FLAME-ASSISTED FUEL CELL INTEGRATED RICH BURN, QUICK MIX, LEAN BURN COMBUSTION FOR REDUCED NOx

What is claimed is: 1 . A combustion system, comprising: a first combustion chamber having a fuel/air mixture inlet, a burner, and an exhaust for exhausting combustion products; a solid oxide fuel cell stack having a plurality of micro-tubular fuel cells coupled to the exhaust of the burner for receiving the combustion products within the plurality of micro-tubular fuel cells, electrochemically reacting the combustion products to produce electricity, and exhausting the electrochemically reacted combustion products; an air inlet extending along the first combustion chamber and solid oxide fuel cell stack to provide preheated air to the micro-tubular solid oxide fuel cell stack; an air nozzle positioned to provide and mix air with the electrochemically reacted combustion products; and a second combustion chamber associated with the micro-tubular solid oxide fuel cell stack and the air nozzle for receiving and combusting the electrochemically reacted combustion. 2 . The combustion system of claim 1 , wherein the first combustion chamber includes a housing enclosing the first combustion chamber, the solid oxide fuel cell stack, and the second combustion chamber. 3 . The combustion system of claim 2 , wherein the air inlet extending into the housing and is in communication with a passage that extends between the housing and the first combustion chamber so that any heat produced by the first combustion chamber will heat air flowing through the passage. 4 . The combustion system of claim 3 , wherein the passage extends between the housing and the solid oxide fuel cell stack so that any heated air in the passage will envelop the plurality of micro-tubular fuel cells of the solid oxide fuel cell stack. 5 . The combustion system of claim 4 , wherein the fuel air mixture inlet is adapted to provide a fuel-rich mixture for combustion within the first combustion chamber. 6 . The combustion system of claim 5 , wherein the air nozzle and solid oxide fuel cell are adapted to provide a fuel-lean mixture for combustion within the second combustion chamber. 7 . The combustion system of claim 6 , wherein the solid oxide fuel cell stack is coupled to an electrical convertor. 8 . The combustion system of claim 7 , wherein the second combustion chamber is coupled to a heat exchanger. 9 . The combustion system of claim 6 , wherein the air nozzle extends transversely into the housing between the solid oxide fuel cell and the secondary combustion chamber. 10 . The combustion system of claim 6 , wherein the air nozzle extends longitudinally into the housing through the secondary combustion chamber and terminates proximately to the solid oxide fuel cell. 11 . A method of providing reduced NOx combustion, comprising the steps of: providing a first combustion chamber having a fuel air mixture inlet, a burner, and an exhaust for exhausting combustion products, a solid oxide fuel cell stack having a plurality of micro-tubular fuel cells coupled to the exhaust of the burner for receiving the combustion products within the plurality of micro-tubular fuel cells, electrochemically reacting the combustion products to produce electricity, and exhausting the electrochemically reacted combustion products, an air inlet extending along the first combustion chamber and solid oxide fuel cell stack to provide preheated air to the micro-tubular solid oxide fuel cell stack, an air nozzle positioned to provide and mix air with the electrochemically reacted combustion products, and a second combustion chamber associated with the micro-tubular solid oxide fuel cell stack and the air nozzle for receiving and combusting the electrochemically reacted combustion; supplying a fuel-rich fuel air mixture to the fuel air mixture inlet; combusting the fuel-rich fuel air mixture in the first combustor to produce the combustion products; delivering air through the air inlet so that the air is preheated and provided to the solid oxide fuel cell; electrochemically reacting the combustion products to produce electricity and to exhaust the electrochemically reacted combustion products; delivering air through the air nozzle to mix the air with the electrochemically reacted combustion products and produce a fuel-lean fuel air mixture; and combusting the fuel-lean fuel air mixture in the second combustion chamber. 12 . The method of claim 11 , wherein the first combustion chamber includes a housing enclosing the first combustion chamber, the solid oxide fuel cell stack, and the second combustion chamber. 13 . The method of claim 12 , wherein the air inlet extends into the housing and is in communication with a passage that extends between the housing and the first combustion chamber so that heat produced by the first combustion chamber will heat air flowing through the passage. 14 . The method of claim 13 , wherein the passage extends between the housing and the solid oxide fuel cell stack so that any heated air in the passage will envelop the plurality of micro-tubular fuel cells of the solid oxide fuel cell stack. 15 . The method of claim 14 , further comprising the step of using an electrical converter to capture electrical potential generated by the solid oxide fuel cell stack. 16 . The method of claim 15 , further comprising the step of using a heat exchanger to capture heat energy in any exhaust from the second combustion chamber. 17 . The method of claim 16 , wherein the air nozzle extends transversely into the housing between the solid oxide fuel cell and the secondary combustion chamber. 18 . The method of claim 16 , wherein the air nozzle extends longitudinally into the housing through the secondary combustion chamber and terminates proximately to the solid oxide fuel cell.