Abstract: An apparatus includes a plurality of islands each carrying multiple cantilevers. The apparatus also includes a fluidic network having a plurality of channels separating the islands. The channels are configured to provide fluid to the islands, and the fluid at least partially fills spaces between the cantilevers and the islands. Heat from the islands vaporizes the fluid filling the spaces between the cantilevers and the islands to transfer the heat away from the islands while driving the cantilevers into oscillation. The apparatus may also include a casing configured to surround the islands and the fluidic network to create a vapor chamber, where the vapor chamber is configured to retain the vaporized fluid. The islands and the fluidic network could be formed in a single substrate, or the islands could be separate and attached together by a binder located within the channels of the fluidic network.

Abstract: A fuel cell based power generator exhibits a plurality of different power outputs. A selection structure carried by the generator facilitates specification of a desired output power.

Abstract: A power generator comprising a hydrogen generator and a fuel cell stack having an anode exposed to hydrogen from the hydrogen generator and a cathode exposed to an ambient environment. Hydrophobic and hydrophilic layers are used to promote flow of water away from the cathode. A diffusion path thus separates the fuel cell cathode from the hydrogen generator. In one embodiment, water vapor generated from the fuel cell substantially matches water used by the hydrogen generator to generate hydrogen.

Abstract: A hydrogen producing fuel comprises a chemical hydride and metal hydride. In one embodiment the chemical hydride evolves hydrogen spontaneously upon exposure to water vapor, and the metal hydride reversibly absorbs/desorbs hydrogen based on temperature and pressure. The hydrogen producing substance may be formed in the shape of a pellet and may be contained within a hydrogen and water vapor permeable, liquid water impermeable membrane.

Abstract: A hydrogen producing fuel comprises a chemical hydride and metal hydride. In one embodiment the chemical hydride evolves hydrogen spontaneously upon exposure to water vapor, and the metal hydride reversibly absorbs/desorbs hydrogen based on temperature and pressure. The hydrogen producing substance may be formed in the shape of a pellet and may be contained within a hydrogen and water vapor permeable, liquid water impermeable membrane. The hydrogen producing substance may further be soaked in a hydrophobic material.

Abstract: A recharger includes a manifold having an input to couple to a hydrogen generating module and an output port to couple to at least one rechargeable fuel cell. A vacuum pump is coupled to the manifold to evacuate the manifold. A valve is coupled to the manifold between the vacuum pump and the input of the manifold.

Abstract: A fuel source for an electrochemical cell includes two or more chemical hydride pellets, a flexible, porous, liquid water impermeable, hydrogen and water vapor permeable membrane in contact with and at least partially surrounding each hydride pellet, and a porous metal hydride layer positioned between each hydride pellet. Air gaps are between each pellet.

Abstract: A device and method of forming a power generator includes a container, a fuel cell stack within the container, a metal hydride hydrogen producing fuel within the container, wherein the fuel cell stack is sandwiched between the container and an anode support surrounding the fuel and in close thermal contact with the fuel. The fuel cell stack has a cathode electrode for exposure to oxygen and an anode electrode for exposure to hydrogen. A cathode is electrically coupled to the cathode electrode of the fuel cell stack and supported by the container such that at least a portion of it is exposed on an outside of the container. An anode is electrically coupled to the anode electrode of the fuel cell stack and supported by the container such that at least a portion of it is exposed on the outside of the container spaced apart from the exposed cathode.

Abstract: An example fuel cell assembly may include a shaped fuel source that is formed into a desired shape. The shaped fuel source may have an outer surface, and a fuel cell may be mounted directly on the outer surface of the shaped fuel source. In some instances, the fuel cell assembly may also include one or more of a cathode cap, an anode cap, a refill port, and an outer shell disposed around an exterior of the fuel cell assembly, but these are not required.

Abstract: An example fuel cell assembly may include a proton exchange membrane (or membrane electrode assembly) that has a first major surface and a second major surface. An anode electrode, which may include a patterned metal layer with a plurality of apertures extending through the patterned metal layer, may also be provided. An anode gas diffusion layer secured to an anode adhesive frame may be situated between the anode electrode and the first major surface of the proton exchange membrane. A cathode electrode may, in some instances, include a patterned metal layer with a plurality of apertures extending through the patterned metal layer. A cathode gas diffusion layer secured to a cathode adhesive frame may be situated between the cathode electrode and the second major surface of the proton exchange membrane. In some instances a fuel cell assembly may be flexible so that the fuel cell assembly can be rolled into a rolled configuration that defines an inner cavity with open ends.

