Radial active clearance control for a gas turbine engine
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F01D-025/14
F01D-011/24
출원번호
US-0314296
(2011-12-08)
등록번호
US-9157331
(2015-10-13)
발명자
/ 주소
Laurello, Vincent P.
출원인 / 주소
Siemens Aktiengesellschaft
인용정보
피인용 횟수 :
2인용 특허 :
15
초록▼
The present invention comprises a gas turbine engine with a compressor for generating compressed air, a turbine comprising upstream and downstream rows of vanes, vane carrier structure surrounding at least one row of vanes and plenum structure at least partially surrounding the vane carrier structur
The present invention comprises a gas turbine engine with a compressor for generating compressed air, a turbine comprising upstream and downstream rows of vanes, vane carrier structure surrounding at least one row of vanes and plenum structure at least partially surrounding the vane carrier structure capable of impinging compressed air onto the vane carrier structure. The gas turbine engine further comprises fluid supply structure including first fluid path structure defining a first path for compressed air to travel to the plenum structure, second fluid path structure defining a second path for compressed air to travel toward the downstream row of vanes, and fluid control structure selectively controlling fluid flow to the first and second fluid path structures.
대표청구항▼
1. A gas turbine engine comprising: an engine casing;a compressor for generating compressed air;a turbine comprising: at least one upstream row of vanes;a downstream row of vanes downstream from said at least one upstream row of vanes;vane carrier structure surrounding at least one of said rows of v
1. A gas turbine engine comprising: an engine casing;a compressor for generating compressed air;a turbine comprising: at least one upstream row of vanes;a downstream row of vanes downstream from said at least one upstream row of vanes;vane carrier structure surrounding at least one of said rows of vanes; andplenum structure at least partially surrounding said vane carrier structure capable of impinging compressed air onto said vane carrier structure; andfluid supply structure comprising: first fluid path structure defining a first path for compressed air to travel to said plenum structure;second fluid path structure defining a second path for compressed air to travel toward said downstream row of vanes; andfluid control structure selectively controlling fluid flow to said first and second fluid path structures;wherein said engine casing and said vane carrier structure define an internal chamber in which said plenum structure is located, compressed air passing through said first fluid path structure flows into said plenum structure, and passes from said plenum structure so as to impinge on said vane carrier structure within said internal chamber;at least one conduit extending from said compressor, through said internal chamber, to a passage through said vane carrier providing cooling air from said compressor to an interior of vanes forming said at least one upstream row of vanes;said fluid control structure alternately providing a flow of compressed air from said first and second fluid path structures to said internal chamber; anda bore through said vane carrier adjacent to said downstream row of vanes defining a flow path for air from said internal chamber to an interior of vanes forming said downstream row of vanes during flow of compressed air from both said first and second fluid path structures. 2. The gas turbine engine as set forth in claim 1, said fluid control structure permitting compressed air to flow through said first fluid path structure during a steady state operation of said gas turbine engine and permitting compressed air to flow through said second fluid path structure during a transient operation of said gas turbine engine. 3. The gas turbine engine as set forth in claim 1, further comprising: at least one downstream row of blades; andat least one downstream ring segment structure surrounding said at least one downstream row of blades, said at least one downstream ring segment structure and said vane carrier structure defining at least one downstream inner cavity, said at least one downstream inner cavity receiving compressed air from said internal chamber. 4. The gas turbine engine as set forth in claim 1, wherein said fluid control structure comprises a valve receiving a compressed air flow from an intermediate fluid path structure and alternately controlling fluid flow out of said valve to both said first and second fluid path structures. 5. The gas turbine engine as set forth in claim 1, wherein said plenum structure comprises: at least one impingement manifold; anda plurality of impingement tubes coupled to and communicating with said impingement manifold, said impingement tubes being axially spaced apart from one another. 6. The gas turbine engine as set forth in claim 5, wherein each of said impingement tubes is sized such that less compressed air is provided by each successive impingement tube the more downstream the impingement tube is located. 7. The gas turbine engine as set forth in claim 5, wherein said fluid control structure comprises a first valve controlling fluid flow through said first fluid path structure and a second valve controlling fluid flow through said second fluid path structure. 8. A gas turbine engine comprising: an engine casing;a compressor for generating compressed air;a turbine comprising: at least one upstream row of vanes and at least one downstream row of vanes;vane carrier structure surrounding at least one of said rows of vanes; andplenum structure at least partially surrounding said vane carrier structure capable of impinging compressed air onto said vane carrier structure; andfluid supply structure comprising: first fluid path structure defining a first path for compressed air from a source location on said compressor to travel to said plenum structure;second fluid path structure defining a second path for compressed air from another source location on said compressor, different from and at a different pressure than said source location for said first fluid path structure, to travel toward said at least one downstream row of vanes; andfluid control structure capable of permitting compressed air to alternately flow through one of said first fluid path structure and said second fluid path structure, said fluid control structure comprises