A heat sink includes a connecting member, a first substrate, a second substrate, and a cooling medium. The connecting member is sandwiched between the first substrate and the second substrate, and defines at least one hole passing through the connecting member. Each hole includes a first end and a second end respectively enclosed by the first substrate and the second substrate to define a cavity. The cooling medium is filled in each cavity.

A heat sink structure and a manufacturing method thereof. The heat sink includes a main body having multiple main body connection sections and multiple radiating fins each having a connection section. The main body has a first end and a second end. The first and second ends define a longitudinal direction. The multiple radiating fins are placed in a mold. A mechanical processing measure is used to high-speed impact the main body so as to thrust the main body into the mold. Accordingly, the connection sections of the radiating fins placed in the mold are high-speed thrust into the main body connection sections and moved in the longitudinal direction to the second end of the main body to tightly integrally connect with the main body.

Methods and apparatus for processing flexible graphite sheet material involve patterning the material, on at least one major surface, prior to further processing of the material such as densification, lamination, folding or shaping into three-dimensional structures. For densification and lamination, the patterning is selected to facilitate the removal of air from the flexible graphite sheet material during the densification and lamination process. For folding or shaping, the patterning is selected to render the graphite sheet material more flexible. In some embodiments, methods for increasing the through-plane conductivity of flexible graphite sheet material are employed. Integrated heat removal devices include sheets of graphite material that have been selectively patterned in different regions to impart desirable localized properties to the material prior to it being shaped or formed into an integrated heat removal device. Coatings and/or resin impregnation can also be used to impart desirable properties to the material or device.

An imaging device including a board section on which imaging element is loaded, a first housing section for fixing board section from a surface on which imaging element is loaded; a second housing section for fixing board section from a surface opposite to the surface on which imaging element is loaded; and a lens section attached to the first housing section side; and the first housing section and the second housing section are fixed by attachment members so as to sandwich board section. The first housing section may be configured from board fixing member for fixing board section, and the lens attachment member for attaching lens section that is fixed to board fixing member in a positionally adjustable manner.

Methods and apparatus for processing flexible graphite sheet material involve patterning the material, on at least one major surface, prior to further processing of the material such as densification, lamination, folding or shaping into three-dimensional structures. For densification and lamination, the patterning is selected to facilitate the removal of air from the flexible graphite sheet material during the densification and lamination process. For folding or shaping, the patterning is selected to render the graphite sheet material more flexible. In some embodiments, methods for increasing the through-plane conductivity of flexible graphite sheet material are employed. Integrated heat removal devices include sheets of graphite material that have been selectively patterned in different regions to impart desirable localized properties to the material prior to it being shaped or formed into an integrated heat removal device. Coatings and/or resin impregnation can also be used to impart desirable properties to the material or device.

Exfoliated graphite materials, and composite materials including exfoliated graphite, having enhanced through-plane thermal conductivity can be used in thermal management applications and devices. Methods for making such materials and devices involve processing exfoliated graphite materials such as flexible graphite to orient or re-orient the graphite flakes in one or more regions of the material.

A method and apparatus for heat sinking a camera module, which may be used in an automotive camera, which includes but is not limited to automotive rear-view cameras, is described herein. Heating conductors and heat conductive pads may be arranged in a parallel orientation within the housing of the camera module to dissipate heat produced by the printed circuit boards (PCBs) and other components within. The heat conducting pads may conduct heat away from the PCB or component being cooled and into the heat sink, which may be a heat conducting material including but not limited to aluminum, aluminum alloys, or copper. The heating pads may also fill the air gaps within the housing of the camera module.

[Problem] To inexpensively provide a heat dissipating component that has thermal conductivity, as well as a low specific gravity, and a coefficient of thermal expansion close to that of a ceramic substrate, and furthermore having warpage so as to be able to be joined with good closeness of contact to a heat dissipating component or the like. [Solution] A silicon carbide composite which is a plate-shaped composite formed by impregnation of a porous silicon carbide molded article by a metal having aluminum as a main component, wherein the amount of warpage with respect to 10 cm of length of the main surface of the composite is 250 m or less, and the amount of warpage of a power module using the plate-shaped composite is 250 m or less; and a heat dissipating component using the same.

A heat sink is provided that includes a lower shell, an upper shell and an internal matrix. The lower shell, the upper shell and the internal matrix are formed as a single component using additive manufacturing techniques. The internal matrix includes a space that is configured to receive a phase change material.

A heat sink structure and a method of manufacturing same are disclosed. The heat sink structure includes a main body and a plurality of radiating fins. The main body has a plurality of coupling flutes circumferentially spaced along an outer surface thereof and longitudinally extended from a first end to a second thereof. The radiating fins respectively have a bent section integrally located between a first and a second heat radiating section. To quickly assemble the radiating fins to the main body, the radiating fins are disposed in a forming mold, and the main body is mechanically driven into the forming mold at a high speed, so that the bent sections of the radiating fins are longitudinally forced into the coupling flutes from the first to the second end of the main body to thereby tightly connect the radiating fins to the main body.