A sealing arrangement includes: a first machine element and a second machine element, each made of an electrically-conductive material; and a seal. The first and second machine elements are sealed against one another by the seal. At least one of the machine elements is made of an electrically-conductive plastic which is at least partially covered by an electrically-insulating, injection-molded skin as a result of production. The seal has an electrically-conductive support body. The support body has at least one substantially mandrel-shaped projection comprising an electrically-conductive material which is arranged on a side of the support body facing the injection-molded skin and completely penetrates the injection-molded skin.

An electromagnetic compatibility (EMC) housing having a first part (2) and a second part (3) for forming an enclosure when fitted together. The first and second parts (2, 3) include first and second interface surfaces (4, 5), respectively, for compressing a gasket (9) interposed between the interface surfaces (4, 5) when the first and second parts are fitted together. At least one of the first and second interface surfaces (4, 5) includes a plurality of undercut regions (7) for reducing compression of the gasket (9) in the region when the first and second parts (2, 3) are fitted together.

A grounding elastic contact and an electronic device including the same. The grounding elastic contact includes an elastic core, and a double-sided polyethylene terephthalate (PET) tape, a polyimide (PI) film, and a conductive layer, where the PI film is laminated and bonded on an outer side of the double-sided PET tape; a middle region of the double-sided PET tape is attached to an upper surface of the elastic core; after passing through left and right sides of the elastic core respectively, two ends of the double-sided PET tape are laminated on a lower surface of the elastic core; the conductive layer includes one end bonded on the upper surface of the elastic core, and the other end passing through the left side of the elastic core; the double-sided PET tape includes a PET backing and an adhesive coated on two sides of the PET backing.

An information handling system to wirelessly transmit and receive data may include a base chassis including a metal C-cover and metal D-cover to house a processor, a memory, and a wireless adapter, the metal C-cover to house a speaker grill, the speaker grill covering a speaker to emit audio waves; the speaker grill formed within the C-cover to emit a target radio frequency (RF) including a slot formed around a portion of the speaker grill forming a peninsula on the speaker grill that is physically separated from the C-cover; an antenna element placed behind the speaker grill and operatively coupled to the wireless adapter; an electromagnetic interference (EMI) shield forming a cavity enclosing the speaker and the antenna element, including a plurality of metallic shielding walls extending from the C-cover to a D-cover of the information handling system; and a conductive rubber gasket placed between the plurality of conductive walls and the D-cover to shield the cavity from EMI sources.

A heat exchange assembly includes a plate stack having fin plates and spacer plates interleaved with the fin plates in the plate stack. Each fin plate has fin sides extending between a fin lower edge and a fin upper edge. Each spacer plate has spacer sides extending between a spacer lower edge and a spacer upper edge. The fin upper edges of the fin plates are located above the spacer upper edges. Air flow channels are formed in gaps between the fin plates above the spacer plates. The fin lower edges and the spacer lower edges define a lower thermal interface configured to be in thermal communication with an electrical component to dissipate heat from the electrical component. The fin plates are independently movable relative to the spacer plates in the plate stack to independently articulate the fin lower edges and the spacer lower edges at the lower thermal interface. The heat exchange assembly includes a plate stabilizer structure positioning the fin upper edges relative to each other. The plate stabilizer structure includes plate stabilizers having stabilizing fingers. The stabilizing fingers coupled to at least two fin plates to control spacing of the fin upper edges of the corresponding fin plates.

A signal transmission circuit includes: a circuit board stored in a housing; a connector which is mounted on the circuit board and includes a first signal terminal and a first ground terminal; and an integrated circuit which is mounted on the circuit board and includes a second signal terminal and a second ground terminal. The first signal terminal and the second signal terminal are connected to each other by a signal wiring arranged on the circuit board. The first around terminal and the second ground terminal are connected to each other by a ground wiring arranged in a predetermined range including a portion immediately above or immediately below the signal wiring in the circuit board. At least a part of the ground wiring immediately above or immediately below the signal wiring has a high impedance structure formed to be wider than the signal wiring and narrower than a combined width of the first signal terminal and the first ground terminal.

A conductive foam includes a foam body, a conductive cloth, and a conductive adhesive layer. The conductive cloth wraps an outer surface of the foam body and includes a device contact surface configured to contact an external device for assembly. The conductive adhesive layer is disposed on the device contact surface.

To create a housing cover for fixing to a housing, wherein the housing cover is provided with a plurality of fastening means through openings and with a sealing bead that comprises an elastomeric material, and wherein the sealing bead is arranged on a seal support face of the housing cover, in which housing cover the course of the sealing bead can be more freely designed and, in particular, laid closer to the fastening means through-openings of the housing cover and which, in particular, is producible from a relatively thin starting material, it is proposed that the housing cover comprises at least one deformation limiting element, which projects over the seal support face in the same direction as the sealing bead and limits a deformation of the sealing bead in the assembled state of the housing cover,

wherein the deformation limiting element comprises a bending region in which the material of the deformation limiting element is bent out of a reference plane extending substantially in parallel to the seal support face by a bend angle of at least 30°.

The present invention relates to an electromagnetic waveguide comprising an electromagnetic interference shielding gasket which includes a self-supporting body of non-woven carbon nanotubes adapted to incorporate one or more apertures and to the electromagnetic interference shielding gasket per se.

An improved ECU for a motor vehicle comprises a housing that includes a top portion and a bottom portion each with an associated gasket. A printed circuit board (PCB) is enclosed between the housing portions. The gaskets provide seals between the housing, portions and respective sides of the PCB and apply balanced forces to each side to minimize strain on the PCB. One or both gaskets may be electromagnetic compliance gaskets.