초록 ▼

Embodiments of a turbine nozzle assembly are provided for deployment within a gas turbine engine (GTE) including a first GTE-nozzle mounting interface. In one embodiment, the turbine nozzle assembly includes a turbine nozzle flowbody, a first mounting flange configured to be mounted to the first GTE

Embodiments of a turbine nozzle assembly are provided for deployment within a gas turbine engine (GTE) including a first GTE-nozzle mounting interface. In one embodiment, the turbine nozzle assembly includes a turbine nozzle flowbody, a first mounting flange configured to be mounted to the first GTE-nozzle mounting interface, and a first radially-compliant spring member coupled between the turbine nozzle flowbody and the first mounting flange. The turbine nozzle flowbody has an inner nozzle endwall and an outer nozzle endwall, which is fixedly coupled to the inner nozzle endwall and which cooperates therewith to define a flow passage through the turbine nozzle flowbody. The first radially-compliant spring member accommodates relative thermal movement between the turbine nozzle flowbody and the first mounting flange to alleviate thermomechanical stress during operation of the GTE.

대표청구항 ▼

1. A turbine nozzle assembly for deployment within a gas turbine engine (GTE) including a first GTE-nozzle mounting interface, the turbine nozzle assembly comprising: a turbine nozzle flowbody, comprising: an inner nozzle endwall; andan outer nozzle endwall fixedly coupled to the inner nozzle endwal

