Embodiments of the present disclosure are directed toward techniques and configurations for a printed circuit board (PCB) assembly mountable to a computer chassis. In one instance, the PCB assembly may comprise a PCB having two through holes and a PCB mounting device that may include a U-shaped component having a non-linear portion and two rods extended from the non-linear portion and a housing having a base with protrusions extending from ends of the base. The rods may be extended through the protrusions such that the base and the non-linear portion of the U-shaped component form an opening to engage a mounting element of the chassis. The extended portions of the rods may be inserted into and soldered to the through holes of the PCB, to electrically couple the PCB to the PCB mounting device and the chassis to ground the PCB. Other embodiments may be described and/or claimed.

An electronic device has a control board having a plurality of wiring layers, a metal-made housing supporting the control board, and a fixing screw for fixing the control board to the housing through a washer. The control board includes a through hole penetrating from a third surface to a fourth surface, a through electrode formed inside the through hole, and a power system GND pattern formed on any wiring layer of the wiring layers. The power system GND pattern and the housing are electrically coupled through the through electrode, the washer, and the fixing screw.

Radio frequency subscriber drop units include a housing having an input port and an output port and a printed circuit board mounted in an interior of the housing. The printed circuit board includes a dielectric layer, a wiring layer that includes conductive wirings that comprise at least part of a communications path between the input port and the output port that is on a first face of the dielectric layer, and a ground plane layer that includes a conductive ground plane that is on a second face of the dielectric layer.

An electronic device including a substrate having opposing top and bottom surfaces is provided. A ground layer is disposed in the substrate. An electrically conductive chassis has a mounting surface to receive the bottom surface of the substrate and is in electrical contact with the ground layer by a ground stitch via. An electromagnetic shield is defined by the ground layer, the ground stitch via and the chassis to enclose the bottom surface of the substrate and protect the bottom surface from electromagnetic interference. A non-conductive cover is assembled to the substrate in tension so that an interior surface of the cover applies a force to the top surface of the substrate thereby ensuring the chassis maintains in electrical contact with the ground layer.

Apparatuses and associated methods for mounting PCBs and other electronics boards in portable medical equipment and/or other portable and non-portable electronic devices are disclosed herein. In some embodiments, the technology disclosed herein can provide PCB mounting systems that isolate the PCB from detrimental shock, vibration, and/or strain, while also providing electrical ground paths that greatly reduce EMI and other electrical disturbances. Some embodiments of the mounting systems described herein include both elastomeric (e.g., rubber) components and resilient metallic grounding members that, when assembled together, provide favorable shock mounting as well as robust electrical grounding without the inconvenience of using separate shock mounts, grounding straps, etc.

A printed wiring board includes a power supply conductor pattern arranged on one conductor layer, one ground conductor pattern arranged on the one conductor layer, and another ground conductor pattern arranged on the another conductor layer so as to be opposed to the power supply conductor pattern. The power supply conductor pattern includes a power supply pad on which a terminal of a capacitor is to be bonded. The one ground conductor pattern includes a ground pad on which another terminal of the capacitor is to be bonded. A slit is formed in the another ground conductor pattern so as to pass through a projection portion defined by projecting the power supply pad onto the another ground conductor pattern and divide a projection portion defined by projecting the power supply conductor pattern onto the another ground conductor pattern.

An electronic control device includes: a housing accommodating a board on which an electronic component is mounted; and a guard pattern formed on an outer peripheral portion of the board. The guard pattern and a ground pattern of a circuit in the circuit board are connected to each other in a vicinity of an intermediate point of fixed positions where an upper portion of the housing and a lower portion of the housing are fixed to each other.

A high-frequency module (100) includes a multilayer board (110) including a plurality of insulator layers and at least one ground conductor layer (113); in the multilayer board (110), a transmission circuit (120) that is a first circuit provided in a first region and an antenna circuit (130) that is a second circuit provided in a second region different from the first region; and shielding conductor films (151 to 156) provided on sides of the multilayer board (110) and being partially in contact with the ground conductor layer (113). The ground conductor layer (113) is not in contact with the shielding conductor films (151 to 156) in, of a side of the multilayer board (110), a portion that is closest both to the first region and to the second region.

An electric apparatus according to one embodiment of the present invention comprises an electric equipment, a circuit board which is provided with a plurality of ground parts and is configured to make the electric equipment operate, and a support member having a conductive property which covers the circuit board in a non-contact way and supports the electric equipment. The electric apparatus comprises one conductive member which is electrically connected to one ground part among the plurality of ground parts and the support member, and another conductive member which is electrically connected to another ground part among the plurality of ground parts and is insulated electrically from the support member.

A circuit shielding structure, relating to a technical field of electronics, includes a substrate, wherein: at least one radio frequency component circuit is fixed on the substrate; a wave-absorbing material layer is embedded in the substrate; a shielding wall made of wave-absorbing material is arranged on the substrate and around the radio frequency component circuit; a conductive material layer covers the shielding wall; a closed space is formed among the substrate in which the wave-absorbing material layer is embedded, the shielding wall and the conductive material layer, and the radio frequency component circuit is sealed in the closed space, so that omnidirectional shielding is achieved.