Embodiments of a multi-function power strip are shown, said strip including a first endcap and a second endcap; at least one rail, said rail being adapted to engage with at least one outlet module; the rail also being engaged with a transformer module, said transformer module in electrical connection with the at least one outlet module, and adapted to receive electrical power therefrom, said transformer module further comprising a transformer adapted to transform electrical power into a plurality of voltages suitable for powering a plurality of different models of electronic accessories, and a connector forming a circuit to provide a suitable one of the plurality of voltages to an electronic accessory; and wherein the at least one outlet module and the transformer module are releasably joined together.

A female connector capable of easily confirming whether or not a male connector is connected thereto, a connector module having the male connector, and an electronic device having the connector module are disclosed. The female connector comprises a connector body, a first terminal engagement pin and a second terminal engagement pin. The first terminal engagement pin is disposed inside the connector body and capable of receiving an input signal from a connection terminal of a male connector when the connection terminal is in contact therewith. The second terminal engaging pin is disposed inside the connector body to be spaced apart from the first terminal engaging pin. The first and second terminal engagement pins are electrically connected with each other through the connection terminal when the connection terminal is inserted and coupled between the first and second terminal engagement pins.

A resettable switching apparatus, useful in a GFCI receptacle, has an auto-monitoring circuit for automatically testing various functions and structures of the device. The auto-monitoring circuit initiates an auto-monitoring routine which, among other things, establishes a test fault situation on either the positive or negative half-wave of the power cycle and determines whether the detection mechanisms within the device appropriately detect the test fault and whether the device would trip in the event of an actual fault. Additional functionality of the auto-monitoring circuit permits automatic verification that the device is properly wired, that is, not miswired, and determines whether the device has reached the end of its useful life.

An exemplary connector insert assembly, and methods of manufacture and use thereof. In one embodiment, the connector insert assembly comprises an insert body assembly consisting of two insert body elements made from a high-temperature polymer. The insert body assembly includes an electronic component receiving cavity that is configured to receive any number of electronic components, including without limitation, chip chokes and wire wound electronic components. The insert body assembly includes a wire termination feature that includes termination slots that position the wire ends of the wire wound electronic components adjacent to a substrate to which the wire ends are ultimately to be secured. The wire ends are then secured to the substrate using, for example, a mass termination technique. The aforementioned connector insert assembly can then be inserted into a single or multi-port connector assembly. Methods of manufacturing the aforementioned single or multi-port connector assemblies are also disclosed.

A connector assembly includes a first side connector and a second side connector. The first side connector includes a first protective housing, a first inductor including a first end face, and a first physical connector element. The second side connector includes a second protective housing, a second inductor including a second face, and a second physical connector element. The second physical connector element is engaged with the first physical connector element and physically connects the first side connector to the second side connector such that the first end face and the second end face are adjacent. The first inductor and the second inductor are axially spaced apart. The first inductor and the second inductor form an inductive telemetry connection between the first side connector and the second side connector.

The present invention relates to methods and systems for minimizing alien crosstalk between connectors. Specifically, the methods and systems relate to isolation and compensation techniques for minimizing alien crosstalk between connectors for use with high-speed data cabling. A frame can be configured to receive a number of connectors. Shield structures may be positioned to isolate at least a subset of the connectors from one another. The connectors can be positioned to move at least a subset of the connectors away from alignment with a common plane. A signal compensator may be configured to adjust a data signal to compensate for alien crosstalk. The connectors are configured to efficiently and accurately propagate high-speed data signals by, among other functions, minimizing alien crosstalk.

A cable connector is provided which includes an insulating body including a frame which defines a region therein; a plurality of electrical terminals fixed to the insulating body and extended into the region; and a plurality of cables electrically connected to the electrical terminals respectively in the region. The region is filled with an insulator to embed the electrical terminals and the cables. The cable connector has a relatively high reliability.

A filter assembly for a high-voltage connector is disclosed. The filter assembly has a first and a second bus bar, a filter circuit disposed on a circuit carrier, a ring core, and a filter housing. Each bus bar has a first terminal section, a second terminal section, and a connecting section between the first terminal section and the second terminal section. The filter circuit, the ring core, and at least a part of the first and second bus bars are disposed in the filter housing. The first and second bus bars extend substantially parallel to each other and through the ring core. The circuit carrier is disposed in a region of the filter housing in which the connecting section of each of the first and second bus bars is accommodated.

Technologies for providing DC arc protection in a DC socket include an electromagnet positioned in the DC socket configured to produce a magnetic field. The electromagnet is positioned to be adjacent to a contact region between one or more supply terminals of a DC socket and one or more prongs of a DC plug. As the DC plug is disconnected from the DC socket, a DC arc might form between one or more of the supply terminals and one or more of the prongs. The magnetic field produced by the electromagnet reduces the energy of the DC arc and reduces the time duration of the DC arc.

The subject disclosure relates to improved integrated connector module (ICM) designs for Ethernet applications. Some aspects provide an improved integrated connector module transformer (ICMt), including a wafer configured to hold a plurality of toroid elements, wherein the wafer is comprised of two or more mechanically coupled wafer portions. The ICMt can include one or more Electro Magnetic Interference (EMI) fingers that are configured to contact a ground pad of a printed circuit board (PCB) in order to provide a low-inductance connection between the ICMt and the ground pad of the PCB.