초록 ▼

A gas turbine engine, system, and method with clearance control are provided. For example, the gas turbine engine includes a static component, and a rotating component that shifts axially in one of an aft direction and a forward direction in relation to the static component during a first operating

A gas turbine engine, system, and method with clearance control are provided. For example, the gas turbine engine includes a static component, and a rotating component that shifts axially in one of an aft direction and a forward direction in relation to the static component during a first operating condition of the gas turbine engine, and shifts axially in the other of the aft direction and the forward direction in relation to the static component during a second operating condition of the gas turbine engine. The first operating condition is when a rotating component growth and a static component growth change at different rates. The second operating condition is when the rotating component growth and static component growth normalize.

대표청구항 ▼

1. A gas turbine engine with clearance control, the gas turbine engine comprising: a static component coupled to the gas turbine engine at a first location and configured to expand and contract without moving from the first location; anda rotating component that shifts axially in one of an aft direc

1. A gas turbine engine with clearance control, the gas turbine engine comprising: a static component coupled to the gas turbine engine at a first location and configured to expand and contract without moving from the first location; anda rotating component that shifts axially in one of an aft direction and a forward direction in relation to the static component that is maintained at the first location during a first operating condition of the gas turbine engine, and shifts axially in the other of the aft direction and the forward direction in relation to the static component that is maintained at the first location during a second operating condition of the gas turbine engine,wherein the first operating condition is when a rotating component growth and a static component growth change at different rates in response to at least one of an expansion and a contraction, andwherein the second operating condition is when the rotating component growth and static component growth normalize. 2. The gas turbine engine of claim 1, wherein the rotating component increases a clearance distance between the rotating component and the static component by shifting axially in the first operating condition; andwherein the rotating component decreases the clearance distance between the rotating component and the static component by shifting axially in the second operating condition. 3. The gas turbine engine of claim 1, wherein a backward most position in the aft direction and a forward most position in the forward direction have a maximum separation distance defined by a thrust bearing freeplay distance. 4. The gas turbine engine of claim 1, wherein the static component growth and the rotating component growth each include a mechanical expansion value and a thermal expansion value. 5. The gas turbine engine of claim 1, further comprising: a compressor that manipulates thrust balance within the compressor that shifts the rotating component axially. 6. The gas turbine engine of claim 5, further comprising: thrust balance vents that vent certain parts of the compressor, wherein venting generates axial force within the compressor that shifts the rotating component axially. 7. The gas turbine engine of claim 6, wherein the compressor comprises a plurality of rotating disks with a chamber between each of the plurality of rotating disks, andwherein the chamber on a forward side of each rotating disk has a lower pressure than the chamber on an aft side of each rotating disk that has a higher pressure. 8. The gas turbine engine of claim 7, further comprising: a higher pressure chamber that axially shifts the rotating component in the aft direction when the higher pressure chamber is vented; anda lower pressure chamber that axially shifts the rotating component in the forward direction when the lower pressure chamber is vented. 9. A system in a gas turbine engine for clearance control, the system comprising: a gas turbine engine controller including a computer processor, the gas turbine engine controller configured to determine first and second operating conditions, and that generates a clearance control signal based on operating conditions of the gas turbine engine, wherein the control signal controls axial shifts within the system;a static component coupled to the gas turbine engine at a first location and configured to expand and contract without moving from the first location; anda rotating component coupled to the gas turbine engine at a second location and that shifts axially in one of an aft direction and a forward direction in relation to the static component that is maintained at the first location during a first operating condition of the gas turbine engine in response to receiving the clearance control signal, and shifts axially in the other of the aft direction and the forward direction in relation to the static component that is maintained at the first location during a second operating condition of the gas turbine engine in response to receiving the clearance control signal,wherein the first operating condition is when a rotating component growth and a static component growth change at different rates in response to at least one of an expansion and a contraction, andwherein the second operating condition is when the rotating component growth and static component growth normalize. 10. A method for clearance control between a rotating component and a static component of a gas turbine engine, the method comprising: coupling the static component to the gas turbine engine at a first location, the static component configured to expand and contract without moving from the first location;shifting the rotating component axially in one of an aft direction and a forward direction in relation to the static component during a first operating condition of the gas turbine engine,wherein the first operating condition is when a rotating component growth and a static component growth change at different rates in response to at least one of an expansion and a contraction;determining that the first operating condition has ended and that the gas turbine engine is operating in a second operating condition during which the rotating component growth and static component growth normalize; andshifting the rotating component axially in the other of the aft direction and the forward direction in relation to the static component that is maintained at the first location during the second operating condition. 11. The method of claim 10, wherein shifting the rotating component axially in the aft direction comprises: increasing a clearance distance between the rotating component and the static component, andwherein shifting the rotating component axially in the forward direction comprises:decreasing the clearance distance between the rotating component and the static component. 12. The method of claim 11, further comprising: maintaining the clearance distance within a max threshold value and a minimum threshold value. 13. The method of claim 11, wherein a backward most position in the aft direction and a forward most position in the forward direction have a maximum separation distance defined by a thrust bearing freeplay distance. 14. The method of claim 11, wherein the rotating component comprises a high spool that includes a compressor and a turbine. 15. The method of claim 11, wherein the static component growth and the rotating component growth each include a mechanical expansion value and a thermal expansion value. 16. The method of claim 11, wherein shifting the rotating component axially comprises: manipulating thrust balance in a compressor of the gas turbine engine. 17. The method of claim 16, wherein manipulating the thrust balance comprises: venting certain parts of the compressor using thrust balance vents,wherein venting generates axial force within the compressor that shifts the rotating component axially. 18. The method of claim 17, wherein the compressor comprises a plurality of rotating disks with a chamber between each of the plurality of rotating disks,wherein a lower pressure is provided in the chamber on a forward side of each rotating disk and a higher pressure is provided in the chamber on an aft side of each rotating disk. 19. The method of claim 18, further comprising: venting a higher pressure chamber by axially shifting the rotating component in the aft direction. 20. The method of claim 18, further comprising: venting a lower pressure chamber by axially shifting the rotating component in the forward direction.