Cooling air configuration in a gas turbine engine
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F01D-005/08
F01D-005/18
출원번호
US-0591527
(2012-08-22)
등록번호
US-9115587
(2015-08-25)
발명자
/ 주소
Zhang, Jiping
Yin, Yan
출원인 / 주소
Siemens Energy, Inc.
인용정보
피인용 횟수 :
0인용 특허 :
19
초록▼
Cooling air is provided from a source of cooling air through a cooling air circuit in a turbine section of a gas turbine engine. A first portion of cooling air is provided from the source along a first path of the circuit to a plurality of blades associated with a stage of the turbine section. A sec
Cooling air is provided from a source of cooling air through a cooling air circuit in a turbine section of a gas turbine engine. A first portion of cooling air is provided from the source along a first path of the circuit to a plurality of blades associated with a stage of the turbine section. A second portion of cooling air is provided from the source along a second path of the circuit. The second path includes a turbine disc bore where the cooling air provides cooling to a radially innermost portion of at least one turbine disc that forms a part of a rotor of the engine. The second path is independent from the first path such that the second portion of cooling air bypasses the stage and is not mixed with the first portion of cooling air in the circuit after leaving the source.
대표청구항▼
1. A method for providing cooling air from a source of cooling air through a cooling air circuit in a turbine section of a gas turbine engine, the method comprising: providing a first portion of cooling air from the source of cooling air along a first path of the cooling air circuit to a plurality o
1. A method for providing cooling air from a source of cooling air through a cooling air circuit in a turbine section of a gas turbine engine, the method comprising: providing a first portion of cooling air from the source of cooling air along a first path of the cooling air circuit to a plurality of blades associated with an upstream stage of the turbine section;providing a second portion of cooling air from the source of cooling air along a second path of the cooling air circuit, the second path including a turbine disc bore where the cooling air provides cooling to a radially innermost portion of at least one turbine disc that forms a part of a rotor of the engine, wherein the second path is independent from the first path such that the second portion of cooling air bypasses the upstream stage and is not mixed with the first portion of cooling air in the cooling air circuit after leaving the source of cooling air; andproviding a third portion of cooling air from the source of cooling air along a third path of the cooling air circuit to a plurality of blades associated with an intermediate stage of the turbine section, the intermediate stage being downstream from the upstream stage with respect to a hot gas flowpath that is defined within the turbine section and that extends generally parallel to a longitudinal axis of the engine;wherein the third path is independent from the first and second paths such that the third portion of cooling air bypasses the upstream stage and is not mixed with the first or second portions of cooling air in the cooling air circuit after leaving the source of cooling air. 2. The method according to claim 1, wherein, after passing through the turbine disc bore, the second portion of cooling air is provided to blade disc structure associated with a downstream stage of the turbine section, the downstream stage being downstream from the upstream stage with respect to the hot gas flowpath. 3. The method according to claim 1, wherein the third path includes a first cooling air cavity located axially between the source of cooling air and the blades associated with the intermediate stage. 4. The method according to claim 3, wherein: the upstream stage comprises a first stage;the intermediate stage comprises a second stage;a first allotment of the cooling air in the first cooling air cavity is provided to the blades associated with the second stage;a second allotment of the cooling air in the first cooling air cavity is provided to a second cooling air cavity for delivery to a plurality of blades associated with a third stage; anda third allotment of the cooling air in the first cooling air cavity is provided to a rotor disc cavity located radially between the first cooling air cavity and the turbine disc bore. 5. The method according to claim 1, wherein the third path includes a first rotor disc cavity located axially between the source of cooling air and the blades associated with the intermediate stage. 6. The method according to claim 5, wherein: the upstream stage comprises a first stage;the intermediate stage comprises a second stage;a first allotment of the cooling air in the first rotor disc cavity is provided to the blades associated with the second stage;a second allotment of the cooling air in the first rotor disc cavity is provided to a second rotor disc cavity for delivery to a plurality of blades associated with a third stage; anda third allotment of the cooling air in the first rotor disc cavity is provided to a cooling air cavity located radially between the first rotor disc cavity and the hot gas path. 7. The method according to claim 1, wherein the source of cooling air comprises a source cavity located radially between the turbine disc bore and the hot gas flowpath. 8. The method according to claim 7, wherein the source cavity is located directly radially inwardly from a row of turbine vanes associated with a first stage in the turbine section. 