Assemblies and apparatus related to integrating late lean injection into combustion turbine engines
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02C-001/00
F23R-003/06
F23R-003/28
F23R-003/34
F23R-003/60
출원번호
US-0204369
(2011-08-05)
등록번호
US-9010120
(2015-04-21)
발명자
/ 주소
DiCintio, Richard Martin
Melton, Patrick Benedict
Stoia, Lucas John
출원인 / 주소
General Electric Company
대리인 / 주소
Henderson, Mark E.
인용정보
피인용 횟수 :
7인용 특허 :
67
초록▼
A transfer tube for use in a late lean injection system of a combustor, wherein the combustor includes an inner radial wall, which defines a primary combustion chamber downstream of a primary fuel nozzle, and an outer radial wall, which surrounds the inner radial wall forming a flow annulus therebet
A transfer tube for use in a late lean injection system of a combustor, wherein the combustor includes an inner radial wall, which defines a primary combustion chamber downstream of a primary fuel nozzle, and an outer radial wall, which surrounds the inner radial wall forming a flow annulus therebetween, the outer radial wall including a late lean nozzle, the transfer tube including flow directing structure that defines a fluid passageway. At a first end, the flow directing structure may include an inlet and attachment means that attach the transfer tube to the late lean nozzle. The flow directing structure may have a configuration such that the fluid passageway spans the flow annulus and positions the outlet at a desirable injection point in the inner radial wall.
대표청구항▼
1. A transfer tube for use in a late lean injection system of a combustor of a combustion turbine engine, wherein the combustor includes an inner radial wall, which defines a primary combustion chamber downstream of a primary fuel nozzle, and an outer radial wall, which surrounds the inner radial wa
1. A transfer tube for use in a late lean injection system of a combustor of a combustion turbine engine, wherein the combustor includes an inner radial wall, which defines a primary combustion chamber downstream of a primary fuel nozzle, and an outer radial wall, which surrounds the inner radial wall forming a flow annulus therebetween, the outer radial wall including a late lean nozzle, the transfer tube comprising: flow directing structure that defines a fluid passageway;wherein: at a first end, the flow directing structure includes an inlet rigidly connected to the late lean nozzle;at a second end, the flow directing structure includes an outlet; andthe flow directing structure comprises a configuration such that the fluid passageway spans the flow annulus and positions the outlet at a desirable injection point in the inner radial wall;the desirable injection point comprises a position along an inner wall surface of the inner radial wall, and the flow directing structure comprises a tube having a predetermined length, the predetermined length corresponding with the distance between the late lean nozzle and the desirable injection point;at the second end, the transfer tube comprises a configuration that slidably and snuggly engages a boss installed through the inner radial wall, the boss defining a hollow passageway through the inner radial wall;further comprising a stop positioned at a predetermined location toward the second end of the transfer tube;wherein the stop comprises a rigid section of enlargement that is larger than the hollow passageway defined by the boss, the section of enlargement being configured to arrest further withdrawal of the transfer tube from the inner radial wall once the section of enlargement contacts the boss. 2. The transfer tube according to claim 1, wherein the inner radial wall comprises a liner and the outer radial wall comprises a flow sleeve. 3. The transfer tube according to claim 1, wherein the inner radial wall comprises a transition piece and the outer radial wall comprises an impingement sleeve. 4. The transfer tube according to claim 2, wherein the flow directing structure is configured to fluidly connect the inlet and the outlet and, in operation, separate a first fluid flowing through the flow directing structure from a second fluid flowing through the flow annulus. 5. The transfer tube according to claim 4, wherein the flow directing structure comprises a flange that surrounds the inlet. 6. The transfer tube according to claim 5, wherein the flange includes a plurality of threaded openings configured to engage bolts that originate from the late lean nozzle, each of the threaded openings being configured such that engagement of the bolts draw the flange toward the late lean nozzle. 7. The transfer tube according to claim 6, wherein the flange includes a compression seat against which a corresponding surface of the late lean nozzle may be drawn when the bolts are fully engaged. 8. The transfer tube according to claim 6, wherein the flow directing structure comprises a narrowing ledge just inside of the inlet; and wherein the narrowing ledge is configured to provide a compression seat against which an edge of a projecting ring formed on the late lean nozzle may be drawn when the bolts are fully engaged. 9. The transfer tube according to claim 6, wherein an inner surface of the flow sleeve comprises an outer radial boundary of the flow annulus, and wherein the inner surface of the flow sleeve comprises a surface contour; wherein an outer face of the flange comprises a surface contour; andwherein the surface contour of the outer face of the flange is configured to correspond to the surface contour of the inner surface of the flow sleeve. 