IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
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출원번호 |
US-0772992
(2010-05-03)
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등록번호 |
US-8888411
(2014-11-18)
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발명자
/ 주소 |
- Wajnikonis, Krzysztof Jan
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출원인 / 주소 |
- Wajnikonis, Krzysztof Jan
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인용정보 |
피인용 횟수 :
1 인용 특허 :
13 |
초록
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This invention introduces three-dimensional (3D) damper arrangements that are used to suppress dynamic motions of a subsea line like a riser, on which the dampers are installed. Damping surfaces (shapes) are mounted on the line so that their combined drag per line unit length dampens motions in 3 mu
This invention introduces three-dimensional (3D) damper arrangements that are used to suppress dynamic motions of a subsea line like a riser, on which the dampers are installed. Damping surfaces (shapes) are mounted on the line so that their combined drag per line unit length dampens motions in 3 mutually perpendicular directions: axial, in-plane (IP) and out-of-plane (OOP). 3D suppression is provided by integral 3D dampers or by combining IP-OOP dampers like strakes with neighboring axial dampers. Increased line motions suppression is achieved by decoupling, particularly on dampers mounted in regions of high line curvature and/or small effective tension. This invention also presents Short Lazy Wave (SLW) configurations of rigid catenary risers, which are also used to suppress dynamic motions. 3D dampers can be used together with SLWs. Motion suppression is introduced to reduce dynamic stresses and to increase fatigue life of the lines.
대표청구항
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1. A three-dimensional damping arrangement device mounted on a subsea line, whereas said three-dimensional damping arrangement device mounted on said subsea line is used to suppress dynamic motions of said subsea line by utilizing shaped surfaces designed to enhance hydrodynamic drag: whereas said s
1. A three-dimensional damping arrangement device mounted on a subsea line, whereas said three-dimensional damping arrangement device mounted on said subsea line is used to suppress dynamic motions of said subsea line by utilizing shaped surfaces designed to enhance hydrodynamic drag: whereas said shaped surfaces designed to enhance hydrodynamic drag are also referred to herein as damping shapes; said subsea line including at least one of a catenary line, or a riser line, or a catenary riser, or a rigid catenary riser, or a metal catenary riser, or a steel catenary riser, or a titanium catenary riser, or an aluminum catenary riser, or a flexible catenary riser, or an umbilical line, or a tendon line, or a cable, or a tether, or a hose, or a jumper, or a tensioned riser, or a free standing riser, or a hybrid riser tower;whereas a plurality of said three-dimensional damping arrangement devices mounted on said subsea line are mounted on said subsea line, including a single said three-dimensional damping arrangement device mounted on said subsea line; said three-dimensional damping arrangement device mounted on said subsea line incorporating said damping shapes that are mounted on said subsea line so that their combined drag per unit length of said subsea line is simultaneously enhanced by design in three mutually perpendicular directions: axial, in-plane and out-of-plane;implementations of said damping shapes having smooth edges or said damping shapes having jagged edges; said three-dimensional damping arrangement device mounted on said subsea line having implementations utilizing planar damping shapes, or said three-dimensional damping arrangement device mounted on said subsea line utilizing curved damping shapes, or said three-dimensional damping arrangement device mounted on said subsea line utilizing damping shapes incorporating curvatures and twists;whereas in particular implementations of said three-dimensional damping arrangement device mounted on said subsea line said damping shapes are oriented so that their combined drag per unit length of said subsea line is simultaneously enhanced by design in three mutually perpendicular directions: axial, in-plane and out-of-plane, whereas said dragger unit length in-plane and said drag per unit length out-of-plane are provided by helicoidal fins; whereas the helixes of said helicoidal fins form small angles with the axis of said subsea line that are defined by the design pitch values of said helicoidal fins and whereas said helicoidal fins essentially form strakes, and whereas said axial damping shapes added to said strakes are oriented so, that vectors normal to the surfaces of said axial damping shapes are essentially aligned with said axis of said subsea line at the mounting locations of said axial shapes on said subsea line;whereas said axial damping shapes are combined with said strakes, or said axial damping shapes are mounted on said subsea line independently in the vicinity of said strakes. 2. The three-dimensional damping arrangement device mounted on the subsea line according to claim 1 utilizing dynamic decoupling to suppress motions. 3. The three-dimensional damping arrangement device mounted on the subsea line according to claim 2, having implementations of said three-dimensional damping arrangement device mounted on said subsea line being built by molding, or said three-dimensional damping arrangement device mounted on said subsea line utilizing prefabricated plates, or said three-dimensional damping arrangement device mounted on said subsea line being strengthened with ribs, or said three-dimensional damping arrangement device mounted on said subsea line using fiber reinforcement technology, or said three-dimensional damping arrangement device mounted on said subsea line utilizing strengthening brace members. 4. The three-dimensional damping arrangement device mounted on the subsea line according to claim 3 clamped mechanically on said subsea line on which it is mounted, whereas implementations of said clamping mechanically utilize bolts, or said clamping mechanically utilizes tape straps, or said clamping mechanically utilizes bolts and straps. 