Abstract: The disclosure relates to plate-fin and manifold assemblies for heat exchangers. In some examples, an assembly includes a first plate and a second plate. The assembly also includes a plurality of fins disposed between the first plate and the second plate. In addition, the plurality of fins are spaced apart by a width large enough adapted for counter-flow of a plurality of fluids between adjacent fins of the plurality of fins. Further, the plurality of fins are configured to direct fluid flow across a length of the first plate and the second plate.

Abstract: The disclosure relates to fin inserts for heat and mass exchangers and corresponding methods. For instance, in some examples, a fin insert to a heat and mass exchanger includes a generally rigid, longitudinally-extending member that includes a top portion and side portions. The side portions may be disposed on opposite sides of the top portion, and may include a concave shape facing away from one another. The side portions may further are each be positioned around a portion of a respective heat transfer tube.

Abstract: A method of producing a mycological composite material comprises inoculating a substrate of fibrous material with an inoculum of mycelial tissue; rolling the inoculated substrate into a roll; and thereafter incubating the rolled inoculated substrate for a time sufficient for the mycelial tissue to grow hyphae that enmesh with the substrate to form a cohesive unified filamentous network with the rolled inoculated substrate being characterized in being flexible. The rolled inoculated substrate may be subsequently processed by subjecting lengths of the roll to heat and pressure in molds to form rigid products.

Abstract: A mycological composite material is made by inoculating a substrate of fibrous material with an inoculum of mycelial tissue; rolling the inoculated substrate into a roll; and thereafter incubating the rolled inoculated substrate for a time sufficient for the mycelial tissue to grow hyphae that enmesh with the substrate to form a cohesive unified filamentous network with the rolled inoculated substrate being characterized in being flexible. The rolled inoculated substrate is subsequently processed by subjecting lengths of the roll to heat and pressure in molds to form rigid products.

Abstract: A liquid desiccant regeneration system and method of liquid desiccant regeneration are described. The liquid desiccant regeneration system includes a liquid desiccant regenerator having an engine producing a heated exit stream, and at least one dehydrating tube comprising a first water vapor permeable wall. A low concentration liquid desiccant stream feeds into the liquid desiccant regenerator, while a high concentration liquid desiccant stream exiting the liquid desiccant regenerator. A carrier stream and the low concentration liquid desiccant are in contact with opposite sides of the first water vapor permeable wall, and the low concentration liquid desiccant stream is heated by heat from the heated exit stream to drive water from the low concentration liquid desiccant stream through the first water vapor permeable wall to the carrier stream to form a humidified carrier stream.

Abstract: A method of producing a mycological composite material comprises inoculating a substrate of fibrous material with an inoculum of mycelial tissue; rolling the inoculated substrate into a roll; and thereafter incubating the rolled inoculated substrate for a time sufficient for the mycelial tissue to grow hyphae that enmesh with the substrate to form a cohesive unified filamentous network with the rolled inoculated substrate being characterized in being flexible. The rolled inoculated substrate may be subsequently processed by subjecting lengths of the roll to heat and pressure in molds to form rigid products.

Abstract: A liquid desiccant regeneration system and method of liquid desiccant regeneration are described. The liquid desiccant regeneration system includes a liquid desiccant regenerator having an engine producing a heated exit stream, and at least one dehydrating tube comprising a first water vapor permeable wall. A low concentration liquid desiccant stream feeds into the liquid desiccant regenerator, while a high concentration liquid desiccant stream exiting the liquid desiccant regenerator. A carrier stream and the low concentration liquid desiccant are in contact with opposite sides of the first water vapor permeable wall, and the low concentration liquid desiccant stream is heated by heat from the heated exit stream to drive water from the low concentration liquid desiccant stream through the first water vapor permeable wall to the carrier stream to form a humidified carrier stream.

Abstract: A heat and mass exchanger system is described. The heat and mass exchange system can include a plurality of exchange components extending across a heat and mass exchanger (HMX) duct, where a flow through the HMX duct is cross-flow relative to said exchange components. The exchange components can include a plurality of first elongated, hollow conduits and a plurality of second elongated, hollow conduit, where either the first elongated, hollow conduits or the second elongated, hollow conduits have water vapor permeable exterior walls, and a carrier air stream and a liquid desiccant stream flow in contact with opposite sides of the water vapor permeable exterior walls.

Abstract: A liquid desiccant regeneration system and method of liquid desiccant regeneration are described. The liquid desiccant regeneration system includes a liquid desiccant regenerator having an engine producing a heated exit stream, and at least one dehydrating tube comprising a first water vapor permeable wall. A low concentration liquid desiccant stream feeds into the liquid desiccant regenerator, while a high concentration liquid desiccant stream exiting the liquid desiccant regenerator. A carrier stream and the low concentration liquid desiccant are in contact with opposite sides of the first water vapor permeable wall, and the low concentration liquid desiccant stream is heated by heat from the heated exit stream to drive water from the low concentration liquid desiccant stream through the first water vapor permeable wall to the carrier stream to form a humidified carrier stream.

Abstract: A fuel cell system is disclosed having at least a first section that operates in a hydrogen filtration mode to filter an incoming hydrogen-rich fuel, specifically a reformate, and at least a second section that operates in a power generation mode. The second section may receive filtered hydrogen fuel from the first section. Also, to rejuvenate the first section after anode poisoning, the first section may switch modes to operate in the power generation mode.

Abstract: A composite flow field element, such as a separator plate used in a high temperature air-cooled fuel cell assembly, preferably includes a metal sheet substrate of non-uniform thickness, such as a mesh, and flexible graphite layers bonded to the metal mesh substrate by an electrically conductive bonding agent.