 714c Prior to moving valve manifold 710 laterally over spool 330, valve 220 and valves 714c are transitioned to the open position allowing hydrocarbon fluids emitted by spool 330 to flow unrestricted through main bore 713 and passages 714, thereby relieving well pressure and offering the potential to reduce the resistance to the coupling of manifold 710 to spool 330.
  • Valves 220, 714c may be transitioned to the open position at the surface 102 prior to deployment, or subsea via one or more ROVs 170.
  • valve manifold 710 With a sealed, secure connection between valve manifold 710 and spool 330, wellbore 101 is shut in by closing valve 220 and valves 714c with ROVs 170.
  • Transducers 421, 422 and side outlets 714 offer the potential to reduce the likelihood of an undesirable blowout during and after shutting in wellbore 101.
  • pressure transducer 422 continuously measures the pressure of wellbore fluids in main bore 413. The measured pressure is communicated to the surface with transmitter 423. If the measured pressure approaches an undesirable level during or after shutting in wellbore 101, one or more valves 220, 714c can be opened to relieve wellbore pressure.
  • Chokes or pressure relief assemblies may also be coupled to connector hubs 617 (with corresponding valves 714c open) to help manage wellbore pressure during and after installation of stack 700.
  • ends 714b of side outlets 714 may be closed with a burst disk assembly that prevents fluid flow through ends 714b below a predetermined pressure and allows fluid flow through ends 714b above the predetermined pressure that causes one or more bust disks to rupture.
  • the assembly is preferably designed such that the predetermined pressure is below the pressure at which a blowout may occur such that wellbore pressure is relieved prior to reaching an undesirable level.
  • cables 180 may be decoupled from valve manifold 710 with ROVs 170 and removed to the surface. However, it may be desirable to keep cables 180 connected to valve manifold 710 until after shutting off the flow of hydrocarbons in case valve manifold 710 needs to be lifted back to the surface for any reason (e.g., there is a blowout or failure while shutting in wellbore 101).
  • capping stack 700 has been shown and described as including valve manifold 710 and transition spool 330, it should be appreciated that valve manifold 710 itself may function as a capping stack that is directly connected to BOP 120 in a similar manner as capping stack 400 previously described. In such embodiments, valve manifold 710 would be deployed as shown in Figures 27A-E, with the exception that female coupling 150b at lower end 712b is directly coupled to male coupling 150a at upper end 123a of BOP 120 following removal of LMRP 140 from BOP 120.
  • capping stacks described herein may be deployed subsea from a surface vessel and installed on a subsea BOP (e.g., BOP 120) or LMRP (e.g., LMRP 140) that is emitting hydrocarbon fluids into the surrounding sea.
  • BOP e.g., BOP 120
  • LMRP e.g., LMRP 140
  • pressure and temperature sensors are included to measure the pressure and temperature of the wellbore fluids, thereby enabling an operator to manage the opening and closing of valves and rams in a manner that reduces the likelihood of a blowout while shutting in the wellbore.
  • the valves and rams are preferably closed in a sequential order while the wellbore pressure is continuously monitored.
  • that valve or ram or another valve or ram
  • the wellbore pressure may be monitored so that a valve or ram may be opened in the event of an unexpected spike in wellbore pressure to relieve such wellbore pressure increase.
  • a subsea capping stack e.g., capping stack 200, 300, 400, 500, 600, 700
  • LMRP 140 is mounted to BOP 120 with wellhead connector 150
  • riser 115 is coupled to LMRP 140 with a flanged connection.
  • potential landing sites include riser adapter 145 of LMRP 140 following removal of riser 115 and male coupling 150a at upper end 123a of BOP 120 following removal of LMRP 140 from BOP 120.
  • These represent particularly suitable landing sites as the flanged connection between riser 115 and riser adapter 145 may be broken subsea with the aid of ROVs 170, and connector 150 between BOP 120 and LMRP 140 may be decoupled with the aid of ROVs 170.
  • the ultimate selection of the most desirable landing site may vary from well to well and depends on a variety of factors including, without limitation, the ease with which a particular connection may be broken and reconnected, the type of damage, the component(s) that are damaged (e.g., BOP 120, LMRP 140, riser 115, etc.), the potential for adverse effects when preparing the selected landing site (e.g., exposure of internal debris, trapped pipes, etc.), the potential for increased well flow/hydrocarbon emissions, the ability of the landing site and associated hardware (e.g., BOP 120, LMRP 140, etc.) to take the load of the capping stack, or combinations thereof.
  • capping stack 300 in which transition spool 330 is deployed and installed to LMRP 140 followed by deployment and installation of BOP 310 onto transition spool 330
  • each component is preferably deployed in substantially the same manner as described in method 800, albeit the landing site of the second component deployed will be the upper end of the first component deployed.
  • the selected landing site is LMRP 140
  • the flanged connection between riser 115 and riser adapter 145 is broken, and riser 115 is removed from riser adapter 115 according to block 806.
  • the selected landing site it BOP 120
  • connector 150 between LMRP 140 and BOP 120 is broken, and LMRP 140 is removed from BOP 120 according to block 807.
  • Identification of the landing site also defines the connection that will be needed at the lower end of the capping stack.
  • the lower end of the capping stack preferably comprise a mating female coupling 150b configured to mate and engage male coupling 150a of BOP 120.
  • the lower end of the capping stack preferably comprises a flange configured to mate and engage with flange 145 a of riser adapter 145.
  • the capping stack After preparation of the landing site via block 806 or 807, the capping stack is deployed from a surface vessel in and lowered subsea in block 810.
  • the valves and rams in the capping stack are preferably opened during deployment and installation to allow the discharged hydrocarbon stream to pass therethrough unrestricted.
  • the capping stack is lowered laterally offset from the landing site and out of the plume of hydrocarbons emitted from the subsea landing site according to block 811.
  • block 812 while laterally offset from the landing site and outside the hydrocarbon plume, the capping stack is lowered until is immediately axially above the landing site.
  • the capping stack is moved laterally over the landing site, and properly alignment with the landing site (e.g., coaxially align mating couplings 150a, b, align pins 217 with mating holes guide holes 148 in flange 145a, etc.) in block 814.
  • ROVs 170 are preferably employed to properly position and orient the capping stack relative to the landing site.
  • blocks 815 and 816 the capping stack is lowered into engagement with the landing site and secured thereto. In embodiments described herein, the capping stack is secured to the landing site with a flanged connection or wellhead-type connector 150.

