초록 ▼

Normally hydroelectric dam powerhouses use river flow once before discharging it as turbulent tailwater, ineffective to spin turbines. The present invention uses tapered channels to confine and constrict turbulent tailwater into laminar flow that drives turbines both submersible and floatable utiliz

Normally hydroelectric dam powerhouses use river flow once before discharging it as turbulent tailwater, ineffective to spin turbines. The present invention uses tapered channels to confine and constrict turbulent tailwater into laminar flow that drives turbines both submersible and floatable utilizing the same water three times concurrently to generate new electricity. Channels originate adjacent to draft tube outlets, constrict in the downstream direction to create narrow necks where turbine/generators benefit from debris free, increased velocity and laminar flows to generate electricity. Hydroelectricity uses zero fuel, creates zero waste and has zero carbon dioxide emissions. Structures are uncomplicated, construction is within project boundaries minimizing environmental impacts and speeding projects coming online. New facilities are protected by existing dam security. Hydroelectricity replaces less dependable renewable energy systems.

대표청구항 ▼

What is claimed is: 1. In a dam for generating hydroelectric power that utilizes water head through at least one gate-controlled intake to a penstock to drive a primary turbine that in turn drives a generator then past the primary turbine exits through at least one draft tube that discharges the wa

What is claimed is: 1. In a dam for generating hydroelectric power that utilizes water head through at least one gate-controlled intake to a penstock to drive a primary turbine that in turn drives a generator then past the primary turbine exits through at least one draft tube that discharges the water into an afterbay, the improvement comprising means for converting turbulent tailwater flow exiting the at least one downstream draft tube into laminar flow, first means for generating electricity from a lowermost portion of the laminar flow, and second means downstream from the first generating means for generating further electricity from an uppermost surface portion of the laminar flow. 2. The dam as defined in claim 1 wherein said turbulent tailwater flow converting means is a channel converging in a flow direction toward said first electricity generating means. 3. The dam as defined in claim 1 wherein said turbulent tailwater flow converting means is a channel converging in a flow direction toward said second electricity generating means. 4. The dam as defined in claim 1 including means for buoyantly supporting said second electricity generating means. 5. The dam as defined in claim 1 including means for buoyantly supporting said second electricity generating means above said first electricity generating means. 6. The dam as defined in claim 1 including means for buoyantly supporting said second electricity generating means above said first electricity generating means and downstream therefrom. 7. The dam as defined in claim 1 wherein said turbulent tailwater flow converting means is a channel, and said channel is defined at least in part by a pair of adjacent walls converging toward said first electricity generating means. 8. The dam as defined in claim 1 wherein said turbulent tailwater flow converting means is a channel converging from an uppermost channel portion in a flow direction toward a downstream channel portion, said first electricity generating means being a turbine positioned within and adjacent said downstream channel portion and being driven by the laminar water flow, and means for accelerating the laminar water flow incident to driving said turbine. 9. The dam as defined in claim 1 wherein said turbulent tailwater flow converting means is a channel converging from an upstream channel portion in a flow direction toward a downstream channel portion, said first electricity generating means being a turbine positioned adjacent said downstream channel portion and being driven by the laminar water flow, means for accelerating the laminar water flow incident to driving said turbine, and said accelerating means is a substantially frusto-conical water flow acceleration tube constructed and arranged to increase laminar flow velocity by venturi effect incident to driving said turbine to thereby increase the efficiency thereof. 10. The dam as defined in claim 1 wherein said turbulent tailwater flow converting means is a channel converging from an uppermost channel portion in a flow direction toward a downstream channel portion, said first electricity generating means being a turbine positioned within and adjacent said downstream channel portion and being driven by the laminar water flow, means for accelerating the laminar water flow incident to driving said turbine, said accelerating means is a substantially frusto-conical water flow acceleration tube constructed and arranged to increase laminar water flow velocity by venturi effect incident to driving said turbine to thereby increase the efficiency thereof, and said frusto-conical water flow acceleration tube is disposed in substantially external surrounding relationship to said turbine. 