초록 ▼

The invention relates to a device for the utilization of wave energy, with an increased efficiency. Thereto, the device according to the invention comprises a Darrieus rotor having at least two Darrieus rotor blades, wherein the Darrieus rotor has a solidity σD, anda Wells rotor having at least two

The invention relates to a device for the utilization of wave energy, with an increased efficiency. Thereto, the device according to the invention comprises a Darrieus rotor having at least two Darrieus rotor blades, wherein the Darrieus rotor has a solidity σD, anda Wells rotor having at least two Wells rotor blades, wherein the Wells rotor has a solidity σW, wherein the Darrieus rotor and the Wells rotor are rotatable about a common axis of rotation A, andσW is larger than or equal to σD. The invention also relates to a method for harnessing wave energy.

대표청구항 ▼

1. A device for the utilisation of wave energy, which device comprises a Darrieus rotor having at least two Darrieus rotor blades, wherein the Darrieus rotor has a Darrieus solidity (σD) calculated under the formula σD=N·Adb/Ad, wherein N=the number of Darrieus rotor blades;Adb=the surface area of e

1. A device for the utilisation of wave energy, which device comprises a Darrieus rotor having at least two Darrieus rotor blades, wherein the Darrieus rotor has a Darrieus solidity (σD) calculated under the formula σD=N·Adb/Ad, wherein N=the number of Darrieus rotor blades;Adb=the surface area of each Darrieus rotor blade; andAd=the effective cross-sectional area of the Darrieus rotor sweep; anda Wells rotor having at least two Wells rotor blades, wherein the Wells rotor has a Wells solidity (σW) calculated under the formula σW=N·Awb/Aw, wherein N=the number of Wells rotor blades;Awb=the surface area of a Wells rotor;Aw=the effective swept surface area of the Wells rotor; wherein the Darrieus rotor and the Wells rotor are rotatable about a common axis of rotation with the effective cross-sectional area of the Darrieus rotor sweep containing the common axis of rotation and with the effective swept surface area of the Wells rotor being perpendicular to the common axis of rotation, andthe Wells solidity (σW) is larger than or equal to the Darrieus solidity (σD). 2. The device according to claim 1, wherein the Wells solidity (σW) is at least 15% larger than the Darrieus solidity (σD). 3. The device according to claim 1, wherein at least one Wells rotor blade is directly connected to a Darrieus rotor blade. 4. The device according to claim 3, wherein a distal end of each Wells rotor blade is connected to one of the Darrieus rotor blades. 5. The device according to claim 1, wherein the device contains a generator selected from i) a generator for generating electricity, and ii) a generator for generating hydraulic pressure. 6. The device according to claim 1, wherein the Wells solidity (σW) is at least 25% larger than the Darrieus solidity (σD). 7. A device according to claim 6, wherein the Wells solidity (σW) is between 30% and 100% larger than the Darrieus solidity (σD). 8. The device according to claim 1 positioned in a body of water in which waves occur naturally. 9. A device according to claim 8, in conjunction with a wave measuring instrument measuring wave height in the body of water at a location at or near the device, the body of water having a level, wherein the Wells rotor blades are situated at a depth between 0.5 and 2.0 times a 5-minutes' average wave height below the level of the body of water, wherein the 5-minutes' average wave height is an average height of naturally occurring waves in the body of water, as determined over a period of five minutes. 10. A device according to claim 9, wherein the Wells rotor blades are situated at a depth between 0.8 and 1.25 times the 5-minutes' average wave height below the level of the body of water. 11. A device according to claim 8, wherein upper ends of at least two Darrieus blades extend to above twice a year-average wave height, wherein the year-average wave height is an average height of naturally occurring waves in the body of water, as determined over a period of one year. 12. A device according to claim 8, wherein the device is supported in the body of water such that a 5-minutes' average of the axis of rotation is in an orientation of less than 5° to vertical, wherein the 5-minutes' average of the axis of rotation is an average that the axis of rotation leans away from vertical when the device is supported in the body of water, as determined over a period of five minutes. 13. A device according to claim 8, wherein energy selected from hydraulic energy, electricity or hydrogen gas is generated. 14. A method for generating energy by the utilisation of wave energy, comprising: placing a device in a body of water at a location in which waves occur naturally, the device comprising: a Darrieus rotor having at least two Darrieus rotor blades, wherein the Darrieus rotor has a solidity (σD) calculated under the formula σD=N·Adb/Ad, wherein N=the number of Darrieus rotor blades;Adb=the surface area of each Darrieus rotor blade; andAd=the effective cross-sectional area of the Darrieus rotor sweep; anda Wells rotor having at least two Wells rotor blades, wherein the Wells rotor has a solidity (σW) calculated under the formula σW=N·Awb/Aw, wherein N=the number of Wells rotor blades;Awb=the surface area of a Wells rotor;Aw=the effective swept surface area of the Wells rotor;whereinthe Darrieus rotor and the Wells rotor are rotatable about a common axis of rotation with the effective cross-sectional area of the Darrieus rotor sweep containing the common axis of rotation and with the effective swept surface area of the Wells rotor being perpendicular to the common axis of rotation, andthe Wells solidity (σW) is larger than or equal to the Darrieus solidity (σD); andusing rotation of the Darrieus rotor and the Wells rotor caused by orbital motion of the naturally occurring waves to generate energy. 15. A method according to claim 14, further comprising: measuring wave height with a wave measuring instrument placed in the body of water at a location at or near the device, the body of water having a level; andsituating the Wells rotor blades at a depth between 0.5 and 2.0 times a 5-minutes' average wave height below the level of the body of water, wherein the 5-minutes' average wave height is an average height of naturally occurring waves in the body of water, as determined over a period of five minutes. 16. A method according to claim 15, wherein the Wells rotor blades are situated at a depth between 0.8 and 1.25 times the 5-minutes' average wave height below the level of the body of water. 17. A method according to claim 14, wherein upper ends of at least two Darrieus blades extend to above twice a year-average wave height, wherein the year-average wave height is an average height of naturally occurring waves in the body of water, as determined over a period of one year. 18. A method according to claim 14, wherein the device is supported in the body of water such that a 5-minutes' average of the axis of rotation is in an orientation of less than 5° to vertical, wherein the 5-minutes' average of the axis of rotation is an average that the axis of rotation leans away from vertical when the device is supported in the body of water, as determined over a period of five minutes. 19. A method according to claim 14, wherein energy selected from hydraulic energy, electricity or hydrogen gas is generated. 20. A method according to claim 14, wherein the Wells solidity (σW) is between 30% and 100% larger than the Darrieus solidity (σD).