초록 ▼

Co-axial, multi-rotor wind turbines, producing more power than a single rotor of the same diameter, are made even more powerful by increasing driveshaft length and supporting the driveshaft from more than one point. Sacrificing the ability to aim, for the extra length to support additional rotors, r

Co-axial, multi-rotor wind turbines, producing more power than a single rotor of the same diameter, are made even more powerful by increasing driveshaft length and supporting the driveshaft from more than one point. Sacrificing the ability to aim, for the extra length to support additional rotors, results in a more powerful co-axial multi-rotor turbine, especially useful for areas with a predominantly unidirectional wind resource. Ideally the turbine is placed at an offset angle α (alpha) from the wind direction, which, in combination with proper spacing between rotors, allows fresh wind to reach each rotor, so that all rotors contribute toward rotation of the driveshaft. Placing the driveshaft under tension can raise critical speeds and reduce the number of intermediate supports required. This places the Earth or underlying substrate in compression, making it effectively part of the structure of the turbine, saving cost. Cross-axis and reversible blades may also be incorporated.

대표청구항 ▼

1. A method of harnessing power, from a fluid flow having a direction, comprising: mounting a series of substantially horizontal-axis type rotors to a continuous, elongate driveshaft, substantially having an axis;supporting each said rotor by said driveshaft, proximate a center of each said rotor;pr

1. A method of harnessing power, from a fluid flow having a direction, comprising: mounting a series of substantially horizontal-axis type rotors to a continuous, elongate driveshaft, substantially having an axis;supporting each said rotor by said driveshaft, proximate a center of each said rotor;providing each said rotor with a substantially coplanar set of elongate blades;orienting said blades, wherein said blades substantially radiate outward, lengthwise, from said center of said rotor;providing said blades with lifting foils, whereby said rotors may operate on the principle of lift;configuring each said rotor, whereby each said set of blades is configured to rotate substantially within a plane of rotation;spacing said rotors at a distance D, along said axis, whereby said planes of rotation are separated;aiming said continuous elongate driveshaft at angle {acute over (α)} (alpha) from said direction of said fluid flow;spinning said rotors, whereby each said rotor sweeps a circular area from which energy is extracted from said current flow;whereby;the combination of angle {acute over (α)} (alpha) and distance D allows fresh fluid flow, substantially undisturbed by an upstream rotor, to reach each said circular swept area, thereby exposing each said rotor to a substantially undisturbed portion of said fluid flow,whereby all said rotors are powered by said fluid flow, rotating said drive shaft;whereby all said rotors contribute to a rotation of said driveshaft about its own said axis,whereby useful power may be drawn from said rotating driveshaft;suspending said driveshaft between two supports selected from the set of: landforms, natural structures, and manmade structures;wherein said aiming step comprises suspending said driveshaft across a canyon. 2. The method of claim 1, further comprising: drawing power from said rotating driveshaft. 3. The method of claim 2, wherein said fluid flow is wind. 4. The method of claim 1, further comprising coupling said rotating driveshaft to an electrical generator, whereby useful electricity may be generated. 5. The method of claim 4, further comprising: generating electricity by rotating said electrical generator, using said rotating driveshaft. 6. The method of claim 5, further comprising: connecting said generator to a grid, whereby power is drawn from said generator by said grid. 7. The method of claim 6, wherein said fluid flow is wind. 8. The method of claim 5, further comprising: combining a small diameter, a high TSR, and an aggregate swept area, of said rotors 13, to cause sufficiently high-speed rotation of said driveshaft 10, at sufficient torque, to directly drive a given electric generator 6 without gearing. 9. The method of claim 5, wherein said fluid flow is wind. 10. The method of claim 1, further comprising, fabricating said continuous elongate driveshaft using a composite material, comprising fibers selected from the set of helically-wrapped fibers 262 and longitudinally-oriented fibers 260. 11. The method of claim 10 further comprising: fabricating said continuous elongate driveshaft by the technique of filament winding. 