System for managing hydrogen utilization in a fuel cell power plant

We claim: 1. A fuel cell power plant, comprising: a plurality of cell stack assemblies each including a plurality of fuel cells comprising anodes and cathodes; a power plant anode inlet configured for carrying fuel toward the anodes of the plurality of fuel cells of the plurality of cell stack assemblies; a power plant anode outlet configured for carrying fluid away from the anodes of the plurality of fuel cells of the plurality of cell stack assemblies; a first hydrogen concentration sensor configured to provide an indication of a first concentration of hydrogen in a fluid flowing into the power plant anode inlet; a second hydrogen concentration sensor configured to provide an indication of a second concentration of hydrogen in a fluid flowing out of the power plant anode outlet; at least one third hydrogen concentration sensor configured to provide an indication of a third concentration of hydrogen associated with the anodes of the plurality of fuel cells of at least one of the plurality of cell stack assemblies; and a processor configured to determine: a utilization of hydrogen by the fuel cell power plant based on the first concentration of hydrogen and the second concentration of hydrogen, a utilization of hydrogen by the at least one of the plurality of cell stack assemblies based on the first concentration of hydrogen and the third concentration, and whether the utilization of hydrogen by the fuel cell power plant and the utilization of hydrogen by the at least one of the plurality of cell stack assemblies are respectively within a preselected range, wherein the processor is configured to provide an indication at least when at least one of the utilization of hydrogen by the fuel cell power plant and the utilization of hydrogen by the at least one of the cell stack assemblies is outside the preselected range, wherein the preselected range is based on at least one predetermined relationship between a power output of the fuel cell power plant and hydrogen utilization. 2. The fuel cell power plant of claim 1 , wherein the indication comprises an alarm indicating fuel starvation if the at least one of the utilization of hydrogen by the fuel cell power plant and the utilization of hydrogen by the at least one of the plurality of cell stack assemblies is above a threshold percentage. 3. The fuel cell power plant of claim 1 , wherein the processor determines the utilization of hydrogen by the fuel cell power plant based on the formula: (first concentration of hydrogen−second concentration of hydrogen)/(first concentration of hydrogen×(1−second concentration of hydrogen)); and the processor determines the utilization of hydrogen by the at least one of the plurality of cell stack assemblies based on the formula: (first concentration of hydrogen−third concentration of hydrogen)/(first concentration of hydrogen×(1−third concentration of hydrogen)). 4. The fuel cell power plant of claim 1 , wherein the at least one third hydrogen concentration sensor is configured to provide an indication of the third concentration of hydrogen from an anode outlet of the at least one of the plurality of cell stack assemblies. 5. The fuel cell power plant of claim 1 , comprising a plurality of third hydrogen concentration sensors associated with the plurality of cell stack assemblies, wherein the plurality of third hydrogen concentration sensors are each configured to provide an indication of the third concentration of hydrogen of one of the plurality of cell stack assemblies; and wherein the processor determines a utilization of hydrogen by each of the plurality of cell stack assemblies based on respective indications from the plurality of third hydrogen concentration sensors. 6. The fuel cell power plant of claim 1 , wherein the processor controls an amount of fuel containing hydrogen provided to the power plant anode inlet based on at least one of the utilizations of hydrogen. 7. The fuel cell power plant of claim 6 , comprising a fuel reformer and wherein the processor controls operation of the fuel reformer based on at least one of the utilizations of hydrogen. 8. The fuel cell power plant of claim 6 , wherein the processor increases an amount of fuel containing hydrogen provided to the power plant anode inlet when at least one of the utilizations of hydrogen is above a preselected range. 9. The fuel cell power plant of claim 1 , wherein the processor shuts down the at least one of the plurality of cell stack assemblies when the utilization of hydrogen by the at least one of the plurality of cell stack assemblies is outside a preselected range; and the processor shuts down the power plant when the utilization of hydrogen by the power plant is outside a preselected range. 10. The fuel cell power plant of claim 1 , wherein each hydrogen concentration sensor comprises: a hydrogen chamber configured to isolate hydrogen within the hydrogen chamber from a gas outside the hydrogen chamber; a hydrogen evolving electrode configured to generate pure hydrogen within the hydrogen chamber; a reference electrode configured to be exposed to pure hydrogen within the hydrogen chamber; and a detection electrode associated with the reference electrode, the detection electrode being configured to be exposed to the gas outside the hydrogen chamber, the detection electrode being further configured to provide an indication of a concentration of hydrogen in the gas outside the hydrogen chamber. 11. The fuel cell power plant of claim 10 , wherein the hydrogen evolving electrode introduces a positive pressure within the hydrogen chamber. 12. The fuel cell power plant of claim 11 , wherein the hydrogen chamber comprises a vent; and the positive pressure within the hydrogen chamber prevents the gas outside the hydrogen chamber from entering the hydrogen chamber through the vent. 13. The fuel cell power plant of claim 10 , wherein the hydrogen evolving electrode is part of a first electrochemical cell; and the reference electrode and the detection electrode are part of a second electrochemical cell. 14. The fuel cell power plant of claim 13 , wherein the first electrochemical cell comprises a first matrix containing an electrolyte; the first electrochemical cell comprises a hydrogen oxidizing electrode; the first matrix is at least partially situated between the hydrogen oxidizing electrode and the hydrogen evolving electrode; and a voltage is applied across the hydrogen evolving electrode and the hydrogen oxidizing electrode. 15. The fuel cell power plant of claim 14 , wherein the second electrochemical cell includes a second matrix containing an electrolyte; the second matrix is at least partially situated between the reference electrode and the detection electrode; and a voltage across the reference electrode and the detection electrode provides the indication of the concentration of hydrogen in the gas outside the hydrogen chamber. 16. The fuel cell power plant of claim 15 , wherein the electrolyte in the first matrix and the electrolyte in the second matrix each comprise phosphoric acid. 17. The fuel cell power plant of claim 1 , wherein the first hydrogen concentration sensor is positioned within the fluid flowing into the power plant anode inlet and the second hydrogen concentration sensor is positioned within the fluid flowing out of the power plant anode exit. 18. The fuel cell power plant of claim 10 , wherein no current passes at the reference electrode. 19. The fuel cell power plant of claim 1 , wherein the at least one predet