초록 ▼

A fuel injector system that reduces and/or eliminates combustion instability. The fuel injector system includes a pilot fuel injector, a pilot swirler that swirls air past the pilot fuel injector, a main airblast fuel injector having an aft end, inner and outer main swirlers that swirl air past the

A fuel injector system that reduces and/or eliminates combustion instability. The fuel injector system includes a pilot fuel injector, a pilot swirler that swirls air past the pilot fuel injector, a main airblast fuel injector having an aft end, inner and outer main swirlers that swirl air past the main airblast fuel injector, and an air splitter located between the pilot swirler and the inner main swirler. The air splitter includes at least one aft end cone angled radially outboard and axially positioned downstream of the main airblast fuel injector aft end. The air splitter divides a pilot air stream exiting the pilot swirler from an inner main air stream exiting the inner main swirler to create a bifurcated recirculation zone.

대표청구항 ▼

What is claimed is: 1. A fuel injection system for a gas turbine, comprising: a pilot fuel injector; a pilot swirler that swirls air past the pilot fuel injector; a main airblast fuel injector having an aft end; inner and outer main swirlers that swirl air past the main airblast fuel injector; a

What is claimed is: 1. A fuel injection system for a gas turbine, comprising: a pilot fuel injector; a pilot swirler that swirls air past the pilot fuel injector; a main airblast fuel injector having an aft end; inner and outer main swirlers that swirl air past the main airblast fuel injector; and an air splitter located between the pilot swirler and the inner main swirler, the air splitter comprising at least one aft end cone angled radially outboard and axially positioned close to or downstream of the main airblast fuel injector aft end, the air splitter dividing an outer pilot air stream exiting the pilot swirler from an inner main air stream exiting the inner main swirler to create a bifurcated recirculation zone. 2. The fuel injection system of claim 1, wherein the pilot fuel injector is an axially located pressure atomizer. 3. The fuel injection system of claim 1 further comprising a fuel supply control system for providing fuel only to the pilot fuel injector at lower power conditions, and for providing fuel to both the pilot fuel injector and the main airblast fuel injector at higher power conditions. 4. The fuel injection system of claim 1, wherein the swirlers are constructed such that from about 5% to about 20% of total airflow is through the pilot swirler, from about 30% to about 70% of total airflow through the swirlers is through the inner main swirler, and the balance of total airflow is through the outer main swirler. 5. The fuel injection system of claim 1, wherein the at least one aft end cone is angled radially outboard at an angle in a range of about 45째 to about 75째 relative to a wall of the air splitter. 6. The fuel injection system of claim 1, wherein the at least one aft end cone is angled radially outboard at an angle about 60째 relative to a wall of the air splitter. 7. The fuel injection system of claim 1, wherein the at least one aft end cone is axially positioned at or downstream of main airblast fuel injector aft end. 8. The fuel injection system of claim 1, wherein the air splitter is made of a high temperature metal. 9. The fuel injection system of claim 8, wherein the air splitter has a thermal barrier coating layer applied thereon. 10. The fuel injection system of claim 9, wherein the thermal barrier coating layer comprises a ceramic material. 11. The fuel injection system of claim 1, wherein the air splitter cone is arranged to constrict an inner main air stream at a location downstream of a main fuel injection location. 12. A fuel injector apparatus for a gas turbine, comprising: an axially located fuel injector; a first swirler located concentrically about the axially located fuel injector; a second swirler located concentrically about the first swirler; a third swirler located concentrically about the second swirler; an airblast fuel injector located concentrically between the second and third swirlers; and an air splitter located concentrically between the first and second swirlers, the air splitter comprising at least one outboard cone axially positioned downstream of an aft end of the main airblast fuel injector. 13. The fuel injector apparatus of claim 12, wherein the swirlers are constructed such that from about 5% to about 20% of total airflow is through the first swirler, from about 30% to about 70% of total airflow through the swirlers is through the second swirler, and the balance of total airflow is through the third swirler. 14. The fuel injector apparatus of claim 12 further comprising a fuel supply control system for providing fuel only to the axially located injector at lower power conditions, and for providing fuel to both the axially located injector and the airblast fuel injector at higher power conditions. 15. The fuel injection system of claim 12, wherein the at least one outboard cone is angled radially outboard at an angle in a range of about 45째 to about 75째 relative to a wall of the air splitter. 16. The fuel injection system of claim 12, wherein the at least one outboard cone is angled radially outboard at an angle about 60째 relative to a wall of the air splitter. 17. The fuel injection system of claim 12, wherein the at least one outboard cone is axially positioned downstream of the airblast fuel injector aft end. 18. The fuel injection apparatus of claim 12, wherein the axially located fuel injector is a pressure atomizer fuel injector. 19. A method of injecting fuel into a gas turbine, comprising: injecting a pilot fuel stream; injecting a main fuel stream concentrically about the pilot fuel stream; providing a swirling pilot air stream to entrain the pilot fuel stream; providing a swirling main air stream to entrain the main fuel stream; and splitting the pilot air stream from the main air stream and creating a bifurcated recirculation zone between the pilot air stream and the main air stream, the swirling main air stream being constricted at a location where the main fuel stream is injected into the gas turbine. 20. The method of claim 18, wherein splitting the pilot air stream from the main air stream and creating a bifurcated recirculation zone further includes avoiding creation of a central recirculation zone. 21. The method of claim 18, wherein constricting the swirling main air stream at the location where the main fuel stream is injected into the gas turbine reduces or prevents the swirling main air stream from modulating with combustor pressure changes. 22. A fuel injection system for a gas turbine, comprising: an axially located fuel injector; a first swirler located concentrically about the axially located fuel injector; a second swirler located concentrically about the first swirler; a third swirler located concentrically about the second swirler; a airblast fuel injector located concentrically between the second and third swirlers; an air splitter located concentrically between the first and second swirlers, the air splitter having an aft end, and at the aft end a first cone angled radially outboard and a second cone angled radially inboard; and at least one passage for air positioned radially between an aft end of the first cone and an aft end of the second cone.