A cross filler for arrangement within a LAN cable has a plurality of twisted pair conductors. The cross filler has a body and a plurality of radially extending arms from a center point. Each of the arms has a plurality of spaced apart notches cut into the arms, the notches spaced apart along the length of the arms. Each of the notches are dimensioned allowing bending of the LAN cable without physical breakdown of the cross filler.

A cross filler for arrangement within a LAN cable has a plurality of twisted pair conductors. The cross filler has a body and a plurality of radially extending arms from a center point. Each of the arms has a plurality of spaced apart notches cut into the arms, the notches spaced apart along the length of the arms. Each of the notches are dimensioned allowing bending of the LAN cable without physical breakdown of the cross filler.

Communications cables having fusible continuous shields are described. A cable may include one or more electrical conductors, such as one or more twisted pairs of individually insulated electrical conductors. A shielding element may be formed around the one or more conductors in order to provide electromagnetic interference shielding for the one or more conductors. The shielding element may include a base layer of dielectric material extending in a longitudinal direction, and a plurality of longitudinally spaced segments of electrically conductive material may be formed on the base layer. A respective fusible element may be positioned between each adjacent set of the longitudinally spaced segments included in the plurality of longitudinally spaced segments. Each fusible element may provide electrical continuity between the adjacent set of longitudinally spaced segments, and each fusible element may have a minimum fusing current between 0.001 amperes and 0.500 amperes.

Communications cables having fusible continuous shields are described. A cable may include one or more electrical conductors, such as one or more twisted pairs of individually insulated electrical conductors. A shielding element may be formed around the one or more conductors in order to provide electromagnetic interference shielding for the one or more conductors. The shielding element may include a base layer of dielectric material extending in a longitudinal direction, and a plurality of longitudinally spaced segments of electrically conductive material may be formed on the base layer. A respective fusible element may be positioned between each adjacent set of the longitudinally spaced segments included in the plurality of longitudinally spaced segments. Each fusible element may provide electrical continuity between the adjacent set of longitudinally spaced segments, and each fusible element may have a minimum fusing current between 0.001 amperes and 0.500 amperes.

A cable harness assembly includes a cable having a pair of wires and a connector assembly including an inner ferrule formed of a conductive material. Each of the wires has a conductor and a insulation disposed around the conductor. The pair of wires have a twisted region and an untwisted region. The inner ferrule has a cable passageway extending through the inner ferrule and a separator disposed within the cable passageway. The untwisted region is disposed in the inner ferrule and the separator is disposed between the wires in the untwisted region.

A cable harness assembly includes a cable having a pair of wires and a connector assembly including an inner ferrule formed of a conductive material. Each of the wires has a conductor and a insulation disposed around the conductor. The pair of wires have a twisted region and an untwisted region. The inner ferrule has a cable passageway extending through the inner ferrule and a separator disposed within the cable passageway. The untwisted region is disposed in the inner ferrule and the separator is disposed between the wires in the untwisted region.

A cable harness assembly includes a cable having a pair of wires and a connector assembly including an inner ferrule formed of a conductive material. Each of the wires has a conductor and a insulation disposed around the conductor. The pair of wires have a twisted region and an untwisted region. The inner ferrule has a cable passageway extending through the inner ferrule and a separator disposed within the cable passageway. The untwisted region is disposed in the inner ferrule and the separator is disposed between the wires in the untwisted region.

A cable harness assembly includes a cable having a pair of wires and a connector assembly including an inner ferrule formed of a conductive material. Each of the wires has a conductor and a insulation disposed around the conductor. The pair of wires have a twisted region and an untwisted region. The inner ferrule has a cable passageway extending through the inner ferrule and a separator disposed within the cable passageway. The untwisted region is disposed in the inner ferrule and the separator is disposed between the wires in the untwisted region.

The present disclosure describes methods of manufacture and implementations of hybrid separators for data cables having conductive and non-conductive or metallic and non-metallic portions, and data cables including such hybrid separators. A hybrid separator comprising one or more conductive portions and one or more non-conductive portions may be positioned within a data cable between adjacent pairs of twisted insulated and shielded or unshielded conductors so as to provide physical and electrical separation of the conductors. The position and extent (laterally and longitudinally) of each conductive portion and each non-conductive portion may be selected for optimum performance of the data cable, including attenuation or rejection of cross talk, reduction of return loss, increase of stability, and control of impedance

The present disclosure describes methods of manufacture and implementations of hybrid separators for data cables having conductive and non-conductive or metallic and non-metallic portions, and data cables including such hybrid separators. A hybrid separator comprising one or more conductive portions and one or more non-conductive portions may be positioned within a data cable between adjacent pairs of twisted insulated and shielded or unshielded conductors so as to provide physical and electrical separation of the conductors. The position and extent (laterally and longitudinally) of each conductive portion and each non-conductive portion may be selected for optimum performance of the data cable, including attenuation or rejection of cross talk, reduction of return loss, increase of stability, and control of impedance