A high efficiency induced-flow wind power system engages and converts both potential (to-pull) and kinetic (to-push) wind energies to effective airflow power, delivering induced (accelerated) airflow power in a controlled flow field to a turbine/rotor, impelling a 360-degree torque on the turbine/ro
A high efficiency induced-flow wind power system engages and converts both potential (to-pull) and kinetic (to-push) wind energies to effective airflow power, delivering induced (accelerated) airflow power in a controlled flow field to a turbine/rotor, impelling a 360-degree torque on the turbine/rotor and, as a result, extracting (converting) more than 80% of the combined effective wind power to mechanical power. The induced push-pull effect results in higher efficiency wind-to-mechanical power extraction (conversion). The induced-flow wind power system can be coupled with (i) an electrical generator, inverter/converter for generating AC and DC power, (ii) pressurized vessel for effective energy storage (iii) a pressurized structure, such as an air supported structure, to ensure its structural integrity. The Induced-Flow Wind System embodiment comprises: a passive-flow nozzle, an active-flow nozzles and a turbine encased in housing interposed within the flow field of the active-flow nozzle and coupled with an electrical generator or a compressor.
대표청구항▼
1. An induced flow wind power system, comprising: a tubular converging intake extending horizontally from an upstream intake end having an upstream intake area sized for receiving air to a downstream intake end having a downstream intake area, said downstream intake area being smaller than said upst
1. An induced flow wind power system, comprising: a tubular converging intake extending horizontally from an upstream intake end having an upstream intake area sized for receiving air to a downstream intake end having a downstream intake area, said downstream intake area being smaller than said upstream intake area to accelerate air passing through the tubular converging intake, said downstream intake end being horizontally spaced from the upstream intake end;a turbine housing mounted downstream from the tubular converging intake;a turbine rotor mounted inside the turbine housing and configured for rotating with respect to the turbine housing about a rotor axis within the turbine housing, said turbine rotor receiving air radially with respect to the turbine axis and turning air passing through the turbine rotor axially with respect to the turbine axis;a tubular diverging diffuser mounted downstream from the turbine rotor, said tubular diverging diffuser extending axially with respect to the turbine rotor axis from an upstream diffuser end having an upstream diffuser area to a downstream diffuser end having a downstream diffuser area, said downstream diffuser area being larger than said upstream diffuser area; anda tubular venturi having a tapering upstream portion extending from a venturi entrance having a entrance area to a venturi throat located downstream from the venturi entrance, said venturi throat having a throat area, said throat area being smaller than said entrance area to accelerate fluid passing through the tapering upstream portion of the tubular venturi, said tubular venturi having a tapering downstream portion extending from the venturi throat to a venturi exit located downstream from the venturi throat having an exit area, said exit area being larger than said throat area, and said tubular venturi having a vacuum port positioned in at least one of the venturi throat and the tapering downstream portion of the tubular venturi in fluid communication with the tubular diverging diffuser to draw air from the tubular diverging diffuser when fluid passes through the tubular venturi from the venturi entrance to the venturi exit. 2. The induced flow wind power system as set forth in claim 1, further comprising an airfoil mounted adjacent the tapering downstream portion of the tubular venturi for accelerating airflow around the tubular venturi. 3. The induced flow wind power system as set forth in claim 1, wherein the tapering upstream portion of the tubular venturi has a converging angle between about 7 and about 15 degrees. 4. The induced flow wind power system as set forth in claim 1, wherein the tapering downstream portion of the tubular venturi has a diverging angle between about 7 and about 15 degrees. 5. The induced flow wind power system as set forth in claim 1, wherein the tubular converging intake has a converging angle between about 7 and about 15 degrees. 6. The induced flow wind power system as set forth in claim 1, wherein the tubular diverging diffuser has a diverging angle between about 7 and about 15 degrees. 7. The induced flow wind power system as set forth in claim 1, wherein said tubular venturi is selectively rotatable about a vertical axis. 8. The induced flow wind power system as set forth in claim 1, wherein said tubular converging intake is selectively rotatable about a vertical axis. 9. The induced flow wind power system as set forth in claim 1, wherein said upstream intake end is positioned above said downstream intake end. 10. The induced flow wind power system as set forth in claim 1, wherein said downstream diffuser end is positioned above said upstream diffuser end. 11. The induced flow wind power system as set forth in claim 1, wherein said system comprises one tubular converging intake. 12. The induced flow wind power system as set forth in claim 1, wherein said tubular converging intake and said tubular diverging diffuser are formed from a rigid material. 