A signal cable comprising a plurality of plug parts forming a plug that is operatively connected to signal and ground conductors at one end of a coaxial cable, wherein the plug parts and the end of the coaxial cable are held together only by an insulating overmold material. The assembly has four operatively connected plug parts (12, 20, 24, 30); a signal conductor at one end (42) of a coaxial cable (40) conductively connected to one of the plug parts (12); and an overmold (54) encapsulating the end of the cable and a conductive connection between a cable ground sleeve and another plug part (30).

A signal cable comprising a plurality of plug parts forming a plug that is operatively connected to signal and ground conductors at one end of a coaxial cable, wherein the plug parts and the end of the coaxial cable are held together only by an insulating overmold material. The assembly has four operatively connected plug parts (12, 20, 24, 30); a signal conductor at one end (42) of a coaxial cable (40) conductively connected to one of the plug parts (12); and an overmold (54) encapsulating the end of the cable and a conductive connection between a cable ground sleeve and another plug part (30).

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 electrical connector includes at least two electrical connector elements extending side by side along a longitudinal direction, each of the electrical connector elements being connectable to a respective wire of an associated electrical cable. An electrical device is in electrical contact with the respective electrical connector elements. A flexible carrier surrounds the electrical connector elements annularly in cross section, and the electrical device is mounted on an inner side of the flexible carrier which faces the connector elements.

An electrical connector includes at least two electrical connector elements extending side by side along a longitudinal direction, each of the electrical connector elements being connectable to a respective wire of an associated electrical cable. An electrical device is in electrical contact with the respective electrical connector elements. A flexible carrier surrounds the electrical connector elements annularly in cross section, and the electrical device is mounted on an inner side of the flexible carrier which faces the connector elements.

To allow a fit-in state between electrical connectors to be firmly maintained, elastic arm-shaped members 23d provided to a conductive shell member 23 so as to elastically displace to a direction orthogonal to a fit-in direction of a mating connector 10 are each provided with an engaging piece 23e having a connector contact surface 23e1 which the mating connector 10 faces from the depth in the fit-in direction and a shell contact surface 23e2 which a part of the conductive shell member 23 faces from the front in the fit-in direction. When an external force is applied to the mating connector 10 in a fit-in state to a removing direction opposite to the fit-in direction, the engaging piece 23e is brought into a state of being interposed between the mating connector 10 and the conductive shell member 23. This avoids a situation in which the engaging piece 23e is removed from the mating connector 10 to cause a lock release.

An electrical connector for a multi-wire electrical cable includes at least two cable-side electrical contact elements including associated electrical terminals to each of which is to be connected a wire of the electrical cable. At least two output-side electrical contact elements, from each of which projects an electrical connector element by which an electrical connection can be established to a mating connector. An electrically conductive carrier body is disposed between the cable-side contact elements and the output-side contact elements. The electrically conductive carrier body carries an electrical device by which the cable-side contact elements and the output-side contact elements are electrically connected to each other. The electrical device is supported by the carrier body without any of the cable-side contact elements or the output-side contact elements being in electrical contact with the carrier body through the electrical device.

An electrical connector for a multi-wire electrical cable includes at least two cable-side electrical contact elements including associated electrical terminals to each of which is to be connected a wire of the electrical cable. At least two output-side electrical contact elements, from each of which projects an electrical connector element by which an electrical connection can be established to a mating connector. An electrically conductive carrier body is disposed between the cable-side contact elements and the output-side contact elements. The electrically conductive carrier body carries an electrical device by which the cable-side contact elements and the output-side contact elements are electrically connected to each other. The electrical device is supported by the carrier body without any of the cable-side contact elements or the output-side contact elements being in electrical contact with the carrier body through the electrical device.

A coaxial cable connector for attachment to an end of a coaxial cable is disclosed. The coaxial cable connector includes a rotatable body segment having a body wall with an outer surface and an inner surface defining a width of the body wall. The body wall has a radial dimension which varies along a perimeter of the rotatable body segment. The inner surface defines a longitudinal opening extending between a forward end of the rotatable body segment and a rearward end of the rotatable body segment. A post positions proximal the forward end of the rotatable body segment. The post has a first end and a second end with a bore extending therebetween. The post is rotationally stationary with respect to the rotatable body segment. A coupling member positions proximal to the first end of the post. The rotatable body segment is rotated to close the coaxial cable connector.