Staged fuel and air injection in combustion systems of gas turbines
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F23R-003/34
F02C-007/22
F02C-003/04
F02C-007/12
F23R-003/00
F23R-003/04
F23R-003/28
F23R-003/46
F23R-003/50
출원번호
US-0978019
(2015-12-22)
등록번호
US-9938903
(2018-04-10)
발명자
/ 주소
Hughes, Michael John
Berry, Jonathan Dwight
출원인 / 주소
General Electric Company
대리인 / 주소
Henderson, Mark E.
인용정보
피인용 횟수 :
0인용 특허 :
12
초록▼
A gas turbine including a working fluid flowpath extending aftward from a forward injector in a combustor. The combustor may include an inner radial wall, an outer radial wall, and, therebetween, a flow annulus, and a third radial wall formed about the outer radial wall that forms an outer flow annu
A gas turbine including a working fluid flowpath extending aftward from a forward injector in a combustor. The combustor may include an inner radial wall, an outer radial wall, and, therebetween, a flow annulus, and a third radial wall formed about the outer radial wall that forms an outer flow annulus. A staged injector may intersect the flow annulus so to attain an injection point within the working fluid flowpath by which aftward and forward annulus sections are defined. Air directing structure may include an aftward intake section corresponding to the aftward annulus section and a forward intake section corresponding to the forward annulus section. The air directing structure may include a switchback coolant flowpath to direct air from the compressor discharge cavity to the staged injector. The switchback coolant flowpath may include an upstream section through the flow annulus, and a downstream section through the outer flow annulus.
대표청구항▼
1. A gas turbine that comprises: a combustor coupled to a turbine that together define a working fluid flowpath, the working fluid flowpath extending aftward along a longitudinal axis from a forward end defined by a forward injector in the combustor, through an interface at which the combustor trans
1. A gas turbine that comprises: a combustor coupled to a turbine that together define a working fluid flowpath, the working fluid flowpath extending aftward along a longitudinal axis from a forward end defined by a forward injector in the combustor, through an interface at which the combustor transitions to the turbine, and then through the turbine to an aftward end defined therein, wherein the combustor includes: an inner radial wall, which defines the working fluid flowpath; an outer radial wall, which is formed outboard and about the inner radial wall such that a flow annulus is formed therebetween; and a third radial wall formed outboard and about the outer radial wall such that an outer flow annulus is formed therebetween;a compressor discharge cavity formed about the combustor for receiving a combustor air supply delivered thereto by a compressor;a staged injection system that includes the forward injector and, axially spaced aftward therefrom, a staged injector, wherein the staged injector intersects the flow annulus so to attain an injection point on the working fluid flowpath;fuel directing structure for apportioning a combustor fuel supply between the forward injector and the staged injector; andair directing structure for apportioning the combustor air supply between the forward injector and the staged injector;wherein: the air directing structure comprises a switchback coolant flowpath by which air derived from the compressor discharge cavity is directed to the staged injector;the switchback coolant flowpath comprises an upstream section, which comprises the flow annulus, and a downstream section, which comprises the outer flow annulus;the switchback coolant flowpath comprises a configuration that redirects a forward flow through the flow annulus into an aftward flow through the outer flow annulus;the switchback coolant flowpath comprises a forward port and an aftward port formed through the outer radial wall;the forward port fluidly connects the upstream section to the downstream section of the switchback coolant flowpath; andthe aftward port fluidly connects the downstream section of the switchback coolant flowpath to the staged injector. 2. The gas turbine according to claim 1, wherein the third radial wall comprises a forward end and an aftward end; andwherein:the forward end of the third radial wall encloses the forward port; andthe aftward end of the third radial wall encloses the aftward port. 3. The gas turbine according to claim 1, wherein: the aftward end of the third radial wall is axially positioned just aftward of the aftward port;the forward end of the third radial wall is axially positioned just forward of the forward port; andthe third radial wall comprises solid separating structure that fluidly isolates flow through the outer flow annulus from flow in the compressor discharge cavity. 4. The gas turbine according to claim 2, wherein the flow annulus includes an axial partition, the axial partition comprising a forward termination point of the upstream section of the switchback coolant flowpath. 5. The gas turbine according to claim 4, wherein the axial partition is forwardly spaced from the staged injector; and wherein, in attaining the injection point in the working fluid flowpath, the staged injector intersects the flow annulus through the upstream section of the switchback coolant flowpath. 6. The gas turbine according to claim 4, wherein, relative an axial position of the axial partition, the flow annulus is separated into an aftward annulus section, which is defined to an aftward side the axial partition, and a forward annulus section, which is defined to a forward side of the axial partition; and wherein the air directing structure includes axially defined intake sections formed through the outer radial wall that fluidly connect the compressor discharge cavity to corresponding axially defined sections of the flow annulus, the intake sections including an aftward intake section that corresponds to the aftward annulus section and a forward intake section that corresponds to the forward annulus section. 