Pursuant to 35 U.S.C. ยง 119 and the Paris Convention Treaty, this application claims foreign priority to Chinese Patent Application No. 201910909820.5 filed Sep. 25, 2019, the contents of which, including any intervening amendments thereto, are incorporated herein by reference. Inquiries from the public to applicants or assignees concerning this document or the related applications should be directed to: Matthias Scholl P.C., Attn.: Dr. Matthias Scholl Esq., 245 First Street, 18th Floor, Cambridge, Mass. 02142.
The disclosure relates to a passive heave compensator (PHC).
Passive heave compensation is a technique used to reduce the influence of waves upon lifting and drilling operations. The main principle in PHC is to store the energy from the external forces such as waves and dissipate them or reapply them later.
The disclosure provides a passive heave compensator, which comprises an elastic cable, an electromagnetic damping device, a cylindrical sector, and a disc damping plate. The electromagnetic damping device comprises a first cylinder comprising a helical coil, a permanent magnet mechanism disposed in the first cylinder, a first cover plate, a second cover plate, a first sliding shaft, a second sliding shaft, a first spring, a second spring, a first end cover, and a second end cover. The cylindrical sector comprises a roof plate, a middle plate, a base plate, a first side plate, a second side plate, and a curved plate. The disc damping plate is disposed around the middle plate of cylindrical sector.
The elastic cable is directly connected to the electromagnetic damping device; the electromagnetic damping device is disposed in a central part of the cylindrical sector; the middle plate is disposed between the roof plate and the base plate, thereby dividing the cylindrical sector into a two-layered structure; the first side plate shares one end with the second side plate, and another ends of the first side plate and the second side plate are connected to the curved plate; the permanent magnet mechanism comprises a second cylinder, and a plurality of permanent magnets disposed in the second cylinder with identical polar directions; two ends of the permanent magnet mechanism are sealed by the first cover plate and the second cover plate, respectively the first cover plate comprises a first mounting hole and the first sliding shaft is disposed in the first mounting hole; the second cover plate comprises a second mounting hole and the second sliding shaft is disposed in the second mounting hole; the first spring and the first end cover are wrapped around the first sliding shaft and the first end cover is disposed on the first spring; and the first end cover is fixedly connected to the first cylinder; the second spring and the second end cover are wrapped around the second sliding shaft and the second end cover is disposed on the second spring; and the second end cover is fixedly connected to the second cylinder; and two ends of the first cylinder are provided with a first through hole and a second through hole, respectively, and an energy storage module is disposed between the first through hole and the second through hole and electrically connected to the helical coil.
The first cylinder is fixedly connected to the cylindrical sector.
The roof plate comprises a first hole, the middle plate comprises a second hole, the first side plate comprises a third hole, and the curved plate comprises a fourth hole.
The included angle between the first side plate and the second side plate is 15-60 degrees.
The disc damping plate comprises a surface provided with a first reinforcing rib and a flange.
The disc damping plate comprises a surface provided with a second reinforcing rib abutting against the cylindrical sector.
In the drawings, the following reference numbers are used: 1. Elastic cable 2. Electromagnetic damping device; 3. Cylindrical sector; 4. Second hole; 4a. First hole; 5. Third hole; 5a. Fourth hole; 6. Middle plate; 6a. Roof plate; 6b. Base plate; 7. Curved plate; 7a. First side plate; 7b. Second side plate; 8. First sliding shaft; 9. First end cover; 10. First spring; 11. First cylinder; 12. Permanent magnets; 13. Second spring; 14. Second end cover; 15. Second sliding shaft; 16. First through hole; 17. Second through hole; 18. Second cylinder; 19. First cover plate; 20. Second cover plate; 21. First mounting hole; 22. Second mounting hole; 23. Disc damping plate; 24. Flange; 25. First reinforcing rib; 26. Second reinforcing rib 27. Energy storage module.
To further illustrate, embodiments detailing a passive heave compensator are described below. It should be noted that the following embodiments are intended to describe and not to limit the disclosure.
The elastic cable 1 can be a polymer elastic cable, or other devices that convert an excitation of vibration to an elastic potential energy through elastic deformation thereof. The elastic cable 1 can be made of polymer elastic material comprising a plurality of elastic yarns. The elastic cable can be prepared through modular production where an elastic cable having a particular length and thickness is used as a module. According to the specific situation of submerged buoys, a plurality of elastic cables can be combined in series or in parallel to meet the requirements for the stiffness coefficient and the stretch ratio of the elastic cables.