13. The induced flow wind power systems set forth in claim 1, wherein said tubular venturi is formed from a rigid material. 14. The induced flow A wind power system as set forth in claim 1, wherein said turbine housing is positioned below the tubular venturi. 15. The induced flow wind power system as set forth in claim 1, further comprising a generator operatively connected to the turbine for generating electricity in response to air turning the turbine. 16. The induced flow wind power system as set forth in claim 15, wherein said generator comprises a direct current generator configured for generating a voltage of at least about 12 volts. 17. The induced flow wind power system as set forth in claim 15, wherein said generator comprises an alternating current generator configured for providing at least one of single-phase, two-phase, and three-phase power. 18. The induced flow wind power system as set forth in claim 15, wherein said generator comprises an alternating current generator configured for generating a voltage of at least about 120 volts. 19. An induced flow wind power system, comprising: a tubular converging intake extending horizontally from an upstream intake end having an upstream intake area sized for receiving air to a downstream intake end having a downstream intake area, said downstream intake area being smaller than said upstream intake area to accelerate air passing through the tubular converging intake, said downstream intake end being horizontally spaced from the upstream intake end;a turbine housing mounted downstream from the tubular converging intake;a turbine rotor mounted inside the turbine housing and configured for rotating with respect to the turbine housing about a rotor axis within the turbine housing;a tubular diverging diffuser mounted downstream from the turbine rotor, said tubular diverging diffuser extending axially with respect to the turbine rotor axis from an upstream diffuser end having an upstream diffuser area to a downstream diffuser end having a downstream diffuser area, said downstream diffuser area being larger than said upstream diffuser area to reduce pressure of air passing through the tubular diverging diffuser;a tubular venturi having a tapering upstream portion extending from a venturi entrance having a entrance area to a venturi throat located downstream from the venturi entrance having a throat area, said throat area being smaller than said entrance area to accelerate fluid passing through the tapering upstream portion of the tubular venturi, said tubular venturi having a tapering downstream portion extending from the venturi throat to a venturi exit located downstream from the venturi throat having exit area, said exit area being larger than said throat area, and said tubular venturi having a vacuum port positioned in at least one of the venturi throat and the tapering downstream portion of the tubular venturi and in fluid communication with the tubular diverging diffuser to draw air from the tubular diverging diffuser when fluid passes through the tubular venturi from the venturi entrance to the venturi exit; andan airfoil mounted adjacent the tapering downstream portion of the tubular venturi for accelerating airflow around the venturi. 20. An induced flow wind power system, comprising: a tubular intake extending horizontally from an upstream intake end having an upstream intake area sized for receiving air to a downstream intake end having a downstream intake area, said downstream intake end being horizontally spaced from the upstream intake end;a turbine housing mounted downstream from the tubular intake;a turbine rotor mounted inside the turbine housing and configured for rotating with respect to the turbine housing about a rotor axis within the turbine housing, said turbine rotor receiving air radially with respect to the turbine axis and turning air passing through the turbine rotor axially with respect to the turbine axis;a tubular outlet passage mounted downstream from the turbine rotor, said tubular outlet passage extending axially with respect to the turbine rotor axis from an upstream passage end having an upstream outlet passage area to a downstream passage end having a downstream outlet passage area;a tubular venturi having a tapering upstream portion extending from a venturi entrance having an entrance area to a venturi throat located downstream from the venturi entrance having a throat area, said throat area being smaller than said entrance area to accelerate fluid passing through the tapering upstream portion of the tubular venturi, said tubular venturi having a tapering downstream portion extending from the venturi throat to a venturi exit located downstream from the venturi throat having an exit area, said exit area being larger than said throat area, and said tubular venturi having a vacuum port positioned in at least one of the venturi throat and the tapering downstream portion of the tubular venturi and in fluid communication with the tubular outlet passage to draw air from the tubular outlet passage when fluid passes through the tubular venturi from the venturi entrance to the venturi exit; and an airfoil mounted adjacent the tapering downstream portion of the tubular venturi for accelerating airflow around the tubular venturi.
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이 특허에 인용된 특허 (3)
Faller, Frank, Apparatus for extracting energy from a fluid flow.
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