System and method for removing heat from a turbine
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02G-003/00
F01D-009/04
F01D-005/18
F01D-005/28
출원번호
US-0709306
(2012-12-10)
등록번호
US-9297267
(2016-03-29)
발명자
/ 주소
Itzel, Gary Michael
Kirtley, Kevin R.
Vandervort, Christian Lee
Bunker, Ronald Scott
출원인 / 주소
GENERAL ELECTRIC COMPANY
대리인 / 주소
Dority & Manning, PA
인용정보
피인용 횟수 :
1인용 특허 :
9
초록▼
A system for removing heat from a turbine includes a component in the turbine having a supply plenum and a return plenum therein. A substrate that defines a shape of the component has an inner surface and an outer surface. A coating applied to the outer surface of the substrate has an interior surfa
A system for removing heat from a turbine includes a component in the turbine having a supply plenum and a return plenum therein. A substrate that defines a shape of the component has an inner surface and an outer surface. A coating applied to the outer surface of the substrate has an interior surface facing the outer surface of the substrate and an exterior surface opposed to the interior surface. A first fluid channel is between the outer surface of the substrate and the exterior surface of the coating. A first fluid path is from the supply plenum, through the substrate, and into the first fluid channel, and a second fluid path is from the first fluid channel, through the substrate, and into the return plenum.
대표청구항▼
1. A stationary vane for a turbine of a gas turbine, the stationary vane comprising: an inner flange radially spaced from an outer flange;an airfoil that extends radially between the inner flange and the outer flange, wherein the airfoil is at least partially formed from a substrate and a coating ap
1. A stationary vane for a turbine of a gas turbine, the stationary vane comprising: an inner flange radially spaced from an outer flange;an airfoil that extends radially between the inner flange and the outer flange, wherein the airfoil is at least partially formed from a substrate and a coating applied to an outer surface of the substrate, wherein the coating has an interior surface facing the outer surface of the substrate and an exterior surface opposed to the interior surface, wherein the airfoil defines a first cavity and a second cavity within the substrate;a supply plenum that extends through the outer flange, wherein the supply plenum is in fluid communication with the first cavity;a return plenum that extends through the outer flange, wherein the return plenum is in fluid communication with the second cavity;a first fluid channel defined between the outer surface of the airfoil substrate and the exterior surface of the coating, wherein the supply plenum, the first cavity, the first fluid channel, the second cavity and the return plenum define a flow path for routing a cooling media into and hack out of the airfoil through the outer flange. 2. The stationary vane as in claim 1, wherein the coating comprises a bond coat applied to the outer surface of the airfoil substrate and a thermal barrier coating applied to the bond coat and wherein the first fluid channel is defined between the bond coat and the thermal barrier coating. 3. The stationary vane as in claim 1, wherein the first fluid channel is embedded in the outer surface of the substrate, and the first fluid channel is embedded in the interior surface of the coating. 4. The stationary vane as in claim 1, wherein the first fluid channel is surrounded by the coating. 5. The stationary vane as in claim 1, wherein the first fluid channel includes an inlet port and an outlet port, wherein the inlet port defines a flow path from the first cavity into the first fluid channel and the outlet port defines a flow path between the first fluid channel and the second cavity. 6. The stationary vane as in claim 1, further comprising a second fluid channel defined between the outer surface of the airfoil substrate and the exterior surface of the coating, wherein an inlet port. of the second fluid channel is in fluid communication with an outlet port of the first fluid channel and an outlet port of the second fluid channel is in fluid communication with the second cavity. 7. The stationary vane as in claim 6, wherein the coating comprises a bond coat applied to the outer surface of the airfoil substrate and a thermal barrier coating applied to the bond coat and wherein the second fluid channel is defined between the bond coat and the thermal barrier coating. 8. The stationary vane as in claim 1, wherein the airfoil substrate defines a third cavity downstream from the first fluid channel and upstream from the second cavity. 