Abstract: A planetary mill is disclosed. The planetary mill comprises a self-balancing milling assembly comprising a pair of elongate floating milling chambers arranged in parallel to and on opposite sides of a main axis wherein the milling chambers are free to move outwards in a direction radial to the main axis, a drive assembly for rotating the milling assembly in a first direction of rotation about the main axis, and at least one of belt surrounding the pair of floating milling chambers such that when the milling assembly rotates about the main axis, the at least one belt limits a radial travel outwards of each of the milling chambers.

Abstract: A planetary mill is disclosed. The planetary mill comprises a self-balancing milling assembly comprising a pair of elongate floating milling chambers arranged in parallel to and on opposite sides of a main axis wherein the milling chambers are free to move outwards in a direction radial to the main axis, a drive assembly for rotating the milling assembly in a first direction of rotation about the main axis, and at least one of belt surrounding the pair of floating milling chambers such that when the milling assembly rotates about the main axis, the at least one belt limits a radial travel outwards of each of the milling chambers.

Abstract: A planetary mill is disclosed. The planetary mill comprises a self-balancing milling assembly comprising a pair of elongate floating milling chambers arranged in parallel to and on opposite sides of a main axis wherein the milling chambers are free to move outwards in a direction radial to the main axis, a drive assembly for rotating the milling assembly in a first direction of rotation about the main axis, and at least one of belt surrounding the pair of floating milling chambers such that when the milling assembly rotates about the main axis, the at least one belt limits a radial travel outwards of each of the milling chambers.

Abstract: The invention relates to new and useful nickel powders, particularly powders for use as an electrode material.

Abstract: The invention relates to new and useful nickel powders, particularly powders for use as an electrode material.

Abstract: The present invention is concerned with a method for the production of fine and ultrafine powders of various materials such as metals, alloys, ceramics, composites etc., through a transferred arc plasma system. The method comprises vaporizing or decomposing the material in the plasma reactor, condensing the vapor in a quench tube comprising two sections, the first one for indirectly cooling or heating the vapor, and the second one for directly cooling the vapor. The powder is recovered in a conventional collection unit. The two step condensation in the quench tube allows a substantial control of powder properties like crystallinity, size distribution and mean particle size.

Abstract: A method is provided for forming a molten oxide ceramic electrode for a plasma arc ignited between first and second electrodes within a plasma arc chamber, wherein the conductivity the oxide ceramic is a function of temperature alone. Following ignition of the plasma arc, a mixture is formed of a small quantity of molten oxide ceramic and a sufficiently high concentration of a volatile contaminant to render the mixture electrically conductive. The plasma arc is then transferred from one of the electrodes to the mixture. The temperature of the mixture is raised sufficiently to render the oxide ceramic electrically conductive. Finally, the volatile contaminant is progressively removed from the mixture so as to leave an electrode composed of substantially pure molten oxide ceramic.

Abstract: A method is provided for forming a molten oxide ceramic electrode for a plasma arc ignited between first and second electrodes within a plasma arc chamber, wherein the conductivity the oxide ceramic is a function of temperature alone. Following ignition of the plasma arc, a mixture is formed of a small quantity of molten oxide ceramic and a sufficiently high concentration of a volatile contaminant to render the mixture electrically conductive. The plasma arc is then transferred from one of the electrodes to the mixture. The temperature of the mixture is raised sufficiently to render the oxide ceramic electrically conductive. Finally, the volatile contaminant is progressively removed from the mixture so as to leave an electrode composed of substantially pure molten oxide ceramic.