a first valve controlling fluid flow through said first fluid path structure and a second valve controlling fluid flow through said second fluid path structure, wherein said fluid control structure permits compressed air to flow through said first fluid path structure during a steady state operation of said gas turbine engine and permits compressed air to flow through said second fluid path structure during a transient operation of said gas turbine engine;wherein said engine casing and said vane carrier structure define an internal chamber in which said plenum structure is located, compressed air passing through said first fluid path structure flows into said plenum structure, and passes from said plenum structure so as to impinge on said vane carrier structure within said internal chamber; andsaid second fluid path structure supplying compressed air through said second valve at a lower pressure during said transient operation of said gas turbine engine than a pressure of compressed air supplied by said first fluid path structure through said first valve during said steady state operation of said gas turbine engine. 9. The gas turbine engine as set forth in claim 8, further comprising: at least one downstream row of blades; andat least one downstream ring segment structure surrounding said at least one downstream row of blades, said at least one downstream ring segment structure and said vane carrier structure defining at least one downstream inner cavity, said at least one downstream inner cavity receiving compressed air from said internal chamber. 10. The gas turbine engine as set forth in claim 8, wherein said plenum structure comprises: at least one impingement manifold; anda plurality of impingement tubes coupled to and communicating with said impingement manifold, said impingement tubes being axially spaced apart from one another. 11. The gas turbine engine as set forth in claim 10, wherein each of said impingement tubes is sized such that less compressed air is provided by each successive impingement tube the more downstream the impingement tube is located. 12. The gas turbine engine as set forth in claim 10, wherein said vane carrier structure comprises at least one radially outwardly extending rail, and wherein at least one of said impingement tubes directs air such that it impinges on said at least one rail. 13. A gas turbine engine comprising: an engine casing;a compressor for generating compressed air;a turbine comprising: at least one upstream row of vanes;at least one downstream row of vanes downstream from said at least one upstream row of vanes;vane carrier structure surrounding at least one of said rows of vanes; andplenum structure at least partially surrounding said vane carrier structure for impinging compressed air onto said vane carrier structure, said plenum structure comprising: at least one impingement manifold; andat least first, second and third impingement tubes coupled to and communicating with said at least one impingement manifold, said impingement tubes being axially spaced apart from one another wherein each successive first, second and third impingement tube, in the downstream direction, has a cross-sectional area that is less than an upstream adjacent impingement tube; andfluid supply structure comprising: first fluid path structure defining a first path for compressed air to travel to said plenum structure;second fluid path structure defining a second path for compressed air to travel toward said at least one downstream row of vanes; andfluid control structure selectively controlling fluid flow to said first and second fluid path structures to alternately permit compressed air flow through said first and second fluid path structures. 14. The gas turbine engine as set forth in claim 1, wherein said at least one conduit provides a flow of compressed air to said at least one upstream row of vanes separate from air flow in the internal chamber. 15. The gas turbine engine as set forth in claim 8, wherein a difference in pressure between the compressed air supplied through the first and second fluid path structures is generally equal to a pressure drop that occurs though said plenum structure as compressed air passes from said first fluid path structure to said internal chamber. 16. The gas turbine engine as set forth in claim 15, including a bore through said vane carrier adjacent to said at least one downstream row of vanes defining a flow path for air from said internal chamber to an interior of vanes forming said downstream row of vanes during flow of compressed air from both said first and second fluid path structures, wherein a pressure of compressed air provided to said at least one downstream row of vanes during flow of compressed air from said first fluid path structure is generally equal to pressure of compressed air provided to said at least one downstream row of vanes during flow of compressed air from said second fluid path structure.
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이 특허에 인용된 특허 (15)
Wright William B. (Leicester GB2) Flatman Richard J. (Derby GB2), Blade tip clearance control.
Bessette Alan D. (Palm Beach Gardens FL) Davies Daniel O. (West Palm Beach FL) Shade John L. (Jupiter FL), Combined turbine stator cooling and turbine tip clearance control.
Redinger ; Jr. Ira H. (Vernon CT) Sadowsky David (South Windsor CT) Stripinis Philip S. (South Windsor CT), External gas turbine engine cooling for clearance control.
Plemmons Larry W. (Fairfield OH) Proctor Robert (West Chester OH) Albers Robert J. (Park Hills KY) Gardner Donald L. (West Chester OH), Gas turbine engine case counterflow thermal control.
Estridge,Scott Anthony; Wartner,Roger Francis; Bucaro,Michael Terry, System and method to exhaust spent cooling air of gas turbine engine active clearance control.
Bucaro, Michael Terry; Ruiz, Rafael Jose; Albers, Robert Joseph; Estridge, Scott Anthony; Wartner, Roger Francis, Thermal control of gas turbine engine rings for active clearance control.
Sun, Changjie; Mukherjee, Yu Xie; Mondal, Bhaskar Nanda; Saha, Atanu; Johnson, Marcia Boyle; Lu, Wenfeng, Method and apparatus for active clearance control for high pressure compressors using fan/booster exhaust air.
Ballard, Jr., Henry Grady; Bozkurt, Ozgur; Black, Kenneth Damon; Danescu, Radu Ioan, Method and apparatus to improve heat transfer in turbine sections of gas turbines.
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