초록 ▼

A conveyor-type apparatus harnesses energy from a fluid flow, for example a river or a tidal flow region, and comprises a support structure, a continuous-loop, flexible driven element, for example a pair of chains, mounted to the support structure and extending along a closed-loop path, the path def

A conveyor-type apparatus harnesses energy from a fluid flow, for example a river or a tidal flow region, and comprises a support structure, a continuous-loop, flexible driven element, for example a pair of chains, mounted to the support structure and extending along a closed-loop path, the path defining an interior region and an exterior region, and a series of reversible fluid foils. The driven element has first and second reaches, the first and second reaches being upflow and downflow reaches when fluid flows from the first reach to the second reach. Each fluid foil is connected to the flexible driven element for movement between a first orientation, situated in the interior region when moving along the upflow reach, and a second orientation, situated in the exterior region when moving along the downflow reach. The first sides are generally concave when moving along the upflow reach and generally convex when moving along the downflow reach. The second sides are generally concave when moving along the downflow reach and generally convex when moving along the upflow reach. The driven element may be coupled to an energy generator so to harness energy from the fluid flow.

대표청구항 ▼

1. A conveyor-type apparatus for harnessing energy from a fluid flow comprising:a support structure;a continuous-loop, flexible driven element mounted to the support structure and extending along a closed-loop path, the path defining an interior region and an exterior region;the driven element havin

