An artificial lighted tree is presented with power routed through the trunk and three-wire safety grounding. The tree comprising a fused electrical plug having improved safety features comprising: a body portion surrounding respective first ends of a first, a second and a third electrical wire, the body portion further comprising a fuse holder embedded within an upper region of the body portion, and a fuse adapted to be releasably secured within the fuse holder via releasable securing means, a live blade in communication with the first end of the first electrical wire, a neutral blade in communication with the first end of the second electrical wire, a ground pin receptacle in communication with the first end of the third electrical wire, wherein the body portion surrounds and maintains the live blade, neutral blade, and ground pin receptacle in spaced apart orientation corresponding to polarized sockets on an electrical wall outlet.

A system includes a power switch configured to receive a voltage on a first terminal. The first terminal is coupled to a voltage regulator. The power switch is also configured to provide the voltage to a second terminal. The second terminal is coupled to a VBUS terminal of a Universal Serial Bus Type-C (USB-C) connector. The system also includes a USB controller coupled to the power switch and to the first terminal and the second terminal. The the USB controller is configured to detect a first voltage at the first terminal and to detect a second voltage at the second terminal. The USB controller is configured to adjust operation of the power switch in response to determining that the second voltage is above a particular voltage or within a particular voltage range.

An electronic device includes a first switch configured to connect a first sideband use (SBU) terminal of a Universal Serial Bus Type-C (USB-C) controller to a first SBU terminal of a USB-C receptacle. The electronic device also includes a second switch configured to connect a second sideband use (SBU) terminal of the USB-C controller to a second SBU terminal of the USB-C receptacle. The electronic device further includes a voltage protection circuit configured to deactivate one or more of the first switch and the second switch when a voltage exceeding a predetermined threshold is detected. The voltage protection circuit includes a first set of diodes coupled to the first SBU terminal of the USB-C controller and a second set of diodes coupled to the second SBU terminal of the USB-C controller.

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.

Embodiments of the disclosure provide an electrical power surge arresting apparatus. Specifically, the surge arresting apparatus may be implemented within a port of an electrical power cord. In some embodiments, the surge arresting power cable comprises a plurality of conductive plates that may be attached to the hot, neutral, and ground leads of the electrical power cord. A plurality of Metal Oxide Varistors (MOV) may be positioned between the plurality of conductive plates. The plurality of conductive plates may be directly coupled to or comprise a plurality of conductive clips that may be configured to directly couple to a surge protected electronic device. Accordingly, there are no leads between the surge protecting device and the surge protected electronic device. The surge arresting device may further comprise one or more capacitors serving as a low-pass filter.

Systems, methods, and apparatus to facilitate wireless device monitoring and control are provided. A first device controller may be adapted to be disposed within a power connector, in series with conductors of the power connector. The power connector may be adapted to provide power from a power source to a device. The first device controller may include two terminals to electrically couple the first device controller with the conductors of the power connector. The first device controller may further include a power component to power the first device controller. The first device controller may be configured to monitor one or more conditions of the device, control one or more functions of the device, and wirelessly communicate with a system controller that is remote from the power connector and the device. The power connector may correspond to a power plug and/or a terminal block.

A wireless-controlled smart plug device and methods of use and operation, using a solid state switch to provide electrical power from an outlet to a load, and provide protection against overload, short circuit, ground, arc, or voltage surge faults. The switch includes a bidirectional semiconductor switch with two back-to-back connected transistors, such as silicon power MOSFETs, silicon insulated-gate bipolar transistors (IGBTs), silicon carbide (SiC) transistors, or gallium nitride (GaN) transistors, each configured to control the current flow from the electrical receptacle to the external electrical load.

A connector comprises a terminal and a layered circuit substrate. The layered circuit substrate connects to an end of the terminal, and comprises a PTC material layer, a first electrode layer forming an upper layer of the layered circuit substrate, and a second electrode layer forming a lower surface of the layered circuit substrate. The PTC material layer is disposed between the first and second electrode layers. The first and second electrode layers comprise first and second electrode pads which connect to a power supply, and the PTC material layer electrically connects to the first and second electrode pads to form an electrically conductive path in which the PTC material layer serves as a PTC resistor in series connection between the first and second electrode pads. When over-current or over-temperature occurs in the electrically conductive path, the PTC resistor will trip to a high resistance state.

A connector structure includes a first connector, a second connector and a capacitance device. The first connector has a first end and a second end opposite to the first end. A plurality of first metal terminals extends in a first direction at the first end. The second end is configured to be detachably connected to a first external device. The second connector has a third end and a fourth end opposite to the third end. A plurality of second metal terminals extends in a second direction at the third end. The second direction is not parallel to the first direction. The fourth end is configured to be detachably connected to a second external device. The capacitance device includes capacitors coupled to the first connector and the second connector respectively through the first metal terminals and the second metal terminals.

A controlled-power RJ45 socket includes a housing having a cavity to receive an RJ45 plug. The socket further includes electrical contacts positioned in the cavity and that come in contact with electrical contacts of the RJ45 plug when the RJ45 plug is plugged into the RJ45 socket. A switch is positioned to disconnect the power to the electrical contacts of the RJ45 socket before the electrical contacts of the RJ45 plug are physically detached from the electrical contacts of the RJ45 socket during a de-mating of the RJ45 plug from the RJ45 socket.