Fuel cell system with waste heat recovery for production of high pressure steam

What is claimed is: 1. A fuel cell system for generating electrical power and high level heat comprising: at least one high temperature fuel cell stack having an anode side and a cathode side and configured to generate electrical power; an exhaust recuperator configured to cool anode exhaust output from the anode side of the at least one fuel cell stack, and to pre-heat an input oxidant gas using heat in the anode exhaust; a heat exchanger configured to receive the pre-heated input oxidant gas from the exhaust recuperator and to receive cathode exhaust from the cathode side of the at least one high temperature fuel cell stack, and further pre-heat the input oxidant gas using heat in the cathode exhaust output from the cathode side of the at least one high temperature fuel cell stack; and an anode gas oxidizer/high level heat recovery assembly comprising: an anode gas oxidizer configured to oxidize anode gas received from the exhaust recuperator using the input oxidant gas that was pre-heated by both the exhaust recuperator and the heat exchanger, and to output high temperature oxidant gas at a temperature in a range of 537.8 to 1093.3° C. (1000 to 2000° F.), and a high level heat recovery system configured to receive the high temperature oxidant gas from the anode gas oxidizer, to recover high level heat from the high temperature oxidant gas, and to output high temperature oxidant gas to the cathode side of the at least one high temperature fuel cell stack. 2. The fuel cell system in accordance with claim 1 , wherein the high level heat recovery system comprises a boiler configured to receive feed water and to generate high pressure high temperature steam using the high level heat generated by the anode gas oxidizer. 3. The fuel cell system in accordance with claim 1 , further comprising: a conditioner/cooler configured to recover water from the anode exhaust and to output water-separated anode exhaust, wherein the gas derived from the anode exhaust includes the water-separated anode exhaust. 4. The fuel cell system in accordance with claim 3 , wherein the exhaust recuperator is further configured to pre-heat the water-separated anode exhaust and to output the heated water-separated anode exhaust to the anode gas oxidizer. 5. The fuel cell system in accordance with claim 2 , further comprising a fuel processing assembly for processing input fuel before supplying the processed fuel to the at least one high temperature fuel cell stack, the fuel processing assembly including a humidifier/heat exchanger assembly configured to humidify the input fuel using one or more of water and a first portion of the high pressure high temperature steam generated in the boiler and to pre-heat humidified fuel using waste heat from oxidant exhaust output by the at least one high temperature fuel cell stack. 6. The fuel cell system in accordance with claim 5 , further comprising a conditioner/cooler configured to recover water from the anode exhaust and to output recovered water to the humidifier/heat exchanger assembly for humidifying the input fuel and to output water-separated anode exhaust for use in the anode gas oxidizer. 7. The fuel cell system in accordance with claim 5 , further comprising an expander assembly configured to expand the first portion of the high pressure high temperature steam and to output lower pressure steam to the humidifier/heat exchanger assembly while generating power from the expansion process, wherein the power generated by the expander assembly is output from the fuel cell system or used within the fuel cell system. 8. The fuel cell system in accordance with claim 7 , further comprising an air blower for supplying the input oxidant gas to the fuel cell system, wherein the air blower is directly coupled with the expander assembly so that the power generated by the expander assembly is directly used by the air blower. 9. The fuel cell system in accordance with claim 1 , wherein the high level heat recovery system provides high level heat to one or more of: a fuel reforming assembly, a refinery coker unit, a heavy oil distillation unit and an expander. 10. A method of generating electrical power and high level heat using a fuel cell system comprising the steps of: operating at least one high temperature fuel cell stack having an anode side and a cathode side so as to generate electrical power; and using an exhaust recuperator, cooling the anode exhaust output from the anode side of the at least one high temperature fuel cell stack, and pre-heating an input oxidant gas using at least heat in the anode exhaust, using a heat exchanger, receiving the pre-heated input oxidant gas from the exhaust recuperator and receiving cathode exhaust from the cathode side of the at least one high temperature fuel cell stack, and further pre-heating the input oxidant gas using heat in the cathode exhaust output from the cathode side of the at least one high temperature fuel cell stack; and using an anode gas oxidizer of an anode gas oxidizer/high level heat recovery assembly, oxidizing anode gas received from the exhaust recuperator using the input oxidant gas that was pre-heated by both the exhaust recuperator and the heat exchanger, and outputting high temperature oxidant gas at a temperature in a range of 537.8 to 1093.3° C. (1000 to 2000° F.), and using a high level heat recovery system of the anode gas oxidizer/high level heat recovery assembly, receiving the high temperature oxidant gas from the anode gas oxidizer, recovering high level heat from the high temperature oxidant gas, and outputting high temperature oxidant gas to the cathode side of the at least one high temperature fuel cell stack. 11. The method in accordance with claim 10 , wherein the step of recovering high level heat comprises generating high pressure high temperature steam from feed water by directly using the high level heat generated in the oxidizing step. 12. The method in accordance with claim 10 , further comprising recovering water from the anode exhaust to output water-separated anode exhaust, wherein the gas derived from the anode exhaust includes the water-separated anode exhaust. 13. The method in accordance with claim 12 , further comprising pre-heating the water-separated anode exhaust using the heat in the anode exhaust while pre-heating the input oxidant gas using the heat in the anode exhaust, and providing the heated water-separated anode exhaust for use in the oxidizing step. 14. The method in accordance with claim 11 , further comprising processing input fuel before supplying processed fuel to the at least one high temperature fuel cell stack, the processing step including humidifying the input fuel using one or more of water and a first portion of the high pressure high temperature steam generated in the generating step and pre-heating humidified fuel using waste heat from oxidant exhaust output by the at least one high temperature fuel cell stack. 15. The method in accordance with claim 14 , further comprising recovering water from the anode exhaust, outputting recovered water for humidifying the input fuel in the processing step and outputting water-separated anode exhaust for use in the oxidizing step. 16. The method in accordance with claim 14 , further comprising expanding a first portion of the high pressure high temperature steam generated in the generating step and outputting lower pressure steam for humidifying the input fuel in the processing step while generating power from the expansion process, wherein the power generated in the expanding step from the expansion process is output for external use or