A dual inlet flow wind power generating system is disclosed having two inflow chambers directing air flow into a common turbine. In one embodiment, a second phase of air flow directly impinges on the air blades of the turbine to provide multi-phased air flow with enhanced power generation. Two inflo
A dual inlet flow wind power generating system is disclosed having two inflow chambers directing air flow into a common turbine. In one embodiment, a second phase of air flow directly impinges on the air blades of the turbine to provide multi-phased air flow with enhanced power generation. Two inflow chambers may be configured on either side of the common impingement chamber and the system may be configured around a vertical axis. Additionally, air deflectors in one or more chambers may direct flow into a flow tube and may be configured as a positive flow vortex inducer. A negative flow vortex inducer is also described, whereby air is directed by air deflectors to reduce the pressure at the outlet end of a flow tube. In another embodiment, a dual outlet flow system is described having a single inflow chamber and two impingement chambers for second phase air flow.
대표청구항▼
1. A dual wind energy power enhancer system comprising: a. a power generating turbine wherein said power generating turbine incorporates air blades in the form of a reverse flow fan that rotate about an axis,b. a first inflow chamber comprising a first fixed structure having one or more openings for
1. A dual wind energy power enhancer system comprising: a. a power generating turbine wherein said power generating turbine incorporates air blades in the form of a reverse flow fan that rotate about an axis,b. a first inflow chamber comprising a first fixed structure having one or more openings for receiving a first chamber first phase air flow from a prevailing wind; anda first flow tube,c. a first separation panel extending between the first inflow chamber and the power generating turbine; wherein the first flow tube extends through said first separation panel and is configured to direct the first chamber first phase air flow into said air blades;d. a second inflow chamber comprising a second fixed structure having one or more openings for receiving a second chamber first phase air flow from the prevailing wind; anda second flow tube,e. a second separation panel extending between the second inflow chamber and the power generating turbine; wherein the second flow tube extends through said second separation panel and is configured to direct the second chamber first phase air flow into said air blades;wherein said air blades are exposed to both the first and second chamber first phase air flows and to a second phase air flow from a second phase wind, wherein the second phase air flow from the prevailing wind is directed to impinge on the air blades and wherein the first phase air flow from both the first and second inflow chambers exits the power generation turbine in a direction substantially perpendicular to the direction of said first and second first phase air flows entering said power generating turbine from said first and second flow tubes, and wherein the dual wind energy power enhancer system is configured to utilize air flow from both the first and second inflow chambers and the second phase air flow to create power. 2. The dual wind energy power enhancer system of claim 1, wherein at least one of the first and the second fixed structures is configured to rotate. 3. The dual wind energy power enhancer system of claim 1, wherein said air blades are configured to extend at least partially from the first inflow chamber and into the second phase air flow. 4. The dual wind energy power enhancer system of claim 1, wherein at least one of the first or the second inflow chambers comprises a plurality of passive inflow dampers. 5. The dual wind energy power enhancer system of claim 1, wherein the axis is in a substantially vertical configuration. 6. The dual wind energy power enhancer system of claim 1, wherein the wind energy power enhancer system is configured on or at least partially within a building. 7. The dual wind energy power enhancer system of claim 1, further comprising an impingement chamber configured at least partially around the air blades. 8. The dual wind energy power enhancer system of claim 7, wherein the impingement chamber is configured between the first and second inflow chambers. 9. The dual wind energy power enhancer system of claim 8, wherein the axis is in a vertical configuration and the first inflow chamber is configured above the impingement chamber and the second inflow chamber is configured below said impingement chamber. 10. The dual wind energy power enhancer system of claim 1, further comprising at least one air deflector configured in or around the first inflow chamber, in or around the second inflow chamber or around the air blades in an outflow chamber. 11. The dual wind energy power enhancer system of claim 10, wherein at least one air deflector is a drag curtain. 12. The dual wind energy power enhancer system of claim 10, wherein at least one air deflector is an exit barrier. 13. The dual wind energy power enhancer system of claim 10, wherein at least one air deflector is an air scoop. 14. The dual wind energy power enhancer system of claim 10, wherein the at least one air deflector is configured as a wind concentrator to direct air from the prevailing wind into the air blades. 15. The dual wind energy power enhancer system of claim 10, wherein the at least one air deflector is configured to move. 16. The dual wind energy power enhancer system of claim 10, wherein the at least one air deflector is configured outside of an air inflow chamber. 17. The dual wind energy power enhancer system of claim 10, wherein a plurality of air deflectors are configured in or around the first inflow chamber as a vortex inducer. 18. The dual wind energy power enhancer system of claim 17, wherein the vortex inducer is a positive flow vortex inducer, configured to produce a positive pressure and a vortex flow into at least one of the first and the second flow tubes. 