An electronic device including a shield structure is provided. The electronic device includes a first device including a first magnetic substance, a second device including a second magnetic substance, and a shield structure configured to shield at least part of a magnetic force generated between the first magnetic substance and the second magnetic substance, wherein the shield structure includes a shield member disposed between the first device and the second device and including a property of a magnetic substance, and a connecting member physically connected to at least part of the shield member and including a property of a nonmagnetic substance, wherein at least part of the connecting member is physically connected to a circuit board.

Embodiments described herein generally relate to a substrate support assembly having a shield cover. In one embodiment, a substrate support assembly is disclosed herein. The substrate support assembly includes a support plate, a plurality of RF return straps, at least one shield cover, and a stem. The support plate is configured to support a substrate. The plurality of RF return straps are coupled to a bottom surface of the support plate. At least one shield cover is coupled to the bottom surface of the support plate, between the plurality of RF return straps and the bottom surface. The stem is coupled to the support plate.

A magnetic stand for a tablet device is disclosed. The magnetic stand is configured to rigidly hold a portion of the tablet device in place and to shield the magnetic field from adversely affecting nearby devices susceptible to strong magnetic fields. The shielding portion of the magnetic stand allows for significant increases in magnetic field strength when compared to similarly configured, unshielded products.

In one embodiment, an electromagnetic interference (EMI) shielding faceplate is configured to mount to a line-card slot of a multi-line-card electronic enclosure having an airflow cooling system. A perforation pattern in the faceplate defines an array of perforations in the faceplate, while a flow control sheet affixed to the faceplate and covering an adjustable percentage of the array of perforations in the faceplate from 0-100%, where an amount of airflow impedance caused by the perforations for the airflow cooling system is based on the percentage of the array of perforations covered by the flow control sheet.

The invention specifies an electronic component which has a first electrode (10), a second electrode (20), an active region (30), which is electrically coupled to the first electrode (10) and to the second electrode (20), and a housing (100), wherein the housing (100) contains carbon layers which are monoatomic at least in subregions.

The invention relates to a hybrid medical PET-SPECT/MR imaging device comprising at least one scintillating crystal and at least one module for detecting radiation which contains at least one matrix of photodetectors and an electronics section, such that said module has a mechanical structure, the external, internal or both surfaces of which are divided into at least two sections, of which at least one is coated in graphene, and the rest in non-ferromagnetic conductive material, or all the sections are coated in graphene, and such that the coating forms a Faraday cage. The invention also relates to a shielding against radiofrequency for a medical imaging device, comprising a graphene coating, which is continuous or in bands, on all the faces of the mechanical structure of the detection module of the device, or a graphene coating, continuous or in bands, on at least one face, combined with a coating of non-ferromagnetic conductive materials on the remaining faces, and said shielding forming a Faraday cage.

Embodiments of the present invention provide an improved access control unit with an asymmetric transmission pattern. A shielded backplate reduces the interior transmission pattern. The secure side transmission pattern is much smaller than the unsecure side transmission pattern, such that a credential located within the secure side area of a building is not likely to trigger the access control unit, thus reducing the risk of an unauthorized access.

An electromagnetic wave shielding structure of a console installed in a passenger compartment of a vehicle has an electrical instrument installed in the console from which electromagnetic waves are radiated, a transmission including a metal member that receives the electromagnetic waves and transmits the electromagnetic waves to the passenger compartment and separated by a distance from the electrical instrument, and a shielding member located between the electrical instrument and the transmission to function as a shield against the electromagnetic waves radiated from the electrical instrument. The transmission is located in a shield region defined such that an electromagnetic wave radiating portion provided at the electrical instrument from which the electromagnetic waves are radiated is connected to a circumferential edge of the shielding member via a straight line, and the line is continuously moved along the circumferential edge of the shielding member around the electromagnetic wave radiating portion.

A display device is basically provided that comprises a display, two circuit boards, and a cable. The cable connects the circuit boards together and includes a sheet-form wiring component having a first face and a second face on the opposite side from the first face, a first insulating part that is disposed on the first face, and a shield component that is disposed on the first insulating part and shields electromagnetic waves. The cable has a bent part that is bent to a second face side. The angle α formed by a direction towards one end of the wiring component from the bent part and a direction towards the other end of the wiring component from the bent part is 0°<α<180°.

A shielding arrangement can be provided for a piece of high voltage equipment spaced from a neighboring object. The piece of high voltage equipment has a first electric potential and the neighboring object has a second electric potential. The shielding arrangement includes a resistor, a shield element for connection to the high voltage equipment via the resistor, and a capacitor connected in parallel with the resistor. A resistance of the resistor and a capacitance of the capacitor together define a time constant in a range of 10 μs-50 ms.