RU2001105922A - COMPOSITE MATERIALS WITH THE ABILITY FOR SORPTION OF HYDROGEN, INDEPENDENT ON THEIR ACTIVATION TREATMENT, AND METHODS FOR PRODUCING THEM - Google Patents

Claims (19)

1. Composite materials (10; 20) capable of sorption of hydrogen, regardless of the activation treatment, formed from powdery non-volatile getter materials (12, 22), the surface of which is covered by at least 10% of the deposited layer (13, 23) formed from one or more species selected from palladium metal, palladium oxide, palladium-silver alloys containing up to 30% silver per atom, and compounds formed by palladium and one or more metals of the getter material.  2. Composite materials according to claim 1, also capable of sorption of gases other than hydrogen, as a result of activation treatment, formed from powdery non-volatile getter materials, the surface of which is partially coated with a deposited layer formed from one or more species selected from metallic palladium, palladium oxide, palladium-silver alloys containing up to 30% silver per atom, and compounds formed by palladium and one or more metals of the getter material, with a coating degree of about 10 - 90%.  3. Composite materials according to claim 1 or 2, wherein the non-volatile getter material is selected from metals Zr, Ti, Nb, Ta, V; alloys between Zr and / or Ti and one or more other elements selected from Cr, Mn, Fe, Co, Ni, A1, Cu, Sn, Si, Y, La and rare earth metals; mixtures of these materials and these alloys.  4. Composite materials according to claim 3, wherein the non-volatile getter material is selected from Ti-V alloys; Zr-V; Zr-Al; Zr-Fe; Zr-Ni; Ti-V-Mn; Zr-Mn-Fe; Zr-V-Fe; Zr-Ni-AM or Zr-Co-A, where A represents an element selected from yttrium, lanthanum, rare earth metals or mixtures thereof, and M represents an element selected from cobalt, copper, iron, aluminum, tin, titanium, silicon or their mixtures.  5. Composite materials according to claim 2, where the degree of coverage is about 25% - 75% of the surface of a non-volatile getter material.  6. Composite materials according to claim 1 or 2, where the thickness of the specified deposited layer is less than 5 microns.  7. Composite materials according to claim 1 or 2, where the powder particles have a size of less than 500 microns.  8. Composite materials according to claim 7, where the particle size of the powdered materials is about 20 to 125 microns.  9. Devices including composite materials according to claim 1 or 2, formed only from pressed or sintered powders of said composite materials.  10. Devices including composite materials according to claim 1 or 2, formed from powders of these materials, placed in an open top container or deposited on a substrate.  11. The method of producing composite materials according to claim 1 or 2, where the deposited coating of palladium, palladium oxide or mixtures thereof is obtained by immersing non-volatile getter materials in powder form in a solution of a salt or palladium complex, evaporating the solvent and thermally decomposing the salt or complex precipitated on powder particles.  12. The method of producing composite materials according to claim 1 or 2, where the deposited layer of palladium, palladium oxide or mixtures thereof on particles of a powdery non-volatile getter material is obtained by chemical vapor deposition of a palladium compound, which is then decomposed by heat treatment.  13. The method of producing composite materials according to claim 2, where the deposited layer of palladium on the particles of powdered non-volatile getter materials is obtained by evaporation of the metal.  14. The method of producing composite materials according to claim 2, where the deposited palladium layer on the particles of a powdered non-volatile getter material is obtained by cathodic deposition.  15. The method of producing composite materials according to claim 2, where the deposited layer of a palladium-silver alloy on particles of a powdered non-volatile getter material is obtained by cathodic deposition.  16. The method according to any one of paragraphs. 11-15, where the powders of a non-volatile getter material are subjected to hydrogenation before the stage of formation of the specified deposited layer and dehydrogenated after this stage by heat treatment.  17. Containers for thermal insulation with a vacuum intermediate space, where such an intermediate space contains a composite material according to claim 1.  18. Pipes having thermal insulation with a vacuum intermediate space, where such an intermediate space contains a composite material according to claim 1.  19. Rechargeable or non-rechargeable batteries containing a composite material according to claim 1.