A shield cover includes a shield cover body, a mounting plate and a rib. The shield cover body has a container shape and covers an object to be shielded. The mounting plate protrudes from the shield cover body and includes a bolt hole. A bolt for assembling the shield cover with an assembly destination is inserted into the bolt hole in a fastening direction. The rib rises from the mounting plate in the fastening direction.

In a camera, a circuit board converts light having passed through a lens into an electric signal. A connector connects the circuit board to an outside cable. A shielding conductor surrounds the circuit board. An insulating housing houses the circuit board and the shielding conductor. A connector includes inner, intermediate, and outer connectors. The inner connector includes a first outer skin conductor, and is mounted to the circuit board. The intermediate connector includes a second outer skin conductor supporting a shielding conductor, and is connected to the inner connector and the shielding conductor. The outer connector includes a third outer skin conductor, and connects an outside cable to the intermediate connector. The shielding conductor wraps the circuit board from a boundary, as a starting point, between the second outer skin conductor and the shielding conductor. The insulating housing is connected to and supported by the intermediate connector.

According to various aspects, exemplary embodiments are disclosed of frames for shielding assemblies. Exemplary embodiments are also disclosed of shielding assemblies including such frames. In exemplary embodiments, a frame for a board level shield (BLS) may include at least one finger or tab (broadly, a portion or contact) configured to fill, cover, or close off a gap or void defined by a cover's sidewalls to thereby inhibit or prevent EMI leakage through the gap or void.

Connector receptacles and device enclosures that can provide proper grounding, improved ventilation, and an aesthetically pleasing appearance. An example can include a device enclosure including an enclosure wall and sleeves for a number of connector receptacles. Each sleeve can electrically contact a shield of a corresponding connector receptacle via a conductive structure, such as a conductive gasket, to provide a good ground path. The sleeves can be narrow at the enclosure wall for improved ventilation and an aesthetically pleasing appearance.

According to various aspects, exemplary embodiments are disclosed of frames for shielding assemblies. Exemplary embodiments are also disclosed of shielding assemblies including such frames. In exemplary embodiments, a frame for a board level shield (BLS) may include at least one finger or tab (broadly, a portion or contact) configured to fill, cover, or close off a gap or void defined by a cover's sidewalls to thereby inhibit or prevent EMI leakage through the gap or void.

A bezel assembly includes a bezel body having an opening formed thereon for receiving at least a part of a connecting piece. At least one opening shield is movably disposed on the bezel body and pressing against the connecting piece via an elastic element such that the connecting piece remains contact with the bezel assembly in the opening. The bezel assembly of the present disclosure can be adapted to connecting pieces of various types and standards, such as connectors or ports, so as to improve universality of the bezel assembly and expand the application range.

A shielded conduction path includes a conduction path main body in which sheathed electrical wires are surrounded by a tubular braided wire. An inner holder through which the sheathed electrical wires pass and is made of a synthetic resin. The shielded conduction path further includes a shield shell to which the braided wire is fixed and configured to house the inner holder. A lock hole is formed in a circumferential surface of the shield shell. A lock arm is formed in the inner holder, and locks the inner holder and the shield shell in an attached state by locking to the lock hole.

A module device includes a substrate, an upper-side case, a lower-side case, and an auxiliary member. The upper-side case has a first wall and covers at least a part of a first surface of the substrate. The lower-side case has a second wall that extends to the substrate and is in contact with the substrate. The lower-side case covers at least a part of a second surface on a side opposite to the first surface of the substrate. The auxiliary member assists an electrical connection between the second wall and at least one of the substrate and the first wall. The upper-side case is fitted to the lower-side case across the substrate to house at least a part of the substrate.

Connector receptacles and device enclosures that can provide proper grounding, improved ventilation, and an aesthetically pleasing appearance. An example can include a device enclosure including an enclosure wall and sleeves for a number of connector receptacles. Each sleeve can electrically contact a shield of a corresponding connector receptacle via a conductive structure, such as a conductive gasket, to provide a good ground path. The sleeves can be narrow at the enclosure wall for improved ventilation and an aesthetically pleasing appearance.

A detachable structure for shielding input/output (I/O) ports of a motherboard includes a housing and a blocking plate. The housing has a plurality of installed portions, an internal space, and an opening, the internal space communicates with the opening, and the plurality of installed portions are arranged in the internal space. The housing is arranged on the motherboard, and the internal space accommodates the I/O ports. The blocking plate is penetrated with a plurality of first holes. A plurality of installing elements are respectively fixed to the installed portions to fix the blocking plate to the housing, thereby shielding the opening. The positions of the plurality of first holes respectively correspond to the positions of the I/O ports to use the plurality of first holes to expose the I/O ports.