7. The gas turbine according to claim 6, wherein the axial partition is configured for fluidly sealing the forward annulus section from the aftward annulus section such that: all of the air of the combustor air supply flowing into the forward annulus section is directed to the forward injector; andall of the air of the combustor air supply flowing into the aftward annulus section is directed through the switchback coolant flowpath for delivery to the staged injector. 8. The gas turbine according to claim 7, wherein the axial partition comprises a wall that extends between the outer radial wall and the inner radial wall and about a circumference of the flow annulus so to seal the flow annulus against fluid communication between the aftward annulus section and the forward annulus section. 9. The gas turbine according to claim 7, wherein the combustor comprises reference planes including: a forward reference plane, a mid reference plane, an aftward reference plane, and an axial partition reference plane, each of which comprising reference planes aligned substantially perpendicular to the longitudinal axis of the working fluid flowpath, wherein: the forward reference plane aligns with the forward end of the working fluid flowpath;the aftward reference plane aligns with the interface at which the combustor transitions to the turbine;the mid reference plane aligns with an axial midpoint between of the working fluid flowpath between the forward and aftward reference plane; andthe partition reference plane aligns with the axial partition; andwherein:the aftward intake section comprises an axial range defined approximately between the partition reference plane and the aftward reference plane; andthe forward intake section comprises an axial range defined approximately between the partition reference plane and the forward reference plane. 10. The gas turbine according to claim 9, wherein: the aftward intake section comprises a plurality of spaced impingement ports, each formed through the outer radial wall for training an impinged air jet against an outer surface of the inner radial wall; andthe forward intake section comprises a plurality of spaced impingement ports, each formed through the outer radial wall for training an impinged air jet against the outer surface of the inner radial wall. 11. The gas turbine according to claim 10, wherein: the plurality of impingement ports of the aftward intake section are axially spaced between an aftward most impingement port positioned just forward of the aftward reference plane and a forward most impingement port positioned just aftward of the partition reference plane;the plurality of impingement ports of the forward intake section are axially spaced between an aftward most impingement port positioned just forward of the partition reference plane and a forward most impingement port positioned just aftward of the forward reference plane; andwherein the plurality of impingement ports of each of the aftward and the forward intake sections are spaced circumferentially about substantially all of a circumference of the outer radial wall. 12. The gas turbine according to claim 9, wherein the staged injector comprises a nozzle that intersects the flow annulus so to attain the injection point on the working fluid flowpath; and wherein the nozzle includes a tube extending between the aftward port of the switchback coolant flow path at a first end and the injection point on the working fluid flowpath at a second end. 13. The gas turbine according to claim 12, wherein the axial partition is positioned forward of the staged injector; and wherein the staged injector is positioned between the forward reference plane and the mid reference plane. 14. The gas turbine according to claim 12, wherein the axial partition is positioned forward of the staged injector; and wherein the staged injector is positioned approximately at the mid reference plane. 15. The gas turbine according to claim 12, wherein the axial partition is positioned forward of the staged injector; and wherein the staged injector is positioned approximately midway between the mid reference plane and the aftward reference plane. 16. The gas turbine according to claim 12, wherein the fuel directing structure includes: a fuel passageway extending axially from a fuel source positioned near the headend of the combustor; andfuel ports formed through the tube of the nozzle that fluidly connect the fuel passageway to the interior of the tube. 17. The gas turbine according to claim 12, wherein the combustor air supply comprises a total supply of air delivered to the compressor discharge cavity; wherein the air directing structure comprises relative orifice sizing between the aftward intake section, the forward intake section, and the headend intake section for metering the supply air to the combustor between the forward injector and the staged injector; andwherein the metering the combustor air supply includes directing at least 20% of the air supply to the combustor to the staged injector. 18. The gas turbine according to claim 12, wherein the combustor air supply comprises a total supply of air delivered to the compressor discharge cavity; wherein the air directing structure comprises relative orifice sizing between the aftward intake section, the forward intake section, and the headend intake section for metering the supply air to the combustor between the forward injector and the staged injector; andwherein the metering the combustor air supply includes directing at least 40% of the air supply to the combustor to the staged injector. 19. The gas turbine according to claim 1, wherein the combustor is configured as one of: a can-annular combustor; and an annular combustor.
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