A receptacle for receiving a plug connector of a high-voltage cable for a microfocus X-ray tube with a cathode, which has a metal filament and grid. The receptacle has a ceramic insulator with three contiguous cavities. The first cavity near the filament includes electrical contacts for the filament and the grid. The second cavity includes spring contacts for supplying current to the filament and a center pin for supplying voltage to the grid. The third cavity receives the plug connector. The insulator has a removable grid cap which is conductively connected to the grid of the cathode. The first and second cavities are surrounded in the radial direction by the grid cap, An air gap extends radially between grid cap and ceramic body. At the end of the grid cap remote from the filament is a circumferential groove in the axial direction between the grid cap and the ceramic insulator.

Disclosed are power distribution systems and methods in which a power distribution unit (PDU) is provided with an overcurrent protection device and per-outlet current sensing at each of the multiple electrical outlets of the PDU. The described embodiments enable the identification of the electronic device connected to a specific outlet or electronic device that may have caused the overcurrent protection device to trip. The methods of outlet identification in a PDU having multiple electrical outlets includes detecting whether either a peak current or a half-cycle root mean square (RMS) current at each outlet has exceeded a selected threshold prior to the occurrence of the trip event associated with the overcurrent protection device.

In the wire harness, a connector attached to an electric wire is attached to a socket in a casing main body from a connection port, and the wire harness is connected to an inverter device. In the voltage suppressing section, the bracket is placed across the casing main body connection port and fastened and fixed to the stud bolt, thereby coming into surface contact with the housing of the connector. In the bracket, a flag terminal of a ground wire connected to the body is fastened and fixed to one of the stud bolts. As a result, the area around the connector and the connection port is grounded through the bracket, thereby suppressing common mode voltage, and suppressing radiation noise without using a ferrite core.

An energy-saving charger capable of automatically powering off includes a bridge rectifier circuit, a switch control circuit, a high-frequency transformer, and a low-voltage output circuit that are sequentially connected. The charger further includes: an electronic switch connected in series between the bridge rectifier circuit and the switch control circuit; a low-voltage-end control detection circuit connected to the low-voltage output circuit, used for feeding back a magnitude of a current output by the charger and outputting a control signal; an isolating drive circuit connected to the low-voltage-end control detection circuit; and a power-on self-holding circuit connected to the isolating drive circuit and a control end of the electronic switch, used for controlling on and off of the electronic switch according to the isolated control signal, and providing a short-time ON level to the control end of the electronic switch at the beginning of power-on of the charger.

A lightning protection system of an aircraft when it is electrically powered on the ground by a generator set is described. Such an aircraft consequently includes a fuselage and a connecting connector to allow the connection to the generator set. The connecting connector includes a frame, male electrical contacts protruding on either side of said frame, and a lightning protection system inserted between the male electrical contacts and electrical elements of the aircraft. The protection system includes peak-clipping devices for clipping an electrical signal and a printed circuit having conductive tracks linking the male electrical contacts to the peak-clipping devices.

A circuit includes a connector having first and second mateable portions. Each portion includes at least two terminals configured to mechanically engage at least two terminals of the other portion. The two terminals within the first and second portions are arranged so that as the first and second portions are mated, a first terminal of the first portion and a first terminal of the second portions come into contact before respective second terminals of the first and second portions. The circuit also includes a polymeric positive temperature coefficient (PPTC) device with a first terminal in electrical communication with the first terminal of the first portion and a second terminal in electrical communication with the second terminal of the first portion. A power terminal is in electrical communication with the second terminal of the first portion and is configured to be connected to a power source. A load terminal is in electrical communication with the first and second terminals of the second portion and is configured to be connected to a load.

An electrical connector includes an insulating housing. The insulating housing has an inner wall, a first end, and a second end. The inner wall of the insulating housing defines a cavity and a groove, the groove including a groove wall, the groove wall extending from the cavity radially into the insulating housing to a groove depth. The electrical connector also includes an electrical component in the cavity; an electrically conductive shell at an outer surface of the insulating housing; and a plug in the housing, the plug including a body and projection that radially extends from the body, the projection being received in the groove, where the groove wall applies more than 35 pounds (lbs) of force on the plug in a direction that is toward the electrical component.

A modular electronic apparatus includes an electric box, an insert, and optionally one or more electric modules. The insert is configured to be inserted at least partially into an internal space of the electric box and connect to electric wires of a building. The insert is further configured to receive the electric modules such that they can be powered from the electric wires without directly connecting to them. The electric modules can engage with the insert and be easily replaceable without the need to reconnect the electric wires. Each of the electric modules can be one of the following: a programmable electric socket (smart socket), traditional electric socket, programmable electric switch (smart switch), traditional electric switch, dimmer, touch screen panel, speaker, personal computer, television device, lighting device, audio player, multimedia device, network hub, a router, and the like.

A grounding module for telecommunication systems is mountable to an AC wall outlet and includes two cable connectors to which signal carrying cables are attached. The grounding module includes a housing having a main ground contact to provide a ground to an external electronic device connected thereto. An external grounding lug is mounted on one of the cable connectors to provide a separate ground connection to the metallic sleeves of the cable connectors. At least one of a surge protection circuit and ground protection circuit is provided and which is in electrical communication with the main ground contact. The grounding lug and metallic sleeves of the cable connectors are selectively electrically isolatable from the main ground contact.

An USB electronic device having functionality of electric leakage protection is discloses. The USB electronic device comprises: a power interface, a power conversion circuit, a system controller, a circuit assembly, and a plurality of USB interfaces, of which the USB interfaces consists of at least one first USB interface and at least one second USB interface, and the first USB interface and the second USB interface both include an electrical terminal for supporting a power delivery (PD) communication protocol. In addition, there is an electric leakage preventing circuit provided in the USB electronic device. As such, in case of a power signal being transmitted between the first/second USB interface and an external electronic device by using the PD communication protocol, the electric leakage preventing circuit is enabled to prevent the power signal has a current leakage occurring between the first/second USB interface and the external electronic device.