1. A conveyor-type apparatus for harnessing energy from a fluid flow comprising:a support structure;a continuous-loop, flexible driven element mounted to the support structure and extending along a closed-loop path, the path defining an interior region and an exterior region;the driven element having first and second reaches, said first and second reaches being upflow and downflow reaches when fluid flows from the first reach to the second reach;a series of reversible fluid foils; andeach fluid foil comprising first and second sides and being connected to the flexible driven element for movement between a first orientation, situated in the interior region when moving along the upflow reach, and a second orientation, situated in the exterior region when moving along the downflow reach, so that:the first sides are generally concave when moving along the upflow reach and generally convex when moving along the downflow reach; andthe second sides are generally concave when moving along the downflow reach and generally convex when moving along the upflow reach;whereby the driven element may be coupled to an energy generator so to harness energy from the fluid flow. 2. The apparatus according to claim 1 wherein the support structure comprises a frame with end members and first and second transverse member connecting the end members to one another. 3. The apparatus according to claim 1 wherein the end members have fluid-channeling surfaces to direct fluid towards the upflow reach. 4. The apparatus according to claim 1 wherein the transverse members have fluid-channeling surfaces to direct fluid towards the upflow reach. 5. The assembly according to claim 1 wherein the support structure comprises first and second rotatable guides engaging the driven element. 6. The assembly according to claim 5 wherein the driven element comprises a chain and the first and second rotatable guides comprise sprockets. 7. The assembly according to claim 5 wherein the first guide drivenly engages the driven element. 8. The apparatus according to claim 7 wherein:the flexible driven element comprises first and second continuous-loop chains; andthe support structure comprises:first and second parallel, spaced-apart transverse members extending between the end members, the end and transverse members having fluid-channeling surfaces to direct fluid towards the upflow reach;first and second shafts extending between the first and second transverse members; andsprockets mounted to each of the first and second shafts and engaging the first and second chains. 9. The apparatus according to claim 1 wherein the path is a generally horizontal path. 10. The apparatus according to claim 1 wherein at least some of the reversible fluid foils comprise a leading end mounted to the driven element and a trailing end. 11. The apparatus according to claim 10 wherein the leading end comprises a leading edge and the trailing end comprises a trailing edge. 12. The apparatus according to claim 10 wherein the leading end is pivotally mounted to the driven element. 13. The apparatus according to claim 12 wherein the fluid foils pivot freely between the first and second orientations. 14. The apparatus according to claim 10 wherein the trailing end is connected to the driven element by a flexible member to limit the movement of the fluid foils to movement between the first and second orientations. 15. The apparatus according to claim 1 wherein the fluid foils are resilient and tend to return to a generally straight, relaxed state. 16. The apparatus according to claim 1 further comprising means for adjusting at least one of the first and second orientations. 17. The apparatus according to claim 1 wherein:the path is a generally horizontal path;the reversible fluid foils comprise a leading end, pivotally mounted to the driven element so to pivot freely between the first and second orientations, and a trailing end;the trailing end is connected to the driven element by a flexible member to limit the movement of the fluid foils to movement between the first and second orientations; andthe fluid foils are resilient and tend to return to a generally straight, relaxed state; and further comprising:means for adjusting at least one of the first and second orientations. 18. The apparatus according to claim 1 wherein said first and second reaches are downflow and upflow reaches when fluid flows from the second reach to the first reach. 19. A conveyor-type apparatus for harnessing energy from moving water comprising:a support structure comprising:a frame with generally vertical end members and first and second spaced-apart transverse members extending between the end members and connecting the end members to one another;first and second shafts extending between the first and second transverse members; andsprockets mounted to each of the first and second shafts;first and second continuous-loop chains engaging the sprockets to extend along first and second spaced apart, generally horizontal closed-loop paths, the paths defining an interior region and an exterior region;the chains having first and second reaches, said first and second reaches being upflow and downflow reaches when fluid flows from the first reach to the second reach, said first and second reaches being downflow and upflow reaches when fluid flows from the second reach to the first reach;the end and transverse members having fluid-channeling surfaces to direct fluid towards the upflow reach;a series of reversible fluid foils comprising first and second sides; andeach fluid foil comprising a leading end pivotally connected to the chains and a trailing end connected to at least one of the chains by a movable member to limit the movement of the fluid foils to movement between a first pivotal orientation, situated in the interior region when moving along the upflow reach, and a second pivotal orientation, situated in the exterior region when moving along the downflow reach, so that:the first sides are generally concave when moving along the upflow reach and generally convex when moving along the downflow reach; andthe second sides are generally concave when moving along the downflow reach and generally convex when moving along the upflow reach;whereby the driven element may be coupled to an energy generator so to harness energy from the fluid flow. 20. The apparatus according to claim 19 wherein the fluid foils pivot freely between the first and second orientations. 21. The apparatus according to claim 19 wherein the fluid foils are resilient and tend to return to a generally straight, relaxed state. 22. The apparatus according to claim 19 further comprising means for adjusting at least one of the first and second orientations. 23. A method for harnessing energy from a fluid flow comprising:positioning a conveyor-type fluid energy apparatus at a fluid flow site, the apparatus comprising:a support structure;a continuous-loop, flexible driven element mounted to the support structure and extending along a closed-loop path, the path defining an interior region and an exterior region;the driven element having first and second reaches as it moves along the path, said first and second reaches being upflow and downflow reaches when fluid flows from the first reach to the second reach; anda series of reversible fluid foils movably connected to the flexible driven element;orienting the driven element so that the upflow reach is transverse to a fluid flow direction;driving fluid foils and the driven element therewith along the upflow reach in a first closed-loop path direction, the fluid foils being driven by the fluid flow with the fluid foils situated in the interior region in a first orientation;the fluid foils moving from the first orientation to a second orientation as the fluid foils move along a first transition region along the path from the upstream reach to the downstream reach;driving fluid foils and the driven element therewith along the downflow reach in the f irst closed-loop path direction, the fluid foils being driven by the fluid flow with the fluid foils situated in the exterior region in the second orientation; andthe fluid foils moving from the second orientation to the first orientation as the fluid foils move along a second transition region along the path from the downstream reach to the upstream reach;whereby the driven element may be coupled to an energy generator so to harness energy from the fluid flow. 24. The method according to claim 23 wherein the positioning step comprises positioning the fluid energy apparatus at a fluid flow site within a river so that the fluid flow is in a single, downstream direction. 25. The method according to claim 23 wherein the positioning step comprises positioning the fluid energy apparatus at a fluid flow site within a dual-flow-direction region so that the fluid flow alternates between an upstream direction and a downstream direction. 26. The method according to claim 25 wherein the positioning step comprises positioning the fluid energy apparatus at a fluid flow site within a tidal region. 27. The method according to claim 23 wherein the positioning step is carried out using flexible sails as the fluid foils. 28. The method according to claim 27 wherein the positioning step is carried out with said second and first reaches being upflow and downflow reaches when fluid flows from the second reach to the first reach. 29. The method according to claim 23 wherein the positioning step is carried out with the first and second reaches being generally straight. 30. The method according to claim 23 wherein the positioning step is carried out with the first and second reaches being generally parallel to one another. 31. The method according to claim 23 wherein the orienting step is carried out so that the upflow reach is generally perpendicular to the fluid flow direction. 32. The method according to claim 23 wherein during the first fluid foils moving step the fluid foils act as sails and jibe from the first orientation to the second orientation. 33. The method according to claim 23 wherein during the first fluid foils moving step the fluid foils act as sails and freely jibe from the first orientation to the second orientation. 34. The method according to claim 23 wherein during the second fluid foils moving step the fluid foils act as sails and tack from the second orientation to the first orientation. 35. The method according to claim 23 wherein during the second fluid foils moving step the fluid foils act as sails and freely tack from the second orientation to the first orientation. 36. A method for harnessing energy from a fluid flow comprising:positioning a conveyor-type fluid energy apparatus at a fluid flow site, the apparatus comprising:a support structure;a continuous-loop, flexible driven element mounted to the support structure and extending along a closed-loop path, the path defining an interior region and an exterior region;the driven element having first and second generally straight reaches as it moves along the path, the upflow reach being generally perpendicular to the fluid flow direction;said first and second reaches being upflow and downflow reaches when fluid flows from the first reach to the second reach;said second and first reaches being upflow and downflow reaches when fluid flows from the second reach to the first reach; anda series of reversible, flexible sails acting as fluid foils movably connected to the flexible driven element;orienting the driven element so that the upflow reach is transverse to a fluid flow direction;driving fluid foils and the driven element therewith along the upflow reach in a first closed-loop path direction, the fluid foils being driven by the fluid flow with the fluid foils situated in the interior region in a first orientation;the fluid foils freely jibing from the first orientation to a second orientation as the fluid foils move along a first transition region along the path from the u pstream reach to the downstream reach;driving fluid foils and the driven element therewith along the downflow reach in the first closed-loop path direction, the fluid foils being driven by the fluid flow with the fluid foils situated in the exterior region in the second orientation; andthe fluid foils freely tacking from the second orientation to the first orientation as the fluid foils move along a second transition region along the path from the downstream reach to the upstream reach;whereby the driven element may be coupled to an energy generator so to harness energy from the fluid flow.