A subsea production system includes a blowout preventer stack that is adapted to seal and contain pressure in a well. The blowout preventer stack has a passageway through which a tubular string may extend into the well. The subsea production system includes a subsea wellhead and a safety shut-in sy
A subsea production system includes a blowout preventer stack that is adapted to seal and contain pressure in a well. The blowout preventer stack has a passageway through which a tubular string may extend into the well. The subsea production system includes a subsea wellhead and a safety shut-in system that has a valve assembly that is adapted to control flow and adapted to allow tools to be lowered therethrough on tubing. The subsea production system includes a cutting module that is adapted to be run into the passageway to allow tools to be lowered therethrough on tubing. The cutting module is further adapted to activate to shear the tubing that is lowered therethrough.
대표청구항▼
What is claimed is: 1. A subsea production system, comprising: a blowout preventer stack adapted to seal and contain pressure in a well, the blowout preventer having a passageway through which a tubular string may extend into the well; a subsea wellhead; a safety shut-in system having a valve asse
What is claimed is: 1. A subsea production system, comprising: a blowout preventer stack adapted to seal and contain pressure in a well, the blowout preventer having a passageway through which a tubular string may extend into the well; a subsea wellhead; a safety shut-in system having a valve assembly adapted to control flow and adapted to allow tools to be lowered therethrough on tubing; and a cutting module located below the valve assembly and adapted to be run into the passageway and adapted to allow tools to be lowered into the passageway an tubing, the cutting module further adapted to activate to shear the tubing lowered into the passageway. 2. The subsea production system of claim 1, wherein the valve assembly comprises at least one ball valve. 3. The subsea production system of claim 1, wherein the tubing is coiled tubing. 4. The subsea production system of claim 1, wherein the cutting module comprises opposing shear blades adapted to overlap upon activation of the cutting module. 5. The subsea production system of claim 4, wherein the opposing shear blades have a V-shaped cutting surface. 6. The subsea production system of claim 4, wherein the opposing shear blades have a curved radii cutting surface. 7. The subsea production system of claim 4, wherein the opposing shear blades are affixed to opposing pistons. 8. The subsea production system of claim 7, wherein the pistons are telescoping pistons. 9. The subsea production system of claim 1, wherein the cutting module is activated by fluid pressure. 10. The subsea production system of claim 9, wherein the fluid pressure is supplied by control lines. 11. The subsea production system of claim 9, wherein the fluid pressure is annular hydraulic pressure. 12. The subsea production system of claim 1, wherein the blowout preventer stack comprises at least one ram preventer. 13. The subsea production system of claim 1, wherein the cutting module is run into the blowout preventer stack after the blowout preventer stack is installed in the subsea production system. 14. The subsea production system of claim 1, wherein the cutting module is adapted to be landed in the blowout preventer stack. 15. The subsea production system of claim 1, wherein the cutting module is separate from the blowout preventer stack. 16. A safety shut-in system for a well, comprising: a valve assembly adapted to control flow and allow tubing deployed tools to be lowered therethrough; and a cutting module located below the valve assembly and adapted to be landed within a blowout preventer stack and allow tubing deployed tools to be lowered therethrough, the cutting module having actuatable opposing shear blades adapted to sever tubing. 17. The safety shut-in system of claim 16, wherein the valve assembly comprises a normally closed flapper valve and a ball valve. 18. The safety shut-in system of claim 16, wherein the opposing shear blades are actuatable by fluid pressure. 19. A cutting module adapted for severing tubing in a well, comprising: a pair of opposing pressure activated telescoping pistons, at least one of the pistons being expandable in length from a first retracted position to a second expanded position to sever the tubing; and shear blades affixed to the pistons such that the shear blades overlap upon activation of the pistons, wherein at least one of the pistons comprises: a first member; a second member slottably disposed inside the first member; and a third member slottably disposed inside the second member, a combined length of the first, second and third members is shorter in the retracted position of the piston than a combined length of the first, second and third members in the expanded position of the piston. 20. A method of severing coiled tubing downhole without collapsing the coiled tubing, comprising: providing a cutting module comprising pressure activated opposing shear blades adapted to sever without collapsing the coiled tubing; disposing the cutting module below a valve assembly adapted to control flow and adapted to allow tools to be lowered therethrough on tubing; running the cutting module at least partially into a blowout preventer stack so that the cutting module is radially contained within at least part of a passageway of the blowout preventer stack through which a tubing string may extend into the well; lowering coiled tubing therethrough the cutting module; and supplying pressure to the cutting module to activate the shear blades to sever the coiled tubing. 21. The method of claim 20, wherein the shear blades have V-shaped cutting surfaces. 22. The method of claim 20, wherein the shear blades have curved radii cutting surfaces. 23. The method of claim 20, further comprising: landing the cutting module housing in a blowout preventer stack. 24. A subsea production system, comprising: a blowout preventer stack adapted to seal and contain pressure in a well; a subsea wellhead; a safety shut-in system having a valve assembly adapted to control flow and adapted to allow tools to be lowered therethrough on tubing; and a cutting module located below the valve assembly and adapted to allow tools to be towered therethrough on tubing, the cutting module further adapted to activate to shear the tubing lowered therethrough. 25. The subsea production system of claim 24, wherein the valve assembly comprises at least one ball valve. 26. The subsea production system of claim 24, wherein the tubing comprises coiled tubing. 27. The subsea production system of claim 24, wherein the cutting module comprises opposing shear blades adapted to overlap upon activation of the cutting module. 28. The subsea production system of claim 24, wherein the opposing shear blades have a V-shaped cutting surface. 29. The subsea production system of claim 27, wherein the opposing shear blades have a curved radii cutting surface. 30. The subsea production system of claim 27, wherein the opposing shear blades are affixed to opposing pistons. 31. A safety shut-in system for a well, comprising: a valve assembly adapted to control flow and allow tubing deployed tools to be lowered therethrough; and a cutting module located below the valve assembly and adapted to allow tubing deployed tools to be lowered therethrough, the cutting module having actuatable opposing shear blades adapted to sever tubing. 32. The safety shut-in system of claim 31, wherein the valve assembly comprises a normally closed flapper valve and a ball valve.
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