Described herein is a rotary coupling structure which comprises a fixing base and a rotary coupling plug; and the fixing base comprises a mounting member and a rotating member; the mounting member comprises a sleeve provided on the inner wall with a lock slot, a limit buckle disposed at the end of the sleeve, and a side boss disposed on the side wall of the sleeve; the rotary coupling plug, configured to be inserted into the sleeve and connected with a connector, is provided with a rotary lock blade rotatively disposed in the lock slot.

A controllable electrical outlet may comprise a resonant loop antenna. The resonant loop antenna may comprise a feed loop electrically coupled to a radio-frequency (RF) communication circuit and a main loop magnetically coupled to the feed loop. The controllable electrical outlet may comprise one or more electrical receptacles configured to receive a plug of a plug-in electrical load and may be configured to control power delivered to the plug-in electrical load in response to an RF signal received via the RF communication circuit. The RF performance of the controllable electrical outlet may be substantially immune to devices plugged into the receptacles (e.g., plugs, power supplies, etc.) due to the operation of the resonant loop antenna. For example, degradation of the RF performance of the controllable electrical outlet may be less when the controllable electrical outlet includes the resonant loop antenna rather than other types of antennas.

An active cable avoiding influence of RX power consumption, comprising: the host connection end, the device connection end and the data wire and the auxiliary wire located between them. The auxiliary wire consists of the main power wire and the auxiliary power wire, wherein, the main power wire is used for current transmission between the VBUS of the host and the device; the auxiliary wire, one end of it is located at the host connection end and connected with the main power wire, and another end at the device connection end and is used for supply power to the active component at the device connection end. The present invention disconnects an active module of the device connection end from the VBUS , thereby solving excessive IR-drop of VBUS; the present invention also arranges the power module between the active component and the auxiliary wire.

A power adapting device includes an upper housing, a power conversion module, and a lower housing. The upper housing comprises a first slot and a second slot. A first power adapter interface is disposed at a bottom of the first slot. A second power adapter interface is disposed at a bottom of the second slot. The first power adapter interface conducts an AC power signal to an external device. The second power adapter interface conducts a DC power signal to an external device. The power conversion module converts the AC power signal into the DC power signal and to transmit the converted DC power signal to the second power adapter interface. The lower housing covers the power conversion module with the upper housing. The lower housing includes a cable transfer interface for transmitting the external power supply to the first power adapter interface or the power conversion module.

A power outlet, and associated method, for an electrical power supply strip. The power outlet includes a housing, an electrical connection for receiving first electrical power type, electrical components to change the first electrical power type to a second electrical power type, and a connection interface to supplying the second electrical power type. The power outlet housing has a body with a shape that corresponds to a shaped aperture of a main housing of the strip. A front portion of the power outlet housing is larger than the shaped aperture. An elastically deformable arm extends from the body and deforms as the arm passes through the shaped aperture of the main housing. An engagement portion of the arm retains the power outlet housing relative to the main housing.

An integrated device includes a power adapter and a wireless module. The power adapter includes a charging plug and a first connector. The wireless module includes a second connector mateable with the first connector. Each of the power adapter and the wireless module is an independent device. In addition, the power adapter and the wireless module can be detachably combined together through the first connector and the second connector. With this arrangement, when the power adapter and the wireless module are used separately, their respective functions can be achieved. When the power adapter and the wireless module are used in combination, the wireless module can be powered by the power adapter, thereby improving the convenience of using the integrated device.

Disclosed are network cable connectors with components such as wireless transceivers, wireless power receivers, displays, and printed circuit with controllers. The disclosed network cable connector may be wirelessly coupled to an external power source. The printed circuit of the cable connector may receive power for the wireless transceiver and/or the display from the external power source. The printed circuit of the cable connector may communicate information about the network cable and/or devices connected thereto via the wireless transceiver to an external device, output the information via the display, or a combination thereof.

A power adaption device includes an electrical cord assembly and an adaptor plug assembly. The adaptor plug assembly includes an electrical conduction member and a tightness adjustment member. The electrical conduction member is formed with an insertion hole and an adjustment hole in communication with each other. The electrical cord assembly is insertable into the insertion hole to electrically connect the electrical cord assembly with the electrical conduction member. The tightness adjustment member is screwed into and connected to the adjustment hole to abut the electrical cord assembly. As such, firmness of connection between the electrical cord assembly and the adaptor plug assembly can be enhanced.

A power adapter is disclosed. The power adapter includes housing parts that carries electronic components. To secure the housing parts together, one housing part includes snaps and another housing part includes protrusions and rails. During assembly, the protrusions slide under the snap, causing the snap to deflect in one direction, while the rails slide over the snap, which keeps the snap partially flat but also causes the snap to deflect in another direction. The engagement (during assembly) of the rails and the protrusions to opposing surfaces of the snap cause bi-directional deflection/bending of the snap. When each protrusion is positioned into an opening of the snap, the snap returns to a flat, non-deflected state, and the housing parts are secured together by the snap, protrusions, and rails. The rails support the snaps by limiting or preventing additional deflection of the snap, which subsequently promotes the housing remaining together.

A fusible link cable harness and systems and methods for addressing fusible link cable harnesses are provided. The fusible link cable harness, for example, may include, but is not limited to, a first connector having a plurality of pins, the plurality of pins comprising a main addressing pin and a plurality of secondary addressing pins, and a fusible link board, the fusible link board including, but not limited to, a bus coupled to the main addressing pin, and a plurality of fusible links, each of the plurality of fusible links coupled between one of the secondary addressing pins and the bus.