The disclosure relates to a mount assembly for add-in card including a base plate, a tray, and a handle. The tray is slidably disposed on the base plate. The handle includes a pivot portion and a tray installation portion. The pivot portion is pivotally disposed on the base plate. The tray installation portion is pivotally and slidably disposed on the tray. In addition, the disclosure also relates to an electronic device having the mount assembly and a chassis for the electronic device.

A thermal management device with electromagnetic (EM) shielding includes a fin pack with a plurality of channels. The fin pack has an upper and lower surface. The fin pack has a pack length, pack height, and pack width. The fin pack has fins are oriented connecting the upper surface to the lower surface. The plurality of channels extends from a first end toward a second end. A first channel of the plurality of channels is adjacent the upper surface, and a second channel of the plurality of channels is adjacent the lower surface.

An apparatus includes a ear piece case housing, a receptacle within the ear piece case housing and configured to hold an earpiece, an earpiece connector at the receptacle and configured to electrically connect with the earpiece, and electromagnetic shielding materials integrated into the ear piece case housing to electromagnetically isolate the earpiece while the earpiece is contained within the case housing. The ear piece case housing may include a charger and a removable slide cover adapted for sliding over the charger.

A remotely controlled unmanned aerial device for use in proximity or in contact with high voltage powerlines, includes an unmanned aerial vehicle and an electrically conductive shield forming part of or operatively coupled to so as to encapsulate the unmanned aerial vehicle. When in the presence of a high voltage powerline, the unmanned aerial vehicle either when bonded-on or within the corresponding magnetic fields of the powerline, so as to transfer the powerline potential in whole or in part to the unmanned aerial vehicle, electrically energizes the conductive shield around the unmanned aerial vehicle while leaving components of the unmanned aerial vehicle within the shield substantially electrically unaffected by the voltage potential.

An electronic device is provided in the present disclosure, and the electronic device includes a middle frame, a heat transfer unit, a shielding case, a heat source and a radiator. The middle frame includes a first surface. The heat transfer unit is disposed on the first surface. The shielding case is spaced apart from the heat transfer unit and is provided with a shielding cavity. The heat source is disposed between the heat transfer unit and the shielding case and includes a circuit board disposed on the heat transfer unit and a first heat source component disposed on the circuit board, the first heat source component is disposed in the shielding cavity. The radiator is configured to dissipate heat from the shielding case and/or the heat source.

Encapsulated PCB assembly (1) for electrical connection to a high- or medium-voltage power conductor in a power distribution network of a national grid, comprising a) a PCB (10), delimited by a peripheral edge (20) and comprising a high-tension pad (60, 62) on a voltage of at least one kilovolt, b) an electrically insulating encapsulation body (70) in surface contact with, and enveloping, the high-tension pad and at least a portion of the PCB edge adjacent to the high-tension pad, c) a shielding layer (80) on an external surface (90) of the encapsulation body and for being held on electrical ground or on a low voltage to shield at least a low-voltage portion of the PCB. The high-tension pad extends to the peripheral edge of the PCB.

According to an embodiment, an electronic device may include: a foldable housing including: a hinge; a first housing connected to the hinge and including a first face facing a first direction and a second face facing a second direction opposite the first direction; and a second housing connected to the hinge and including a third face facing a third direction and a fourth face facing a fourth direction opposite the third direction, the second housing configured to be folded relative to the first housing about the hinge, wherein, in a folded state, the first face faces the third face, and, in an unfolded state, the third direction is the same as the first direction; a display including a first portion and a second portion extending from the first face to the third face to form the first face and the third face, respectively; a digitizer including a third portion disposed between the first portion of the display and the second face and a fourth portion disposed between the second portion of the display and the fourth face; a first magnet disposed in the first housing to overlap the third portion of the digitizer when viewed from above the second face; a second magnet disposed in the second housing to overlap the fourth portion of the digitizer when viewed from above the fourth face and to face the first magnet in the folded state; a first magnetic shield fixed to the hinge and at least partially disposed in the first housing, the first magnetic shield configured to be movable relative to the first magnet wherein, when viewed from above the second face, the first magnetic shield member does not overlap the first magnet in the folded state and overlaps the first magnet in the unfolded state; and a second magnetic shield fixed to the hinge and at least partially disposed in the second housing, the second magnetic shield configured to be movable relative to the second magnet wherein, when viewed from above the second face, the second magnetic shield member does not overlap the second magnet in the folded state and overlaps the second magnet in the unfolded state.

A modular system of plastic walls having embedded and coextensive electrically conductive components configured to electrically connect with each other when the walls are mated. The walls have joining edges that form joint seams with other walls when joined together to create an enclosure. When enough walls are used to surround a storage space, a Faraday cage is created. The walls additionally have portions of tortuous paths at each joining edge that mate with a complementary portion of a tortuous path of another wall when the walls are joined together. A torturous path seal is thereby created at each joint seam. The plastic walls can be configured in a multiplicity of combinations to create various enclosures necessary for RFID-enabled storage and tracking of medical articles. Containers, enclosures, cabinets, and drawers of differing heights and sizes can be made and they may be stacked or otherwise assembled.

A method of operating a public utility facility includes receiving a commodity at a processing facility communicably coupled to a control system that includes primary electrical components configured to operate the processing facility, and transitioning operation of the processing facility to an electromagnetic pulse mitigation module communicably coupled to the processing facility via a fiber optic line when the primary electrical components are rendered inoperable. The electromagnetic pulse mitigation module comprises a continuous conductive enclosure that is impervious to radiated and coupled electromagnetic energy. Operation of the primary electrical components is then assumed with one or more backup electrical components housed within the electromagnetic pulse mitigation module.

This sensor includes: a housing 10 which houses an electronic component in the internal space; a detection unit 40 which has a coil 42 and a core 41 that houses the coil 42 and which is arranged on the end side in the internal space; a substrate 30 which is arranged more inside the internal space than the detection unit 40 and on which a circuit electrically connected to the coil 42 is provided; a first shield 451 at least one portion of which is arranged further on the end side in the internal space than the detection unit 40 and which suppresses the penetration of noise from outside of the housing 10; and a spacer 51 which is positioned between the first shield 451 and the detection unit 40 and which separates the surfaces of the first shield 451 and the detection unit 40 that face each other.