An exemplary faraday bag with magnetic closure system includes an actuatable closure section defined between a shielding compartment and an access mouth. The closure section preferably includes a retention segment, a distal flap segment, and an intermediate flap segment therebetween. Base magnets are disposed within the retention segment and a first panel of the bag. Flap magnets are disposed within the distal flap segment and a second panel of the bag. When the closure section is in open configuration, the flap magnets are substantially out of attractive magnetic engagement with respective base magnets, and the shielding compartment is accessible from an ambient environment through the access mouth. When the closure section is in closed configuration, the flap and retention segments are folded with respect to one another, the flap magnets are in attractive magnetic engagement with respective base magnets, and the access mouth is thereby retained in an RF-sealed configuration.

In embodiments, a device may include a single electromagnetic interference (EMI) shield plate that defines an enclosed area. The EMI shield plate may have an inner surface and an outer surface opposite the inner surface. The device may further include a first printed circuit board (PCB) coupled with the inner surface, wherein the first PCB is within the enclosed area. Other embodiments may be described and/or claimed.

A two-piece EMR-shielding smart-key holder is disclosed including a first piece having a cavity within a body sized to hold one or more smart keys, an EMR-shielding layer lining the cavity, and a first piece of a touch fastener incorporated into a second face of the body. A second piece of the smart-key holder includes a second piece of the touch fastener. A method is also disclosed including adhering a second face of the second piece of the smart-key holder to an object's surface leaving a first face of the second piece having the second piece of the touch fastener exposed. The method also includes fastening the first and second pieces of the smart-key holder together by way of complementary touch-fastener features, thereby attaching the first piece to the object's surface shielding the one or more smart keys from at least radiofrequency communications in place on the object's surface.

A retaining device for an EMF-generating device includes a first surface or opening which is transparent to the EMF of the EMF-generating device, and a second surface which is at least partially opaque to the EMF generated by the EMF-generating device. The device can be installed such that the second surface is oriented towards an individual or pet while the first surface faces away.

A wrappable textile sleeve for protecting a conductive elongate member against at least one of EMI, RFI or ESD and method of construction thereof is provided. The sleeve includes a plurality of warp filaments and at least one weft filament woven with one another to form a woven substrate. The woven substrate has opposite sides extending lengthwise between opposite ends. The opposite sides are wrappable about a central longitudinal axis into overlapping relation with one another to circumferentially enclose the elongate member within a cavity of the sleeve. At least some of the warp filaments are provided as generally flat, thin conductive filaments shield the conductive elongate member against the effects of EMI, RFI and/or ESD.

A wrappable textile sleeve for protecting a conductive elongate member against at least one of EMI, RFI or ESD and method of construction thereof is provided. The sleeve includes a plurality of warp filaments and at least one weft filament woven with one another to form a woven substrate. The woven substrate has opposite sides extending lengthwise between opposite ends. The opposite sides are wrappable about a central longitudinal axis into overlapping relation with one another to circumferentially enclose the elongate member within a cavity of the sleeve. At least some of the warp filaments are provided as generally flat, thin conductive filaments shield the conductive elongate member against the effects of EMI, RFI and/or ESD.

The present disclosure provides a housing assembly, and the housing assembly is applied to an electronic device. The housing assembly includes a first part and a second part. The first part includes at least one opening. The second part includes at least one mesh area. The mesh area deformably connects to the first part, and covers the opening.

Provided is an assembly that includes a first shield part and a second shield part. The first shield part is foldable on the second shield part. Each of the first shield part and the second shield part includes or is connected to at least one closure element, so that the at least one closure element associated with the first shield part is in contact with at least one corresponding closure element associated with the second shield part. The contact allows ensuring an electrical continuity between the first shield part and the second shield part and generating a Faraday cage. Other embodiments disclosed.

Described herein is electromagnetic shielding that is configured to attenuate electromagnetic interference (EMI) by at least a threshold amount when the EMI has a frequency within a predefined frequency range. The electromagnetic shielding includes a layer of metal, such as aluminum foil, and a layer of thermoplastic polymer fabric (such as woven polyethylene fabric), where the electromagnetic shielding has several apertures that extend therethrough. The electromagnetic shielding is at least partially draped over electronic equipment that is to be shielded from EMI.

A protective enclosure having a flexible outer wall including a conducting layer and an insulating layer and having a closable opening for protecting a vehicle from damaging electromagnetic fields. Also, the method of using the protective enclosure to protect vehicles or other devices from damage by electromagnetic fields.