| GMZ Energy, Inc. Patent applications |
| Patent application number | Title | Published |
|---|
| 20120326097 | Half-Heusler Alloys with Enhanced Figure of Merit and Methods of Making - Thermoelectric materials and methods of making thermoelectric materials having a nanometer mean grain size less than 1 micron. The method includes combining and arc melting constituent elements of the thermoelectric material to form a liquid alloy of the thermoelectric material and casting the liquid alloy of the thermoelectric material to form a solid casting of the thermoelectric material. The method also includes ball milling the solid casting of the thermoelectric material into nanometer mean size particles and sintering the nanometer size particles to form the thermoelectric material having nanometer scale mean grain size. | 12-27-2012 |
| 20120217165 | Metal deposition using seed layers - Methods of forming a conductive metal layers on substrates are disclosed which employ a seed layer to enhance bonding, especially to smooth, low-roughness or hydrophobic substrates. In one aspect of the invention, the seed layer can be formed by applying nanoparticles onto a surface of the substrate; and the metallization is achieved by electroplating an electrically conducting metal onto the seed layer, whereby the nanoparticles serve as nucleation sites for metal deposition. In another approach, the seed layer can be formed by a self-assembling linker material, such as a sulfur-containing silane material. | 08-30-2012 |
| 20120160290 | THERMOELECTRIC SYSTEM AND METHOD OF OPERATING SAME - An apparatus includes an evacuated enclosure which comprises a tubular member extending along a longitudinal axis, a radiation absorber disposed in the enclosure and having a front surface and a back surface, the front surface being adapted for exposure to solar radiation so as to generate heat, at least one thermoelectric converter disposed in the enclosure and thermally coupled to the absorber, the converter having a high-temperature end to receive at least a portion of the generated heat, such that a temperature differential is achieved across the at least one thermoelectric converter, a support structure disposed in the enclosure coupled to a low-temperature end of the thermoelectric converter, where the support structure removes heat from a low-temperature end of the thermoelectric converter, and a heat conducting element extending between the support structure and the evacuated enclosure and adapted to transfer heat from the support structure to the enclosure. The absorber, the at least one thermoelectric converter, and the support structure are arranged as a planar unit located within the tubular member. | 06-28-2012 |
