According to one aspect, embodiments of the invention provide a system for monitoring a load center including a plurality of current sensors, a communication bus, a plurality of sensor circuits, a power module configured to be coupled to a load center input line and to receive input AC power from the input line, a collector, and a cable configured to be coupled between the power module and the collector, wherein the power module is further configured to provide power to the plurality of sensor circuits via the communication bus, provide power to the collector via the cable, measure at least one of voltage, frequency and phase of input AC power and provide signals related to the measured voltage, frequency or phase to the collector via the cable, receive current measurement signals from the plurality of sensor circuits and provide the received current measurement signals to the collector via the cable.

A plug connector device, in particular an RJ plug connector device, has a plug connector unit which is configured to create a plug connection extending along a plugging direction and which comprises a contact unit with at least two electric plug contacts, wherein the plug connector device includes a cable receiving unit comprising a wiring block for an accommodation of conductor cores of an electric cable and comprising a connection unit for creating a connection to at least one further element of the cable that is different from a conductor core, and that the plug connector device includes a wiring assistance unit, which is configured for a tool-less establishing of a connection between the wiring block and the contact unit.

An electrical contact terminal includes a base portion for positioning and retaining the electrical contact terminal within a connector housing, an insulation displacement connecting portion extending upwardly from the base portion and comprising a pair of spaced apart arms defining an opening therebetween for receiving and making electrical contact with an electrical conductor, and a contact portion extending downwardly from the base portion and configured to float when the electrical contact terminal is retained and positioned within a connector housing. The contact portion includes a first arm, a second arm, and an arcuate base portion. The first arm extends downwardly and includes a first end attached to the base portion and an opposite second end. The second arm extends downwardly and includes a free first end closer to the base portion and an opposite second end farther from the base portion. The second arm is configured to deflect when making electrical contact with a mating contact pin. The arcuate base portion connects the second ends of the first and second arms.

A wire containment cap includes a first side having a plurality of retainers for retaining wires, and a second side opposite the first side. Two sidewalls extend between the first side and the second side, and a support rib extends between the two sidewalls. The support rib includes two pair separators for separating wire pairs. In one embodiment, a plurality of sloped pair splitters is located between two of the retainers and includes a sharp point for cutting through insulation material on a pair of bonded wires. A communication jack assembly including a front portion and the wire containment cap is also described.

An apparatus and method for crosstalk compensation in a jack of a modular communications connector includes a flexible printed circuit board connected to jack contacts and to connections to a network cable. The flexible printed circuit board includes conductive traces arranged as one or more couplings to provide crosstalk compensation.

A connector (10) configured to bring an object (70) into conduction comprises: a pair of fitting bodies fittable to each other; and a filler (60) with which at least one fitting body of the pair of fitting bodies is loaded, wherein a fitting body of the pair of fitting bodies includes an accommodating portion (35a) configured to accommodate an end of the object (70), and the filler (60) is configured to cover the end of the object (70) in the accommodating portion (35a).

The present disclosure relates to a telecommunications connector having cross-talk compensations, and a method of managing alien crosstalk in such a connector. In one example, the telecommunications connector includes electrical conductors arranged in differential pairs and a circuit board with conductive layers that provide a cross-talk compensation arrangement for applying capacitance between the electrical conductors. The circuit board includes conductive paths that provide capacitive coupling and a conductive plate that intensifies capacitive coupling of the electrical conductors. In another example, the telecommunications connector is used with a twisted pair system. Capacitances applied by the crosstalk compensation arrangement between electrical conductors associated with the pairs are provided such that, for each differential pair, a magnitude of an overall capacitance at a first electrical conductor of a differential pair is approximately equal to a magnitude of an overall capacitance at a second electrical conductor of the differential pair.

A connector for receiving a ribbon cable is provided. The connector includes a housing including an open top, a cable organizer, and a cover. The cable organizer is configured to be positioned within an interior of the housing and configured to receive the ribbon cable upon an upper surface thereof. The cover is configured to selectively cover the open top of the housing to enclose the cable organizer within the interior of the housing. The cover is coupled to the housing and includes a latch configured to engage the housing and the cable organizer and move in a both vertical direction relative to the housing and rotate relative to the housing.

Plug connector (10) with at least one spring or blade contact element (410) arranged in a housing, the spring or blade contact element being connected in an electrically conductive manner to at least one displacement insulation contact (430), which contacts and fixes at least one single-core, insulated cable (301, 302, 303, 304), characterised in that the at least one displacement insulation contact (430) is arranged offset by 90° in the plug direction (R) of the spring or blade contact element (410) relative to the spring or blade contact element (410) such that the at least one single-core, insulated cable is contacted and fixed in the plug direction passing through a displacement insulation contact.

A connector includes a modular connector including: a connector body; a substrate positioned in the connector body; wire termination contacts electrically coupled to the substrate; connector contacts electrically coupled to the substrate; the substrate including traces that electrically connect each of the wire contacts to a respective one of the connector contacts; a lacing cap subassembly including: a lacing cap having a plurality of wire receiving slots; a lacing cap body coupled to the lacing cap; a lacing cap door hingedly coupled to the lacing cap body, the lacing cap door moveable between an open and closed position.