Distributed combustion process and burner

What is claimed is: 1. A burner for performing distributed combustion, comprising: a burner block having a first face adapted to face away from a combustion space and a second face adapted to face towards a combustion space; a fuel/oxidant nozzle extending from the first face to the second face, the fuel/oxidant nozzle comprising an inner tube concentrically disposed within an outer tube, the fuel/oxidant nozzle adapted to inject fuel and primary oxidant into a furnace along a fuel injection axis; first and second dynamical lances equally spaced from the fuel/oxidant nozzle and extending from the first face to the second face, each of the first and second dynamical lances comprising: a main body with an inlet end adjacent the first face and a terminal end facing the second face, extending through the main body from the first face of the burner block to the main body terminal end are a secondary oxidant injection channel and an actuating fluid injection channel, the actuating fluid injection channel being disposed on a side of the secondary oxidant injection channel away from the fuel/oxidant nozzle; and a cap disposed over the main body terminal end, the cap having a mating end adapted to mate with the main body terminal end and a terminal end adjacent the second face, the cap further having an opening in the cap terminal end that is sized to correspond to an inner diameter of the outer tube and is adapted to allow a jet of secondary oxidant to emerge from the secondary oxidant injection channel and out of the terminal end opening, wherein the cap is configured to provide fluid communication between the actuating fluid injection channel and the cap terminal end and is adapted to allow a jet of actuating fluid to impinge against a jet of secondary oxidant from the secondary oxidant injection channel to angle the jet of secondary oxidant away from the fuel injection axis. 2. The burner of claim 1 , wherein: each of the caps further comprises a cavity in fluid communication between the respective actuating fluid injection channel and cap terminal opening; and the actuating fluid injection channels, secondary oxidant injection channels, cavities, and terminal openings are configured and adapted such that the jet of actuating fluid impinges against the jet of secondary oxidant before the secondary oxidant exits the terminal opening. 3. The burner of claim 1 , wherein: each of the caps further comprises a hole extending between the respective actuating fluid injection channel and the cap terminal end; and the actuating fluid injection channels, secondary oxidant injection channels, holes, and terminal openings are configured and adapted such that the jet of actuating fluid impinges against the jet of secondary oxidant after the secondary oxidant exits the terminal opening. 4. The burner of claim 1 , wherein each of the secondary oxidant injection channels extends along an axis forming an angle to the fuel injection axis. 5. The burner of claim 1 , wherein each of the secondary oxidant injection channels extends along an axis parallel to the fuel injection axis. 6. A burner system, comprising the burner of claim 1 , a source of fuel in fluid communication with the fuel/oxidant nozzle, and a source of oxidant in fluid communication with the fuel/oxidant nozzle and the dynamical lances. 7. The burner system of claim 6 , wherein the fuel is fuel oil. 8. The burner system of claim 6 , wherein the fuel is pulverized coal that is fluidized with a conveying gas of air or recycled flue gas. 9. The burner system of claim 6 , wherein the fuel is natural gas. 10. The burner system of claim 1 , wherein each of the first and second dynamical lances is oriented parallel to the fuel injection axis. 11. The burner system of claim 1 , wherein each of the first and second dynamical lances is oriented at an angle away from the fuel injection axis.