Landscapes

  • Geology (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Mining & Mineral Resources (AREA)
  • Environmental & Geological Engineering (AREA)
  • Fluid Mechanics (AREA)
  • Physics & Mathematics (AREA)
  • General Life Sciences & Earth Sciences (AREA)
  • Geochemistry & Mineralogy (AREA)
  • Chemical & Material Sciences (AREA)
  • Oil, Petroleum & Natural Gas (AREA)
  • Earth Drilling (AREA)
  • Pens And Brushes (AREA)

Abstract

La présente invention a trait à un procédé de coiffage d'un puits sous-marin, lequel procédé comprend une étape (a) consistant à identifier un site de réception sous-marin sur le bloc d'obturation de puits (BOP) ou la colonne montante marine inférieure (LMRP) afin de connecter un empilement de coiffage. De plus, le procédé comprend une étape (b) consistant à préparer le site de réception sous-marin afin de connecter l'empilement de coiffage. En outre, le procédé comprend une étape (c) consistant à installer un empilement de coiffage sur le site de réception sous-marin. D'autre part, le procédé comprend une étape (d) consistant à fermer le puits avec l'empilement de coiffage après l'étape (c).
PCT/US2012/033305 2011-04-13 2012-04-12 Systèmes et procédés de coiffage d'un puits sous-marin WO2012142274A2 (fr)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
US201161475032P 2011-04-13 2011-04-13
US61/475,032 2011-04-13

