A method for forming a multilayer composite structure comprises providing a first sheet comprising a copper-comprising layer sandwiched by first and second graphene layers, wrapping the first sheet to form a first rod, and compacting the first rod to form a first multilayer composite structure.

A method for forming a multilayer composite structure comprises providing a first sheet comprising a copper-comprising layer sandwiched by first and second graphene layers, wrapping the first sheet to form a first rod, and compacting the first rod to form a first multilayer composite structure.

A cable device has a first connector, a connecting cable and at least one electrical component. The connecting cable has at least one signaling yarn and a first textile. The at least one signaling yarn is arranged within the first textile and has a supporting material having a strength of 26S through 40S. One end of the at least one signaling yarn is electrically connected to the first connector, and one end of the first textile is connected to the first connector. The electric signals are propagated between the at least one electrical component and the first connector, and the at least one electrical component is electrically connected to the other end of the at least one signaling yarn and connected to the other end of the first textile.

A cable device has a first connector, a connecting cable and at least one electrical component. The connecting cable has at least one signaling yarn and a first textile. The at least one signaling yarn is arranged within the first textile and has a supporting material having a strength of 26S through 40S. One end of the at least one signaling yarn is electrically connected to the first connector, and one end of the first textile is connected to the first connector. The electric signals are propagated between the at least one electrical component and the first connector, and the at least one electrical component is electrically connected to the other end of the at least one signaling yarn and connected to the other end of the first textile.

A method for manufacturing a high conductive Al alloy wire without conducting an annealing process includes: providing an Al alloy rod comprising 0.01 parts by weight to 0.08 parts by weight of Fe, Fe:Si=2 to 3:1 of Si and the balance Al and inevitable impurities, based on 100 parts by weight of an entire A1350 alloy; conform-extruding the Al alloy rod by passing through a dies of a conform extruder having a polygonal shaped structure to form a polygonal shaped Al alloy wire; cooling the extruded Al alloy wire to room temperature; and winding the cooled Al alloy wire using a winder.

A method for manufacturing a high conductive Al alloy wire without conducting an annealing process includes: providing an Al alloy rod comprising 0.01 parts by weight to 0.08 parts by weight of Fe, Fe:Si=2 to 3:1 of Si and the balance Al and inevitable impurities, based on 100 parts by weight of an entire A1350 alloy; conform-extruding the Al alloy rod by passing through a dies of a conform extruder having a polygonal shaped structure to form a polygonal shaped Al alloy wire; cooling the extruded Al alloy wire to room temperature; and winding the cooled Al alloy wire using a winder.

Provided is a transmissive wire of a micrometer or nanometer scale diameter, and a method of forming such a transmissive wire, that can be produced and handled at macrometer scale, and which has a mechanical strength suitable for being formed and handled at a macrometer scale. A transmissive element having micrometer or nanometer scale thickness may be continuously applied, such as fixedly applied, to a nanomaterial structure, or vice versa, and the combined structure jointly wrapped about an axis of the nanomaterial structure to produce a wire. In one example, a continuously formed transmissive element may be continuously applied to a continuously formed length of a nanomaterial sheet with the combined structure being wrapped about a longitudinal axis of the nanomaterial sheet to form a transmissive wire having a micrometer or nanometer scale diameter along the longitudinal axis of the formed transmissive wire.

A cable device has a first connector, a connecting cable and at least one electrical component. The connecting cable has at least one signaling yarn and a first textile. The at least one signaling yarn is arranged within the first textile and has a supporting material having a strength of 26 through 40 strands. One end of the at least one signaling yarn is electrically connected to the first connector, and one end of the first textile is connected to the first connector. The electric signals are propagated between the at least one electrical component and the first connector, and the at least one electrical component is electrically connected to the other end of the at least one signaling yarn and connected to the other end of the first textile.

A cable device has a first connector, a connecting cable and at least one electrical component. The connecting cable has at least one signaling yarn and a first textile. The at least one signaling yarn is arranged within the first textile and has a supporting material having a strength of 26 through 40 strands. One end of the at least one signaling yarn is electrically connected to the first connector, and one end of the first textile is connected to the first connector. The electric signals are propagated between the at least one electrical component and the first connector, and the at least one electrical component is electrically connected to the other end of the at least one signaling yarn and connected to the other end of the first textile.

A conductor shaping apparatus includes a driving device that relatively rotates an upper die and a lower die and integrally rotates the upper and lower dies with respect to a shaping member. The driving device rotates one of the upper and lower dies in a direction from an edgewise bent portion to a distal end of a conductor so as to separate the one of the upper and lower dies from the other. One of the upper and lower dies includes a supporting surface configured to support a side surface of an end portion of the conductor as the edgewise bent portion is formed in the end portion, and a guide surface that is formed to intersect the support surface. The guide surface extends away from the end portion of the conductor in a direction opposite to a bent direction of a flatwise bent portion closest to the edgewise bent portion as it extends away from the supporting surface on an opposite side of a rotational axis.