IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
US-0649636
(2009-12-30)
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등록번호 |
US-8596076
(2013-12-03)
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발명자
/ 주소 |
- Gritton, Mark
- Starr, Matthew J.
- Fritsch, Theodore J.
|
출원인 / 주소 |
- Rolls-Royce North American Technologies Inc.
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
0 인용 특허 :
7 |
초록
▼
The present invention provides a variable pressure ratio gas turbine. In an embodiment, the engine is configured to selectively bypass all or a portion of a high pressure compressor and a high pressure turbine. In an embodiment, during bypass operation, all or a portion of the flow that would otherw
The present invention provides a variable pressure ratio gas turbine. In an embodiment, the engine is configured to selectively bypass all or a portion of a high pressure compressor and a high pressure turbine. In an embodiment, during bypass operation, all or a portion of the flow that would otherwise pass through the high pressure compressor and the high pressure turbine may be routed through a respective compressor bypass duct and turbine bypass duct.
대표청구항
▼
1. A variable pressure ratio gas turbine engine, comprising: a high pressure spool having a high pressure turbine and a high pressure compressor mechanically driven by said high pressure turbine;a lower pressure spool having a lower pressure turbine and a lower pressure compressor mechanically drive
1. A variable pressure ratio gas turbine engine, comprising: a high pressure spool having a high pressure turbine and a high pressure compressor mechanically driven by said high pressure turbine;a lower pressure spool having a lower pressure turbine and a lower pressure compressor mechanically driven by said lower pressure turbine;a combustor; anda flow control system structured to selectively provide flow to said combustor from said high pressure compressor and said lower pressure compressor,wherein an inlet of said high pressure compressor is in fluid communication with a discharge of said lower pressure compressor, further comprising a compressor bypass flowpath in parallel fluid communication with the discharge of said lower pressure compressor with respect to the inlet of said high pressure compressor; andwherein said high pressure compressor employs a plurality of shrouded compressor blades, and wherein said compressor bypass flowpath has an inner flowpath wall formed in part by shrouds of said shrouded compressor blades. 2. The gas turbine engine of claim 1, wherein said flow control system includes a moveable compressor flow guide structured to selectively direct the lower pressure compressor discharge flow exiting said lower pressure compressor to a selected one of said high pressure compressor and said compressor bypass flowpath. 3. The gas turbine engine of claim 1, wherein said flow control system includes a moveable compressor flow guide structured to selectively direct a lower pressure compressor discharge flow into a destination selected from between at least two of: said inlet of said high pressure compressor;an inlet of said compressor bypass flowpath; andboth said inlet of said high pressure compressor and said inlet of said compressor bypass flowpath. 4. The gas turbine engine of claim 3, wherein said moveable compressor flow guide is positioned upstream of said high pressure compressor. 5. The gas turbine engine of claim 1, further comprising means for selectively bypassing said high pressure compressor. 6. The gas turbine engine of claim 1, wherein said high pressure turbine is drivingly coupled to said high pressure compressor;wherein said lower pressure turbine is drivingly coupled to said lower pressure compressor; andwherein said flow control system is structured to selectively couple an outlet of said combustor to a selected one of an inlet of said high pressure turbine and an inlet of said lower pressure turbine. 7. The gas turbine engine of claim 6, wherein said inlet of said high pressure turbine is in fluid communication with said outlet of said combustor, further comprising a turbine bypass flowpath in parallel fluid communication with said outlet of said combustor with respect to said inlet of said high pressure turbine. 8. The gas turbine engine of claim 7, wherein said flow control system includes a moveable turbine flow guide structured to selectively permit the combustor output flow exiting said combustor to pass through a selected one of said high pressure turbine and said turbine bypass flowpath. 9. The gas turbine engine of claim 7, wherein said flow control system includes a moveable turbine flow guide structured to selectively permit the combustor output flow exiting said combustor to pass into a destination selected from between at least two of: said inlet of said high pressure turbine;an inlet of said turbine bypass flowpath; andboth said inlet of said high pressure turbine and said inlet of said turbine bypass flowpath. 10. The gas turbine engine of claim 7, further comprising a variable turbine nozzle structured to selectively open and close said inlet of said high pressure turbine. 11. The gas turbine engine of claim 7, further comprising a variable turbine nozzle structured to selectively open and close an inlet of said turbine bypass flowpath. 12. The gas turbine engine of claim 7, further comprising two independently variable turbine nozzles, wherein one of the independently variable turbine nozzles is structured to selectively open and close said inlet of said high pressure turbine and the other of the independently variable turbine nozzles is structured to selectively open and close an inlet of said turbine bypass flowpath. 13. The gas turbine engine of claim 12, wherein each independently variable turbine nozzle has a turbine vane rotatable about a same axis of rotation as a corresponding turbine vane of the other independently variable turbine nozzle. 14. The gas turbine engine of claim 6, further comprising two independently variable turbine nozzles, wherein one of the independently variable turbine nozzles is structured to selectively allow and prevent flow from the outlet of said combustor through the one of the independently variable turbine nozzles to said high pressure turbine and the other of the independently variable turbine nozzles is structured to selectively allow and prevent flow from the outlet of said combustor through the other of the independently variable turbine nozzles to said lower pressure turbine. 15. The gas turbine engine of claim 14, wherein each independently variable turbine nozzle has a turbine vane rotatable about a same axis of rotation as a corresponding turbine vane of the other independently variable turbine nozzle. 