An insulation displacement contact system includes a first insulation displacement contact, a second insulation displacement contact, and a cover having a first portion over the first insulation displacement contact and a second portion over the second insulation displacement contact. The cover includes a retention gap between the first portion and the second portion to engage the cover with a first pair of prongs of the first insulation displacement contact. The first portion of the cover includes a first ledge and a second ledge configured to engage the cover with a second pair of prongs of the first insulation displacement contact.

An insulation displacement contact system includes a first insulation displacement contact, a second insulation displacement contact, and a cover having a first portion over the first insulation displacement contact and a second portion over the second insulation displacement contact. The cover includes a retention gap between the first portion and the second portion to engage the cover with a first pair of prongs of the first insulation displacement contact. The first portion of the cover includes a first ledge and a second ledge configured to engage the cover with a second pair of prongs of the first insulation displacement contact.

A power metering device includes a tap unit including a clamp for engaging a coaxial cable and a probe for electrically coupling to a center conductor of the coaxial cable without damaging the center conductor. A power consumption meter and a power port are electrically connected to the probe. A power transformer is optionally connected between the probe and the power port. A housing surrounds the meter and transformer. The power port supplies power to a customer device, and the meter measures an amount of power passing through the power port. The power consumed by the customer device is reported by the meter to a modem within the housing. The modem may utilize the probe and the center conductor of the coaxial cable to send power consumption data to a service provider, so that an operator of the customer device may be billed and/or the customer device may be controlled to limit its power consumption. Further, the modem may transfer data between the customer device and the service provider.

A power metering device includes a tap unit including a clamp for engaging a coaxial cable and a probe for electrically coupling to a center conductor of the coaxial cable without damaging the center conductor. A power consumption meter and a power port are electrically connected to the probe. A power transformer is optionally connected between the probe and the power port. A housing surrounds the meter and transformer. The power port supplies power to a customer device, and the meter measures an amount of power passing through the power port. The power consumed by the customer device is reported by the meter to a modem within the housing. The modem may utilize the probe and the center conductor of the coaxial cable to send power consumption data to a service provider, so that an operator of the customer device may be billed and/or the customer device may be controlled to limit its power consumption. Further, the modem may transfer data between the customer device and the service provider.

An insulation displacement contact system includes a first insulation displacement contact, a second insulation displacement contact, and a cover having a first portion over the first insulation displacement contact and a second portion over the second insulation displacement contact. The cover includes a retention gap between the first portion and the second portion to engage the cover with a first pair of prongs of the first insulation displacement contact. The first portion of the cover includes a first ledge and a second ledge configured to engage the cover with a second pair of prongs of the first insulation displacement contact.

An insulation displacement contact system includes a first insulation displacement contact, a second insulation displacement contact, and a cover having a first portion over the first insulation displacement contact and a second portion over the second insulation displacement contact. The cover includes a retention gap between the first portion and the second portion to engage the cover with a first pair of prongs of the first insulation displacement contact. The first portion of the cover includes a first ledge and a second ledge configured to engage the cover with a second pair of prongs of the first insulation displacement contact.

A connector for connecting to a cable having a conducting wire includes an outer shield adapted to receive the cable. A holder is mounted within the shield and receives a center contact of the connector. The center contact receives and electrically contacts the conducting wire, with at least a portion of the center contact being elastically deformed by the conducting wire as it is inserted into the center contact.

A twinax cable assembly comprises a cable lacing section between the assembly end sections. The cable assembly includes twinax cable sets of twinax cables. Each cable includes a pair of conductors spaced apart in a lateral direction. Each of the cable sets has connector ends where each of the cables in the cable sets connects to a terminal component. A tie bar is mounted on one end and another tie bar is mounted on the other end between the lacing section and the ends of the cables. The cables in each cable set lace through the other cable sets with the pair of conductors in each of the twinax cables substantially aligned in the lateral direction such that when the cable assembly bends substantially around a bend axis in the lateral direction the pairs of conductors in each of the twinax cables remain substantially aligned in the lateral direction.

A twinax cable assembly comprises a cable lacing section between the assembly end sections. The cable assembly includes twinax cable sets of twinax cables. Each cable includes a pair of conductors spaced apart in a lateral direction. Each of the cable sets has connector ends where each of the cables in the cable sets connects to a terminal component. A tie bar is mounted on one end and another tie bar is mounted on the other end between the lacing section and the ends of the cables. The cables in each cable set lace through the other cable sets with the pair of conductors in each of the twinax cables substantially aligned in the lateral direction such that when the cable assembly bends substantially around a bend axis in the lateral direction the pairs of conductors in each of the twinax cables remain substantially aligned in the lateral direction.

The invention relates to a positioning element for twin axial cables as well as to a contacting element comprising a positioning element of said type. In an illustrative embodiment of a positioning element for twin axial cables, the positioning element is at least partially electroconductive. Furthermore, the positioning element has at least one recess which is arranged and designed to accommodate a twin axial cable in such a way that an electroconductive connection is established between an outer conductor of the twin axial cable and the positioning element.