Recharger for hydrogen fuel cells

The invention claimed is: 1. A recharger comprising: a fuel container having multiple fuel rods and a humid air inlet, wherein the fuel rods are disposed in selectively permeable membranes, wherein the fuel container has an outlet that provides hydrogen generated from the fuel rods to recharge multiple removable hydrogen-rechargeable power generators, and wherein the multiple removable hydrogen-rechargeable power generators each has its own hydrogen storage and has a shape corresponding to a form factor of primary alkaline or lithium batteries; a manifold attached to the outlet, wherein the manifold includes multiple output ports to receive the multiple removable hydrogen-rechargeable power generators and to distribute the hydrogen for storage in the multiple removable hydrogen-rechargeable power generators, wherein each output port includes an independently actuated valve; a hydrogen pump coupled to the manifold to provide pressurized hydrogen to the removable hydrogen-rechargeable power generators; a vacuum pump coupled to the manifold and adapted to remove air from the multiple removable hydrogen-rechargeable power generators prior to providing hydrogen to the removable hydrogen-rechargeable power generators; control electronics adapted to control the hydrogen pump, to control the vacuum pump, and to control each independently actuated valve within the manifold; and an internal fuel cell coupled to receive generated hydrogen and provide power to the control electronics, the hydrogen pump, the vacuum pump, and a fan. 2. The recharger of claim 1 , wherein the hydrogen pump is coupled to the manifold to provide pressurized hydrogen to the multiple removable hydrogen-rechargeable power generators. 3. The recharger of claim 2 , wherein the vacuum pump is coupled to the manifold and adapted to remove air from the manifold prior to the hydrogen pump providing hydrogen to the multiple removable hydrogen-rechargeable power generators. 4. The recharger of claim 3 , wherein the control electronics are adapted to control the hydrogen pump and vacuum pump. 5. The recharger of claim 1 wherein the fuel rods comprise chemical hydride fuel rods, and wherein the humid air inlet is positioned to receive ambient humid air. 6. The recharger of claim 1 wherein the fuel container further comprises a fan positioned to draw humid air in the humid air inlet, pass the humid air by the fuel rods, and vent dry air via an air outlet in the fuel container. 7. The recharger of claim 1 wherein the fuel rods are arranged in a series of fins. 8. The recharger of claim 7 wherein the fuel rods produce hydrogen at pressure. 9. The recharger of claim 7 wherein the fins create a large surface area for passive transport of water vapor from the surrounding air past the fins. 10. The recharger of claim 1 wherein the fuel rods comprise LiAlH4. 11. The recharger of claim 1 wherein the manifold comprises at least one heat sink for each hydrogen-rechargeable power generator. 12. A recharger comprising: a power generator manifold including: an input to attach to a hydrogen generating module; and multiple output ports shaped to receive multiple removable hydrogen-rechargeable power generators and to distribute hydrogen for storage in the multiple removable hydrogen-rechargeable power generators, each output port including an independently actuated power generator manifold valve; wherein the multiple removable hydrogen-rechargeable power generators each has its own hydrogen storage and has a shape corresponding to a form factor of primary alkaline or lithium batteries; a vacuum pump coupled to the power generator manifold to evacuate the multiple removable hydrogen-rechargeable power generators prior to providing hydrogen to the removable hydrogen-rechargeable power generators; a vacuum valve coupled to the power generator manifold between the vacuum pump and the input of the power generator manifold; and a controller adapted to control the vacuum pump, to control each power generator manifold valve, and to control the vacuum valve, the controller including: an internal fuel cell coupled to receive generated hydrogen and to provide power to the controller; and a rechargeable battery coupled to the internal fuel cell. 13. The recharger of claim 12 , and further including the hydrogen generating module that further includes a plurality of replaceable fuel source modules, each fuel source module including an independently actuated fuel source valve, wherein the controller further controls each independently actuated fuel source valve. 14. The recharger of claim 13 , further including: a hydrogen pump controlled by the controller and coupled to the hydrogen generating module and to the first power generator manifold; and a fuel source manifold coupled to the hydrogen-generating module and to the hydrogen pump. 15. The recharger of claim 1 , further including a pressure sensor coupled to the manifold to provide pressure data to the control electronics, the pressure data representative of a negative vacuum pressure and of a positive hydrogen-filling pressure. 16. The recharger of claim 15 , wherein the control electronics, pressure sensor, and each independently actuated valve within the manifold are configured to: individually vacuum test the multiple removable hydrogen-rechargeable power generators for damage by causing the vacuum pump to apply a vacuum while the pressure sensor monitors negative vacuum pressure; and individually pressure test the multiple removable hydrogen-rechargeable power generators for completion of hydrogen charging by causing the hydrogen pump to provide hydrogen while the pressure sensor monitors positive hydrogen pressure.