An aluminum alloy wire is composed of an aluminum alloy. The aluminum alloy contains equal to or more than 0.005 mass % and equal to or less than 2.2 mass % of Fe, and a remainder of Al and an inevitable impurity. In a transverse section of the aluminum alloy wire, a surface-layer crystallization measurement region in a shape of a rectangle having a short side length of 50 m and a long side length of 75 m is defined within a surface layer region extending from a surface of the aluminum alloy wire by 50 m in a depth direction, and an average area of crystallized materials in the surface-layer crystallization measurement region is equal to or more than 0.05 m.sup.2 and equal to or less than 3 m.sup.2.

A compressed stranded conductor includes a central stranded wire having a plurality of conductive strands which are twisted together and an outer circumferential stranded wire having a plurality of conductive strands which are twisted together at an outer circumference of the central stranded wire. A composite stranded wire configured by the central stranded wire and the outer circumferential stranded wire is compressed, and an occupancy ratio of the composite stranded wire is 90.2% or more and 91.0% or less.

An apparatus to process a plurality of electrical wires as well as a method that uses the apparatus are indicated. The apparatus includes a feed device, a stationary holding device, a holding device that is non-stationary along a linear guiding direction, a non-stationary bundling device that is separate from the non-stationary holding device and a controller connected to a drive of the non-stationary bundling device. The stationary holding device and/or the non-stationary holding device are configured to twist the respectively held end of the wires; The controller controls the drive in such a way that a distance between a bundling segment of the non-stationary bundling device and the non-stationary holding device assumes a specified or a specifiable distance.

An apparatus (1) is designed to manufacture a twisted wire by twisting a plurality of electric wires (101), and includes an raising and lowering unit (2), an twisting unit (3), and a control unit (4). The raising and lowering unit lifts the plurality of electric wires and lowers the manufactured twisted wire, and includes: a raising and lowering portion (6); a guiding portion (7) vertically guiding the raising and lowering portion; and a raising and lowering mechanism (8) capable of switching a raising and lowering speed of the raising and lowering portion to a high speed or a low speed.

A compressed stranded conductor includes a central stranded wire having a plurality of conductive strands which are twisted together and an outer circumferential stranded wire having a plurality of conductive strands which are twisted together at an outer circumference of the central stranded wire. A composite stranded wire configured by the central stranded wire and the outer circumferential stranded wire is compressed, and an occupancy ratio of the composite stranded wire is 90.2% or more and 91.0% or less.

A carbon nanotube (CNT) cable includes: a pair of plated twisted wires, each wire comprising one or more sub-cores, at least one sub-core comprising CNT yarn; a dielectric surrounding the plated twisted wires; and an electrical layer surrounding the dielectric, the electrical layer configured to shield the CNT cable. A method for making a CNT cable includes: controlling a deposition rate, depositing plating so as to surround a pair of wires, each wire comprising one or more sub-cores, at least one sub-core comprising CNT yarn; twisting the plated wires together; and surrounding the plated twisted wires with an electrical layer configured to shield the plated twisted wires, thereby creating the CNT cable.

A dual cable alignment apparatus aligns assembled cable ends provided with contact elements on two cables of a twisted cable strand in a predetermined correct rotational position. The alignment apparatus includes two cable rotating modules arranged on an apparatus frame and equipped with rotary cable grippers for rotating each assembled cable end about its longitudinal axis, and an optical detection apparatus for determining the corresponding rotational position of the assembled cable ends. To adjust the distance between the assembled cable ends, a cable rotating module is displaceable by a drive on the apparatus frame, whereby it is ensured that each assembled cable end can be brought into the desired rotational position precisely and reliably, and an optimal shadow image of the two contact elements can be detected for position detection.

A multi-core cable for vehicle includes two power wires, two signal wires, two electric wires, and a sheath. The two power wires have the same size and are made of the same material. The two signal wires have the same size and are made of the same material, and a pair of the two signal wires is twisted and is configured a twisted pair of signal wires. The two electric wires have the same size and are made of the same material, and a pair of the electric wires is twisted and is configured as a twisted pair of electric wires. The two power wires, the twisted pair of signal wires and the twisted pair of electric wires are stranded.

A miniature photoelectric composite cable for high-definition video signal transmission includes a flat optical fiber component and a round electrical component. The flat optical fiber component includes a multi-core optical fiber, a strengthening layer, and a light jacket. The round electrical component includes a multi-core electrical cable, a cladding, and an electric jacket. The cladding covers outside the multi-core electrical cable. The optical fiber component and the electrical component are arranged side-by-side.

A carbon nanotube (CNT) cable includes a pair of plated twisted wires, wherein each wire includes one or more sub-cores, wherein at least one sub-core includes CNT yarn; a dielectric surrounding the plated twisted wires; and an electrical layer surrounding the dielectric, wherein the electrical layer is configured to shield the CNT cable. A method for making a CNT cable includes the steps of controlling a deposition rate, depositing plating so as to surround a pair of wires, wherein each wire includes one or more sub-cores, wherein at least one sub-core includes CNT yarn, twisting the plated wires together, and surrounding the plated twisted wires with an electrical layer configured to shield the plated twisted wires, thereby creating the CNT cable.