19. The dual wind energy power enhancer system of claim 17, wherein the vortex inducer is a negative flow vortex inducer configured to reduce pressure at the turbine outlet thereby increasing the differential pressure across the turbine. 20. The dual wind energy power enhancer system of claim 1, wherein the first inflow chamber has a first inflow area, and the first flow tube has a first flow tube cross-sectional area, whereby a ratio of the first inflow area to the first flow tube cross-sectional area is greater than 0.01:1. 21. A dual wind energy power enhancer system comprising: a. a power generating turbine, wherein said power generating turbine incorporates air blades in the form of a reverse flow fan that rotate about an axis;b. a first inflow chamber comprising: a first fixed structure having one or more openings for receiving first chamber air flow, anda plurality of passive in-flow dampers;c. a second inflow chamber comprising: a second fixed structure having one or more openings for receiving second chamber air flow, anda plurality of passive in-flow dampers;d. an outflow chamber configured between said first and second inflow chambers to direct flow away from the dual wind energy power enhancer system after impinging on the air blades; ande. a first flow tube configured to direct air from the first inflow chamber into said air blades,f. a second flow tube configured to direct air from the second inflow chamber into said air blades,f. a separation panel extending between the first inflow chamber and the power generating turbine; wherein said first flow tube extends through said separation panel and is configured to direct a first phase air flow into said air blades;wherein said air blades are configured to extend at least partially into an impingement chamber, and wherein the dual wind energy power enhancer system is configured to utilize said first and second chamber air flow to create powerwherein said air blades are exposed to both the first phase air flow from the first inflow chamber and a first phase air flow from the second inflow chamber and to a second phase air flow from a prevailing wind, wherein the second phase air flow directly impinges on the air blades. 22. The dual wind energy power enhancer system of claim 21, wherein the outflow chamber is configured with air outflow dampers configured around the air blades for preventing a portion of the second phase air flow from entering the impingement chamber. 23. The dual wind energy power enhancer system of claim 21, wherein the impingement chamber comprises a plurality of air deflectors. 24. The dual wind energy power enhancer system of claim 21, further comprising at least one air deflector configured in the first inflow chamber or in the second inflow chamber or around the air blades to direct the second phase air flow towards the air blades. 25. A dual wind energy power enhancer system comprising: a. a first outflow chamber comprising: i. a first fixed structure having a plurality of openings for receiving second phase air flow from a prevailing wind;ii. a first turbine having a first set of air blades in the form of a reverse flow fan that rotate about an axis;b. a second outflow chamber comprising: i. a second fixed structure having a plurality of openings for receiving second phase air flow from the prevailing wind,ii. a second turbine having a second set of air blades;c. an inflow chamber comprising a third fixed structure and a plurality of openings for receiving first phase air flow from the prevailing wind;d. a first flow tube configured to direct air from the air inflow chamber into said first turbine; ande. a second flow tube configured to direct air from the air inflow chamber into said second turbine;f. a first separation panel extending between the inflow chamber and the first outflow chamber;g. a second separation panel extending between the inflow chamber and the second outflow chamber;wherein the first flow tube extends through said first separation panel and is configured to direct a portion of the inflow chamber first phase air flow into said first set of air blades; andwherein the second flow tube extends through said second separation panel and is configured to direct a portion of the inflow chamber first phase air flow into said second set of air blades; andwherein at least one of said first and second sets of air blades are configured to extend at least partially into said outflow chambers, and wherein the dual wind energy power enhancer system is configured to utilize air flow from the inflow chamber to direct air into said first and second air blades to create wind power, and whereby said power enhancing system creates useful power from the prevailing wind;wherein said first and second set of air blades are exposed to both the first phase air flow from the inflow chamber and to a said second phase air flow,wherein the second phase air flow from the prevailing wind is directed to impinge on the first and second set of air blades. 26. The dual wind energy power enhancer system of claim 25, further comprising at least one air deflector configured in the first inflow chamber or the second inflow chamber or around the air blades to direct the second phase air flow towards the air blades. 27. The dual wind energy power enhancer system of claim 25, wherein at least one of the outflow chambers is configured as an impingement chamber. 28. The dual wind energy power enhancer system of claim 25, wherein the outflow chambers are configured with air outflow dampers configured around the air blades in both the first and second outflow chambers for preventing a portion of the second phase air flow from the prevailing wind from entering the first and second outflow chambers. 29. The dual wind energy power enhancer system of claim 25, wherein the inflow chamber has a first inflow area and the flow tube has a flow tube cross-sectional area, whereby a ratio of the inflow area to the cross-sectional area of the flow tube is greater than 0.01:1.
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Preito Santiago, Francisco Javier, Cyclonic or anti-cyclonic conversion tower.
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