12. The method of claim 10 further comprising: fabricating said continuous elongate driveshaft by the technique of pultrusion. 13. The method of claim 1, further comprising: channeling said flow, by selecting said supports, whereby at least one said support serves to channel said fluid flow through said rotors. 14. The method of claim 13, wherein said fluid flow is wind. 15. The method of claim 1, further comprising: channeling said flow, by selecting a relative placement of said driveshaft and at least one obstacle to said flow, whereby said obstacle tends to channel said flow through said rotors. 16. The method of claim 1, further comprising: providing said foils with sufficient symmetry to operate in reverse, whereby a prevailing flow from a second direction causes said rotors to operate in reverse. 17. The method of claim 1, further comprising: locating at least one additional, similar driveshaft with rotors, substantially parallel to the first said driveshaft with rotors, whereby said rotors form a virtual surface of rotors. 18. The method of claim 17, whereby said virtual surface is at angle {acute over (α)} (alpha) to said flow direction. 19. The method of claim 18, wherein said locating step comprises placing one said driveshaft aside another, whereby said virtual surface of rotors comprises a slope. 20. The method of claim 19, wherein said fluid flow is wind. 21. The method of claim 17, further comprising: supporting said driveshafts by a common support. 22. The method of claim 21, further comprising: providing that said common support serves to channel said flow through said virtual surface. 23. The method of claim 21, further comprising: providing that said rotors are staggered between adjacent of said driveshafts to avoid contact. 24. The method of claim 17, further comprising: supporting said driveshafts by a common support frame. 25. The method of claim 24, further comprising: providing that said rotors are staggered between adjacent of said driveshafts to avoid contact. 26. The method of claim 24, wherein said fluid flow is wind. 27. The method of claim 17, further comprising: providing that said rotors are staggered between adjacent of said driveshafts to avoid contact. 28. The method of claim 1, wherein said aiming step comprises supporting said driveshaft by at least one bearing. 29. The method of claim 26, wherein said aiming step comprises projecting said driveshaft from at least one bearing. 30. The method of claim 29, wherein said aiming step comprises supporting at least one said bearing by an elevating structure. 31. The method of claim 26, wherein said aiming step comprises suspending said driveshaft between a pair of bearings. 32. The method of claim 31, wherein said aiming step further comprises utilizing an intermediate support 220, to help support said driveshaft. 33. The method of claim 32, wherein said fluid flow is wind. 34. The method of claim 31, wherein said aiming step comprises supporting at least one said bearing by an elevating structure. 35. A method of harnessing power, from a fluid flow having a direction, comprising: mounting a series of substantially horizontal-axis type rotors to a continuous, elongate driveshaft, substantially having an axis;supporting each said rotor by said driveshaft, proximate a center of each said rotor;providing each said rotor with a substantially coplanar set of elongate blades;orienting said blades, wherein said blades substantially radiate outward, lengthwise, from said center of said rotor;providing said blades with lifting foils, whereby said rotors may operate on the principle of lift;configuring each said rotor, whereby each said set of blades is configured to rotate substantially within a plane of rotation;spacing said rotors at a distance D, along said axis, whereby said planes of rotation are separated;aiming said continuous elongate driveshaft at angle {acute over (α)} (alpha) from said direction of said fluid flow;spinning said rotors, whereby each said rotor sweeps a circular area from which energy is extracted from said current flow;whereby;the combination of angle {acute over (α)} (alpha) and distance D allows fresh fluid flow, substantially undisturbed by an upstream rotor, to reach each said circular swept area, thereby exposing each said rotor to a substantially undisturbed portion of said fluid flow,whereby all said rotors are powered by said fluid flow, rotating said drive shaft;whereby all said rotors contribute to a rotation of said driveshaft about its own said axis,whereby useful power may be drawn from said rotating driveshaft;suspending said driveshaft between two supports selected from the set of: landforms, natural structures, and manmade structures;wherein said driveshaft 10 is hollow, and said suspending step comprises locating said driveshaft around a nonrotating inner core 222, about which said driveshaft rotates. 