An image capture device that includes a housing and a heatsink located partially or completely within the housing. The heatsink comprises a planar surface, a printed circuit board in communication with the heatsink, and a sheet conductor that is a graphite sheet connected to the planar surface of the heatsink and in direct contact with the printed circuit board or components of the printed circuit board.

A heat dissipating circuit board assembly includes a heat sink having a first wall, a second wall spaced from the first wall, and an end wall extending between the first and second walls. The first wall, the second wall, and the end wall collectively define a cavity. The assembly additionally includes a printed circuit board having a first face and a second face opposite the first face. The printed circuit board is located within the cavity such that the first wall of the heat sink extends over the first face and the second wall of the heat sink extends over the second face to allow heat to be transferred from the printed circuit board to the heat sink. The heat sink is configured to interface with a connector socket when the circuit board is connected to the connector socket for stabilizing the printed circuit board.

Circuit board assemblies include a circuit board portion having a recess formed therein, an electrically and thermally conductive insert, shaped to fit in the recess formed in the circuit board portion, an electrically and thermally conductive layer adapted and configured to interface with an external chassis, and a thermally conductive electrically insulative portion interposed between the electrically and thermally conductive insert and the electrically and thermally conductive layer, adapted and configured to conduct heat from the electrically and thermally conductive insert to the electrically and thermally conductive layer without conducting electricity.

Embodiments may utilize a series of exposed fins, which increase the surface area of the heat sink creating additional air flow. As hotter air rises within the system, cooler is drawn into the heatsink. The fins may be exposed on both sides of the longitudinal axis, allowing cooler air to be drawn towards the longitudinal axis above the heatsink and flow upward. This process may cool the fins. Additionally, the spacing between the fins may have to be wide enough to allow for air to freely enter the heatsink.

A temperature rise due to thermal interference between electronic components is suppressed. Electronic components (11a, 11b) are adjacently mounted on a circuit board (12). The circuit board (12) is fixed to a base (13). A rectangular convex portion (21) is provided on the base (13). The rectangular convex portion (21) is disposed so as to be located below the electronic components (11a, 11b) when the circuit board (12) is assembled to a housing (10). The rectangular convex portion (21) includes N concave portions (21a). The concave portions (21a) are arranged on a surface (21b) facing the region between the electronic components (11a, 11b).

Provided are a power amplification device and a manufacturing method thereof, wherein the power amplification device provides compact substrates by laminating a plurality of substrates, and has improved heat dissipating performance since a heat dissipating plate is installed to be in surface-contact with one of the plurality of substrates, and a heating element mounted on the substrate is in contact with the heat dissipating plate.

To this end, the power amplification device, according to the present disclosure, comprises: a first board having a first through-hole penetrating from the front to rear thereof; a second board of which the front surface is disposed on the rear surface of the first board, has a second through-hole penetrating from the front to rear thereof at a position corresponding to the first through-hole, and has a heating element penetrating the first through-hole and the second through-hole; and a heat dissipating plate of which the front surface is disposed on the rear surface of the second board and is in contact with the rear surface of the heating element.

An assembly configured to dissipate heat in a gateway, the assembly including: a bracket, the bracket including one or more openings extending from a front side to a back side of the vertically oriented bracket; and a plurality of heat sink fins attached to a base member, and wherein the base member is configured to be attachable to a front side of the bracket and the plurality of heat sink fins extend through the one or more openings to a back side of the bracket.

A Thermal Interface Material (TIM) for chip warpage may be provided. A system may comprise an Integrated Circuit (IC) chip, a Thermal Interface Material (TIM) layer disposed on the IC chip, and a heatsink disposed on the TIM layer. The heatsink may comprise, a plate, a plurality of fins, and at least one TIM storage chamber disposed in the plate between two of the plurality of fins. The at least one TIM storage chamber may be filled with a TIM that is solid at a lower temperature end of a thermal cycle of the IC chip and that is liquid at a higher temperature end of the thermal cycle of the IC chip.

A device includes a package body including a central flange and an amplifier module mounted to the central flange of the surface-mount device. The amplifier module includes a module substrate mounted to the central flange. The module substrate includes a first die mount window, a first circuitry on a first surface of the module substrate, a second circuitry on the first surface of the module substrate, and a first amplifier die mounted on the central flange. The first amplifier die is at least partially disposed within the first die mount window and the first amplifier die is electrically connected to the first circuitry and the second circuitry. The first circuitry is electrically connected to a first lead of the package body and the second circuitry is electrically connected to a second lead of the package body.

A circuit board assembly includes an inner circuit substrate, a first outer circuit substrate, a second outer circuit substrate, a heat conducting block, an electronic component, and a reinforcing plate. The first outer circuit substrate and second outer circuit substrate are disposed on surfaces of the inner circuit substrate. The heat conducting block penetrates through the inner circuit substrate and connects to the first outer circuit substrate and the second outer circuit substrate. The heat conducting block made of aluminum nitride. An electronic component at least partially accommodated in the heat conducting block. The reinforcing plate is disposed on a surface of the second outer circuit substrate corresponding to the electronic component and faces away from the electronic component. The present disclosure further provides a method for manufacturing the circuit board assembly.