A circuit board arrangement, and method for assembling at least one connection element, provides a first circuit board and a second circuit board arranged in a parallel orientation to one another in different planes, and at least one rigid connection element communicates between the first and the second circuit boards and the connection element has an exterior housing which encloses an internal conductor part, and the exterior housing constitutes a first electrical path between the first and second circuit boards, and the internal conductor part constitutes a second electrical path between the first and second circuit boards.

A back cover module adapted to be disposed on a casing having a back opening is provided. The back cover module includes a fixing bracket, a sliding bracket and a rotating mask. The sliding bracket is slidably disposed on the fixing bracket along a first direction. The rotating mask is pivoted to the sliding bracket. When the fixing bracket is fixed to a position of the casing adjacent to the back opening, the fixing bracket and the sliding bracket are adapted to be inside the casing and a portion of the rotating mask is exposed from the casing. The rotating mask is adapted to follow the sliding bracket and move relative to the fixing bracket toward the first direction to a position out of the casing, and is adopted to rotate relative to the sliding bracket and shield the back opening after being moved out of the casing.

Apparatus and method for trapping RF on shields of a multiply shielded RF cable. In some embodiments, the RF trap shorts an outer conductor shield to an inner shield conductor of the cable successively at selected locations along an end length of the shield conductors. Some embodiments provide an RF-trap apparatus for blocking stray signals on a shielded RF cable that has two or more concentric peripheral shield conductors separated from one another by one or more electrically insulating layers, and at least one inner conductor for carrying RF signals. The RF trap apparatus includes: a first housing; and a plurality of projections configured be coupled to the first housing and to move to selectively electrically connect an outer shield conductor to an inner shield conductor by a pierce operation on the shielded RF cable.

A method of manufacturing an electronic device housing includes obtaining a monolithic body of RF transparent material and plating a surface of the monolithic body with a nanograin coating to increase the structural rigidity of the monolithic body. A portion of the nanograin coating is thereafter removed to create an RF window.

An object of the present invention is to improve the reliability of a power converter against electromagnetic noise. A power converter according to the present invention includes: a power semiconductor circuit unit; a DCDC converter circuit unit; a first drive circuit board that outputs a drive signal to the power semiconductor circuit unit; a second drive circuit board that outputs a drive signal to the DCDC converter circuit unit; and a control circuit board that outputs a first control signal for controlling the first drive circuit board and a second control signal for controlling the second drive circuit board, in which the control circuit board is arranged at a position facing the second drive circuit board with the power semiconductor circuit unit and the DCDC converter circuit unit interposed therebetween, the first drive circuit board is arranged to be substantially parallel to an array direction of the control circuit board and the second drive circuit board, and the first drive circuit board has a relay wiring that relays the second control signal output from the control circuit board to the second drive circuit board.

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.

A vapor chamber with circuit unit is provided, which has a first flexible substrate structure and a second flexible substrate structure, wherein the first flexible substrate structure and the second flexible substrate structure relatively enclose a working fluid. A plurality of wicking spaces is formed between the first flexible substrate structure and the second flexible substrate structure. A circuit unit is formed at least partially on the side of the first flexible substrate structure away from the working fluid, so as to integrate the electronic components and circuit units, and to evenly dissipate the heat generated by the electronic components and circuit units. The vapor chamber with circuit unit makes an effective improvement to the space efficiency of the electronic device.

An enclosure for gas detectors is disclosed. In some embodiments, the enclosure is configured to house a gas sensor. The enclosure comprises a cover configured to be detachably connected to the enclosure. The cover comprises one or more openings configured for providing a Faraday cage; and a top layer configured for covering the one or more openings and guiding an indicator light from inside the enclosure to outside the enclosure.

An example apparatus includes a connection module. The example connection module includes a connection interface and a connection matrix having a root transmission line to conduct signals to and from the connection interface. The connection matrix also includes branch transmission lines that are connectable electrically to the root transmission line to conduct the signals to and from the root transmission line. Each of the branch transmission lines is part of an electrical pathway between a device and the root transmission line. A housing encloses the connection matrix and enables access to the connection interface. The root transmission line and the branch transmission lines are each multi-conductor transmission lines that conduct the signals in transverse electromagnetic (TEM) mode.

A housing device for isolating electromagnetic interference emitting devices includes a structural frame for housing the electromagnetic interference emitting devices. The housing device further includes a non-structural electromagnetic interference isolating enclosure. The non-structural electromagnetic interference isolating enclosure is for encapsulating the structural frame. The non-structural electromagnetic interference isolating enclosure includes an access portion that enables the structural frame to be accessed. The access portion includes a vent.