Abstract: A portable fuel cell charger has a water source and an electrolyzer coupled to the water source and adapted to be coupled to a power source. A fuel cell cartridge coupler is coupled to the electrolyzer and is adapted to be coupled to a fuel cell cartridge for providing pressurized hydrogen from the electrolyzer to the fuel cell cartridge.

Abstract: A power generator comprising a hydrogen generator and a fuel cell stack having an anode exposed to hydrogen from the hydrogen generator and a cathode exposed to an ambient environment. Hydrophobic and hydrophilic layers are used to promote flow of water away from the cathode. A diffusion path thus separates the fuel cell cathode from the hydrogen generator. In one embodiment, water vapor generated from the fuel cell substantially matches water used by the hydrogen generator to generate hydrogen.

Abstract: Improved portable power sources such as batteries, fuel cells, power generators and the like can include structure or apparatus that are adapted to provide an indication of the power capacity remaining within the portable power source. In some cases, these power sources may be configured to accommodate remote communication regarding their remaining power capacity.

Abstract: An apparatus includes a power source configured to provide power to one or more external components. The power source includes one or more metallization layers. At least one of the one or more metallization layers is configured as an antenna for transmitting or receiving wireless signals. The power source could include a hydrogen generator configured to produce hydrogen gas and a fuel cell configured to generate an electrical current using the hydrogen gas. The hydrogen generator could include a fuel for producing the hydrogen gas and a selectively permeable membrane surrounding the fuel. The fuel cell could include a first electrode surrounding the selectively permeable membrane, a proton exchange membrane surrounding the first electrode, and a second electrode surrounding the proton exchange membrane. The hydrogen generator may be configured to produce the hydrogen gas using water, and the power source may consume only oxygen gas and optionally water vapor from an ambient environment.

Abstract: Improved portable power sources such as batteries, fuel cells, power generators and the like can include structure or apparatus that are adapted to provide an indication of the power capacity remaining within the portable power source. In some cases, these power sources may be configured to accommodate remote communication regarding their remaining power capacity.

Abstract: Embodiments of the present invention relate to a power generator comprising one or more fuel cells and a fuel, wherein the fuel comprises an alkali metal silicide.

Abstract: A device has an annulus having a first end and a second end. A valve plate is coupled to the first end of the annulus by a fastener, wherein the valve plate is adapted to contact a valve seat on a hydrogen producing fuel cover. A diaphragm is coupled to the second end of the annulus by a fastener, wherein the annulus extends through a container for holding the hydrogen producing fuel and wherein the diaphragm moves the valve plate relative to the valve seat responsive to a different in pressure across the diaphragm.

Abstract: A method includes assembling a top portion of a proton exchange membrane fuel cell based power generator that includes an anode cover, fuel cell, top portion of a valve assembly and fuel container cover. A bottom portion of the power generator that includes a fuel container with fuel, an opening for the top portion of the valve assembly, and a diaphragm portion of the valve assembly is also assembled. The top portion of the power generator is then attached to the bottom portion such that the bottom portion is a cathode of the power generator.

Abstract: A portable, calibratible gas detector includes a multi-position gas inflow limiting orifice. When this orifice is in a calibrating position, a source of calibrating gas can be activated to provide a quantity of gas that diffuses into ambient atmosphere flowing through the orifice. The calibration gas can then be sensed.

Abstract: A nanoresonator device with high quality factor and method for fabricating the same is disclosed herein. The nanoresonator device generally includes an input electrode, an output electrode, a nanoresonator anchored at its motionless nodal points of its resonance modes by support beam(s) and/or anchor. The nanoresonator device can be fabricated on various wafers including a silicon on insulator (SOI) wafer, which includes an insulating layer and a heavily doped silicon layer. The nano structures with high quality factor can be patterned on a film utilizing nano fabrication tools and the patterned structures can be utilized as a mask to form permanent nano structures on the silicon layer by reactive ion etching (RIE). The insulating layer can be removed to form the anchor beams and a cavity by wet etching utilizing an etching solution.