Trapped vortex combustor for a gas turbine engine with a driver airflow channel

What is claimed is: 1. A trapped vortex combustor for use in a gas turbine engine, the trapped vortex combustor defining an axial direction, a radial direction, and a circumferential direction relative to a centerline of the gas turbine engine, the trapped vortex combustor comprising: an outer vortex chamber, comprising: an outer vortex chamber wall extending axially from a forward end to an aft end and comprising an inner surface; a dome extending radially inwardly from, and formed integrally with, the forward end of the outer vortex chamber wall; a transition wall extending radially inward from the aft end of the outer vortex chamber wall; a first annular wall extension extending from a radial inner end of the transition wall; and a second annular wall extension extending radially inward from the outer vortex chamber wall, wherein a first annular lip extends axially aft from the dome to define, at least in part, a first annular channel between the first annular lip and the outer vortex chamber wall, wherein the first annular channel extends along the circumferential direction at the forward end of the outer vortex chamber wall, wherein the first annular channel is configured to receive a primary first channel airflow from a primary first channel airflow opening through one of the outer vortex chamber wall or the dome, and provide such primary first channel airflow as a continuous annular airflow to the inner surface of the outer vortex chamber wall, wherein the dome further defines a fuel nozzle opening, wherein all openings in the dome outward of the fuel nozzle opening along the radial direction, excepting any effusion cooling holes having a diameter less than 0.035 inches, are in airflow communication with the first annular channel, wherein the outer vortex chamber is configured to receive a total amount of airflow during operation, the total amount of airflow generating a single vortex airflow within the outer vortex chamber, wherein at least 13.5 percent of the total amount of airflow is provided through the first annular channel, wherein at least an end portion of the first annular wall extension is parallel to the transition wall, wherein the transition wall comprises a transition wall opening, wherein the transition wall opening directly faces the first annular wall extension such that a transition wall airflow therethrough is redirected by the first annular wall extension in the radial direction toward the outer vortex chamber wall, wherein the second annular wall extension and the transition wall define, at least in part, a second annular channel therebetween, wherein the second annular channel is configured to receive a second channel airflow from a second channel airflow opening through the outer vortex chamber wall, and direct such second channel airflow toward the first annular wall extension, and wherein the primary first channel airflow opening, the second channel airflow opening, and the transition wall opening, are configured to generate the single vortex airflow within the outer vortex chamber as a rotating vortex, which rotates aft from the first annular channel toward the transition wall, radially inward toward the first annular wall extension, forward toward the dome, and returns radially outward toward the first annular channel. 2. The trapped vortex combustor of claim 1 , further comprising: an inner combustion chamber liner and an outer combustion chamber liner together defining a combustion chamber, wherein the outer vortex chamber is positioned upstream of the combustion chamber. 3. The trapped vortex combustor of claim 1 , wherein the first annular channel includes a secondary first channel airflow opening formed in the other of the dome or the outer vortex chamber wall different from the one of the dome or the outer vortex chamber wall in which the primary first channel airflow opening is formed, the secondary first channel airflow opening being in airflow communication with the first annular channel for providing a secondary first channel airflow to the first annular channel. 4. The trapped vortex combustor of claim 3 , wherein the primary first channel airflow opening and the secondary first channel airflow opening are offset from each other in the axial direction perpendicular to the radial direction and the circumferential direction. 5. The trapped vortex combustor of claim 1 , wherein at least fifteen percent of the total amount of airflow is provided through the first annular channel. 6. The trapped vortex combustor of claim 1 , wherein the first annular channel extends continuously three hundred and sixty degrees about the centerline of the gas turbine engine. 7. The trapped vortex combustor of claim 1 , wherein the first annular channel is an outer channel, and wherein the trapped vortex combustor further comprises: an inner vortex chamber, comprising: an inner vortex chamber wall extending axially from a forward end to an aft end and comprising an inner surface, wherein the dome extends radially outward from the forward end of the inner vortex chamber wall, wherein an inner annular lip extends axially aft from the dome to define, at least in part, an inner annular channel between the inner annular lip and the inner vortex chamber wall, wherein the inner annular channel extends along the circumferential direction at the forward end of the inner vortex chamber wall, and wherein the inner annular channel is configured to receive an inner channel airflow through an inner channel airflow opening through one of the inner vortex chamber wall, or the dome, and provide such inner channel airflow as a continuous annular airflow to the inner surface of the inner vortex chamber wall. 8. The trapped vortex combustor of claim 7 , wherein the fuel nozzle opening of the dome is an outer fuel nozzle opening, wherein the dome further defines an inner fuel nozzle opening, and wherein all openings in the dome inward of the inner fuel nozzle opening along the radial direction, excepting any effusion cooling holes having a diameter less than 0.035 inches, are in airflow communication with the inner annular channel. 9. The trapped vortex combustor of claim 7 , wherein the inner annular channel extends continuously three hundred and sixty degrees about the centerline of the gas turbine engine. 10. The trapped vortex combustor of claim 1 , wherein the first annular channel is an outer channel defining an outlet, wherein the trapped vortex combustor further comprises: an inner vortex chamber, comprising: an inner vortex chamber wall extending axially from a forward end to an aft end, wherein the dome extends radially outward from the forward end of the inner vortex chamber wall, wherein an inner annular lip extends axially aft from the dome to define, at least in part, an inner annular channel between the inner annular lip and the forward end of the inner vortex chamber wall, wherein the inner annular channel defines an outlet, wherein the trapped vortex combustor defines a cavity height between the outer vortex chamber wall at the outlet of the outer channel and the inner vortex chamber wall at the outlet of the inner annular channel, wherein the outer channel further defines a maximum height from the first annular lip to the outer vortex chamber wall, and wherein the maximum height of the outer channel is between two percent and eight percent of the cavity height. 11. The trapped vortex combustor of claim 1 , wherein the first annular channel is an outer channel defining an outlet, wherein the trapped vortex combustor further comprises: an inner vortex chamber, comprising: an inner vortex chamber wall extending axially fr