9. The method according to claim 1, further comprising providing an auxiliary portion of cooling air from the source of cooling air along an auxiliary path of the cooling air circuit, the auxiliary path including an auxiliary cavity and the turbine disc bore, wherein the auxiliary cavity is located radially inwardly from the source of cooling air, and wherein the auxiliary portion of cooling air flows through the turbine disc bore with the second portion of cooling air. 10. A method for providing cooling air from a source of cooling air through a cooling air circuit in a turbine section of a gas turbine engine, the method comprising: providing a first portion of cooling air from the source of cooling air along a first path of the cooling air circuit to an upstream stage of the turbine section;providing a second portion of cooling air from the source of cooling air along a second path of the cooling air circuit, the second path including a turbine disc bore where the cooling air provides cooling to at least one turbine disc that forms a part of a rotor of the engine, wherein the second path is independent from the first path such that the second portion of cooling air bypasses the upstream stage and is not mixed with the first portion of cooling air in the cooling air circuit after leaving the source of cooling air; andproviding a third portion of cooling air from the source of cooling air along a third path of the cooling air circuit to downstream stage of the turbine section, the downstream stage being located downstream from the upstream stage with respect to a hot gas flowpath that is defined within the turbine section and that extends generally parallel to a longitudinal axis of the engine, wherein the third path is independent from the first and second paths such that the third portion of cooling air bypasses the upstream stage and is not mixed with the first or second portions of cooling air in the cooling air circuit after leaving the source of cooling air. 11. The method according to claim 10, wherein: the third path includes a first cooling air cavity located axially between the source of cooling air and blades associated with the downstream stage;a first allotment of the cooling air in the first cooling air cavity is provided to the blades associated with the downstream stage;a second allotment of the cooling air in the first cooling air cavity is provided to a second cooling air cavity for delivery to a plurality of blades associated with a further downstream stage; anda third allotment of the cooling air in the first cooling air cavity is provided to a rotor disc cavity located radially between the first cooling air cavity and the turbine disc bore. 12. The method according to claim 11, wherein the upstream stage comprises a first stage, the downstream stage comprises a second stage, and the further downstream stage comprises a third stage. 13. The method according to claim 12, wherein, after passing through the turbine disc bore, the second portion of cooling air is provided to blade disc structure associated with a final stage of the turbine section, the final stage being downstream from the first, second, and third stages with respect to the hot gas flowpath. 14. The method according to claim 10, wherein: the third path includes a first rotor disc cavity located axially between the source of cooling air and blades associated with the downstream stage;a first allotment of the cooling air in the first rotor disc cavity is provided to the blades associated with the downstream stage;a second allotment of the cooling air in the first rotor disc cavity is provided to a second rotor disc cavity for delivery to a plurality of blades associated with a further downstream stage; anda third allotment of the cooling air in the first rotor disc cavity is provided to a cooling air cavity located radially between the first rotor disc cavity and the hot gas path. 15. The method according to claim 14, wherein, after passing through the turbine disc bore, the second portion of cooling air is provided to blade disc structure associated with a final stage of the turbine section, the final stage being downstream from the upstream, downstream, and further downstream stages with respect to the hot gas flowpath. 16. The method according to claim 15, further comprising providing an auxiliary portion of cooling air from the source of cooling air along an auxiliary path of the cooling air circuit, the auxiliary path including an auxiliary cavity and the turbine disc bore, wherein the auxiliary cavity is located radially inwardly from the source of cooling air. 17. The method according to claim 16, wherein the auxiliary portion of cooling air flows through the turbine disc bore and to the blade disc structure associated with the final stage of the turbine section with the second portion of cooling air. 18. The method according to claim 10, wherein the source cavity is located directly radially inwardly from a row of turbine vanes associated with the upstream stage in the turbine section. 19. The method according to claim 10, wherein the first portion of cooling air is provided to a plurality of blades associated with the upstream stage, the second portion of cooling air provides cooling to a radially innermost portion of the at least one turbine disc, and the third portion of cooling air is provided to a plurality of blades associated with the downstream stage.
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이 특허에 인용된 특허 (19)
Kervistin Robert (Le Mee sur Seine FRX), Assembly for controlling the flow of cooling air in an engine turbine.
Andersen Richard H. (Cincinnati OH) Dins Carl R. (Cincinnati OH) Herzner Frederick C. (Fairfield OH), Bore vane assembly for use with turbine discs having bore entry cooling.
Scalzo Augustine J. (Philadelphia PA) Gunderlock Richard P. (Chester Township PA), Rotor disk, blade, and seal plate assembly for cooled turbine rotor blades.
Reigel James R. (Cincinnati OH) Corsmeier Robert J. (Cincinnati OH) Bertke James H. (Cincinnati OH) Lenahan Dean T. (Cincinnati OH), Turbine cooling air transferring apparatus.
Quinones Armando J. (Cincinnati OH) Rieck ; Jr. Harold P. (West Chester OH) Albrecht Richard W. (Fairfield OH) Sullivan Michael A. (Ballston Spa NY) Weisgerber Robert H. (Loveland OH) Plemmons Larry , Turbine disk cooling system.
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