초록 ▼

The invention relates to a rotatable fairing (1) for a marine riser (2) or other slender marine structure. The fairing (1) is arranged on the riser for reducing watercurrent-induced stresses on said riser (2), said fairing (1) having a tail portion (3) for trailing generally in the downstream direct

The invention relates to a rotatable fairing (1) for a marine riser (2) or other slender marine structure. The fairing (1) is arranged on the riser for reducing watercurrent-induced stresses on said riser (2), said fairing (1) having a tail portion (3) for trailing generally in the downstream direction behind said riser. The fairing (1) is provided with an attenuation unit (8) for counteracting the unstable rotation of said fairing (2) relative to said riser (2), in order to prevent undesired vibrations of said riser (2). The fairing is provided with one or more clamps (10) for attachment to and around a periphery of said riser (2), said clamps (10) arranged with a gear rim (12) for engagement with an actuating cogged wheel (14) of said attenuation unit (8).

대표청구항 ▼

The invention claimed is: 1. A rotatable fairing for a marine riser or other slender marine structure, said fairing for reducing watercurrent-induced stresses on said riser, said fairing having a tail portion for trailing generally in the downstream direction behind said riser, wherein said fairing

The invention claimed is: 1. A rotatable fairing for a marine riser or other slender marine structure, said fairing for reducing watercurrent-induced stresses on said riser, said fairing having a tail portion for trailing generally in the downstream direction behind said riser, wherein said fairing is provided with an attenuation unit for counteracting the unstable rotation of said fairing relative to said riser, in order to prevent undesired vibrations of said riser, said attenuation unit having an energy dissipation rate which increases as a function of the fairing's angular speed. 2. The fairing of claim 1, said fairing provided a nose portion between which said nose portion and said tail portion a bore for said riser is accommodated, said nose portion arranged for generally heading upstream relative to said riser. 3. The fairing of claim 1, said fairing provided with one or more clamps for attachment to and around a periphery of said riser, said clamps arranged with a gear rim for engagement with an actuating cogged wheel of said attenuation unit. 4. The fairing of claim 3, said cogged wheel of said attenuation unit arranged for being disconnectable from said gear rim for preventing locking of said fairing in a disadvantageous angular position. 5. The fairing of claim 3 said attenuation unit comprising a rotational spring connected between the fairing and the gear rim. 6. The fairing of claim 1, said attenuation unit comprising a dashpot. 7. The fairing of claim 1, said attenuation unit comprising a mechanical brake. 8. The fairing of claim 1, said attenuation unit comprising a generator. 9. The fairing of claim 1, said attenuation unit comprising a motor. 10. The fairing of claim 1, said fairing provided with one or more force sensors arranged for measuring forces induced by watercurrents on said riser. 11. The fairing of claim 10, said fairing provided with a control unit for receiving force sensor signals from said one or more sensors indicating said measured forces on said riser, said control unit arranged for calculating a control signal indicating the desired corrective moment to act on said fairing in order to reduce said forces. 12. The fairing of claim 11, said attenuation unit comprising a pump; said pump having a pump energy dissipation rate being a product of a pump constant and a function increasing with an increasing angular rate (θ) of said fairing relative to said riser; and said pump energy dissipation rate's pump constant having a variable value controlled by a control signal calculated by said control unit during operation. 13. The fairing according to claim 10, said force sensors comprising axial stress sensors for being arranged on said marine riser by combining three or four axially directed strain sensors. 14. The fairing according to claim 10, said fairing further provided with angular rate sensors arranged for sensing an angular rate of said fairing or said riser. 15. The fairing of claim 1, said fairing provided with one or more moment sensors arranged for measuring moments induced by watercurrents on said riser. 16. The fairing of claim 15, said fairing provided with a control unit for receiving moment sensor signals from said one or more moment sensors indicating said measured moments on said riser, said control unit arranged for calculating a control signal indicating a desired corrective moment to act on said fairing in order to reduce said moments on said riser. 17. The fairing according to claim 16, said moment sensors being bending moment sensors for being arranged on said marine riser, said bending moment sensors arranged for measuring local bending strain due to bending moments between successive portions of said riser. 18. The fairing of claim 16, said attenuation unit comprising a pump; said pump having a pump energy dissipation rate being a product of a pump constant and a function increasing with an increasing angular rate (θ) of said fairing relative to said riser; and said pump energy dissipation rate's pump constant having a variable value controlled by a control signal calculated by said control unit during operation. 19. The fairing of claim 1, said fairing provided with one or more acceleration sensors arranged for measuring accelerations induced by watercurrents on said riser. 20. The fairing of claim 19, said fairing provided with a control unit for receiving acceleration sensor signals from said one or more acceleration sensors indicating said measured accelerations on said riser, said control unit arranged for calculating a control signal indicating a desired corrective moment to act on said fairing in order to reduce said accelerations on said riser. 21. The fairing of claim 20, said attenuation unit comprising a pump; said pump having a pump energy dissipation rate being a product of a pump constant and a function increasing with an increasing angular rate (θ) of said fairing relative to said riser; and said pump energy dissipation rate's pump constant having a variable value controlled by a control signal calculated by said control unit during operation. 22. The fairing of claim 1, said attention unit comprising a pump. 23. The fairing of claim 22, said pump having a pump energy dissipation rate being a product of a pump constant and a function increasing with an increasing angular rate (θ) of said fairing relative to said riser. 24. The fairing of claim 23, said pump energy dissipation rate's pump constant having a predefined value given before assembly and launch of said riser. 25. A method for reducing watercurrent-induced stresses on a marine riser with a rotatable fairing having a tail portion for trailing generally in the downstream direction behind said riser, the method comprising a continuous loop of the following steps: a) measuring forces induced by watercurrents on said riser using one or more force sensors arranged on said fairing; b) providing sensor signals from said one or more force sensors indicating said measured forces on said riser to a control unit arranged with said fairing; c) calculating in said control unit a control signal representing a change of rotational angle of said fairing relative to said riser in order for reducing said forces on said riser; and d) actuating said desired change of rotational angle of said fairing relative to said riser upon receipt of said control signal using a motor. 26. A method for reducing watercurrent-induced stresses on a marine riser with a rotatable fairing having a tail portion for trailing generally in the downstream direction behind said riser, the method comprising a continuous loop of the following steps: a) measuring accelerations induced by watercurrents on said riser using one or more acceleration sensors arranged on said fairing; b) providing sensor signals from said one or more acceleration sensors indicating said measured accelerations of said riser to a control unit arranged with said fairing; c) calculating in said control unit a control signal representing a change of rotational angle of said fairing relative to said riser in order for reducing said accelerations of said riser; and d) actuating said desired change of rotational angle of said fairing relative to said riser upon receipt of said control signal using a motor.