The present invention relates to an electromagnetic shielding device comprising (40) at least one hollow protective textile sleeve (50) having a main rest diameter D1 and an interior volume configured to receive one or several elongated element(s) (20, 21), at least one hollow connecting textile sleeve (60) having a rest diameter D2, D2 greater than D1. The protective textile sleeve (50) comprises a substantially annular front part (52) having a front open end (54), the connecting textile sleeve (60) comprises a substantially annular rear part (62) having a rear open end (64), and the shielding device (40) comprises a first electrically conductive, in particular at least partially annular, securing area (70) in which the rear part (62) of the connecting sleeve (60) and the front part (52) of the protective sleeve (50) are at least partly secured.

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.

Sheet comprising a flexible support and a coating at least partially covering at least one face of the support, the support being made of a support material exhibiting dielectric properties, the coating being made of a coating material different from the support material and exhibiting magneto-dielectric properties or dielectric properties.

Disclosed are exemplary embodiments of electromagnetic interference (EMI) mitigation materials and EMI absorbing compositions including carbon nanotubes. The carbon nanotubes may comprise single-walled carbon nanotubes, multi-walled carbon nanotubes, and/or carbon nanostructures comprising a branched network of crosslinked carbon nanotube structures. For example, exemplary embodiments may include a composition comprising carbon nanotubes within a polymer resin, whereby the composition is operable for absorbing noise and/or for reflecting signals thereby inhibiting passage or transmission of the signals through the composition. Also, for example, exemplary embodiments may include broadband millimeter wave EMI absorbers comprising carbon nanotubes.

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.

The present invention provides an anisotropic, thermal conductive, electromagnetic interference (EMI) shielding composite including a plurality of aligned polymer nanofibers to form a polymer mat or scaffold having a first and second planes of orientation of the polymer nanofibers. The first plane of orientation of the polymer nanofibers has a thermal conductivity substantially the same as or similar to that of the second plane, and the thermal conductivity of the first or second plane of orientation of the polymer nanofibers is at least 2-fold of that of a third plane of orientation of the polymer nanofibers which is about 90 degrees out of the first and second planes of orientation of the polymer nanofibers, respectively, while the electrical resistance of each of the first and second planes is at least 3 orders lower than that of the third plane. A method for preparing the present composite is also provided.

The present disclosure is directed to providing a carbon film having an excellent shield performance against electromagnetic waves. The carbon film of the present disclosure is a carbon film made of a carbon nanotube assembly, wherein a pore distribution curve of the carbon film indicating the relationship between the pore size and the Log differential pore capacity obtained from an adsorption isotherm at 77 K of liquid nitrogen based on the Barrett-Joyner-Halenda method has a peak in which the Log differential pore capacity is maximized within a pore size range of 10 nm or more and 100 nm or less, and the value of the Log differential pore capacity at the peak is 1.2 cm.sup.3/g or more.

A method, a device, and a composition are disclosed. The method includes providing a polyol blend that includes a polyol resin and an electromagnetic (EMA) additive, providing an isocyanate resin selected such that blending the isocyanate resin with the polyol blend results in an EMA spray foam. The device includes a first compartment containing an isocyanate resin and a second compartment containing a polyol blend, which includes a polyol resin and an EMA additive. The composition includes a polyurethane spray foam and an EMA additive blended into the polyurethane spray foam.

An electromagnetic shielding laminated sheet includes: an electromagnetic wave absorbing layer which includes a matrix and carbon nanotubes dispersed in the matrix and which has a bulk density equal to or less than 997 kg/m.sup.3; and a metal layer laid on top of the electromagnetic wave absorbing layer.

A supply unit for electromagnetically shielded rooms is provided where the supply unit includes a passthrough unit and is designed to be arranged entirely or partly beneath the electromagnetically shielded room, and where an entrance is situated at a first side of the passthrough unit and an exit is situated at a second side of the passthrough unit, and where the exit is designed to be arranged at the floor of the electromagnetically shielded room, and where the passthrough unit is designed with at least one passthrough arranged in concrete.