The present invention relates generally to the field of faraday cages. More specifically, the present invention relates to a carport tent faraday cage device. The device is primarily comprised of a tent body, further comprised of at least one roof frame, at least one wall frame, and at least one door. The tent body is comprised of three layers, an exterior layer, a middle layer, and an interior layer. Further, the tent body material has a middle layer that is comprised of a woven copper wire to prevent the electromagnetic radiation from entering the device. The device further is comprised of a grounding stake and a tether to direct the electrical current away from the device and into the ground. The device provides users with a device to store their vehicles, or other electronic devices without the risk of damage by electromagnetic radiation.

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 sliding door system having one or more sliding doors, door frames (e.g., static frames of different sizes for different wall thicknesses or adjustable frames that can be used to fit different wall thicknesses), sliding door hardware (e.g., tracks, wheels, soft closers, stops, or the like), header, door receiver, a plurality of seals, or the like. The sliding door system utilizes improvements to the components in order to provide security features, such as electromagnetic (EMC—EMI/RFI) shielding, sound resistance, blast resistance, forced entry and/or ballistic resistance, privacy features, light reduction, fire and/or smoke resistance, or the like to the sliding door system. In particular, the sliding door system allows for the use of the security features with the static or adjustable door frames described herein.

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

The present invention relates generally to the field of faraday cages. More specifically, the present invention relates to a carport tent faraday cage device. The device is primarily comprised of a tent body, further comprised of at least one roof frame, at least one wall frame, and at least one door. The tent body is comprised of three layers, an exterior layer, a middle layer, and an interior layer. Further, the tent body material has a middle layer that is comprised of a woven copper wire to prevent the electromagnetic radiation from entering the device. The device further is comprised of a grounding stake and a tether to direct the electrical current away from the device and into the ground. The device provides users with a device to store their vehicles, or other electronic devices without the risk of damage by electromagnetic radiation.

A protective housing for shielding against electro-magnetic field (EMF) radiation includes a conductive mesh, a frame coupled to the conductive mesh and configured to define a shape of the conductive mesh, and a frame cover coupled to the frame and the conductive mesh, the frame cover including a main body coupled to the frame, a first swivel portion rotatably coupled to a first end of the main body, and a second swivel portion rotatably coupled to a second end of the main body, the first and second swivel portions corresponding to an entry of the protective housing.

An electromagnetic emission shield for protecting a facility having a volume comprised of coal combustion residue. The shield includes a carbon-based material positioned inside an interior space of the coal combustion residue proximate to and interposed between a potential source of electromagnetic emission and the facility.

Electromagnetically shielded and self-supporting panels form a shielded enclosure. The use of prefabricated, shielded and self-supporting panels to construct an enclosure reduces the time and cost of constructing such an enclosure.

A plurality of different sized and shaped lightweight, shielded enclosures can be configured from a plurality of lightweight, shielded walls that attenuate one or more electromagnetic frequencies.

The present invention provides an infrared sauna room with a low electric field and low electromagnetic wave radiation comprising a room body, heating plates with a low electric field and low electromagnetic wave radiation and shielding lines, wherein a plurality of heating plates with a low electric field and low electromagnetic wave radiation are distributed in the room body; the first insulating layer has concave points or/and convex points; and the shielding line comprises a stranded power wire, an electric field absorbing shielding layer and a wire insulating layer. Through the above-mentioned manner, the infrared sauna room with a low electric field and low electromagnetic wave radiation can significantly reduce electromagnetic wave radiation and electric field radiation for sauna rooms.