A cable structure includes a tubular body, a main spacer, a first spacer, a first protector, a second protector and a plurality of twisted pairs. The tubular body is disposed in the tubular body. The first spacer is substantially perpendicularly connected to the main spacer in a central position. The first protector and the second protector are disposed at two ends of the main spacer. A first channel is formed by the main spacer, the first protector and the second protector, a second channel is formed by the main spacer, the first protector and the first spacer, and a third channel is formed by the main spacer, the second protector and the first spacer. The twisted pairs are disposed in the first channel, the second channel and the third channel.

A cable structure and a manufacturing method thereof are provided. The cable structure includes a transmission component and a protection component. The transmission component includes at least one first intermedium unit, and the least one first intermedium unit includes at least one first transmission cable and a first barrier layer covering the at least one first transmission cable. The protection component includes at least one shielding layer covering the at least one first intermedium unit and an insulating layer covering the at least one shielding layer. The at least one shielding layer includes a metal foil layer covering the at least one first intermedium unit and at least one conducting layer formed on a surface of the metal foil layer.

A cable structure and a manufacturing method thereof are provided. The cable structure includes a transmission component and a protection component. The transmission component includes at least one first intermedium unit, and the least one first intermedium unit includes at least one first transmission cable and a first barrier layer covering the at least one first transmission cable. The protection component includes at least one shielding layer covering the at least one first intermedium unit and an insulating layer covering the at least one shielding layer. The at least one shielding layer includes a metal foil layer covering the at least one first intermedium unit and at least one conducting layer formed on a surface of the metal foil layer.

The invention relates to a data cable. One embodiment of the data cable has at least one pair of wires and a cable sheath surrounding the at least one pair of wires. The at least one pair of wires has two wires twisted together in the longitudinal direction of the data cable. Cavities between the at least one pair of wires and the cable sheath are at least partially filled with a filler. The filler has a viscosity which is such that it adheres in the data cable in such a way as to remain in the data cable at least nearly completely when there is a specified pressure difference between one end of the data cable and the other end of the data cable.

A cable includes a jacket surrounding first and second twisted pairs, as well as, first and second dielectric tapes. In alternative or supplemental embodiments of the invention, the first dielectric tape has a cross sectional shape, which presents first and second recessed portions; the first dielectric tape is different in shape or material content as compared to a second dielectric tape; the insulated conductors of the first and second twisted pairs are identical in appearance, while the first and second dielectric tapes are different in appearance; and/or the first dielectric tape has a hollow core possessing a gas or material with a lower dielectric constant.

A cable includes a jacket surrounding first and second twisted pairs, as well as, first and second dielectric tapes. In alternative or supplemental embodiments of the invention, the first dielectric tape has a cross sectional shape, which presents first and second recessed portions; the first dielectric tape is different in shape or material content as compared to a second dielectric tape; the insulated conductors of the first and second twisted pairs are identical in appearance, while the first and second dielectric tapes are different in appearance; and/or the first dielectric tape has a hollow core possessing a gas or material with a lower dielectric constant.

A communications cable is described. The communications cable can include a cable jacket, a separator structure that defines one or more channels for receiving at least one communications medium, and an insulator that surrounds the communications medium. The cable jacket can include one or more corrugations on at least one of its interior or exterior surfaces. The separator can also include one or more grooves on at least a portion of its surface. The insulator can also include one or more indentations on at least one of its interior or exterior surfaces. The corrugations, grooves, and indentations can extend along the longitudinal length of the cable and define one or more air channels for forwarding and circulating air through or on the surface the cable. The circulation of air in the cable can reduce the temperature of the cable and increase the quality of the signal transmitted through the cable.

Various examples are provided for superlattice conductors. In one example, a planar conductor includes a plurality of stacked layers including copper thin film layers and nickel thin film layers, where adjacent copper thin film layers of the copper thin film layers are separated by a nickel thin film layer of the plurality of nickel thin film layers. In another example, a conductor includes a plurality of radially distributed layers including a non-ferromagnetic core; a nickel layer disposed about and encircling the non-ferromagnetic core; and a copper layer disposed on and encircling the nickel layer. In another example, a hybrid conductor includes a core; and a plurality of radially distributed layers disposed about a portion of an outer surface of the core, the plurality of radially distributed layers include alternating ferromagnetic and non-ferromagnetic layers. In other hybrid conductors, the radially distributed layers can utilize magnetic and non-magnetic materials.

Various examples are provided for superlattice conductors. In one example, a planar conductor includes a plurality of stacked layers including copper thin film layers and nickel thin film layers, where adjacent copper thin film layers of the copper thin film layers are separated by a nickel thin film layer of the plurality of nickel thin film layers. In another example, a conductor includes a plurality of radially distributed layers including a non-ferromagnetic core; a nickel layer disposed about and encircling the non-ferromagnetic core; and a copper layer disposed on and encircling the nickel layer. In another example, a hybrid conductor includes a core; and a plurality of radially distributed layers disposed about a portion of an outer surface of the core, the plurality of radially distributed layers include alternating ferromagnetic and non-ferromagnetic layers. In other hybrid conductors, the radially distributed layers can utilize magnetic and non-magnetic materials.

The present disclosure relates to a telecommunications cable. The telecommunications cable includes a plurality of twisted pairs of insulated conductors. The plurality of twisted pairs of insulated conductors extends substantially along a longitudinal axis of the telecommunications cable. In addition, the telecommunications cable includes a separator. The separator separates each twisted pair of insulated conductor of the plurality of twisted pairs of insulated conductors. Moreover, the telecommunications cable includes a first layer. The first layer surrounds the separator and the plurality of twisted pairs of insulated conductors along a length of the telecommunications cable. The separator is I-shaped filler. The separator is made of low smoke zero halogen material or MDPE. The first layer is made of low smoke zero halogen material, polyethylene or poly vinyl chloride. The first layer has a thickness in a range of about 0.4 millimeter-2.5 millimeters.