A method according to one embodiment includes securing a first plurality of conductive sheets to a surface, applying a conductive tape to a first plurality of joints between conductive sheets of the first plurality of conductive sheets, and securing a second plurality of conductive sheets to the first plurality of conductive sheets without fully penetrating the first plurality of conductive sheets. In such an embodiment, each of a second plurality of joints between conductive sheets of the second plurality of conductive sheets is offset relative to the first plurality of joints.

An electromagnetic and radiation shielding system includes an enclosure shaped to define a room interior which is accessible through a single passageway, and a door assembly for selectively enclosing the passageway. The door assembly includes a frame mounted within the passageway in conductive contact with a metal skin incorporated into the enclosure, a door with a conductive rear face which is adapted to selectively enclose the passageway, and a seal for selectively establishing continuous, peripheral contact between the frame and the rear face of the door when the door is disposed in its closed position. In this manner, the door assembly cooperates with the enclosure to form an electromagnetic barrier around the room interior in all directions. Additionally, both the enclosure and the door are constructed with a layer of radiation-shielding material to form a radiation barrier around the room interior in all directions.

Door sealing systems for providing an RF seal to a door to an enclosure such as an anechoic chamber are disclosed. According to one aspect, a door sealing system includes a door having an outer periphery and a plurality of extendable and retractable knife edges along at least a portion of the outer periphery. The door sealing system includes a door frame having a plurality of channels corresponding to the plurality of knife edges, each knife edge projecting outward in a direction parallel to a face of the door and into the corresponding channels when the door is in a sealed position. Further, the door sealing system may include channels in the door frame along which knife edges of the door frame move.

A circuit card assembly including a printed circuit board arranged to include one or more electronic circuits and a frame connected to the printed circuit board. The circuit card including at least one connector arranged to detachably engage with a backplane connector of the electronic chassis to establish an electrical connection with a backplane printed wiring board (PWB) of the electronic chassis. The circuit card also including a front panel having at least one input/output connector and an EMI/RFI gasket positioned along a perimeter of the back side of the front panel where the EMI/RFI gasket is arranged to contact a surface of the electronic chassis along a perimeter of the circuit card assembly slot when the circuit card assembly is extended into the circuit card assembly slot.

Lightweight, glidable shielded components (e.g. doors) may be used in conjunction with accredited enclosures to provide electromagnetic, acoustic and CBR protection.

An enclosure includes a power flow control device to attach to a high voltage transmission line, a plurality of panels formed of metal, a shorting connection provided between each pair of panels, an electrical connection from at least one panel of the plurality of panels to the high voltage transmission line, a receiving region provided on each panel for each shorting connection, and an equipotential surface for reducing electromagnetic interference from the high voltage transmission line to internal components of the power flow control device, and from the internal components of the power flow control device to the high voltage transmission line.

Apparatuses, systems, and methods are disclosed for electromagnetic pulse (“EMP”) shielding. An enclosure may include a plurality of sheets of structural EMP shielding material disposed to enclose a space, and one or more EMP shielding connectors to bridge gaps between the sheets of structural EMP shielding material. The sheets of structural EMP shielding material may individually include a first set of alternating layers of ferrous metal and non-ferrous metal, a second set of alternating layers of ferrous metal and non-ferrous metal, and an electrically non-conductive layer disposed between the first set of alternating layers and the second set of alternating layers. The one or more EMP shielding connectors may individually include at least one layer of ferrous metal, at least one layer of non-ferrous metal, and a bonding material for bonding to the sheets of structural EMP shielding material.

A protective housing for shielding an individual against electro-magnetic field (EMF) radiation includes a conductive mesh configured to be suspended from an elevated position, a conductive plane at a base of the protective housing and configured to be a grounding plane for the protective housing, the conductive plane and conductive mesh being configured to shield an interior space, defined by the conductive plane and conductive mesh when suspended, against EMF radiation, and a cable coupled to a circumference of the conductive mesh and configured to weigh down the conductive mesh and to electrically couple the conductive mesh to the conductive plane.

In an example, a conductive concrete structure disclosed. The conductive concrete can include a plurality of conductive side structures defining an interior of the conductive concrete structure and a plurality of conductive concrete partitions disposed within the interior of the conductive concrete structure. The plurality of conductive concrete partitions are arranged to define a labyrinth within the conductive concrete structure.

A combination type shielding structure includes a top assembly member, a bottom assembly member, and a wall assembly member. The top assembly member is provided on the bottom thereof with a first connector. The wall assembly member is provided on the top thereof with a second connector. The first connector is detachably connected with the second connector. The wall assembly member is provided on the bottom thereof with a third connector. The bottom assembly member is provided on the top thereof with a fourth connector. The third connector is detachably connected with the fourth connector.