Fuel cell spacer and electrolyte reservoir

I claim: 1. A fuel cell device, comprising: a cell stack assembly including a plurality of fuel cells that each include an anode and a cathode; a pressure plate near one end of the cell stack assembly; and an electrically conductive component between the end of the cell stack assembly and the pressure plate, the electrically conductive component having a length, a width and a height, the height defining a spacing between the pressure plate and the end of the cell stack assembly, the length being greater than the height, the width being greater than the height, the electrically conductive component having a plurality of ribs that define at least two fluid reservoirs, at least one of the ribs separating the at least two fluid reservoirs so that fluid in one of the at least two fluid reservoirs is isolated from fluid in the other of the at least two fluid reservoirs. 2. The fuel cell device of claim 1 , wherein the plurality of ribs includes a set of strengthening ribs that define cavities within the at least two reservoirs; a plurality of channels are respectively associated with at least some of the strengthening ribs; and the channels allow fluid to pass between cavities within a respective one of the at least two reservoirs. 3. The fuel cell device of claim 2 , wherein the strengthening ribs have a rib height that corresponds to a depth of the respective one of the at least two reservoirs. 4. The fuel cell device of claim 1 , wherein the at least two reservoirs are open toward the pressure plate; and a body of the electrically conductive component isolates the at least two reservoirs from the end of the cell stack assembly. 5. The fuel cell device of claim 1 , wherein the fuel cells are liquid electrolyte fuel cells; and the at least two reservoirs contain some of the liquid electrolyte. 6. The fuel cell device of claim 5 , wherein the liquid electrolyte comprises phosphoric acid. 7. The fuel cell device of claim 1 , comprising a manifold configured to deliver a reactant to the fuel cells and wherein the manifold includes a portion adjacent the electrically conductive component; and wherein the at least two reservoirs are respectively in fluid communication with the portion of the manifold. 8. The fuel cell device of claim 7 , wherein a first one of the at least two reservoirs is in fluid communication with a first section of the manifold through which a first turn of fuel cell fuel passes; and a second one of the at least two reservoirs is in fluid communication with a second section of the manifold through which a second turn of fuel cell fuel passes. 9. The fuel cell device of claim 8 , wherein the plurality of ribs includes an outer edge rib for each of the at least two reservoirs; the outer edge rib for the first one of the at least two reservoirs includes at least one channel through which fluid may pass between the first section of the manifold and the first one of the at least two reservoirs; and the outer edge rib for the second one of the at least two reservoirs includes at least one channel through which fluid may pass between the second section of the manifold and the second one of the at least two reservoirs. 10. The fuel cell device of claim 1 , wherein the height of the electrically conductive component is less than 40 mm. 11. The fuel cell device of claim 10 , wherein the height of the electrically conductive component is between 35 mm and 20 mm. 12. The fuel cell device of claim 1 , wherein the electrically conductive component is a spacer that is configured to carry electrical current from the cell stack assembly to the pressure plate. 13. The fuel cell device of claim 12 , wherein the spacer comprises graphite. 14. A fuel cell device, comprising: a cell stack assembly including a plurality of fuel cells that each include an anode and a cathode; a pressure plate near one end of the cell stack assembly; a component between the end of the cell stack assembly and the pressure plate, the component having a length, a width and a height, the height defining a spacing between the pressure plate and the end of the cell stack assembly, the length being greater than the height, the width being greater than the height, the component having a plurality of ribs that define at least two fluid reservoirs, at least one of the ribs separating the at least two fluid reservoirs so that fluid in one of the at least two fluid reservoirs is isolated from fluid in the other of the at least two fluid reservoirs; a manifold configured to deliver a reactant to the fuel cells, the manifold including a portion adjacent the component, and the at least two reservoirs are respectively in fluid communication with the portion of the manifold; wherein a first one of the at least two reservoirs is in fluid communication with a first section of the manifold through which a first turn of fuel cell fuel passes; and wherein a second one of the at least two reservoirs is in fluid communication with a second section of the manifold through which a second turn of fuel cell fuel passes. 15. The fuel cell device of claim 14 wherein the plurality of ribs includes an outer edge rib for each of the at least two reservoirs; the outer edge rib for the first one of the at least two reservoirs includes at least one channel through which fluid may pass between the first section of the manifold and the first one of the at least two reservoirs; and the outer edge rib for the second one of the at least two reservoirs includes at least one channel through which fluid may pass between the second section of the manifold and the second one of the at least two reservoirs. 16. The fuel cell device of claim 14 , wherein the component is an electrically conductive spacer configured to carry electrical current from the cell stack assembly to the pressure plate. 17. The fuel cell device of claim 14 , wherein the plurality of ribs includes a set of strengthening ribs that define cavities within the at least two reservoirs; a plurality of channels are respectively associated with at least some of the strengthening ribs; and the channels allow fluid to pass between cavities within a respective one of the at least two reservoirs. 18. The fuel cell device of claim 17 , wherein the strengthening ribs have a rib height that corresponds to a depth of the respective one of the at least two reservoirs. 19. The fuel cell device of claim 14 , wherein the at least two reservoirs are open toward the pressure plate; and a body of the component isolates the at least two reservoirs from the end of the cell stack assembly. 20. The fuel cell device of claim 14 , wherein the fuel cells are phosphoric acid fuel cells; and the at least two reservoirs contain some of the phosphoric acid.