초록 ▼

A method to interchangeably connect a plurality of Lower Marine Riser Packages with a lower BOP stack includes engaging a Lower Marine Riser Package connector of the Lower Marine Riser Package, with a Lower Stack mandrel connector of a Lower Stack, thereby aligning the Lower Marine Riser Package and

A method to interchangeably connect a plurality of Lower Marine Riser Packages with a lower BOP stack includes engaging a Lower Marine Riser Package connector of the Lower Marine Riser Package, with a Lower Stack mandrel connector of a Lower Stack, thereby aligning the Lower Marine Riser Package and the Lower Stack axially about a vertical axis, engaging at least one ring alignment pin of the Lower Marine Riser Package with at least one alignment plate of the Lower Stack, thereby rotationally aligning the Lower Marine Riser Package and the Lower Stack within a specified angle about the vertical axis, and engaging feed-thru connections between the Lower Marine Riser Package and the Lower Stack.

대표청구항 ▼

1. A method of assembling a subsea pressure control device to be interchangeably attached with plural receiving pressure control devices, the method comprising: providing a layout including at least one hole on a frame of the movable pressure control device;forming the hole in the frame such that a

1. A method of assembling a subsea pressure control device to be interchangeably attached with plural receiving pressure control devices, the method comprising: providing a layout including at least one hole on a frame of the movable pressure control device;forming the hole in the frame such that a size of the formed hole along an axis of the frame is larger than a size of a first half of a feed-thru component by a first predetermined amount, which is larger than normal tolerances;placing the first half of the feed-thru component in the formed hole of the frame;positioning the first half inside the formed hole relative to a first datum selected on the frame and a second datum selected as a centerline of the pressure control device;moving the first half inside the formed hole until a position of the first half relative to the first and second datums is within normal tolerances with regard to one of plural desired positions of the first half relative to the first and second datums; andfixing the first half to the frame. 2. The method of claim 1, further comprising: providing the layout including the at least one hole on a receiving frame of a receiving pressure control device;forming a corresponding hole in the receiving frame of the receiving pressure control device such that a size of the formed hole along an axis of the receiving frame is larger than a size of a second half of the feed-thru component by a second predetermined amount, which is larger than normal tolerances;placing the second half of the feed-thru component in the formed hole of the receiving frame; andfloating the second half of the feed-thru component. 3. The method of claim 2, wherein the floating comprises: freely rotating at least a part of the second half of the feed-thru component about a point of contact between the first half of the feed-thru component and the second half of the feed-thru component. 4. The method of claim 2, wherein the floating comprises: translating at least a part of the second half of the feed-thru component in a plane bounded by the hole of the receiving frame of the receiving pressure control device. 5. The method of claim 2, further comprising: providing a bearing ring or a spherical alignment element between the receiving frame of the receiving pressure control device and the second half of the feed-thru component to allow the entire second half of the feed-thru component to rotate relative to the receiving frame. 6. The method of claim 1, further comprising: providing the layout including the at least one hole on a receiving frame of a receiving pressure control device;forming a corresponding hole in the receiving frame of the receiving pressure control device such that a size of the formed hole along an axis of the receiving frame is larger than a size of a second half of the feed-thru component by a second predetermined amount, which is larger than normal tolerances;placing the second half of the feed-thru component in the formed hole of the receiving frame;positioning the second half inside the formed hole of the receiving frame relative to a third datum selected on the receiving frame until a position of the second half relative to the third datum is within normal tolerances with regard to a desired position of the second half relative to the third datum; andfixing the second half to the receiving frame. 7. The method of claim 1, wherein the feed-thru component is at least one of a choke line, a kill line, a wellbore, a hot stab line, a multiplex hydraulic line, a hydraulic line, an electrical line, or a blowout preventer operating line. 8. The method of claim 1, wherein the pressure control device is a lower marine riser package and the plural receiving pressure control devices are lower blowout preventer stacks, which are deployed undersea. 9. A subsea pressure control device configured to be interchangeable with plural receiving pressure control devices, the subsea pressure control device comprising: a frame on which at least an oversized hole is formed, the oversized hole being larger than a layout hole that is designed to accommodate a first half of a feed-thru component; andthe first half of the feed-thru component which is configured to mate with a second half of the feed-thru component, the first half being positioned inside the oversized hole such that a position of the first half relative to a first datum on the frame and a second datum which is a centerline of the subsea pressure control device is within normal tolerances with regard to one of plural desired positions of the first half relative to the first and second datums, whereina part of the first half is fixed to the frame after being positioned inside the oversized hole. 10. The subsea pressure control device of claim 9, wherein the entire first half is fixed to the frame. 11. The subsea pressure control device of claim 9, wherein the feed-thru component is at least one of a choke line, a kill line, a wellbore, a hot stab line, a multiplex hydraulic line, a hydraulic line, an electrical line, or a blowout preventer operating line. 12. A system including a subsea pressure control device configured to be interchangeable with plural receiving pressure control devices, the system comprising: a frame of the subsea control device on which at least an oversized hole is formed, the oversized hole being larger than a layout hole that is designed to accommodate a first half of a feed-thru component; andthe first half of the feed-thru component which is configured to mate with a second half of the feed-thru component, the first half being positioned inside the oversized hole such that a position of the first half relative to a first datum on the frame and a second datum which is a centerline of the subsea pressure control device is within normal tolerances with regard to one of plural desired positions of the first half relative to the first and second datums, whereina part of the first half is fixed to the frame after being positioned inside the oversized hole. 13. The system of claim 12, further comprising: a receiving frame of a receiving pressure control device, the receiving frame having an oversized hole corresponding to the oversized hole of the subsea pressure control device and the oversized hole of the receiving frame being configured to accommodate the second half of the feed-thru component; andthe second half of the feed-thru component being positioned in the oversized hole of the receiving frame and being configured to float. 14. The system of claim 13, wherein the second half floats by rotating at least a part of the second half of the feed-thru component about a point of contact between the first half of the feed-thru component and the second half of the feed-thru component. 15. The system of claim 13, wherein the second half floats by translating at least a part of the second half of the feed-thru component in a plane bounded by the oversized hole of the receiving frame of the receiving pressure control device. 16. The system of claim 12, further comprising: a bearing ring or a spherical alignment element provided between the receiving frame of the receiving pressure control device and the second half of the feed-thru component to allow the entire second half of the feed-thru component to rotate relative to the receiving frame. 17. The system of claim 12, wherein the feed-thru component is one of a choke line or kill line. 18. The system of claim 17, further comprising: another feed-thru component that is a multiplex hydraulic line, a first half of the another feed-thru component being a wedge block and a second half of the another feed-thru component being a wedge receiver;the wedge block being configured to perform a linear motion relative to the wedge receiver, andthe wedge receiver being configured to rotate and translate when contacted by the wedge block.