Abstract: A tubular membrane pervaporation separation system, comprising a heater, one or multiple membrane separators arranged in parallel, a condenser and a vacuum pump; the separator comprises a vacuum vessel, a concurrent heating vessel and one or multiple pervaporation lines arranged in parallel; the line comprises membrane tube bundle modules and concurrent heating modules connected in series or in a series-parallel hybrid form, in the line, the membrane tube bundle modules are arranged between two adjacent concurrent heating modules; the vacuum vessel is connected to the condenser and the vacuum pump in sequence; the concurrent heating vessel is provided with an inlet and an outlet; one end of the line is connected to the heater and the other end is used to discharge; the modules are placed respectively in the vacuum vessel and the concurrent heating vessel, comprise one or multiple membrane tubes and concurrent heating tubes arranged in parallel respectively.

Abstract: The invention relates to chemical-based methods and products for mitigating the impact of an oil spill, that act via mechanisms which include reducing adhesiveness, herding, thickening and gelling. N-fatty acid amino acid (FA-AA) conjugates display oil-herding behavior when formulated as a salt, or the free acid in water-miscible organic solvents. Various salts of FA-AA conjugates are water soluble and can herd oils and increase the thickness of the oil layer. Replacement of the acid group of fatty acid ?-amino acid conjugates with other groups that act as hydrogen bond donors and acceptors results in potent phase selective organo gellants. The oil thickeners or gellants include can be prepared from biobased feedstocks, have low toxicity, high capacity for oil and reduction of the need to use an organic solvent to apply the thickener or gellant to an oil and water mixture in order to gel the oil phase.

Abstract: Chemical-based methods and products for mitigating the impact of an oil spill are disclosed. The products act by herding, thickening, gelling, and reducing adhesiveness. N-fatty acid amino acid (FA-AA) conjugates display oil-herding behavior when formulated as a free acid in water-miscible organic solvents. A water-miscible organic solvent is not required if the FA-AA conjugate is formulated as a salt. Various salts of FA-AA conjugates are water soluble and can herd oils and increase the thickness of the oil layer. Replacement of the acid group of fatty acid ?-amino acid conjugates with other groups that act as hydrogen bond donors and acceptors results in potent phase selective organo-gellants. The oil spill herders can be prepared from bio-based feedstocks and are biodegradable.

Abstract: An electroless plating Ru bath for the deposition of Ru on the surface of a substrate comprises a Ru stock solution and hydrazine as a reducing reagent. Ru layers may be applied, for example, for use in membranes for the separation of hydrogen gas from mixtures of gases or to protect materials from corrosion. An example Ru stock solution comprises Ru chloride, hydrochloric acid, ammonia, nitrite salt, alkali hydroxide, and deionized water. The electroless plating bath may be applied to deposit ruthenium layers onto palladium layers to prepare Pd—Ru composite or alloy membranes or multilayer Pd—Ru composite or alloy membranes. Such membranes have example application to the separation of hydrogen from mixtures of gases.

Abstract: This invention relates to a metallic composite membrane for separating hydrogen from a mixed gas, a membrane module and a manufacturing method thereof. The composite membrane consists of a three-layer sandwich structure, e.g. the porous metal substrate, an intermediate layer and the hydrogen-selective dense thin metal layer. In the embodiments of the invention, the porous metal substrates were first pretreated to reduce their surface roughness without reducing their gas permeability. The pretreated substrates were coated with intermediate layer, wherein the intermediate layer served as not only a barrier layer to prevent interdiffusion between the substrate and the hydrogen-selective layer, but also a surface modifier to reduce surface roughness and pore size of the substrate. A hydrogen-selective metal layer was then deposited on the intermediate layer-coated substrate by coating methods.

Abstract: This invention relates to a method of bonding a metallic membrane with metallic part involving pressing a smooth surface of the metallic membrane against the smooth surface of the metallic part, and heating the metallic membrane and metallic part to a temperature above the half melting point of the metallic membrane while subjecting the metallic membrane and metallic part to a controlled environment of a proper gas atmosphere. The metallic membrane can comprise palladium and the pressurized gas can comprise one of hydrogen, an inert gas or their mixture.

Abstract: This invention relates to a method of bonding a metallic membrane with metallic part involving pressing a smooth surface of the metallic membrane against the smooth surface of the metallic part, and heating the metallic membrane and metallic part to a temperature above the half melting point of the metallic membrane while subjecting the metallic membrane and metallic part to a controlled environment of a proper gas atmosphere. The metallic membrane can comprise palladium and the pressurized gas can comprise one of hydrogen, an inert gas or their mixture.