초록 ▼

One embodiment of a transition-to-turbine seal (300) comprises a first, flattened section (302) adapted to be received in a peripheral axial slot (320) of a transition (325), and a second, generally C-shaped section (301). The generally C-shaped section (301) comprises a flattened portion (305) near

One embodiment of a transition-to-turbine seal (300) comprises a first, flattened section (302) adapted to be received in a peripheral axial slot (320) of a transition (325), and a second, generally C-shaped section (301). The generally C-shaped section (301) comprises a flattened portion (305) near the first, flattened section (302), and a curved portion (306) extending to a free edge (307). A fiber metal strip component (309) may be attached to the flattened portion (305) to define a first engagement surface adapted to engage an upstream side (336) of an outer vane seal rail (337), and a second engagement surface 308, adjacent the free edge (307), provides an opposed wear surface adapted to engage a downstream side (338) of the outer vane seal rail (337). System embodiments also are described, in which such transition-to-turbine seal (300) is isolated from a hot gas path (350) by provision of a plurality of cooling apertures (327) in the transition (325).

대표청구항 ▼

What is claimed is: 1. A transition-to-turbine seal for sealing a gap between an outlet of a gas turbine engine transition and a plurality of row 1 vane segments, the transition-to-turbine seal comprising: a seal component comprising a first, flattened section adapted to be received in a peripheral

What is claimed is: 1. A transition-to-turbine seal for sealing a gap between an outlet of a gas turbine engine transition and a plurality of row 1 vane segments, the transition-to-turbine seal comprising: a seal component comprising a first, flattened section adapted to be received in a peripheral axially oriented slot in a transition outlet, and a second, generally C-shaped section locating a first engagement surface near the first, flattened section and comprising a curved portion extending to a second engagement surface spaced apart a specified distance from the first engagement surface; wherein the generally C-shaped section is adapted to provide a selected spring-loaded sliding engagement over a respective vertical flange of each of the row 1 vane segments. 2. The transition-to-turbine seal of claim 1, the generally C-shaped section additionally comprising a flattened portion adjacent the first, flattened section, the flattened portion locating the first engagement surface. 3. The transition-to-turbine seal of claim 2, additionally comprising a fiber metal strip adhered to the flattened portion and defining the first engagement surface. 4. The transition-to-turbine seal of claim 3, additionally comprising a plurality of dimples along or adjacent the flattened section, wherein added height of the dimples is effective to obtain a restricted radial movement of the flattened section when disposed in a transition slot. 5. The transition-to-turbine seal of claim 2, wherein the second engagement surface is adjacent a flared free end of the curved portion. 6. The transition-to-turbine seal of claim 2, the generally C-shaped section additionally comprising a second, flattened portion, the second, flattened portion locating the second engagement surface. 7. The transition-to-turbine seal of claim 6, wherein the second engagement surface is comprised of a fiber metal strip adhered to the second, flattened portion. 8. The transition-to-turbine seal of claim 6, wherein the second engagement surface is comprised of a metal strip sprayed with a porous abradable coating adhered to the second, flattened portion. 9. The transition-to-turbine seal of claim 2, additionally comprising a dimple strip comprising a plurality of dimples, wherein a portion of the dimple strip comprising the dimples fits against the flattened section, and wherein added height of the dimples is effective to obtain a restricted radial movement of the flattened section when disposed in a transition slot. 10. The transition-to-turbine seal of claim 1, wherein the seal component is multi-ply. 11. The transition-to-turbine seal of claim 1, wherein the seal component is two-ply. 12. A gas turbine engine comprising the transition-to-turbine seal of claim 1. 13. A sealing system for a transition-to-turbine interface in a gas turbine engine comprising: a transition comprising a duct defining a boundary for a hot gas path and at an outlet end an interior and an exterior slot; a plurality of row 1 vane segments downstream and opposed the transition, each respective row 1 vane segment comprising an inner and an outer vane seal rail, wherein at least one of the transition and the plurality of row 1 vane segments further comprise respective pluralities of cooling apertures for passage of air, each respective plurality effective to establish, during operation, a respective air barrier effective to shield the respective first and second transition-to-turbine seals from temperatures in the hot gas path; the first transition-to-turbine seal comprising a seal component, outwardly disposed from the plurality of cooling apertures, comprising a flattened section adapted to be received in the transition interior slot, and a generally C-shaped section adapted to fit in spring-loaded sliding engagement about the inner vane seal rail, the C-shaped section comprising opposed engagement surfaces for said sliding engagement; and the second transition-to-turbine seal comprising a seal component, outwardly disposed from the plurality of cooling apertures, comprising a flattened section adapted to be received in the transition exterior slot, and a generally C-shaped section adapted to fit in spring-loaded sliding engagement about the exterior vane seal rail, the C-shaped section comprising opposed engagement surfaces for said sliding engagement; wherein each respective plurality of cooling apertures is effective to shield the respective outwardly disposed first and second transition-to-turbine seals from hot gas path temperatures. 14. The sealing system of claim 13, the transition comprising an integrated exit piece fitting about the duct and comprising the interior and the exterior slot and comprising the respective pluralities of cooling apertures. 15. The sealing system of claim 13, wherein the transition outlet exterior slot is formed by attachment of an attachable member, comprising an exterior wall defining the slot, to a mating member positioned about the duct. 16. The sealing system of claim 15, wherein the attachable member and the mating member comprise a modified integrated exit piece. 17. A sealing system for a transition-to-turbine interface in a gas turbine engine comprising: a transition comprising a duct defining a boundary for a hot gas path, and further comprising at an outlet end an interior and an exterior slot and, between the duct and each said slot, a respective plurality of cooling apertures for passage of air, effective to establish a respective air barrier during operation; a plurality of row 1 vane segments downstream and opposed the transition, each respective row 1 vane segment comprising an inner and an outer vane segment flange; a first transition-to-turbine seal comprising a seal component comprising a flattened section adapted to be received in the transition interior slot, and a means for encircling adapted to fit in spring-loaded sliding engagement about the inner vane segment flange, the means for encircling comprising opposed means for sealing against opposite sides of the inner vane segment flange; and a second transition-to-turbine seal comprising a seal component comprising a flattened section adapted to be received in the transition exterior slot, and a means for encircling adapted to fit in spring-loaded sliding engagement about the exterior vane segment flange, the means for encircling comprising opposed means for sealing against opposite sides of the outer vane segment flange; wherein the first and the second transition-to-turbine seals each are respectively displaced radially away from the hot gas path, and wherein each respective plurality of cooling apertures is effective to shield the respective radially displaced first and second transition-to-turbine seals from hot gas path temperatures. 18. The sealing system of claim 17, the transition comprising an integrated exit piece fitting about the duct and comprising the interior and the exterior slot and the respective pluralities of cooling apertures. 19. The sealing system of claim 17, wherein the transition outlet exterior slot is formed by attachment of an attachable member, comprising an exterior wall defining the slot, to a mating member positioned about the duct. 20. The sealing system of claim 19, wherein the attachable member and the mating member comprise a modified integrated exit piece. 21. A gas turbine engine comprising the sealing system of claim 17.