Combustor having a main chamber and one or more trapped vortex cavities

The invention claimed is: 1 . A combustor for a turbine engine, the combustor comprising: a main chamber including an outer liner and an inner liner; one or more trapped vortex cavities extending from at least one of the outer liner or the inner liner; a plurality of mixing assemblies configured to inject fuel and air into the one or more trapped vortex cavities to generate a fuel-air mixture in the one or more trapped vortex cavities, the combustor configured to combust the fuel-air mixture to produce combustion gases in the one or more trapped vortex cavities, the one or more trapped vortex cavities providing the combustion gases to the main chamber; and a steam system in fluid communication with the main chamber, the steam system including one or more steam injectors, wherein the one or more steam injectors are in flow communication with the plurality of mixing assemblies, and at least one of the one or more steam injectors configured to provide steam to at least one of the one or more trapped vortex cavities to supply the steam to the combustor, to reduce nitrogen oxide emissions and to reduce a specific fuel consumption of the turbine engine. 2 . The combustor of claim 1 , further comprising an annular dome positioned at a forward end of the outer liner or the inner liner, the annular dome located upstream of the main chamber, and an air injector located in the annular dome configured to inject compressed air in the axial direction into the main chamber, wherein a water-to-air ratio of the steam and the compressed air in the main chamber is zero percent to sixty percent (0% to 60%). 3 . The combustor of claim 1 , wherein the one or more trapped vortex cavities define one or more trapped vortex cavity openings, the one or more trapped vortex cavity openings defined by an opening in one of the outer liner or the inner liner, such that the one or more trapped vortex cavities are in fluid communication with the main chamber, and the one or more trapped vortex cavities are configured to inject the combustion gases through the one or more trapped vortex cavity openings into the main chamber. 4 . The combustor of claim 1 , wherein each trapped vortex cavity is located radially above or radially below the main chamber. 5 . The combustor of claim 1 , further comprising an annular dome positioned at a forward end of the outer liner or the inner liner. 6 . The combustor of claim 5 , wherein the one or more steam injectors include a first steam injector disposed through the annular dome to inject the steam into the main chamber. 7 . A method of operating the combustor of claim 1 , the method comprising: injecting, using the plurality of mixing assemblies, the fuel and the air into the one or more trapped vortex cavities to generate the fuel-air mixture in the one or more trapped vortex cavities, the fuel-air mixture being combusted in the combustor to produce the combustion gases in the one or more trapped vortex cavities, the one or more trapped vortex cavities providing the combustion gases to the main chamber; providing the steam system in fluid communication with the main chamber, the steam system including the one or more steam injectors, wherein the one or more steam injectors are in flow communication with the plurality of mixing assemblies, and at least one of the one or more steam injectors providing the steam to at least one of the one or more trapped vortex cavities to supply the steam to the combustor; mixing the combustion gases with the steam to generate a steam-combustion gases mixture; and causing the steam-combustion gases mixture to flow downstream of the one or more trapped vortex cavities, to reduce the nitrogen oxide emissions and to reduce the specific fuel consumption of the turbine engine. 8 . The method of claim 7 , wherein mixing the combustion gases with the steam to generate the steam-combustion gases mixture takes place in the one or more trapped vortex cavities. 9 . The method of claim 7 , further comprising injecting the steam such that a water-to-air ratio is zero percent to thirty percent (0% to 30%) during a low-power operation of the combustor, the water-to-air ratio is one percent to forty percent (1% to 40%) during a mid-power operation, and the water-to-air ratio is two percent to sixty percent (2% to 60%) during a high-power operation. 10 . The combustor of claim 1 , wherein the steam system generates steam from exhaust of the turbine engine. 11 . A combustor for a turbine engine, the combustor comprising: a main chamber including an outer liner and an inner liner; an annular dome positioned at a forward end of the outer liner or the inner liner, the annular dome located upstream of the main chamber; one or more trapped vortex cavities located downstream of the annular dome and upstream of the main chamber, the one or more trapped vortex cavities extending from at least one of the outer liner or the inner liner, each of the one or more of the trapped vortex cavities including an inner wall located between the inner liner and the outer liner in the radial direction, the inner wall extending axially downstream from the annular dome; a plurality of mixing assemblies configured to inject fuel and air into the one or more trapped vortex cavities to generate a fuel-air mixture in the one or more trapped vortex cavities, the combustor configured to combust the fuel-air mixture to produce combustion gases in the one or more trapped vortex cavities, the one or more trapped vortex cavities providing the combustion gases to the main chamber; and a steam system in fluid communication with the main chamber, the steam system including one or more liner steam holes in the outer liner, the inner liner, or both the outer liner and the inner liner, and at least one of the one or more liner steam holes providing steam to the main chamber to supply the steam to the combustor, to reduce nitrogen oxide emissions and to reduce a specific fuel consumption of the turbine engine. 12 . The combustor of claim 11 , further comprising an air orifice located in a forward end of the annular dome configured to direct compressed air in the axial direction into the one or more trapped vortex cavities, or the main chamber, or both, wherein a water-to-air ratio of the steam and the compressed air in the main chamber is zero percent to sixty percent (0% to 60%). 13 . The combustor of claim 11 , wherein the one or more trapped vortex cavities define one or more trapped vortex cavity openings, the one or more trapped vortex cavity openings defined by an opening in one of the outer liner or the inner liner, such that the one or more trapped vortex cavities are in fluid communication with the main chamber, and the one or more trapped vortex cavities are configured to inject the combustion gases through the one or more trapped vortex cavity openings into the main chamber. 14 . The combustor of claim 11 , wherein the main chamber is defined downstream of the one or more trapped vortex cavities. 15 . The combustor of claim 11 , wherein the outer liner and the inner liner are angled towards each other to define a converging nozzle. 16 . The combustor of claim 11 , wherein a plurality of fuel injectors extends radially inwards or radially outwards from at least one of the inner wall or a combustor outer case, the combustor outer case located radially outwards of the inner liner and the outer liner, the plurality of fuel injectors configured to inject the fuel radially into each trapped vortex cavity to generate a fuel stream within each trapped vortex cavity.