36. A method of harnessing power, from a fluid flow having a direction, comprising: mounting a series of substantially horizontal-axis type rotors to a continuous, elongate driveshaft, substantially having an axis;supporting each said rotor by said driveshaft, proximate a center of each said rotor;providing each said rotor with a substantially coplanar set of elongate blades;orienting said blades, wherein said blades substantially radiate outward, lengthwise, from said center of said rotor;providing said blades with lifting foils, whereby said rotors may operate on the principle of lift;configuring each said rotor, whereby each said set of blades is configured to rotate substantially within a plane of rotation;spacing said rotors at a distance D, along said axis, whereby said planes of rotation are separated;aiming said continuous elongate driveshaft at angle {acute over (α)} (alpha) from said direction of said fluid flow;spinning said rotors, whereby each said rotor sweeps a circular area from which energy is extracted from said current flow;whereby;the combination of angle {acute over (α)} (alpha) and distance D allows fresh fluid flow, substantially undisturbed by an upstream rotor, to reach each said circular swept area, thereby exposing each said rotor to a substantially undisturbed portion of said fluid flow,whereby all said rotors are powered by said fluid flow, rotating said drive shaft;whereby all said rotors contribute to a rotation of said driveshaft about its own said axis,whereby useful power may be drawn from said rotating driveshaft;further comprising: locating at least one additional, similar driveshaft with rotors, substantially parallel to the first said driveshaft with rotors, whereby said rotors form a virtual surface of rotors;whereby said virtual surface is at angle {acute over (α)} (alpha) to said flow direction;wherein said locating step comprises placing one said driveshaft above another, whereby said virtual surface is a substantially vertical surface. 37. The method of claim 36, wherein said fluid flow is wind. 38. A method of harnessing power, from a fluid flow having a direction, comprising: mounting a series of substantially horizontal-axis type rotors to a continuous, elongate driveshaft, substantially having an axis;supporting each said rotor by said driveshaft, proximate a center of each said rotor;providing each said rotor with a substantially coplanar set of elongate blades;orienting said blades, wherein said blades substantially radiate outward, lengthwise, from said center of said rotor;providing said blades with lifting foils, whereby said rotors may operate on the principle of lift;configuring each said rotor, whereby each said set of blades is configured to rotate substantially within a plane of rotation;spacing said rotors at a distance D, along said axis, whereby said planes of rotation are separated;aiming said continuous elongate driveshaft at angle {acute over (α)} (alpha) from said direction of said fluid flow;spinning said rotors, whereby each said rotor sweeps a circular area from which energy is extracted from said current flow;whereby;the combination of angle {acute over (α)} (alpha) and distance D allows fresh fluid flow, substantially undisturbed by an upstream rotor, to reach each said circular swept area, thereby exposing each said rotor to a substantially undisturbed portion of said fluid flow,whereby all said rotors are powered by said fluid flow, rotating said drive shaft;whereby all said rotors contribute to a rotation of said driveshaft about its own said axis,whereby useful power may be drawn from said rotating driveshaft;wherein said aiming step comprises supporting said driveshaft by at least one bearing;wherein said aiming step comprises suspending said driveshaft between a pair of bearings;further comprising: applying tension to said driveshaft through application of a tension means 210. 39. The method of claim 38, wherein said tension means 210 comprises the weight of an elevating structure. 