5. The three-dimensional damping arrangement device mounted on the subsea line according to claim 4 utilizing split clamp design being implemented as a symmetrically split clamp, or being implemented as an asymmetrically split clamp, or being implemented as a clamp design split on one side. 6. The three-dimensional damping arrangement device mounted on the subsea line according to claim 1 having implementations incorporating said damping shapes provided with slots, or said three-dimensional damping arrangement device incorporating said damping shapes provided with holes, or said three-dimensional damping arrangement device mounted on said subsea line incorporating said damping shapes provided with slots and holes. 7. The three-dimensional damping arrangement device mounted on the subsea line according to claim 6, having implementations of said three-dimensional damping arrangement device mounted on said subsea line being built by molding, or said three-dimensional damping arrangement device mounted on said subsea line utilizing prefabricated plates, or said three-dimensional damping arrangement device mounted on said subsea line being strengthened with ribs, or said three-dimensional damping arrangement device mounted on said subsea line using fiber reinforcement technology, or said three-dimensional damping arrangement device mounted on said subsea line utilizing strengthening brace members. 8. The three-dimensional damping arrangement device mounted on the subsea line according to claim 7 clamped mechanically on said subsea line on which it is mounted, whereas implementations of said clamping mechanically utilize bolts, or said clamping mechanically utilizes tape straps, or said clamping mechanically utilizes bolts and straps. 9. The three-dimensional damping arrangement device mounted on the subsea line according to claim 8 utilizing split clamp design being implemented as a symmetrically split clamp, or being implemented as an asymmetrically split clamp, or being implemented as a clamp design split on one side. 10. The three-dimensional damping arrangement device mounted on the subsea line according to claim 1 having implementations of said three-dimensional damping arrangement device being built by molding, or said three-dimensional damping arrangement device utilizing prefabricated plates, or said three-dimensional damping arrangement device mounted on said subsea line being strengthened with ribs, or said three-dimensional damping arrangement device mounted on said subsea line using fiber reinforcement technology, or said three-dimensional damping arrangement device mounted on said subsea line utilizing strengthening brace members. 11. The three-dimensional damping arrangement device mounted on the subsea line according to claim 10 clamped mechanically on said subsea line on which it is mounted, whereas implementations of said clamping mechanically utilize bolts or said clamping mechanically utilizes tape straps, or said clamping mechanically utilizes bolts and straps. 12. The three-dimensional damping arrangement device mounted on the subsea line according to claim 11 utilizing split clamp design being implemented as a symmetrically split clamp, or being implemented as an asymmetrically split clamp, or being implemented as a clamp design split on one side. 13. The three-dimensional damping arrangement device mounted on the subsea line according to claim 1, whereas said three-dimensional damping arrangement device is installed on said subsea line on which it is mounted using an adhesive or using welding. 14. The three-dimensional damping arrangement device mounted on the subsea line according to claim 1, implementations of which include said three-dimensional damping arrangement device mounted on said subsea line that is installed on a newly designed said subsea line or said three-dimensional damping arrangement device mounted on said subsea line is retrofitted on a previously installed said subsea line. 15. A lazy wave configuration of a rigid catenary riser, including at least one of a metal catenary riser, or a steel catenary riser, or a titanium catenary riser, or an aluminum catenary riser used in offshore engineering; whereas the length of the positively buoyant segment of said lazy wave configuration of said rigid catenary riser does not exceed the length of 15% of the design water depth and said positively buoyant segment of said lazy wave configuration of said rigid catenary riser is located so, that said positively buoyant segment of said lazy wave configuration of said rigid catenary riser lies in the lower ⅜ of the suspended length of said rigid catenary riser. 16. The lazy wave configuration of said rigid catenary riser according to claim 15, whereas a plurality of three-dimensional damping arrangement devices are mounted on said lazy wave configuration of said rigid catenary riser, including a single said three-dimensional damping arrangement device mounted on said lazy wave configuration of said rigid catenary riser; said three-dimensional damping arrangement device incorporating damping shapes that are mounted on said lazy wave configuration of said rigid catenary riser so that their combined drag per unit length of said rigid catenary riser is simultaneously effective in three mutually perpendicular directions: axial, in-plane and out-of-plane; implementations of said damping shapes including at least said damping shapes having smooth edges or said damping shapes having jagged edges; whereas implementations of said three-dimensional damping arrangement device utilize planar said damping shapes, or said three-dimensional damping arrangement device utilizing curved damping shapes, or said three-dimensional damping arrangement device utilizing said damping shapes incorporating curvatures and twists, or said three-dimensional damping arrangement device incorporating axial damping shapes added to strakes, or said three-dimensional damping arrangement device combining strakes providing in-plane and out-of-plane damping with axial damping shapes mounted independently on said lazy wave configuration rigid catenary riser. 17. The three-dimensional damping arrangement device according to claim 16 utilizing dynamic decoupling to suppress motions. 18. The three-dimensional damping arrangement device according to claim 16 including said three-dimensional damping arrangement device having implementations incorporating said damping shapes provided with slots, or said three-dimensional damping arrangement device incorporating said damping shapes provided with holes, or said three-dimensional damping arrangement device provided with slots and holes. 19. The lazy wave configuration of said rigid catenary riser according to claim 15, whereas said lazy wave configuration of a rigid catenary riser is obtained from a free hanging rigid riser configuration by retrofitting positive buoyancy on a pre-existing free hanging rigid riser.
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