Abstract: The invention relates to a compound of the formula Li7-xPS6-xXx-z(BH4)z, in which x is selected from the group comprising Cl, Br, I, F and CN, 0?x?2, 0?z?0.50. This compound can be used as a solid electrolyte of a lithium-ion electrochemical element.

Abstract: The invention relates to a compound of the formula Li7?xPS6?xXx?x(BH4)x in which x is selected from the group comprising Cl, Br, I, F and CN, 0?x?2, 0?z?0.50. This compound can be used as a solid electrolyte of a lithium-ion electrochemical element.

Abstract: Systems and methods for manufacturing a tank for storing hydrogen in metal hydride powder are disclosed. The tank can include a closed enclosure divided into closed cells. Each of the cells can contain metal hydride powder. Each of the cells can also be manufactured successively by assembling the cells in order to form an open cavity or alveolar cell. One or more bulk pieces of a material capable of forming a metal hydride can be placed in the cavity. The cell can be closed with the bulk pieces by closing the cavity. After cells are closed, hydrogen can be introduced into the tank for transforming the bulk pieces into metal hydride powder.

Abstract: A device for trapping flammable gases such as hydrogen comprises active means (3) inside a casing (1) which is closed except for openings which are plugged by filters (2) that normally allow only the gases that are to be trapped to pass through them. The trapping maintains a reduced pressure inside the casing, which continually draws in the gases produced outside. The trap can operate without any maintenance and for long periods of time, even in a completely enclosed environment.

Abstract: A device for trapping flammable gases such as hydrogen comprises active means (3) inside a casing (1) which is closed except for openings which are plugged by filters (2) that normally allow only the gases that are to be trapped to pass through them. The trapping maintains a reduced pressure inside the casing, which continually draws in the gases produced outside. The trap can operate without any maintenance and for long periods of time, even in a completely enclosed environment.

Abstract: An alloy comprising tin, silicon and carbon, and containing a crystalline M-Sn phase, M being an inert metal. An alloy comprising tin and silicon, comprising: a) a nanocrystalline phase containing at least 50 at. % of the element silicon Si°; b) a nanocrystalline phase containing a compound based on tin; c) a nanocrystalline phase constituted by the element tin Sn°. A manufacturing process for this alloy.

Abstract: A hydridable alloy of formula R1-x-yMgxMyNis-aBa wherein R is selected from the group consisting in rare earths, yttrium and a mixture thereof; M represents Zr and/or Ti; B is selected from the group consisting in Mn, Al, Co, Fe and a mixture thereof; 0.1<x<0.4; 0?y<0.1; 3<s<4.5 and 0?a<1; at least 5% of the volume of which consists of a stack of sequences of a pattern of the A2B4 type and of n patterns of the CaCu5 type randomly distributed along one direction, n being an integer comprised between 1 and 10 and representing the number of patterns of the CaCu5 type per pattern of the A2B4 type. A method for making a hydridable alloy comprising steps for compression and applying a current through a mixture comprising Mg2Ni and a compound comprising nickel and one or several elements selected from the group consisting in rare earths and yttrium.

Abstract: A method for manufacturing a tank for storing hydrogen in metal hydride powder comprising a closed enclosure divided into closed elementary cells (1) defined by walls (2, 3, 4, 5), each of the cells (1) containing metal hydride powder (6), characterized in that each of the cells (1) is manufactured successively by carrying out the following steps: certain of the walls defining it are assembled in order to form an open cavity or alveolar cell, and then one or more massive pieces (7) of a material capable of forming a metal hydride are placed in said cavity, and then the last walls of the cell (1) are assembled in order to close the latter; the aforementioned steps are repeated for manufacturing all the cells (1) of the enclosure, and then the enclosure is closed, hydrogen is introduced into the enclosure for transforming the massive piece(s) (7) into the metal hydride powder (6).

Abstract: An alloy comprising tin, silicon and carbon, and containing a crystalline M-Sn phase, M being an inert metal. An alloy comprising tin and silicon, comprising: a) a nanocrystalline phase containing at least 50 at. % of the element silicon Si°; b) a nanocrystalline phase containing a compound based on tin; c) a nanocrystalline phase constituted by the element tin Sn°. A manufacturing process for this alloy.

Abstract: Therefore the invention provides a hydrogen-absorbing alloy comprising at least one A5B19 type crystalline phase having the formula R1-yMgyNi3.8±0.1-zMz, in which R represents one or more elements chosen from La, Ce, Nd or Pr; M represents one or more elements chosen from Mn, Fe, Al, Co, Cu, Zr, Sn and M does not contain Cr; 0?y?0.30; z?0.5. The invention extends to an electrode comprising an active ingredient comprising said alloy. It also extends to a nickel metal hydride alkaline storage battery the negative electrode of which comprises said alloy. The invention also relates to the process for the manufacture of said alloy.

Abstract: Therefore the invention provides a hydrogen-absorbing alloy comprising at least one A5B19 type crystalline phase having the formula R1?yMgyNi3.8±0.1?zMz, in which R represents one or more elements chosen from La, Ce, Nd or Pr; M represents one or more elements chosen from Mn, Fe, Al, Co, Cu, Zr, Sn and M does not contain Cr; 0?y?0.30; z?0.5. The invention extends to an electrode comprising an active ingredient comprising said alloy. It also extends to a nickel metal hydride alkaline storage battery the negative electrode of which comprises said alloy. The invention also relates to the process for the manufacture of said alloy.