The cylindrical sector 3 comprises a roof plate 6a, a middle plate 6, abase plate 6b, a curved plate 7, a first side plate 7a, and a second side plate 7b. The middle plate 6 is disposed between the roof plate 6a and the base plate 6b, thereby dividing the cylindrical sector into a two-layered structure; the first side plate 7a shares one end with the second side plate 7b, and another ends of the first side plate 7a and the second side plate 7b are connected to the curved plate 7. A disc damping plate 23 is disposed around the middle plate 6 of the cylindrical sector 3. The disc damping plate 23 comprising a flange 24, a first reinforcing rib 25, and a second reinforcing rib 26. The flange 24 is disposed around the outer edge of the disc damping plate 23, and the first reinforcing rib 25 is disposed on the surface of the disc damping plate 23, and the second reinforcing rib 26 is disposed between the cylindrical sector 3 and the disc damping plate 23. The roof plate 6a comprises a first hole 4a, and the middle plate 6 comprises a second hole 4, and the first side plate 7a comprises a third hole 5, and the curved plate 7 comprises a fourth hole 5a. All of the holes are configured to maintain the consistency of pressure between the inside and outside of the cylindrical sector 3. The included angle A between the first side plate 7a and the second side plate 7b is 60 degrees.
The first spring 10 and the second spring 13 comprise stainless steel or other elastic materials resistant to corrosion, which are stable in seawater and resistant to seawater corrosion.
The helical coil of the first cylinder 11 can be a single coil or a plurality of coils. The frame of the first cylinder 11 can be polymer insulating materials with an insulating and anti-corrosive coating. The surfaces of the frame and the helical coil are coated with a layer of insulating and anti-corrosive material which is immune to seawater corrosion.
The plurality of permanent magnets 12 comprises a plurality of laminated magnetic steel sheets in the identical polar directions, and the gap between the magnetic steel sheets are filled with epoxy resin gasket. The plurality of the magnetic steel sheets and the epoxy resin gasket are placed in the second cylinder 18, thus producing the magnet field lines perpendicular to the surface of the permanent magnets 12.
The second cylinder 18 comprises a polymer material, or an austenitic stainless steel, which is not magnetic and has a tensile strength, with little effect on the magnetic field of the permanent magnets 12. The material is stable in seawater and resistant to seawater corrosion.
When no excitations of vibration occur, the first spring 10 and the second spring 13 keep the permanent magnets 12 in their original positions, thus being ready to produce an effective damping stroke to generate an electromagnetic damping when an excitation of vibration occurs.
When the excitation of vibration occurs and applies to the permanent magnetic mechanism, the permanent magnetic mechanism is driven by the excitation to move, partly offsetting the excitation. The rest excitation is then transmitted to the first spring 10 and the second spring 13 which convert the rest excitation to an elastic potential energy. The working mechanism avoids the first end cover 19 and the second end cover 14 from colliding with the permanent magnets when the electromagnetic damping cannot completely offset a relatively high excitation of vibration, thereby avoiding excessive vibration and preventing structural damage to the equipment. The elastic potential energy converted by the first spring 10 and the second spring 13 is continually released to the first end cover 9 and the second end cover 14 which constrain the translational motion of the sliding shaft in the horizontal plane (two degrees of freedom) while allowing the permanent magnet mechanism to move only in the vertical direction in the first cylinder 11. The first through hole 16 and the second through hole 17, which are disposed on both ends of the first cylinder 11, balance the internal and external pressure of the first cylinder 11.
The cylindrical sector 3 is filled with water thereby increasing the inertial force of the cylindrical sector 3. A plurality of the cylindrical sector 3 connected in series can increase the damping effect, as shown in
The permanent magnet mechanism vertically moves in the first cylinder 11, and the magnetic field moves accordingly. The first cylinder 11 is immobilized. The helical coil cuts through the magnetic lines of the changing magnetic field to induce a current which produces a new magnetic field preventing the movement of the permanent magnet mechanism, thus forming a damping effect.
The electrical energy generated in the electromagnetic damping device 2 is recovered by the energy storage module, and further supplied to a surface buoy or a submerged buoy, to an external resistor or the first cylinder for short-circuit power consumption.
The passive heave compensator provides a stable working environment for the submerged buoy regardless of the water depth, and reduce the operation costs, facilitating the release of the submerged buoy.
It will be obvious to those skilled in the art that changes and modifications may be made, and therefore, the aim in the appended claims is to cover all such changes and modifications.
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