A Turbofan engine includes a fan mounted to a fan frame inside a fan nacelle. A booster compressor is joined to the fan inboard a flow splitter. A booster bleed system is disposed inside the splitter, and includes an inlet at the compressor outlet, and an outlet joined to the bypass duct following
A Turbofan engine includes a fan mounted to a fan frame inside a fan nacelle. A booster compressor is joined to the fan inboard a flow splitter. A booster bleed system is disposed inside the splitter, and includes an inlet at the compressor outlet, and an outlet joined to the bypass duct following the fan.
대표청구항▼
Accordingly, what is desired to be secured by Letters Patent of the United States is the invention as defined and differentiated in the following claims in which I claim: 1. A turbofan engine comprising: a fan, first compressor, second compressor, combustor, first turbine, and second turbine coaxia
Accordingly, what is desired to be secured by Letters Patent of the United States is the invention as defined and differentiated in the following claims in which I claim: 1. A turbofan engine comprising: a fan, first compressor, second compressor, combustor, first turbine, and second turbine coaxially disposed in serial flow communication; a flow splitter surrounding said first compressor behind said fan; a nacelle surrounding said fan and said splitter, and spaced from said splitter to define a bypass duct therebetween; a fan frame disposed behind said first compressor, and including a row of struts extending radially outwardly through said bypass duct from an annular hub disposed between said first and second compressors; and a booster bleed system disposed inside said splitter, and including a bleed inlet disposed between said first compressor and hub, and a bleed outlet disposed at the aft end of said splitter in front of said struts. 2. An engine according to claim 1 wherein said bleed system further includes a valve disposed inside said splitter between said bleed inlet and bleed outlet to selectively open and close bleed flow between said first compressor and said bypass duct. 3. An engine according to claim 2 further comprising a row of outlet guide vanes disposed between said first compressor and said hub, and said bleed inlet is disposed between said first compressor and said vanes. 4. An engine according to claim 3 wherein: said first compressor includes an outlet in front of said vanes; said bleed inlet comprises an annular slot extending radially outwardly from said compressor outlet, and includes a row of inlet bleed vanes spaced circumferentially apart; said bleed outlet comprises a plurality of louvers extending circumferentially around said aft end of said splitter radially outwardly of said bleed vanes; and said valve is disposed radially between said bleed vanes and louvers for selectively blocking bleed flow therebetween. 5. An engine according to claim 4 wherein said valve is cylindrical, and is mounted in said bleed system for axial translation between said bleed vanes and louvers. 6. An engine according to claim 5 further comprising a plurality of actuators joined to said valve for selective axial translation thereof. 7. An engine according to claim 6 wherein: said bleed inlet is divided into inner and outer slots; said inner slot surrounding said compressor outlet, and having an axially arcuate profile; said outer slot surrounding said inner slot, and extending radially outwardly therefrom; and said inner and outer slots having corresponding bleed vanes therein. 8. An engine according to claim 7 wherein said inlet slot has an axially arcuate profile extending radially outwardly; said bleed vanes are curved circumferentially inside said axially arcuate slot; and said louvers have axially arcuate profiles. 9. An engine according to claim 8 wherein said valve is mounted to said fan frame on a plurality of axial bolts having compression springs thereon to bias closed said valve atop said bleed vanes. 10. An engine according to claim 8 wherein said valve is sealed closed when positioned atop said bleed vanes to prevent bleeding from said compressor. 11. A turbofan engine comprising: a fan rotatably mounted to a fan frame inside a fan nacelle; a flow splitter disposed forward of said frame and spaced from said nacelle to define a fan bypass duct therebetween; a booster compressor joined to said fan radially inboard of said splitter; and a booster bleed system disposed inside said splitter, and including a bleed inlet disposed in flow communication with an outlet of said compressor, and a bleed outlet disposed in flow communication with said bypass duct in front of said frame. 12. An engine according to claim 11 wherein: said fan frame includes a row of struts extending radially outwardly though said bypass duct from an annular hub; said hub includes a row of flow ducts joined in flow communication with said compressor outlet, and a plurality of bearing supports rotatably supporting a drive shaft joined to said fan; and said bleed system further includes a valve disposed inside said splitter between said bleed inlet and bleed outlet to selectively open and close bleed flow between said compressor and said bypass duct. 13. A turbofan engine comprising: a fan rotatably mounted to a fan frame inside a fan nacelle; a booster compressor joined to said fan forward of said frame, and disposed radially inboard of a flow splitter spaced from said nacelle to define a fan bypass duct therebetween; said fan frame including a row of struts extending radially outwardly through said bypass duct from an annular hub; said hub including a row of flow ducts joined in flow communication with an outlet of said compressor, and a plurality of bearing supports rotatably supporting a drive shaft joined to said fan; a row of outlet guide vanes disposed between said compressor outlet and said hub; a booster bleed system disposed inside said splitter, and including a bleed inlet disposed in flow communication with said compressor outlet between said compressor and said vanes, a bleed outlet disposed in flow communication with said bypass duct in front of said struts, and a valve disposed inside said splitter between said bleed inlet and bleed outlet to selectively open and close bleed flow between said compressor and said bypass duct. 14. An engine according to claim 13 wherein: said bleed inlet comprises an annular slot extending radially outwardly from said compressor outlet, and includes a row of inlet bleed vanes spaced circumferentially apart; said bleed outlet comprises a plurality of louvers extending circumferentially around an aft end of said splitter radially outwardly of said bleed vanes; and said valve is disposed radially between said bleed vanes and louvers for selectively blocking bleed flow therebetween. 15. An engine according to claim 14 wherein said valve is cylindrical, and is mounted in said bleed system for axial translation between said bleed vanes and louvers. 16. An engine according to claim 15 further comprising a plurality of actuators joined to said valve for selective axial translation thereof. 17. An engine according to claim 15 wherein: said bleed inlet is divided into inner and outer slots; said inner slot surrounding said compressor outlet, and having an axially arcuate profile; said outer slot surrounding said inner slot, and extending radially outwardly therefrom; and said inner and outer slots having corresponding bleed vanes therein. 18. An engine according to claim 15 wherein said valve is mounted to said fan frame on a plurality of axial bolts having compression springs thereon to bias closed said valve atop said bleed vanes. 19. An engine according to claim 15 wherein said valve is sealed closed when positioned atop said bleed vanes to prevent bleeding from said compressor. 20. An engine according to claim 15 wherein: said inlet slot has an axially arcuate profile extending radially outwardly; said bleed vanes are curved circumferentially inside said axially arcuate slot; and said louvers have axially arcuate profiles.
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