9. The stationary vane as in claim 8, wherein an outlet port of the first fluid channel is in fluid communication with the third cavity. 10. The stationary vane as in claim 8, further comprising a second fluid channel defined between the outer surface of the airfoil substrate and the exterior surface of the coating, wherein an inlet port of the second fluid channel is in fluid communication with the third cavity and an outlet port of the second fluid channel is in fluid communication with the second cavity. 11. The stationary vane as in claim 8, further comprising a second fluid channel defined between the outer surface of the airfoil substrate and the exterior surface of the coating, wherein an outlet port of the first fluid channel is in fluid communication with the third cavity, an inlet port of the second fluid channel is in fluid communication with the outlet port of the first fluid channel via the third cavity and an outlet port of the second fluid channel is in fluid communication with the second cavity. 12. A rotating blade, comprising: a platform;a root that extends radially inwardly from the platform;an airfoil that extends radially outwardly from the platform, the airfoil including a leading edge, a trailing edge a concave pressure side surface and a convex suction side surface, wherein the airfoil is at least partially formed from a substrate and a coating applied to an outer surface of the substrate, wherein the coating has an interior surface facing the outer surface of the substrate and an exterior surface opposed to the interior surface, wherein the airfoil defines a forward supply plenum and an aft supply plenum in fluid communication with a cooling media inlet defined in the root of the airfoil and a return plenum in fluid communication with a cooling media outlet defined in the root of the airfoil;a first fluid channel defined between the outer surface of the airfoil substrate and the exterior surface of the coating, wherein the first fluid channel is in fluid communication with at least one of the forward supply plenum and the aft supply plenum and with the return plenum to define a closed flow path for routing a cooling media from the cooling media inlet, through the airfoil and out of the cooling media outlet. 13. The rotating blade as in claim 12, wherein the coating comprises a bond coat applied to the outer surface of the airfoil substrate and a thermal barrier coating applied to the bond coat, wherein the first fluid channel is defined between the bond coat and the thermal barrier coating. 14. The rotating blade as in claim 12, wherein the first fluid channel is in fluid communication with both the forward supply plenum and the aft supply plenum via a plurality of inlets defined by the airfoil substrate. 15. The rotating blade as in claim 12, wherein the first fluid channel extends beneath at least one of the convex suction side surface and the concave pressure side surface of the airfoil. 16. The rotating blade as in claim 12, wherein the airfoil further defines an intermediate plenum downstream from the first fluid channel and a second fluid channel defined between the outer surface of the airfoil substrate and the exterior surface of the coating, wherein the second fluid channel defines a flow path between the intermediate plenum and the return plenum. 17. The rotating blade as in claim 16, wherein the second fluid channel extends beneath the convex suction side surface of the airfoil. 18. The rotating blade as in claim 16, wherein the first fluid channel extends beneath the concave pressure side surface of the airfoil. 19. The rotating blade as in claim 16, further comprising a third fluid channel defined between the outer surface of the airfoil substrate and the exterior surface of the coating, wherein the third fluid channel defines a flow path between the aft supply plenum and the return plenum. 20. The rotating blade as in claim 19, wherein the third fluid plenum extends beneath at least one of the convex suction side surface and the concave pressure side surface of the airfoil.
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이 특허에 인용된 특허 (9)
Bunker Ronald S. (Niskayuna NY), Closed-circuit air cooled turbine.
Glynn Christopher C. ; Wilson Paul S. ; Martus James A. ; Carlson Clay K., Low cost airfoil cooling circuit with sidewall impingement cooling chambers.
Darolia, Ramgopal; Lee, Ching-Pang; Schafrik, Robert Edward, Process for forming micro cooling channels inside a thermal barrier coating system without masking material.
Krumanaker, Matthew Lee; Dooley, Weston Nolan; Brassfield, Steven Robert; Helmer, David Benjamin; Bailey, Jeremy Clyde; Briggs, Robert David, Turbine blade.
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