A cost-effective process and structure is provided for a thermal dissipation element for semiconductor device packages incorporating antennas that can incorporate RF/EMI shielding from the antenna elements. Certain embodiments provide incorporated antenna element structures as part of the same process. These features are provided using a selectively-plated thermal dissipation structure that is formed to provide shielding around semiconductor device dies that are part of the package. In some embodiments, the thermal dissipation structure is molded to the semiconductor device, thereby permitting a thermally efficient close coupling between a device die requiring thermal dissipation and the dissipation structure itself.

An add-in module is provided. The add-in module includes a substrate, a plurality of first heat sources, a plurality of second heat sources, a heat sink and a heat-dissipation plate. The substrate includes a first substrate surface and a second substrate surface. The first substrate surface is opposite the second substrate surface. The first heat sources are disposed on the first substrate surface. The second heat sources are disposed on the second substrate surface. The heat sink corresponds to the first substrate surface and is thermally connected to the first heat sources, wherein the heat sink includes a heat-sink base and a plurality of heat-dissipation fins, and the heat-dissipation fins are connected to the heat-sink sink base. The heat-dissipation plate corresponds to the second substrate surface and is thermally connected to the second heat sources.

A portable communication device is provided. A portable communication device includes a first nanofiber member having a first density, a second nanofiber member attached to the first nanofiber member and having a second density lower than the first density, a heat transfer member positioned on or above the second nanofiber member, and a conductive material coated on at least a portion of the first nanofiber member and the second nanofiber member. At least some of the conductive material may penetrate into the first nanofiber member or the second nanofiber member. Various other embodiments may be possible.

A phone case with a phone case body and a thermal ground plane is disclosed. The phone case, for example, may include fin that folds, bends, and/or extends outward from the phone case body. The phone case, for example, may include a magnetic area that comprises a toroid or donut shape. The phone case, for example, may include an aperture that extends through the phone case body and/or the thermal ground plane. The thermal ground plane may include a first casing; a liquid transport layer comprising a mesh or an array of pillars; a vapor transport layer comprising a mesh or an array of pillars; and a second casing, an outer periphery of the first casing and an outer periphery of the second casing are sealed together encasing the liquid transport layer, the vapor transport layer, and a heat transfer fluid.

A resin composition includes: a resin as Component (A); and an inorganic filler as Component (B). The Component (B) includes anhydrous magnesium carbonate as Component (b1) and aluminum oxide as Component (b2). Content of the Component (b1) falls within a range from 35% by volume to 65% by volume relative to 100% by volume of the Components (b1) and (b2) combined. Content of the Component (B) falls within a range from 60% by volume to 75% by volume relative to 100% by volume of the resin composition.

The present disclosure concerns a mounting device for semiconductor packages, and a heat dissipation assembly with such a mounting device. The mounting device includes a bottom side comprising one or more cavities to house semiconductor packages, and a top side comprising a plurality of holes extending from the bottom side to the top side for accommodating contact pins of the semiconductor packages. A fixation mechanism fixes the mounting device to a heat dissipation structure.

An electronic device may include a circuit board, a heat generating component carried by the circuit board, a heat sink body, and a heat transfer assembly between the heat generating component and the heat sink body. The heat transfer assembly may include a flexible, heat conductive layer having a first portion in thermal contact with the heat generating component and a second portion in thermal contact with the heat sink body. The first and second portions are thermally coupled, and a compressible layer is between the first and second portions of the flexible, heat conductive layer.

An electronic device includes a substrate, at least one electronic element and a heat dissipating electromagnetic shielding structure. The heat dissipating electromagnetic shielding structure is disposed on the substrate and covers the at least one electronic element, wherein the heat dissipating electromagnetic shielding structure includes a shielding frame and a heatsink. The shielding frame includes a plurality of spring members. The spring members are bent toward the substrate and partially abut against the heatsink. When the heatsink and the shielding frame are correspondingly arranged, a shielding space is defined, the electronic element is disposed in the shielding space, and a heat generated by the at least one electronic element is conducted out of the shielding space via the heatsink.

An add-in module is provided. The add-in module includes a substrate, a plurality of first heat sources, a plurality of second heat sources, a heat sink and a heat-dissipation plate. The substrate includes a first substrate surface and a second substrate surface. The first substrate surface is opposite the second substrate surface. The first heat sources are disposed on the first substrate surface. The second heat sources are disposed on the second substrate surface. The heat sink corresponds to the first substrate surface and is thermally connected to the first heat sources, wherein the heat sink includes a heat-sink base and a plurality of heat-dissipation fins, and the heat-dissipation fins are connected to the heat-sink sink base. The heat-dissipation plate corresponds to the second substrate surface and is thermally connected to the second heat sources.

An electronic device may include a circuit board, a heat generating component carried by the circuit board, a heat sink body, and a heat transfer assembly between the heat generating component and the heat sink body. The heat transfer assembly may include a flexible, heat conductive layer having a first portion in thermal contact with the heat generating component and a second portion in thermal contact with the heat sink body. The first and second portions are thermally coupled, and a compressible layer is between the first and second portions of the flexible, heat conductive layer.