A shield assembly includes a closing structure configured to be disposed over an opening of an enclosure. The closing structure includes an inner surface configured to face an inside of the enclosure when the closing structure is closed and a finger bracket structure mounted on the inner surface, the finger bracket structure having a bracket and one or more finger gaskets coupled to the bracket. An electromagnetic interference (EMI) shielded gasket disposed along a portion of the opening of the enclosure shields an edge of the opening of the enclosure or a radio frequency (RF) fence bracket coupled to a frame disposed around the opening of the enclosure creates a narrow path between the frame and the closing structure, the narrow path attenuating RF signals passing through the narrow path and shielding an edge of the opening of the enclosure.

A removable door for an electronic device. The door may include a spring plate having a first second surface, and a plurality of springs attached to a perimeter of the spring plate. The plurality of springs may engage a portion of an enclosure of the electronic device to retain at least the spring plate within an access opening formed in the enclosure. The door may also include a door cap covering the access opening formed in the enclosure. The door cap may include an interior surface connected to the first surface of the spring plate, and an exterior surface forming a portion of an outer surface of the enclosure. Additionally, the door may include a cover connected to the second surface of the spring plate. The cover may face an interior of the enclosure and separated from the door cap by the spring plate.

The invention relates to an EMI gasket for mounting on a wall of a housing of an electrical appliance. The gasket includes a plurality of elements arranged in a row wherein two adjacent elements are interconnected by connection pieces. At least one of the elements includes a clamping section for clamping the device onto the housing and a shielding section to perform the shielding function. According to the invention, at least one element further includes a snapping member which serves as a barb for latching into a recess within the wall of the housing where the gasket is to be installed such that the gasket is locked on the wall thereby preventing unintentional movement of the gasket or even that the gasket is slipping off of the housing.

A connecting element for galvanically connecting two electrically conductive surfaces, comprises: a body plate having a body plate upper surface defining a body plate top level; and a spring tab extending from the body plate and having a spring tab upper surface comprising an upper contact section above the body plate top level. The connecting element has a connecting element bottom level, and the spring tab has a spring tab lower surface comprising a lower contact section, the spring tab having a rest position in which, with no external force applied onto the upper contact section, the lower contact section lies above the connecting element bottom level, and is bendable, by applying external force onto the upper contact section, to a compressed position in which the lower contact section lies in or below the connecting element bottom level.

A radio frequency shield door system is provided. The radio frequency shield door system provides an effective RF and electromagnetic seal between a door and the perimeter of the doorway through a continuous interface of conductive or magnetic material between peripheral sealing surface of the door and a perimeter frame of the doorway. The perimeter frame may provide spring-loaded contact rails electrically or magnetically coupled thereto so that when the door is in a closed configuration a RF seal is formed between the interfacing sealing surface and contract rails, yet the door is still readably between an open configuration and closed configuration.

A chassis-mounted electronic device includes a conductive chassis, an upper EMI gasket, and a lower EMI gasket. An upper chassis and a lower chassis of the conductive chassis are coupled to form an interior of the chassis housing an electronic device. The upper EMI gasket is attached to the upper chassis, and resiliently contacts a portion of the electronic device. The lower EMI gasket is attached to the lower chassis, and resiliently contacts a different portion of the electronic device. The upper and lower EMI gaskets include perforations to allow cooling air through the EMI gaskets and into the interior of the chassis. The conductive chassis, the upper EMI gasket, and the lower EMI gasket provide EMI shielding for the electronic device.

A shield assembly includes a closing structure configured to be disposed over an opening of an enclosure. The closing structure includes an inner surface configured to face an inside of the enclosure when the closing structure is closed and a finger bracket structure mounted on the inner surface, the finger bracket structure having a bracket and one or more finger gaskets coupled to the bracket. An electromagnetic interference (EMI) shielded gasket disposed along a portion of the opening of the enclosure shields an edge of the opening of the enclosure or a radio frequency (RF) fence bracket coupled to a frame disposed around the opening of the enclosure creates a narrow path between the frame and the closing structure, the narrow path attenuating RF signals passing through the narrow path and shielding an edge of the opening of the enclosure.

A door assembly is described. The door assembly includes a door structure that is mounted over an opening of an enclosure. The door structure includes a body that includes a first surface and a second surface opposite to the first surface. The first surface may face an inside of the enclosure when the door structure is closed. The door structure includes a number of finger bracket structures mounted on the first surface. Each one of the finger bracket structures includes a bracket and one or more finger gaskets coupled to the bracket. The finger gaskets of the finger bracket structures may contact enclosure brackets mounted around an edge of the opening of the enclosure when the door structure is closed. A combination of the finger gaskets in contact with enclosure brackets may create an electromagnetic interference (EMI) shield at the edge of the opening of the enclosure.

A chassis-mounted electronic device includes a conductive chassis, an upper EMI gasket, and a lower EMI gasket. An upper chassis and a lower chassis of the conductive chassis are coupled to form an interior of the chassis housing an electronic device. The upper EMI gasket is attached to the upper chassis, and resiliently contacts a portion of the electronic device. The lower EMI gasket is attached to the lower chassis, and resiliently contacts a different portion of the electronic device. The upper and lower EMI gaskets include perforations to allow cooling air through the EMI gaskets and into the interior of the chassis. The conductive chassis, the upper EMI gasket, and the lower EMI gasket provide EMI shielding for the electronic device.

A receptacle cage assembly includes a receptacle cage having first and second side walls extending from a top wall at first and second corners. A gasket has EMI springs electrically connected to the receptacle cage and a panel in a panel opening including top EMI springs and first and second side EMI springs. A first corner EMI spring is located outward of the first corner of the receptacle cage to engage the panel at a first corner of the panel opening. A second corner EMI spring is located outward of the second corner of the receptacle cage to engage the panel at a second corner of the panel opening.