16. The gas turbine engine of claim 6, further comprising means for bypassing said high pressure turbine. 17. The gas turbine engine of claim 6, further comprising means for bypassing both said high pressure compressor and said high pressure turbine without bypassing said combustor. 18. The gas turbine engine of claim 7, wherein said high pressure turbine employs a plurality of shrouded turbine blades, and wherein said turbine bypass flowpath has an inner flowpath wall formed in part by shrouds of said shrouded turbine blades. 19. A gas turbine engine, comprising: a higher pressure spool having a higher pressure compressor mechanically driven by a higher pressure turbine;a lower pressure spool having a lower pressure turbine and a lower pressure compressor mechanically driven by said lower pressure turbine;a combustor; andmeans for selectively providing the discharge flow of said lower pressure compressor to at least one of said higher pressure compressor and said combustor,wherein an inlet of said higher pressure compressor is in fluid communication with a discharge of said lower pressure compressor, further comprising a compressor bypass flowpath in parallel fluid communication with the discharge of said lower pressure compressor with respect to the inlet of said higher pressure compressor; andwherein said higher pressure compressor employs a plurality of shrouded compressor blades, and wherein said compressor bypass flowpath has an inner flowpath wall formed in part by shrouds of said shrouded compressor blades. 20. A gas turbine engine, comprising: a higher pressure spool having a higher pressure compressor mechanically driven by a higher pressure turbine;a lower pressure spool having a lower pressure turbine and a lower pressure compressor mechanically driven by said lower pressure turbine;a combustor; andmeans for selectively fluidly coupling the outlet of said combustor with at least one of said higher pressure turbine and said lower pressure turbinewherein said higher pressure turbine is drivingly coupled to said higher pressure compressor; wherein said lower pressure turbine is drivingly coupled to said lower pressure compressor; and wherein said means for selectively fluidly coupling is structured to selectively couple an outlet of said combustor to a selected one of an inlet of said higher pressure turbine and an inlet of said lower pressure turbine;wherein said inlet of said higher pressure turbine is in fluid communication with said outlet of said combustor, further comprising a turbine bypass flowpath in parallel fluid communication with said outlet of said combustor with respect to said inlet of said higher pressure turbine; andwherein said higher pressure turbine employs a plurality of shrouded turbine blades, and wherein said turbine bypass flowpath has an inner flowpath wall formed in part by shrouds of said shrouded turbine blades. 21. A variable pressure ratio gas turbine engine, comprising: a first spool having a first turbine and a first compressor mechanically driven by said first turbine, said first spool having a first pressure ratio;a second spool having a second turbine and a second compressor mechanically driven by said second turbine, said second spool having a second pressure ratio different from said first pressure ratio;a combustor; anda flow control system structured to selectively provide flow to said combustor from said first compressor and said second compressor,wherein an inlet of said first compressor is in fluid communication with a discharge of said second compressor, further comprising a compressor bypass flowpath in parallel fluid communication with the discharge of said second compressor with respect to the inlet of said first compressor; andwherein said first compressor employs a plurality of shrouded compressor blades, and wherein said compressor bypass flowpath has an inner flowpath wall formed in part by shrouds of said shrouded compressor blades. 22. A gas turbine engine, comprising: a higher pressure spool driven by a higher pressure turbine;a lower pressure spool driven by a lower pressure turbine;a combustor; andmeans for selectively fluidly coupling the outlet of said combustor with at least one of said higher pressure turbine and said lower pressure turbine, wherein said means for selectively fluidly coupling is structured to selectively couple an outlet of said combustor to a selected one of an inlet of said higher pressure turbine and an inlet of said lower pressure turbine;wherein said inlet of said high pressure turbine is in fluid communication with said outlet of said combustor, further comprising a turbine bypass flowpath in parallel fluid communication with said outlet of said combustor with respect to said inlet of said higher pressure turbine;further comprising two independently variable turbine nozzles, wherein one of the independently variable turbine nozzles is structured to selectively open and close said inlet of said higher pressure turbine and the other of the independently variable turbine nozzles is structured to selectively open and close an inlet of said turbine bypass flowpath,wherein each independently variable turbine nozzle has a turbine vane rotatable about a same axis of rotation as a corresponding turbine vane of the other independently variable turbine nozzle. 23. A gas turbine engine, comprising: a higher pressure spool driven by a higher pressure turbine;a lower pressure spool driven by a lower pressure turbine;a combustor;means for selectively fluidly coupling the outlet of said combustor with at least one of said higher pressure turbine and said lower pressure turbine, wherein said means for selectively fluidly coupling is structured to selectively couple an outlet of said combustor to a selected one of an inlet of said higher pressure turbine and an inlet of said lower pressure turbine;two independently variable turbine nozzles, wherein one of the independently variable turbine nozzles is structured to selectively allow and prevent flow from the outlet of said combustor through the one of the independently variable turbine nozzles to said high pressure turbine and the other of the independently variable turbine nozzles is structured to selectively allow and prevent flow from the outlet of said combustor through the other of the independently variable turbine nozzles to said lower pressure turbine,wherein each independently variable turbine nozzle has a turbine vane rotatable about a same axis of rotation as a corresponding turbine vane of the other independently variable turbine nozzle.
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