A device of the type of an antenna, a heater, an electromagnetic screen, an electrical interconnection and the like, includes at least one laminar supporting layer for at least one flexible ribbon-like conducting path which is essentially constituted by preassembled graphene derivatives.

An EMI shielding device is provided. A first shielding layer is formed on a first surface of a first substrate, and a first through hole is formed through the first substrate. A second substrate is mounted in an opening of the first through hole, and a second shielding layer is formed on a surface of the second substrate. A conductive paste is mounted between the first substrate and the at least one second substrate to electrically connected the first shielding layer and the second shielding layer. The EMI shielding device is adopted to be mounted on a printed circuit board (PCB) by Surface Mount Technology. Therefore, the EMI shielding device may be firmly mounted on the PCB, and there is not any narrow gap that may leak electromagnetic radiation.

An EMI shielding device is provided. A first shielding layer is formed on a first surface of a first substrate, and a first through hole is formed through the first substrate. A second substrate is mounted in an opening of the first through hole, and a second shielding layer is formed on a surface of the second substrate. A conductive paste is mounted between the first substrate and the at least one second substrate to electrically connected the first shielding layer and the second shielding layer. The EMI shielding device is adopted to be mounted on a printed circuit board (PCB) by Surface Mount Technology. Therefore, the EMI shielding device may be firmly mounted on the PCB, and there is not any narrow gap that may leak electromagnetic radiation.

There is disclosed a functional lamellar particle including an unconverted portion of the lamellar particle, wherein the unconverted portion includes a first metal, a converted portion of the lamellar particle disposed external to a surface of the unconverted portion, wherein the converted portion includes a chemical compound of the first metal; and a functional coating disposed external to a surface of the converted portion.

There is disclosed a lamellar particle including an unconverted portion of the lamellar particle, wherein the unconverted portion includes a first metal, a converted portion of the lamellar particle disposed radially outward of at least one of a surface of the unconverted portion, wherein the converted portion includes a chemical compound of the first metal.

The present invention discloses a form-in-place conductive and waterproof colloid, being composed of: dimethyl siloxane or dimethylvinyl-terminated or vinyl terminated polydimethylsiloxane; hydroxy terminated polydimethylsiloxane; dispersant; dimethyl, methylhydrogen siloxane crosslinking agent; adhesion promoter; Pt catalyst; forming agent; hydrocarbon solvent; Nickel Graphite; thickening agent; Trimethylated silica; and inhibitor. With the implementation of the present invention, no production mold or die cutter is required to simplify the process of applying the colloid and reduce the cost of applying, and with the characteristics of being providing waterproof and dustproof capability for enclosures, providing excellent adhesion capability, providing excellent compressibility and resilience, isolating EMI and providing EMI shielding capability at the same time. Besides, the space required is small when forming or applying making the colloid suitable for applications to small or mini devices and save the cost of material and cost of implementation.

The present invention discloses a form-in-place conductive and waterproof colloid, being composed of: dimethyl siloxane or dimethylvinyl-terminated or vinyl terminated polydimethylsiloxane; hydroxy terminated polydimethylsiloxane; dispersant; dimethyl, methylhydrogen siloxane crosslinking agent; adhesion promoter; Pt catalyst; forming agent; hydrocarbon solvent; Nickel Graphite; thickening agent; Trimethylated silica; and inhibitor. With the implementation of the present invention, no production mold or die cutter is required to simplify the process of applying the colloid and reduce the cost of applying, and with the characteristics of being providing waterproof and dustproof capability for enclosures, providing excellent adhesion capability, providing excellent compressibility and resilience, isolating EMI and providing EMI shielding capability at the same time. Besides, the space required is small when forming or applying making the colloid suitable for applications to small or mini devices and save the cost of material and cost of implementation.

The present invention provides an electromagnetic wave blocking device having electromagnetic wave shielding and absorbing capacity. The electromagnetic wave blocking device having electromagnetic wave shielding and absorbing capacity includes: an electromagnetic wave blocking device body part configured such that an identical material is mixed with shielding and absorbing materials or different materials are arranged on both sides of a boundary of their sides to thus enable electromagnetic wave absorption and electromagnetic wave shielding; and an edge electromagnetic wave absorbing part formed along the boundary of the blocking device body part to thus additionally block electromagnetic waves. Furthermore, the present invention provides a method for manufacturing the electromagnetic wave blocking device.

An inductively charged portable electronic device has a charging receive coil that receives electromagnetic energy during a charge event. An electrically conductive shield is disposed within the portable electronic device and is disposed between the charging receive coil and an exterior housing of the portable electronic device to shield a touch sensitive user interface of the portable electronic device from noise generated during a charge event.

An EMI shielding device is provided. A first shielding layer is formed on a first surface of a first substrate, and a first through hole is formed through the first substrate. A second substrate is mounted in an opening of the first through hole, and a second shielding layer is formed on a surface of the second substrate. A conductive paste is mounted between the first substrate and the at least one second substrate to electrically connected the first shielding layer and the second shielding layer. A protective layer, an antirust layer, and a shielding layer are sequentially mounted on the conductive paste. The EMI shielding device is mounted on a printed circuit board (PCB) by Surface Mount Technology. Therefore, the EMI shielding device may be firmly mounted on the PCB, and there is not any narrow gap that may leak electromagnetic radiation.