10. The transfer tube according to claim 9, wherein the surface contour of the outer flange is configured such that, when the engagement of the bolts draws the flange against the flow sleeve, substantially all of the outer face of the flange is drawn tightly against the inner surface of the flow sleeve. 11. The transfer tube according to claim 9, wherein the flow directing structure comprises a cylindrical tube; wherein the inlet and the outlet comprise a circular shape; andwherein the flow sleeve and the liner each comprises a circular cross-sectional shape. 12. The transfer tube according to claim 11, wherein an edge of the transfer tube at the outlet comprises a surface contour that corresponds to the contour of the inner wall surface of the liner such that the outlet resides approximately flush in relation to the inner wall surface of the liner. 13. The transfer tube according to claim 11, wherein an edge of the transfer tube at the outlet comprises a surface contour that corresponds to the contour of the inner wall surface of the liner such that the outlet resides uniformly recessed in relation to the inner wall surface of the liner. 14. The transfer tube according to claim 2, wherein the flow sleeve includes a longitudinally extending fuel passage formed therein that supplies fuel to the late lean nozzle embedded within the flow sleeve. 15. The transfer tube according to claim 2, further comprising a stop positioned at a predetermined location toward the second end of the transfer tube; wherein the stop comprises a rigid section of enlargement that is larger than the hollow passageway defined by the boss, the section of enlargement being configured to arrest further withdrawal of the transfer tube from the liner once the section of enlargement contacts the boss. 16. The transfer tube according to claim 15, wherein the predetermined location of the stop comprises one at which, when the section of the enlargement contacts the boss: i) the outlet of the transfer tube comprises the desirable injection point, and ii) the first end of the transfer tube protrudes from the liner a predetermined distance. 17. The transfer tube according to claim 16, wherein the predetermined distance that the first end of the transfer tube protrudes from the liner comprises a distance that results in the first end of the transfer tube engaging the late lean nozzle in a desired manner. 18. The transfer tube according to claim 6, wherein the late lean nozzle comprises a cylindrical configuration that defines a hollow passageway through the flow sleeve; wherein a plurality of fuel outlets are formed on an inner surface of the cylindrical configuration. 19. The transfer tube according to claim 2, wherein the late lean injection system comprises a system for injecting a mixture of fuel and air within the aft end of the primary combustion chamber defined by the liner; and wherein the flow annulus is configured to carry a supply of compressed air toward a forward end of the combustor. 20. A transfer tube for use in a late lean injection system of a combustor of a combustion turbine engine, wherein the combustor includes an inner radial wall, which defines a primary combustion chamber downstream of a primary fuel nozzle, and an outer radial wall, which surrounds the inner radial wall forming a flow annulus therebetween, the outer radial wall including a late lean nozzle, the transfer tube comprising flow directing structure that defines a fluid passageway; wherein: at a first end, the flow directing structure includes an inlet rigidly connected to the late lean nozzle;at a second end, the flow directing structure includes an outlet;the flow directing structure comprises a configuration such that the fluid passageway spans the flow annulus and positions the outlet at a desirable injection point in the inner radial wall that comprises a position along an inner wall surface of the liner;the flow directing structure comprises a tube having a predetermined length, the predetermined length corresponding with the distance between the late lean nozzle and the desirable injection point;at the second end, the transfer tube comprises a configuration that slidably and snugly engages a boss installed through the liner, the boss defining a hollow passageway through the liner;the flow directing structure is configured to fluidly connect the inlet and the outlet and, in operation, separate a first fluid flowing through the flow directing structure from a second fluid flowing through the flow annulus;the flow directing structure comprises a flange that surrounds the inlet, the flange includes a plurality of threaded openings configured to engage bolts that originate from the late lean nozzle, each of the threaded openings being configured such that engagement of the bolts draw the flange toward the late lean nozzle; andthe flow directing structure comprises a narrowing ledge just inside of the inlet, the narrowing ledge being configured to provide a compression seat against which an edge of a projecting ring formed on the late lean nozzle may be drawn when the bolts are engaged.
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