40. A method of harnessing power, from a fluid flow having a direction, comprising: mounting a series of substantially horizontal-axis type rotors to a continuous, elongate driveshaft, substantially having an axis;supporting each said rotor by said driveshaft, proximate a center of each said rotor;providing each said rotor with a substantially coplanar set of elongate blades;orienting said blades, wherein said blades substantially radiate outward, lengthwise, from said center of said rotor;providing said blades with lifting foils, whereby said rotors may operate on the principle of lift;configuring each said rotor, whereby each said set of blades is configured to rotate substantially within a plane of rotation;spacing said rotors at a distance D, along said axis, whereby said planes of rotation are separated;aiming said continuous elongate driveshaft at angle {acute over (α)} (alpha) from said direction of said fluid flow;spinning said rotors, whereby each said rotor sweeps a circular area from which energy is extracted from said current flow;whereby;the combination of angle {acute over (α)} (alpha) and distance D allows fresh fluid flow, substantially undisturbed by an upstream rotor, to reach each said circular swept area, thereby exposing each said rotor to a substantially undisturbed portion of said fluid flow,whereby all said rotors are powered by said fluid flow, rotating said drive shaft;whereby all said rotors contribute to a rotation of said driveshaft about its own said axis,whereby useful power may be drawn from said rotating driveshaft;whereby said aiming step comprises placing said driveshaft in catenary suspension. 41. A method of harnessing power, from a fluid flow having a direction, comprising: mounting a series of substantially horizontal-axis type rotors to a continuous, elongate driveshaft, substantially having an axis;supporting each said rotor by said driveshaft, proximate a center of each said rotor;providing each said rotor with a substantially coplanar set of elongate blades;orienting said blades, wherein said blades substantially radiate outward, lengthwise, from said center of said rotor;providing said blades with lifting foils, whereby said rotors may operate on the principle of lift;configuring each said rotor, whereby each said set of blades is configured to rotate substantially within a plane of rotation;spacing said rotors at a distance D, along said axis, whereby said planes of rotation are separated;aiming said continuous elongate driveshaft at angle {acute over (α)} (alpha) from said direction of said fluid flow;spinning said rotors, whereby each said rotor sweeps a circular area from which energy is extracted from said current flow;whereby;the combination of angle {acute over (α)} (alpha) and distance D allows fresh fluid flow, substantially undisturbed by an upstream rotor, to reach each said circular swept area, thereby exposing each said rotor to a substantially undisturbed portion of said fluid flow,whereby all said rotors are powered by said fluid flow, rotating said drive shaft;whereby all said rotors contribute to a rotation of said driveshaft about its own said axis,whereby useful power may be drawn from said rotating driveshaft;wherein said aiming step comprises supporting said driveshaft by at least one bearing;wherein said aiming step comprises suspending said driveshaft between a pair of bearings;whereby said aiming step comprises placing said driveshaft in catenary suspension. 42. A method of harnessing power, from a fluid flow having a direction, comprising: mounting a series of substantially horizontal-axis type rotors to a continuous, elongate driveshaft, substantially having an axis;supporting each said rotor by said driveshaft, proximate a center of each said rotor;providing each said rotor with a substantially coplanar set of elongate blades;orienting said blades, wherein said blades substantially radiate outward, lengthwise, from said center of said rotor;providing said blades with lifting foils, whereby said rotors may operate on the principle of lift;configuring each said rotor, whereby each said set of blades is configured to rotate substantially within a plane of rotation;spacing said rotors at a distance D, along said axis, whereby said planes of rotation are separated;aiming said continuous elongate driveshaft at angle {acute over (α)} (alpha) from said direction of said fluid flow;spinning said rotors, whereby each said rotor sweeps a circular area from which energy is extracted from said current flow;whereby;the combination of angle {acute over (α)} (alpha) and distance D allows fresh fluid flow, substantially undisturbed by an upstream rotor, to reach each said circular swept area, thereby exposing each said rotor to a substantially undisturbed portion of said fluid flow,whereby all said rotors are powered by said fluid flow, rotating said drive shaft;whereby all said rotors contribute to a rotation of said driveshaft about its own said axis,whereby useful power may be drawn from said rotating driveshaft;wherein said aiming step comprises supporting said driveshaft by at least one bearing;wherein said aiming step comprises suspending said driveshaft between a pair of bearings;wherein said elevating structure comprises a tree. 43. The method of claim 1, wherein said fluid flow is wind.