Translating outer cowl flow modulation device and method
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02K-001/00
F02K-003/077
F02K-003/02
F02K-003/075
F02K-001/09
F02K-001/15
출원번호
US-0522819
(2014-10-24)
등록번호
US-10145336
(2018-12-04)
발명자
/ 주소
Buey, John R.
Bush, Robert H.
Izquierdo, Felix
출원인 / 주소
United Technologies Corporation
대리인 / 주소
Kinney & Lange, P.A.
인용정보
피인용 횟수 :
0인용 특허 :
6
초록▼
A flow control device includes a first axially extending flow control surface, a second axially extending flow control surface radially offset from the first surface to define a gas flow path therebetween, the gas flow path having a downstream flow path exit, and a third axially extending flow contr
A flow control device includes a first axially extending flow control surface, a second axially extending flow control surface radially offset from the first surface to define a gas flow path therebetween, the gas flow path having a downstream flow path exit, and a third axially extending flow control surface radially offset from the first surface and capable of axially translating with respect to the first and second surfaces for modifying the gas flow path and selectively closing the flow path exit. A turbofan engine includes a core flow passage, a fan bypass passage located radially outward from the core flow passage, a third stream bypass passage located radially outward from the fan bypass passage, and a flow control device that dynamically regulates the third stream bypass passage, allowing fluid flowing through the third stream bypass passage to provide thrust to the turbofan engine and reduce afterbody drag.
대표청구항▼
1. A flow control device for a gas turbine engine comprising: a first axially extending flow control surface having a first upstream end and a first downstream end;a second axially extending flow control surface having a second upstream end and a second downstream end, the second downstream end of t
1. A flow control device for a gas turbine engine comprising: a first axially extending flow control surface having a first upstream end and a first downstream end;a second axially extending flow control surface having a second upstream end and a second downstream end, the second downstream end of the second axially extending flow control surface upstream of the first downstream end of the first axially extending flow control surface, and wherein the second axially extending flow control surface is radially outward from the first axially extending flow control surface to define a gas flow path therebetween, the gas flow path having a downstream flow path exit;a third axially extending flow control surface having a third upstream end and a third downstream end, the third upstream end of the third axially extending flow control surface sealingly engaged to the second downstream end of the second axially extending flow control surface, the third axially extending flow control surface extending downstream from the second axially extending flow control surface, and wherein the third upstream end of the third axially extending flow control surface is located downstream of the first upstream end of the first axially extending flow control surface, and the third axially extending flow control surface is radially offset from the first axially extending flow control surface; and wherein the third axially extending flow control surface is capable of axially translating with respect to the first and second axially extending flow control surfaces between an upstream closed position where the third downstream end of the third axially extending flow control surface contacts the first axially extending flow control surface to close the gas flow path, and a downstream open position where the third downstream end of the third axially extending flow surface is spaced from the first downstream end of the first axially extending flow control surface; andwherein the gas flow path is axisymmetric. 2. The flow control device of claim 1, wherein the first, second, and third axially extending flow control surfaces are annular structures for reducing afterbody drag. 3. The flow control device of claim 1, wherein the first axially extending flow control surface comprises a portion that is convex relative to the gas flow path, and wherein the third axially extending flow control surface comprises a portion that is concave relative to the gas flow path, the portion of the third axially extending flow control surface that is concave relative to the gas flow path being opposite the portion of the first axially extending flow control surface that is convex relative to the gas flow path. 4. The flow control device of claim 3, wherein the convex portion of the first axially extending flow control surface and the concave portion of the third axially extending flow control surface have complementary shapes. 5. The flow control device of claim 3, wherein the convex portion of the first axially extending flow control surface and the concave portion of the third axially extending flow control surface are shaped so that the gas flow path converges at a first location between the first axially extending flow control surface and the third axially extending flow control surface and diverges at a second location downstream from the first location. 6. The flow control device of claim 1, wherein the third axially extending flow control surface comprises a metal sheet. 7. The flow control device of claim 2, further comprising: one or more actuators located circumferentially around the third axially extending flow control surface for controlling movement of the third axially extending flow control surface. 8. The flow control device of claim 2, further comprising: a seal located between the second axially extending flow control surface and the third upstream end of the third axially extending flow control surface. 9. The flow control device of claim 1, wherein the gas flow path is located radially outward from a first bypass flow path, and wherein the gas flow path provides thrust to the gas turbine engine. 10. A turbofan engine comprising: a core flow passage defined by a core flow path liner;a fan bypass passage defined between the core flow path liner and an inner liner containing a first axially extending flow control surface opposite the fan bypass passage, the fan bypass passage located radially outward from the core flow passage;a third stream bypass passage located radially outward from the fan bypass passage, the third stream bypass defined by the first axially extending flow control surface having a first upstream end and a first downstream end, a second axially extending flow control surface having a second upstream end and a second downstream end, the second axially extending flow control surface radially outward from the first axially extending flow control surface wherein the second downstream end of the second axially extending flow control surface is upstream of the first downstream end of the first axially extending flow control surface, and a third axially extending flow control surface comprising a third upstream end and a third downstream end, wherein the third upstream end is downstream of the first upstream end of the first axially extending flow control surface, the third axially extending surface is sealingly engaged with and extending from the second axially extending flow control surface at the third upstream end of the third axially extending flow control surface and the second downstream end of the second axially extending flow control surface;a flow control device that dynamically regulates the third stream bypass passage, allowing fluid flow through the third stream bypass passage to provide thrust to the turbofan engine and reduce afterbody drag, the flow control device selectively allowing closing of the third stream bypass passage to prevent the fluid flow by translating the third axially extending flow control surface, the third axially extending flow control surface translatable between an upstream closed position where the third downstream end of the third axially extending flow control surface contacts the first axially extending flow control surface, and a downstream open position where the third downstream end of the third axially extending flow control surface is spaced from the first downstream end of the first axially extending flow control surface; andwherein the third stream bypass passage is axisymmetric. 11. The turbofan engine of claim 10, wherein the first axially extending flow control surface comprises a portion that is convex relative to the third stream bypass passage, and the third axially extending flow control surface comprises a portion that is concave relative to the third stream bypass passage. 12. The turbofan engine of claim 10, wherein the convex portion of the first axially extending flow control surface and the concave portion of the third axially extending flow control surface have complementary shapes. 13. The turbofan engine of claim 11, wherein the convex portion of the first axially extending flow control surface and the concave portion of the third axially extending flow control surface are shaped so that the third stream bypass passage converges at a first location and diverges at a second location downstream from the first location. 14. The turbofan engine of claim 10, further comprising: one or more actuators located circumferentially around the third axially extending flow control surface for controlling movement of the third axially extending flow control surface. 15. The turbofan engine of claim 11, further comprising: a seal located between the second axially extending flow control surface and the upstream end of the third axially extending flow control surface.
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이 특허에 인용된 특허 (6)
Bruchez ; Jr. Raymond J. (North Palm Beach) Hurchalla James (Stuart) Johnson Steven B. (Stuart FL), Damper for augmentor liners.
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