This twisted wire conductor 10 for an insulated electrical wire is configured so as to be in a mixed state in which a first conductor 20 and a second conductor 40 are twisted together. The first conductor comprises a specific aluminum alloy: which has an alloy composition that contains, by mass %, 0.2-1.8% of Mg, 0.2-2.0% of Si, 0.01-0.33% of Fe and a total of 0.00-2.00% of one or more elements selected from the group consisting of Cu, Ag, Zn, Ni, Co, Au, Mn, Cr, V, Zr, Ti and Sn, with the remainder comprising Al and unavoidable impurities; which has a fibrous metal structure in which crystal grains extend in one direction; and in which the average value of a dimension t which is perpendicular to the longitudinal direction of crystal grains is 400 nm or less in a cross section parallel to this one direction. The second conductor has a higher electrical conductivity than the first conductor 20 and comprises a metal or alloy selected from the group consisting of copper, copper alloys, aluminum and aluminum alloys. The twisted wire conductor exhibits high electrical conductivity, high strength and excellent bending fatigue resistance, and enables a reduction in weight.

The present invention relates to a fabric material-based flexible electrode and a manufacturing method thereof, and a fabric material-based flexible electrode according to the present invention comprises: a substrate (10) including multiple fibers (11) crossing each other; a bonding layer (20), on the substrate (10), including an amine group (NH2)-containing monomolecular substance adsorbed thereon; a nanoparticle layer (30), on the bonding layer (20), having metallic nanoparticles (31) coated thereon; and a plating layer (40), on the nanoparticle layer (30), having a predetermined metal electroplated thereon.

A flat conductor wire includes a flat conductor made of aluminum containing inevitable impurities. A cross section of the flat conductor orthogonal to a longitudinal direction of the flat conductor has a rounded corner portion, a radius of curvature of the corner portion being equal to or greater than one fourth of a thickness of the cross section of the flat conductor. A width of the cross section of the flat conductor is equal to or smaller than 60/(1), being a uniform elongation of the flat conductor.

A wire conductor has a plurality of elemental wires made of aluminum or an aluminum alloy, which are stranded with each other and arranged, in cross-section intersecting an axial direction of the wire conductor, in which one or a plurality of virtual elemental wires are removed from an outer peripheral portion of a virtual cross-section represented by a maximum number of virtual elemental wires accommodated in a circumscribing figure approximated by a regular hexagon, the virtual elemental wires having a same diameter as the elemental wires. The wire conductor includes a plurality of slave strands, each being a strand of the plurality of elemental wires, a maximum diameter cross-sectional area ratio is 0.63 or higher that is calculated by dividing a cross-sectional area of the wire conductor by an area of a circle having a diameter equal to a maximum value of an outer diameter of the wire conductor.

The present invention relates to a composite material based on aluminium and alumina, its method of manufacture, and a cable comprising said composite material as an electrical conductor element.

The aluminum alloy material of the present disclosure has a specific alloy composition and has a fibriform metallographic structure where crystal grains extend so as to be aligned in one direction, wherein an average value of a size perpendicular to a longitudinal direction of the crystal grains is 400 nm or less in a cross section parallel to the one direction. The aluminum alloy material of the present disclosure has a main surface having a crystal orientation distribution which satisfies a peak intensity ratio R (I.sub.200/I.sub.220) of a peak intensity I.sub.200 of a diffraction peak due to a {100} plane to a peak intensity I.sub.220 of a diffraction peak due to a {110} plane, of 0.20 or more, determined by an X-ray diffraction method.

An electric current supply system (20) is designed to be at least partially submerged in an electrically conductive liquid during operation thereof, and comprises at least one electrically conductive component (21, 22, 23, 24) enveloped in liquid-tight material (40). The component (21, 22, 23, 24) comprises sacrificial material that is capable of reacting electrochemically with the liquid. Further, the component (21, 22, 23, 24) comprises at least one gas trap portion (50) at which the sacrificial material occupies a space in the liquid-tight material (40) that is thereby defined with a gas trapping shape. If, in case of damage to the system (20) in an actual submerged state thereof, the component (21, 22, 23, 24) gets exposed to the liquid, it is achieved that an electrochemical reaction occurring at the exposed area of the component (21, 22, 23, 24) and an outflow of electric current to the liquid are stopped.

A terminal material in which galvanic corrosion is not occurred using a copper or copper alloy base material as a terminal crimped to an end part of an electrical wire formed from an aluminum wire material: an intermediate zinc layer 4 formed from zinc or zinc alloy and a tin layer 5 formed from tin or tin alloy are layered in this order on a base material 2 formed from copper or copper alloy; the intermediate zinc layer 4 has a thickness of 0.1 m to 5.0 m inclusive and a zinc concentration equal to or more than 5 mass %; and the tin layer 5 has a zinc concentration of 0.4 mass % to 15 mass % inclusive and a grain size of the tin layer 5 is 0.1 m to 3.0 m inclusive preferably.

A flat conductor wire includes a flat conductor made of aluminum containing inevitable impurities. A cross section of the flat conductor orthogonal to a longitudinal direction of the flat conductor has a rounded corner portion, a radius of curvature of the corner portion being equal to or greater than one fourth of a thickness of the cross section of the flat conductor. A width of the cross section of the flat conductor is equal to or smaller than 60/(1), being a uniform elongation of the flat conductor.

An aluminum alloy wire manufacturing method comprises (A) a step for melting an aluminum alloy containing 0.40-0.55 mass % of Mg and 0.45-0.65 mass % of Si, the balance being obtained from Al and unavoidable impurities, (B) a step for casting molten metal of the aluminum alloy and rolling to form a rough-drawn wire rod, (C) a step for solutionizing the rough-drawn wire rod, (D) a step for drawing the rough-drawn wire rod after solutionizing to form a drawn wire rod with a wire diameter of 0.5 mm or less, and (E) a step for heat treatment so that internal strain is removed with substantially no deposition of Mg.sub.2Si.