Fluidic burner with heat stability

What is claimed is: 1. A burner apparatus, comprising (A) a burner body having: a central passageway within the burner body having an upstream end and an axially opposed downstream end which opens at a downstream end of the burner, wherein the cross-sectional diameter of the central passageway increases in the direction toward the downstream end; a plurality of first ports in the downstream end of the burner which are located substantially evenly around the downstream end of the central passageway, wherein the first ports are connected by first passageways within the body of the burner to one or more inlets through which a first fluid can be fed, and a plurality of second ports in the downstream end of the burner which are located substantially evenly around the downstream end of the central passageway, wherein the second ports are connected by second passageways within the body of the burner to one or more inlets through which a second fluid can be fed, the first and second passageways being separate from each other; wherein the first ports and the second ports are substantially uniformly distant from the central axis of the central passageway; wherein the plurality of first ports and the plurality of second ports are located in the inner surface of the central passageway upstream from the downstream end of the central passageway; and wherein the central passageway, the first ports, and the second ports, are the only openings in the burner apparatus through which fluid can flow out of the downstream end of the burner apparatus; (B) a fluidic cavity communicating at the downstream end thereof with the upstream end of the central passageway of the burner, said fluidic cavity having a diameter D at said point of communication sufficient to enable fluid passing therethrough to have a supersonic velocity, said central passageway having a length from said point of communication to its downstream end of from 2D to 9D; (C) a plurality of biasing gas passageways through which biasing gas can be fed into the fluidic cavity in a direction substantially perpendicular to the axial centerline of the fluidic cavity, said passageways having a diameter d such that d/D is within the range of from 0.18 to 0.75, said passageways communicating with the fluidic cavity at a point within the range of from 3d/4 upstream to d/4 downstream of the point of communication between the fluidic cavity and the upstream end of the central passageway, where D and d are expressed in the same units; and (D) a housing which surrounds the downstream end of the burner and which is open at the end of the housing that surrounds the downstream end of the burner, wherein the open end of the housing is located a distance L downstream from the downstream end of the burner, wherein L is at least 25% of the distance across the open end of the housing, wherein the portion of the housing that extends downstream of the downstream end of the burner comprises passageways therein through which coolant can flow to absorb heat generated by combustion occurring at the burner. 2. The burner apparatus of claim 1 wherein the biasing gas outlets are positioned to provide biasing gas into the fluidic cavity at or upstream of the point of communication between the fluidic cavity and the upstream end of the central passageway. 3. The burner apparatus of claim 2 wherein the number of biasing gas outlets is 2 to 8. 4. The burner apparatus of claim 1 wherein d/D is within 0.18 to 0.25. 5. The burner apparatus of claim 1 wherein the surface of the central passageway forms an angle of 10 to 30 degrees with its central axis. 6. The burner apparatus of claim 1 wherein said central passageway has a length from said point of communication to its downstream end of from 3D to 9D. 7. The burner apparatus of claim 6 wherein the central passageway has an inner surface which is curved. 8. The burner apparatus of claim 6 wherein the central passageway has an inner surface which is conical. 9. The burner apparatus of claim 6 wherein the biasing gas outlets are positioned to provide biasing gas into the fluidic cavity at or upstream of the point of communication between the fluidic cavity and the upstream end of the central passageway. 10. The burner apparatus of claim 6 wherein d/D is within 0.18 to 0.25. 11. The burner apparatus of claim 6 wherein the surface of the central passageway forms an angle of 10 to 30 degrees with its central axis. 12. A method of combustion, comprising: (A) feeding fuel out of the downstream end of a burner according to claim 1 through the first ports of the burner; (B) feeding gaseous oxidant out of the downstream end of the burner through the second ports of the burner; (C) feeding gaseous oxidant through the fluidic cavity of the aforesaid burner and through and out of the downstream end of the central passageway of the burner, wherein the gaseous oxidant flows through the fluidic cavity at a velocity of at least 400 feet per second to establish a reduced pressure zone adjacent a portion of the surface of the central passageway; (D) combusting the fuel and the gaseous oxidant; and (E) periodically or continually, injecting a stream of biasing gas having a diameter d into the fluidic cavity in a direction substantially perpendicular to the flow direction of the gaseous oxidant passing through the fluidic cavity at a point within the range of from 3d/4 upstream to d/4 downstream of the point of communication between the fluidic cavity and the central passageway, where D and d are measured in the same units, thereby changing the flow direction of the gaseous oxidant passing out of the downstream end of the central passageway. 13. The method of claim 12 wherein the biasing gas comprises oxygen. 14. The method of claim 12 wherein the flow rate of the biasing gas is 0.5 to 4.0 percent of the flow rate of the oxidant through the central passageway. 15. The method of claim 12 wherein the biasing gas is injected into the fluidic cavity at or upstream of the point of communication between the restricted flow area and the upstream end of the central passageway. 16. The method of claim 12 wherein the gaseous oxidant flows through the fluidic cavity at a velocity of at least 500 feet per second to establish a reduced pressure zone adjacent a portion of the surface of the central passageway. 17. The method of claim 16 wherein the biasing gas comprises oxygen. 18. The method of claim 16 wherein the flow rate of the biasing gas is 0.5 to 3.0 percent of the flow rate of the oxidant through the central passageway. 19. The method of claim 16 wherein the biasing gas is injected into the fluidic cavity at or upstream of the point of communication between the restricted flow area and the upstream end of the central passageway. 20. The burner apparatus of claim 1 wherein the central passageway has an inner surface which is curved.