11. The dam as defined in claim 1 wherein said turbulent tailwater flow converting means, first electricity generating means and second electricity generating means are disposed in substantially linearly aligned consecutive relationship in the direction of tailwater/laminar water flow. 12. The dam as defined in claim 1 wherein said turbulent tailwater flow converting means is a channel, said channel is defined at least in part by a pair of adjacent walls converging toward said first electricity generating means, at least two pair of vertical supports, a first upstream pair of said supports being spaced a greater distance from each other than a second downstream pair of said supports, means for connecting a first of said pair of walls between a first and second support of said respective first upstream and second downstream pair of supports, and means for connecting a second of said pair of walls between another first and another second support of said respective first upstream and second downstream pair of supports. 13. The dam as defined in claim 1 wherein said turbulent tailwater flow converting means is a channel, said channel is defined at least in part by a pair of adjacent walls converging toward said first electricity generating means, at least two pair of vertical supports, a first upstream pair of said supports being spaced a greater distance from each other than a second downstream pair of said supports, means for slidably connecting a first of said pair of walls between a first and second support of said respective first upstream and second downstream pair of supports, and means for slidably connecting a second of said pair of walls between another first and another second support of said respective first upstream and second downstream pair of supports. 14. The dam as defined in claim 3 including means for buoyantly supporting said second electricity generating means. 15. The dam as defined in claim 3 wherein said turbulent tailwater flow converting means is a channel, and said channel is defined at least in part by a pair of adjacent walls converging toward said first electricity generating means. 16. The dam as defined in claim 3 wherein said turbulent tailwater flow converting means is a channel converging from an uppermost channel portion in a flow direction toward a downstream channel portion, said first electricity generating means being a turbine positioned with and adjacent said downstream channel portion and being driven by the laminar water flow, and means for accelerating the laminar water flow incident to driving said turbine. 17. The dam as defined in claim 3 wherein said turbulent tailwater flow converting means is a channel converging from an upstream channel portion in a flow direction toward a downstream channel portion, said first electricity generating means being a turbine positioned adjacent said downstream channel portion and being driven by the laminar water flow, means for accelerating the laminar water flow incident to driving said turbine, and said accelerating means is a substantially frusto-conical water flow acceleration tube constructed and arranged to increase laminar water flow velocity by venturi effect incident to driving said turbine to thereby increase the efficiency thereof. 18. The dam as defined in claim 12 including means for buoyantly supporting said second electricity generating means. 19. The dam as defined in claim 12 wherein said turbulent tailwater flow converting means, first electricity generating means and second electricity generating means are disposed in substantially linearly aligned consecutive relationship in the direction of tailwater/laminar water flow. 20. The dam as defined in claim 12 including means for buoyantly supporting said second electrically generating means above said first electricity generating means and downstream therefrom. 21. In a dam for generating hydroelectric power that utilizes water head through at least one gate-controlled intake to a penstock to drive a primary turbine that in turn drives a generator then past the primary turbine exits through at least one draft tube that discharges the water into an afterbay, the improvement comprising means for converting turbulent tailwater flow exiting the at least one downstream draft tube into laminar flow, said turbulent tailwater flow converging means being a venturi channel defined by an upstream channel portion converging in the direction of the tailwater flow from the at least one draft tube with a medial parallel channel portion which opens into a downstream diverging channel portion; first means in said medial parallel channel portion for generating electricity from a lowermost portion of the laminar flow, and second means adjacent the diverging channel portion for generating further electricity from an uppermost surface portion of the laminar flow. 22. The dam as defined in claim 21 wherein said first electricity generating means and said second electricity generating means are disposed in substantially linearly aligned relationship in the direction of tailwater/laminar water flow. 23. The dam as defined in claim 21 including means for buoyantly supporting said second electricity generating means. 24. The dam as defined in claim 21 including means for buoyantly supporting said second electricity generating means above said first electricity generating means and downstream therefrom. 25. The dam as defined in claim 21 wherein said first electricity generating means is a turbine and means for further accelerating the laminar flow within said medial parallel channel portion incident to driving said turbine. 26. The dam as defined in claim 25 wherein said accelerating means is a substantially frusto-conical water flow acceleration tube constructed and arranged to increase laminar water flow velocity by venturi effect incident to driving said turbine to thereby increase the efficiency thereof, and said frusto-conical water flow acceleration tube is disposed in substantially external surrounding relationship to said turbine.