A data center equipment rack includes an electronic equipment enclosure defined by RF-shielded walls. Openings in the RF-shielded walls are provided for being aligned with complimentary-sized and shaped openings in one or more like data center equipment racks and adapted for permitting a shielded electromagnetic connection between two or more racks. At least one access door in the enclosure is provided for facilitating access to the electronic equipment in the rack. Panels are provided for covering the respective openings in the RF-shielded walls when the openings are not being used to permit an electromagnetic interconnection between two or more racks.

A data center equipment rack, including an electronic equipment enclosure defined by RF-shielded walls. Openings in the RF-shielded walls are provided for being aligned with complimentary-sized and shaped openings in one or more like data center equipment racks and adapted for permitting a shielded electromagnetic connection between two or more racks. At least one access door in the enclosure is provided for facilitating access to the electronic equipment in the rack. Panels are provided for covering the respective openings in the RF-shielded walls when the openings are not being used to permit an electromagnetic interconnection between two or more racks.

A Faraday enclosure apparatus and method for manufacturing same are disclosure. The enclosure may comprise one or more sewn seam portions constructed to prevent signal leakage through stitch apertures in the seam. A vestibule section facilitates signal-shielded movement of electronic devices between the ambient environment and the main cavity of the enclosure. A connector filter may be mounted to extend through a wall of the enclosure to manage wired power and signal communications entering and exiting the main cavity of the enclosure. Foldable side walls facilitate the collapsibility of the enclosure for compact transport and storage.

Provided is a connector module that is highly durable and that also allows easy position alignment with a connection target instrument while maintaining high shielding performance. The connector module includes a connector case and a connector inserted in the connector case. The connector includes a contact, a holder, a conductive tubular shell, a housing and a conductive shield case. The shield case includes a first member having an elastic portion and a second member in the form of a bottomed tube. The first member forms an elastic piece contactable with the second member. Fixing of the connector case to a main body case via a fastener member causes, in the connector, elastic deformation of the elastic piece, resulting in decrease in a gap between the first member and the second member, consequently in establishment of electrical connection between the first member and the second member.

A data processing device includes an internal volume that is electromagnetic interference (EMI) isolated. The data processing device further includes an electromagnetic radiation (EMR) suppressing vent that defines one wall of the internal volume. The data processing device further includes a wireless system. The wireless system includes a first portion that is disposed in the internal volume. The first portion receives network data units from EMI emitting devices disposed in the internal volume and a second portion of the wireless system. The second portion is disposed outside of the internal volume and obtains the network data units from the first portion using a wireless connection that utilizes a transmission path that traverses through the EMR suppressing vent.

A Faraday enclosure apparatus and method for manufacturing same are disclosure. The enclosure may comprise one or more sewn seam portions constructed to prevent signal leakage through stitch apertures in the seam. A vestibule section facilitates signal-shielded movement of electronic devices between the ambient environment and the main cavity of the enclosure. A connector filter may be mounted to extend through a wall of the enclosure to manage wired power and signal communications entering and exiting the main cavity of the enclosure. Foldable side walls facilitate the collapsibility of the enclosure for compact transport and storage.

A connector assembly includes a receptacle connector, a shielding cage, a heat sink and a clip. The shielding cage covers the receptacle connector. The clip assembles the heat sink to the shielding cage, is integrally formed by a metal sheet and includes a fixed plate, a movable plate and a plate spring. The fixed plate is provided to the shielding cage, and the movable plate is provided to a side surface of the heat sink. Two ends of the plate spring are respectively connected to the fixed plate and the movable plate, and the movable plate is capable of moving relative to the fixed plate by means of the plate spring.

The present invention relates to an enclosure and method of manufacture of an enclosure arranged to define a cavity for electromagnetic shielding of equipment to be housed within the cavity, the enclosure comprising: an aperture (16) arranged to allow access to the enclosure; a conductive membrane (18) arranged to close the aperture; and a waveguide element (20) arranged between the conductive membrane (18) and the cavity; wherein the waveguide element (20) and conductive membrane (18) are configured to attenuate electromagnetic radiation originating from the equipment to be housed within the enclosure (10) thereby to inhibit the transmission of electromagnetic radiation from the enclosure via the aperture (16).

A strand leadthrough device for leading a plurality of strands in the form of cables or cable bundles, pipes, and/or tubes through a passage in a wall includes: a frame which is fastenable to an outer side of the wall and encloses at least one clearance through which the strands are led; a first sealing membrane which has a plurality of leadthrough openings through which a strand is led; and a second sealing membrane having a plurality of leadthrough points through which a strand is led. In order to form a leadthrough channel for a strand, in each case one leadthrough point of the second sealing membrane is assigned in each case to one leadthrough opening in the first sealing membrane. In a region of the leadthrough points, the second sealing membrane has elastically deformable sealing lamellae which, in a starting state, lie against one another closing the leadthrough channel.

An anti-noise component is an anti-noise component for a connector including a plug provided on an end portion of a coaxial cable and a jack provided at an opening of a metal housing of an electronic device, the anti-noise component including a cylindrical first conductive member into which the plug is inserted, and a cylindrical second conductive member into which the first conductive member is inserted, wherein a holding portion for the plug is formed on an inner circumferential portion of the first conductive member, an external thread portion is formed on an outer circumferential portion of the first conductive member, an internal thread portion is formed on an inner circumferential portion of the second conductive member, the external thread portion can be screwed into engagement with the internal thread portion, a flange portion is formed at a first end of the second conductive member, and a joining portion to be joined to an outer face of the metal housing is formed on the flange portion.