The present invention includes methods of manufacturing a metal infused graphitic material. Also described is how this device may be rendered impermeable. The present invention includes the electroplating/electroless deposition of metal on exposed internal and external surfaces of a porous graphitic substrate. The deposition of metal on the internal structure is accomplished by replacing the void space in the porous substrate with an electrolyte solution containing dissolved metallic species. The plating is initiated either through electrochemical means, electroless means, chemical vapor deposition means, or other means obvious to one familiar in the art of metal plating. A post-deposition bath is also described wherein the plating may be removed from one or both sides of the external surface without impacting the internal pore plating.

A heat sink plate having a structure in which two or more kinds of materials are laminated, includes: a core layer in the thickness direction of the heat sink plate; and cover layers covering a top surface and a bottom surface of the core layer; wherein the cover layers comprise a material containing copper, wherein the core layer is formed of a matrix having a first thermal expansion coefficient and a plurality of layers extending in parallel along the thickness direction of the core layer in a lattice form in the matrix, wherein the plurality of layers are made of an alloy having a second thermal expansion coefficient.

A manifold structure has at least one flow passage and a center manifold section that has at least one machined cavity. The manifold structure includes a plurality of ultrasonically additively manufactured (UAM) finstock layers arranged in the flow passage. After the finstock is formed by UAM, the finstock is permanently joined to the center manifold section via a brazing or welding process. Using UAM and a permanent joining process enables joining of the UAM finstock having enhanced thermal features to a vacuum brazement structure. UAM enables the finstock to be formed of dissimilar metal materials or multi-material laminate materials. UAM also enables bond joints of the finstock to be arranged at angles greater than ten degrees relative to a horizontal axis by using the same aluminum material in the UAM process and in the vacuum brazing process.

An automotive heat exchanger (10) has a heat exchanger core (12) including a header part (16) with a plurality of heat transfer tubes (38) and a head tank (20) with an opening receives end portions of the heat transfer tubes (38). A plastic header plate (18) is secured with the header tank (20) and header part (16). The header plate (18) includes a plurality of apertures (24) extending through the plate (18) that enable fluid passage. Each aperture (24) includes a cutout portion (28) that receives an end of a heat transfer tube (38). The cutout portion (28) has a complimentary shape to mate with the end of the heat transfer tube (30). A seal (50), in the cutout portion (28), seals the end of the heat transfer tube (28) with the header plate (18).

The present invention provides an aluminum-diamond composite which combines high thermal conductivity and a coefficient of thermal expansion close to a semiconductor element, and in which the difference between the thicknesses of both surfaces is reduced so as to be suitable for use as a heat sink etc. for a semiconductor element. Provided is a flat plate-shaped aluminum-diamond composite that has an aluminum-diamond composite part and a surface layer that coats both surfaces of the composite part and includes a metal that has aluminum as a principal component, wherein: the composite part is composed of a composite material that is composed of an aluminum or aluminum alloy matrix and diamond particles dispersed in said matrix; the composite material is composed of a diamond powder in which diamond particles having a particle size of 1-20 m, inclusive, make up 10-40 vol % of the diamond particles and diamond particles having a particle size of 100-250 m, inclusive, make up 50-80 vol %, said powder not containing diamond particles having a particle size of less than 1 m or diamond particles having a particle size of more than 250 m; and the average value for the differences in in-plane thickness per 50 mm50 mm is 100 m or less.

A metal member includes a metal substrate and a porous metal layer. A composite includes the metal member and a resin member. The metal substrate has one surface, is made of a metal material, and has a region formed as an uneven layer having an uneven shape with respect to the one surface. The porous metal layer has a mesh-like shape and is formed on the uneven layer. The uneven layer includes a plurality of protrusions protruding in a direction normal to the one surface.

The present application provides a composite material and a method for producing the same. The present application can provide a composite material having excellent other necessary properties such as impact resistance or processability, as well as excellent heat conduction characteristics as a tight heat transfer network is formed therein by an anisotropic heat-conductive filler.

A vascular composite heat exchanger includes a first fluid network sandwiched between upper and central plies; and a second fluid network fluidly isolated from the first fluid network sandwiched between the central and lower plies.

A monolithic substrate including a silica material fused to bulk copper is provided for coupling with electronic components, along with methods for making the same. The method includes arranging a base mixture in a die mold. The base mixture includes a bottom portion with copper micron powder and an upper portion with copper nanoparticles. The method includes arranging a secondary mixture on the upper portion of the base mixture. The secondary mixture includes a bottom portion with silica-coated copper nanoparticles and an upper portion with silica nanoparticles. The method includes heating and compressing the base mixture and the secondary mixture in the die mold at a temperature, pressure, and time sufficient to sinter and fuse the base mixture with the secondary mixture to form a monolithic substrate. The resulting monolithic substrate defines a first major surface providing thermal conductivity, and a second major surface providing an electrically resistive surface.

To provide a thermally conductive sheet that has high thermal conductivity. A thermally conductive sheet contains carbon fibers and a flake graphite powder that are dispersed in a polymer matrix. The flake graphite powder is disposed between the carbon fibers, the fiber axis directions of the carbon fibers are oriented in a sheet thickness direction Z, long axis directions of flake surfaces of the flake graphite powder are oriented in the sheet thickness direction Z, and normal directions to the flake surfaces are randomly oriented in a surface direction of the sheet. A mass ratio of the carbon fibers to the flake graphite powder is in a range of 120:10 to 60:70. According to this thermally conductive sheet, the thermal conductivity can be increased compared to when carbon fibers are used alone or a flake graphite powder is used alone.