Described herein is a use-limiting connector for limiting use of an electrical tool. The use-limiting connector comprises a plurality of electrical circuits each having an electrical resistance different than any other of the plurality of electrical circuits. Each electrical circuit of at least two of the plurality of electrical circuits corresponds with a different use of a plurality of uses of the use-limiting connector.

An electrical connector assembly includes a connector body and an electrical component having wire leads extending axially from each end of the body, and electrical terminals. The wire leads are connected to the terminals. The assembly further includes a retainer housing disposed within the connector body. The retainer housing defines a pair of longitudinal channels in which the terminals are disposed. The retainer housing defies a cradle having an arcuate cross section in which the electrical component is disposed. The retainer housing defines a retaining feature configured to retain the electrical component within the cradle.

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.

A plug for joining a polyethylene (PE) jacketed cable to a PE tube is provided. The plug includes first and second heating wires and a PE body. The PE body includes a first section and a second section. The first section is insertible into the PE tube and includes a first surface to engage with the PE tube. The first heating wires are embeddable in the first surface. The second section is within the first section and the PE jacketed cable is insertible into the second section. The second section includes a second surface to engage with the PE jacketed cable. The second heating wires are embeddable in the second section.

Aspects of the present disclosure are directed to a power distribution device. The power distribution device includes an input to receive power, a plurality of outputs, each output of the plurality of outputs being configured to provide output power, and being coupled to the input, a plurality of switching devices, each switching device of the plurality of switching devices being coupled to a respective output of the plurality of outputs, and a controller coupled to each of the plurality of switching devices. The controller is configured to receive power information indicative of the output power provided by each output of the plurality of outputs, determine, based on the power information, that an overcurrent condition exists, select, based on the power information and based on the determination that the overcurrent condition exists, at least one of the plurality of switching devices to disable, and disable the at least one switching device.

An electric connection structure includes: a connection terminal that includes a compression coil spring part; a terminal holding part that includes a base supporting one end surface side of the compression coil spring part and a guide part provided along an outer surface of the compression coil spring part; and a lead wire that includes a folded-back part in one end part. In the electric connection structure, the folded-back part is held between the one end surface of the compression coil spring part and a support part and two lines of the folded-back part are brought into contact with the connection terminal, and the connection terminal and the lead wire are thereby electrically connected.

A connector-assembly includes a housing, a terminal-position-assurance device, and a resistor-assembly. The housing includes a plurality of electrical-terminals. The terminal-position-assurance device is configured to retain the plurality of electrical-terminals within the housing. The resistor-assembly is disposed within the terminal-position-assurance device and includes a first-spring-terminal, a second-spring-terminal, and a resistor disposed between the first-spring-terminal and the second-spring-terminal. The first-spring-terminal and the second-spring-terminal are in separate electrical-communication with at least one of the plurality of electrical-terminals. The resistor has connection-leads disposed within slots formed in both the first-spring-terminal and the second-spring-terminal, and is disposed within channels formed in the terminal-position-assurance device. The first-spring-terminal, the second-spring-terminal, and the terminal-position-assurance device are in compressive contact with a portion of the connection-leads.

A wire tracing system includes a voltage output source having a director circuit with a plurality of output channels. Each of the output channels outputs a unique voltage signature. A voltage reader/data recorder includes a conductive probe and a data memory that is partitioned into a plurality of data bins. Each of the data bins in the voltage reader/data recorder is associated with one of the voltage signatures output via the output channels of the director circuit, and each of the data bins is configured to store information associated with each of a plurality of wires to which the output channels are respectively connectable. The system and method permit a single individual to rapidly discover the identities of individual wires and cables without having to repeatedly travel back and forth between those extremities.

An in-line suspended power sensor coupling configuration situated within a high frequency transmission line housing that allows forward, reverse, and sampling voltage elements to all be produced simultaneously on one double sided printed circuit board (PCB). The power sensor coupling allows for calibrated coupling responses across a much wider frequency range with a single PCB assembly, as opposed to the need to cover equivalently sized frequency ranges with multiple individually fabricated coupling element assemblies.

An electrical connecting device for a charging cable is for charging an electric vehicle. The electrical connecting device includes a network-side first connecting element for electrically connecting the connecting device to an electrical supply network and a charging-cable-side second connecting element for connecting the connecting device to a network-side connector of the charging cable. The first connecting element includes at least two contact elements, each connected in an electrically conductive manner to one of at least two contact elements of the second connecting element; and a first temperature sensor, used for temperature monitoring and which is electrically connected to the second connecting element via a communication cable. The second connecting element has a further contact, connectable to a corresponding further contact of the network-side connector of the charging cable to transmit a signal of the temperature sensor to the charging cable.