Described are a shielding case, a Printed Circuit Board (PCB) and a terminal device. The shielding case includes a first shielding case body (1) and a second shielding case body (2) which are interconnected with each other, wherein the second shielding case body (2) at least partially covers an outside of the first shielding case body (1), and a heat storage material (3) is accommodated between the first shielding case body (1) and the second shielding case body (2).

A radio frequency (RF) shield includes a shield enclosure formed of conductive material that defines and partially encloses an interior cavity. The shield enclosure is configured to receive, within the interior cavity, a shielding partition securable in a fixed position that defines one end of a first chamber within a narrow portion of the shield enclosure. The first chamber provides RF isolation of an RF conductor that is enclosed within the first chamber.

Various circuit board systems and methods of use and manufacture thereof are disclosed. A circuit board system can have a first circuit board including a substrate and a first component susceptible to electromagnetic interference carried by the substrate. The system can also include a second circuit board including a second substrate, and a shield engaged to the substrate of the first component, the shield at least partially covering the first component and being configured to protect the first component from electromagnetic interference, wherein the shield couples the substrate of the first circuit board to the substrate of the second circuit board.

The present disclosure provides a protective enclosure for electronic systems. The enclosure comprises a polymer-containing matrix and a metamaterial incorporated into the matrix. The metamaterial is tuned to a specific permittivity or permeability to absorb or reflect a particular frequency. The protective enclosure may be used to create a safe inner environment for electronic components while facilitating uninterrupted wireless communications to/from the outer environment. Additionally, the protective enclosure may be used to protect against electromagnetic interference. In particular, shielding metamaterials are configured individually or in combination to specifically shield (via reflection, absorption, etc.) against relatively wide bands of electromagnetic frequencies, while transparent metamaterials are configured specifically to pass electromagnetic signals within narrow bands of frequencies. This new approach resolves and vastly improves current shield solutions, such as Faraday cages. For example, tuned metamaterials may be configured across a variety of preconfigured frequencies, and can be constructed of lightweight materials.

Various circuit board systems and methods of use and manufacture thereof are disclosed. A circuit board system can have a first circuit board including a substrate and a first component susceptible to electromagnetic interference carried by the substrate. The system can also include a second circuit board including a second substrate, and a shield engaged to the substrate of the first component, the shield at least partially covering the first component and being configured to protect the first component from electromagnetic interference, wherein the shield couples the substrate of the first circuit board to the substrate of the second circuit board.

A negative potential inducing device has a box body, an AC/DC converter, a booster, a second wire, a lid and an insulating rod. The box body has a side wall, and the side wall has a via. The AC/DC converter is arranged inside the box body, and electrically connected with a plug through a first wire. The booster is arranged inside the box body and electrically connected with the AC/DC converter. The second wire passes through the via, wherein one end of the second wire is electrically connected with the booster. The lid covers the box body. A metal wire on another end of the second wire is exposed and inserted to one end of the insulating rod and touches the insulating rod.

A receptacle connector assembly includes a receptacle cage having shielding walls including a top wall, a first side wall extending from the top wall to a bottom of the receptacle cage, and a second side wall extending from the top wall opposite the first side wall to the bottom of the receptacle cage. The receptacle connector assembly includes an EMI shield coupled to the receptacle cage at the front end. The EMI shield has a shield member including a base electrically connected to the receptacle cage and spring fingers that extend from the base to distal ends. The EMI shield includes a gasket between the receptacle cage and the corresponding spring fingers. The gasket electrically connects the corresponding spring fingers to the receptacle cage.

Various implementations include a casing device for controlling the distance and direction of readability of a wave. The casing device includes at least one wall having an outer surface and an inner surface that defines a chamber. The at least one wall has at least a first wall portion and a second wall portion. At least the first wall portion includes an electrically conductive material. At least the second wall portion defines an aperture extending from the outer surface to the inner surface.

An enclosure for an electronic device includes one or more surface features that account for manufacturing tolerances associated with the enclosure. The enclosure includes a first portion and a second portion that mates with the first portion. The surface feature extends from a contact surface of the first portion of the enclosure and acts as a contact point between the first portion of the enclosure and the second portion of the enclosure. The surface feature helps ensure each portion of the enclosure remain in contact, which provides the electronic device optimal protection from electrical interference.

A cooling appliance is proposed. A cavity (S) may be provided inside a casing (100, 200). A first heat source module (400) may be arranged in the casing (100, 200) and emit microwaves. A second heat source module (500) may be arranged at a bottom surface of the casing (100, 200) and emit magnetic fields. In addition, the second heat source module (500) may include a base plate (510) having a base hole (512) that is open at a center portion thereof, and a supporter (520) arranged below the base plate (510). A coil assembly (550) may be arranged between base plate (510) and the supporter (520). At this point, a shield filter (540) of the second heat source module (500) covers a working coil (570) of the coil assembly (550), and an outer end of the shield filter (540) may be arranged between the base plate (510) and a coil base (560).