1. A turbine nozzle assembly for deployment within a gas turbine engine (GTE) including a first GTE-nozzle mounting interface, the turbine nozzle assembly comprising: a turbine nozzle flowbody, comprising: an inner nozzle endwall; andan outer nozzle endwall fixedly coupled to the inner nozzle endwall and cooperating therewith to define a flow passage through the turbine nozzle flowbody;an outer mounting flange configured to be mounted to the first GTE-nozzle mounting interface; andan outer radially-compliant spring member coupled between an end portion of the outer nozzle endwall and the outer mounting flange, the outer radially-compliant spring member accommodating relative thermal movement between the turbine nozzle flowbody and the outer mounting flange to alleviate thermomechanical stress during operation of the GTE, the outer radially-compliant spring member comprising a first axially-elongated beam extending from a leading end portion of the outer nozzle endwall in a downstream direction. 2. A turbine nozzle assembly according to claim 1 wherein the outer radially-compliant spring member further comprises a second axially-elongated beam coupled between the first axially-elongated beam and the outer mounting flange. 3. A turbine nozzle assembly according to claim 2 wherein the first axially-elongated beam overlaps radially with the second axially-elongated beam. 4. A turbine nozzle assembly according to claim 2 wherein the second axially-elongated beam is integrally formed with the outer mounting flange. 5. A turbine nozzle assembly according to claim 2 wherein the first axially-elongated beam comprises a first substantially annular band generally circumscribing the outer nozzle endwall. 6. A turbine nozzle assembly according to claim 5 wherein the second axially-elongated beam comprises a second substantially annular band generally circumscribing the first substantially annular band. 7. A turbine nozzle assembly according to claim 2 wherein the GTE further comprises a second GTE-nozzle mounting interface, and wherein the turbine nozzle assembly further comprises: an inner mounting flange configured to be mounted to the second GTE-nozzle mounting interface; andan inner radially-compliant spring member coupled between the inner mounting flange and the leading end portion of the inner nozzle endwall, the inner radially-compliant spring member accommodating relative thermal movement between the inner nozzle endwall and the inner mounting flange to alleviate thermomechanical stress during operation of the GTE. 8. A turbine nozzle assembly according to claim 7 wherein the inner radially-compliant spring member comprises a third axially-elongated beam extending between the inner mounting flange and the leading end portion of the inner nozzle endwall. 9. A turbine nozzle assembly according to claim 8 wherein the inner mounting flange is axially offset from the leading edge of the inner nozzle endwall, and wherein the third axially-elongated beam extends from the leading edge of the inner nozzle sidewall in an upstream direction. 10. A turbine nozzle assembly according to claim 7 further comprising a compression seal sealingly deformed between the inner mounting flange and the inner radially-compliant spring member. 11. A turbine nozzle assembly according to claim 7 wherein the first axially-elongated beam, the second axially-elongated beam, and the third axially-elongated beam each extend along an axis substantially parallel to the longitudinal axis of the GTE. 12. A turbine nozzle assembly for deployment within a gas turbine engine (GTE) including a first GTE-nozzle mounting interface, the turbine nozzle assembly comprising: a turbine nozzle flowbody, comprising: an inner nozzle endwall; andan outer nozzle endwall fixedly coupled to the inner nozzle endwall and cooperating therewith to define a flow passage through the turbine nozzle flowbody;an outer mounting flange configured to be mounted to the first GTE-nozzle mounting interface; andan outer radially-compliant spring member coupled between an end portion of the outer nozzle endwall and the outer mounting flange, the outer radially-compliant spring member accommodating relative thermal movement between the turbine nozzle flowbody and the outer mounting flange to alleviate thermomechanical stress during operation of the GTE, the outer radially-compliant spring member comprising: a first axially-elongated beam comprising a first substantially annular band generally circumscribing the outer nozzle endwall; anda second axially-elongated beam coupled between the first axially-elongated beam and the outer mounting flange, the second axially-elongated beam comprising a second substantially annular band generally circumscribing the first substantially annular band and cooperating therewith to form a continuous 360 degree seal between the outer nozzle endwall and the outer mounting flange. 13. A turbine nozzle assembly according to claim 12 wherein the outer mounting flange comprises a substantially annular sealing surface, and wherein the turbine nozzle assembly further comprises a compression seal sealingly deformed between the substantially annular sealing surface and the first GTE-nozzle mounting interface. 14. A turbine nozzle assembly according to claim 13 wherein the outer mounting flange radially overlaps with the leading end portion of the outer nozzle endwall. 15. A turbine nozzle assembly for deployment within a gas turbine engine (GTE) including an inner GTE-nozzle mounting interface and an outer GTE-nozzle mounting interface, the turbine nozzle assembly comprising: an outer nozzle endwall;an inner nozzle endwall fixedly coupled to the outer nozzle endwall and cooperating therewith to define a flow passage through the turbine nozzle assembly;an outer mounting flange configured to be mounted to the outer GTE-nozzle mounting interface;an inner mounting flange configured to be mounted to the inner GTE-nozzle mounting interface;an outer radially-compliant spring member coupled between the outer nozzle endwall and the outer mounting flange;an inner radially-compliant spring member coupled between the inner nozzle endwall and the inner mounting flange, the inner radially-compliant spring member cooperating with the outer radially-compliant spring member to accommodate relative thermal movement between the outer nozzle endwall, the inner nozzle endwall, the outer mounting flange, and the inner mounting flange to alleviate thermomechanical stress during operation of the GTE; anda compression seal sealingly deformed between the inner mounting flange and the inner radially-compliant spring member. 16. A turbine nozzle assembly according to claim 15 wherein the outer radially-compliant spring member comprises at least one axially-elongated beam extending between an end portion of the outer nozzle endwall and the outer mounting flange along an axis substantially parallel to the longitudinal axis of the GTE, and wherein the inner radially-compliant spring member comprises at least one axially-elongated beam extending between an end portion of the inner nozzle endwall and the inner mounting flange along an axis substantially parallel to the longitudinal axis of the GTE. 17. A turbine nozzle assembly for deployment within a gas turbine engine (GTE) including an outer GTE-nozzle mounting interface, the turbine nozzle assembly comprising: an outer nozzle endwall;an inner nozzle endwall fixedly coupled to the outer nozzle endwall and cooperating therewith to define a flow passage through the turbine nozzle assembly;an outer mounting flange configured to be mounted to the inner GTE-nozzle mounting interface, the outer mounting flange having a substantially annular sealing surface;a compression seal sealingly deformed between the substantially annular sealing surface and the outer GTE-nozzle mounting interface; andan outer radially-compliant spring member comprising at least one axially-elongated beam extending between the outer nozzle endwall and the outer mounting flange, the outer radially-compliant spring member: (i) accommodating thermal movement between the turbine nozzle assembly and the outer GTE-nozzle mounting interface to alleviate thermomechanical stress during operation of the GTE, and (ii) further thermally isolating the substantially annular sealing surface of the outer mounting flange from the inner surfaces of the outer nozzle endwall to reduce the heating of the compression seal during operation of the GTE.