Publications (2)

Publication Number Publication Date
WO2012142274A2 true WO2012142274A2 (fr) 2012-10-18
WO2012142274A3 WO2012142274A3 (fr) 2013-09-19

Family

ID=46022669

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/US2012/033305 WO2012142274A2 (fr) 2011-04-13 2012-04-12 Systèmes et procédés de coiffage d'un puits sous-marin

Country Status (2)

Country Link
US (1) US20130020086A1 (fr)
WO (1) WO2012142274A2 (fr)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2014083434A3 (fr) * 2012-11-28 2015-07-23 Stena Drilling Ltd Equipement de sécurité de puits
EP3042032A4 (fr) * 2013-09-04 2017-06-07 Trendsetter Engineering, Inc. Bloc de coiffage pour utilisation avec un puits sous-marin
CN109690021A (zh) * 2016-08-26 2019-04-26 海德里尔美国配送有限责任公司 用于离岸钻井立管的换能器组件
WO2020032920A1 (fr) * 2018-08-06 2020-02-13 Halliburton Energy Services, Inc. Pile de coiffage de robinet à bille

Families Citing this family (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US9057243B2 (en) * 2010-06-02 2015-06-16 Rudolf H. Hendel Enhanced hydrocarbon well blowout protection
US8820411B2 (en) * 2011-06-09 2014-09-02 Organoworld Inc. Deepwater blow out throttling apparatus and method
US9567830B2 (en) * 2011-09-15 2017-02-14 Bryan L. Collins Transition tool and method
US9045959B1 (en) * 2012-09-21 2015-06-02 Trendsetter Engineering, Inc. Insert tube for use with a lower marine riser package
US11187052B2 (en) * 2016-12-08 2021-11-30 Kinetic Pressure Control Ltd. Explosive disconnect
AU2017370435B2 (en) * 2016-12-08 2020-10-22 Kinetic Pressure Control, Ltd. Explosive disconnect
BR112020006502A2 (pt) 2017-10-17 2020-09-29 Halliburton Energy Services, Inc. sistema híbrido de pilha de capeamento de poço e método para controlar um fluxo de fluido de um furo de poço
US11028663B1 (en) * 2019-11-18 2021-06-08 Trendsetter Engineering, Inc. Process and apparatus for installing a payload onto a subsea structure

Family Cites Families (18)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4461354A (en) * 1981-08-13 1984-07-24 Buras Allen M Hydraulic well cap
US4515399A (en) * 1982-12-27 1985-05-07 Lockheed Corporation Symmetrically loaded flexible connector having multiple passageways
US5046896A (en) * 1990-05-30 1991-09-10 Conoco Inc. Inflatable buoyant near surface riser disconnect system
US5150752A (en) * 1991-04-22 1992-09-29 Ole Gunst Oil well-fire containment device
US5492373A (en) * 1994-09-28 1996-02-20 J. M. Huber Corporation Wellhead flange for interconnecting a threaded wellhead and a flanged blowout preventer
EP1270870B1 (fr) * 2001-06-22 2006-08-16 Cooper Cameron Corporation Appareil pour tester un obturateur anti-éruption
US7322407B2 (en) * 2002-02-19 2008-01-29 Duhn Oil Tool, Inc. Wellhead isolation tool and method of fracturing a well
EP1519002A1 (fr) * 2003-09-24 2005-03-30 Cooper Cameron Corporation Combinaison de vanne d'éruption et de séparateur
CA2444043C (fr) * 2003-10-08 2007-04-24 L. Murray Dallas Outil de stimulation de puits et methode d'insertion d'un bouchon de contre-pression par un mandrin de l'outil
US7216714B2 (en) * 2004-08-20 2007-05-15 Oceaneering International, Inc. Modular, distributed, ROV retrievable subsea control system, associated deepwater subsea blowout preventer stack configuration, and methods of use
NO323513B1 (no) * 2005-03-11 2007-06-04 Well Technology As Anordning og fremgangsmate for havbunnsutplassering og/eller intervensjon gjennom et bronnhode pa en petroleumsbronn ved hjelp av en innforingsanordning
US7921917B2 (en) * 2007-06-08 2011-04-12 Cameron International Corporation Multi-deployable subsea stack system
CA2700136C (fr) * 2007-09-21 2012-11-20 Scott Phillip Mcgrath Systeme et procede pour fournir une redondance supplementaire de commande de bloc obturateur de puits
US9004176B2 (en) * 2010-07-21 2015-04-14 Marine Well Containment Company Marine well containment system and method
US8408310B1 (en) * 2010-07-23 2013-04-02 Philip J. Oddo Method and apparatus of mounting a valve on a flange with flexible bolts to stop oil flow from a ruptured pipe or device
US8434558B2 (en) * 2010-11-15 2013-05-07 Baker Hughes Incorporated System and method for containing borehole fluid
US8746345B2 (en) * 2010-12-09 2014-06-10 Cameron International Corporation BOP stack with a universal intervention interface
US8826989B2 (en) * 2011-01-18 2014-09-09 Noble Drilling Services Inc. Method for capping a well in the event of subsea blowout preventer failure

