Cooling arrangement using an electrochemical cell

I claim: 1. An electric power generator cooling method, the method comprising: introducing a fluid stream containing gaseous hydrogen and impurities into an electrochemical cell comprising a polymer electrolyte membrane through which hydrogen ions are transported, an anode plate having anode channels and a cathode plate having cathode channels, wherein at least one the anode plate and the cathode plate include coolant channels connected to a coolant loop, wherein the polymer electrolyte membrane is hydrated through the coolant channels; maintaining a pressure of coolant in the coolant channels at a lower pressure than a pressure of a gas in either of the anode channels or the cathode channels; providing a refined supply of hydrogen from the fluid stream introduced into the electrochemical cell by using the electrochemical cell to remove the impurities and provide the refined supply of hydrogen in a more refined state than the fluid stream introduced into the electrochemical cell; communicating the refined supply of hydrogen to an electric power generator; moving the refined supply of hydrogen through the electric power generator whereby thermal energy is removed from the electric power generator via direct contact of the refined supply of hydrogen with the electric power generator and whereby impurities are introduced into the refined supply of hydrogen; communicating the fluid stream containing gaseous hydrogen and impurities directly from the electric power generator to the electrochemical cell and purifying hydrogen within the fluid stream using the electrochemical cell to provide the refined supply of hydrogen; and venting the impurities. 2. The electric power generator cooling method of claim 1 , including storing the refined supply of hydrogen before moving the refined supply of hydrogen through the electric power generator to remove thermal energy from the electric power generator. 3. The electric power generator cooling method of claim 1 wherein the coolant in the coolant channels is water flowing near the polymer electrolyte membrane. 4. The electric power generator cooling method of claim 1 further comprising: communicating a first portion of thermal energy away from the electric power generator, the communicating including exhausting the first portion of thermal energy via a line directly connected to the electric power generator; and communicating a second portion of thermal energy away from the electric power generator to the electrochemical cell. 5. The electric power generator cooling method of claim 4 wherein communicating the second portion of thermal energy includes communicating the second portion of thermal energy to a heat exchanger in fluid communication with the electrochemical cell. 6. An electric power generator cooling method, the method comprising: routing a stream of hydrogen gas with impurities entrained therein from an electric power generator to an electrochemical hydrogen pump having a polymer electrolyte membrane through which hydrogen ions are transported and having plates with coolant channels through which the polymer electrolyte membrane is hydrated, the coolant channels connected to a coolant loop, wherein pressure of water flowing in the coolant channels is maintained at a lower pressure than pressure of gas in anode and cathode channels of the electrochemical hydrogen pump; operating the electrochemical hydrogen pump to remove the impurities and to generate a refined stream of hydrogen gas in a more refined state than the stream of hydrogen gas with impurities routed to the electrochemical hydrogen pump; routing the refined stream of hydrogen gas from the electrochemical hydrogen pump through the electric power generator whereby thermal energy is removed from the electric power generator via direct contact of the refined stream of hydrogen gas with the electric power generator and whereby impurities are introduced into the refined stream of hydrogen gas to generate the stream of hydrogen gas with impurities to be routed to the electrochemical hydrogen pump to be refined; monitoring at least one of purity, temperature, and pressure of the refined stream of hydrogen gas in the electric power generator with a hydrogen control system in communication with the electric power generator and having a controller in communication with the electrochemical hydrogen pump and the electric power generator; and adjusting via the electrochemical hydrogen pump a corresponding at least one of purity, temperature, and pressure of the refined stream of hydrogen gas in the electric power generator based at least in part on the monitoring. 7. The electric power generator cooling method of claim 6 , further comprising: storing the refined stream of hydrogen gas before routing the refined stream of hydrogen gas through the electric power generator to remove thermal energy from the electric power generator. 8. The electric power generator cooling method of claim 6 , wherein adjusting the at least one of purity, temperature and pressure of the refined stream of hydrogen gas based at least in part on said monitoring includes at least one of the following: increasing the stream of hydrogen gas routed to the electrochemical hydrogen pump to be refined; increasing a generation rate of the refined stream of hydrogen gas generated by the electrochemical hydrogen pump; increasing the pressure of the refined stream of hydrogen gas generated by the electrochemical hydrogen pump; and increasing the purity of the refined stream of hydrogen gas generated by the electrochemical hydrogen pump. 9. An electric power generator cooling method, the method comprising: routing a stream of hydrogen gas with impurities entrained therein directly from an electric power generator to an electrochemical cell, the electrochemical cell having a polymer electrolyte membrane, first and second catalyst layers adjacent opposing sides of the polymer electrolyte membrane, an anode plate adjacent the first catalyst layer and having anode channels, and a cathode plate adjacent the second catalyst layer and having cathode channels, wherein at least one of the anode plate and cathode plate includes coolant channels; hydrating the polymer electrolyte membrane via the anode or cathode plate via a coolant loop in fluid communication with the coolant channels; maintaining a pressure of water flowing in the coolant channels at a lower pressure than a pressure of a gas in either of the anode channels or cathode channels; operating the electrochemical cell to remove the impurities and to generate a refined stream of hydrogen gas in a more refined state than the stream of hydrogen gas with impurities routed to the electrochemical cell, wherein operating the electrochemical cell to remove the impurities includes venting the impurities via a vent directly connected to the electrochemical cell; routing the refined stream of hydrogen gas from the electrochemical cell through the electric power generator whereby thermal energy is removed from the electric power generator via direct contact of the refined stream of hydrogen gas with the electric power generator and whereby impurities are introduced into the refined stream of hydrogen gas to generate the stream of hydrogen gas with impurities to be routed directly to the electrochemical hydrogen pump to be refined; monitoring at least one of purity, temperature, and pressure of the refined stream of hydrogen gas in the electric power generator with a hydrogen control system; and adjusting a corresponding at least one of purity, temperature, and pressure of the refined stream of hydrogen gas in the electric power generator based at least in part on the monitoring. 10. The electric power