A circuit for improving instantaneous current flow in an AC-to-DC power supply for an electronic device, said circuit positioned immediately prior to an AC input for the AC-to-DC power supply and providing a reserve of electrical charge independent of the inductive impedance of the AC power line.

A conductive component including: a substrate, a first layer comprising a plurality of island structures disposed on the substrate, wherein the island structures include graphene; and a second layer disposed on the first layer, wherein the second layer includes a plurality of conductive nanowires. Also, an electronic device including the conductive component.

A power distribution system element formed via an additive manufacturing technique, such as applying a conductive material to a memory metal substrate, are discussed herein. In operation (e.g. in response to delivering current through the distribution system), the memory metal contracts while the conductive material expands. The result is distribution system element having reduced thermal expansion, which can be net zero coefficient of thermal expansion.

This copper alloy for an electronic/electric device includes Mg at an amount of 3.3 atom % to 6.9 atom % with a remainder substantially being Cu and inevitable impurities, wherein a strength ratio TS.sub.TD/TS.sub.LD is more than 1.02, and the strength ratio TS.sub.TD/TS.sub.LD is calculated from a strength TS.sub.TD measured by a tensile test carried out in a direction perpendicular to a rolling direction and a strength TS.sub.LD measured by a tensile test carried out in a direction parallel to the rolling direction.

The present invention relates to electrical conductors for electrical transmission and distribution with pre-stress conditioning of the strength member so that the conductive materials of aluminum, aluminum alloys, copper, copper alloys, or copper micro-alloys are mostly tension free or under compressive stress in the conductor, while the strength member is under tensile stress prior to conductor stringing, resulting in a lower thermal knee point in the conductor.

The disclosure relates to a metal nanowire structure. The metal nanowire structure includes a substrate and a metal nanowire film located on the substrate. The metal nanowire film includes a number of first metal nanowires parallel with and spaced from each other. A width of each of the plurality of first metal nanowires is in a range from about 0.5 nanometers to about 50 nanometers. Each of the plurality of first metal nanowires is a solid structure and consists of metal material.

A stranded electrical conductor includes a single center strand in aluminum or aluminum alloy (10, 20, 30, 40A, 50A) and a plurality of conductor strands (11, 21, 31, 41, 51) arranged in at least one layer around said center strand. The relation between the diameter of said center strand in aluminum or aluminum alloy and the diameter of said peripheral conductor strands is greater than or equal to 3.

Described is a composition suitable for the preparation of an electroconductive transparent layer, said composition comprising silver nanowires and fibers of crystalline cellulose.

A copper wire rod with an excellent surface quality and a magnet wire, in which the occurrence of blister defects is suppressed, are provided. The copper wire rod has a composition consisting of: more than 10 ppm by mass and 30 ppm by mass or less of P; 10 ppm by mass or less of O; 1 ppm by mass or less of H; and the balance Cu and inevitable impurities, wherein hydrogen concentration after performing a heat treatment at 500 for 30 minutes in vacuum is 0.2 ppm by mass or less. The magnet wire includes: a drawn wire material produced by using the copper wire rod; and an insulating film coating an outer periphery of the drawn wire material.

In an electrical wire/cable a central wire (11) made of Aluminum is used. The central wire is surrounded by at least one wire of Copper (12) in direct contact with the central wire.