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
WO2014083434A3 (fr) * 2012-11-28 2015-07-23 Stena Drilling Ltd Equipement de sécurité de puits
US9222327B2 (en) 2012-11-28 2015-12-29 Stena Drilling Ltd. Well safety equipment
EP3042032A4 (fr) * 2013-09-04 2017-06-07 Trendsetter Engineering, Inc. Bloc de coiffage pour utilisation avec un puits sous-marin
CN109690021A (zh) * 2016-08-26 2019-04-26 海德里尔美国配送有限责任公司 用于离岸钻井立管的换能器组件
WO2020032920A1 (fr) * 2018-08-06 2020-02-13 Halliburton Energy Services, Inc. Pile de coiffage de robinet à bille

Also Published As

Publication number Publication date
WO2012142274A3 (fr) 2013-09-19
US20130020086A1 (en) 2013-01-24

Similar Documents

Publication Publication Date Title
US20130020086A1 (en) Systems and methods for capping a subsea well
US20120318521A1 (en) Subsea containment cap adapters
US9488024B2 (en) Annulus cementing tool for subsea abandonment operation
US7410003B2 (en) Dual purpose blow out preventer
US9260931B2 (en) Riser breakaway connection and intervention coupling device
US4077472A (en) Well flow control system and method
US20130032351A1 (en) Releasable connections for subsea flexible joints and service lines
US20120318516A1 (en) Subsea connector with a latching assembly
US9284806B2 (en) Systems and methods for pulling subsea structures
EP2321491A2 (fr) Systèmes et procédés d'intervention dans des puits sous-marins
US20130048295A1 (en) Apparatus and methods for establishing and/or maintaining controlled flow of hydrocarbons during subsea operations
US9127524B2 (en) Subsea well intervention system and methods
US20130140035A1 (en) Systems And Methods For Collecting Hydrocarbons Vented From A Subsea Discharge Site
US20130014954A1 (en) Subsea Connector with a Split Clamp Latch Assembly
US20120273212A1 (en) Flange separation and retrieval tool
WO2012177713A2 (fr) Raccord sous-marin comportant un ensemble de capuchon de verrou actionné
WO2017137622A1 (fr) Dispositif et procédé permettant de retirer ou d'installer un arbre de noël horizontal
AU2012271162A1 (en) Air-freightable containment cap for containing a subsea well

Legal Events

Date Code Title Description
121 Ep: the epo has been informed by wipo that ep was designated in this application

Ref document number: 12717965

Country of ref document: EP

Kind code of ref document: A2

122 Ep: pct application non-entry in european phase

Ref document number: 12717965

Country of ref document: EP

Kind code of ref document: A2