A micro heat pipe includes a pipe body, a second capillary structure disposed inside the pipe body, and a working fluid injected into the pipe body. The pipe body has two enclosed ends and is defined with a heat absorbing section, a heat isolating section and a condensing section. The pipe body is provided on an inner pipe wall thereof with etched patterns serving as a first capillary structure and fully distributed in the aforementioned sections. The heat absorbing section is filled up with the second capillary structure. The micro heat pipe is manufactured in a way that the inner pipe wall of the pipe body is etched to form the first capillary structure, the second capillary structure is filled in the heat absorbing section and then sintered, the working fluid is injected into the pipe body, and the pipe body is vacuumed and sealed.

A vapor chamber that includes a housing having a first sheet and a second sheet that oppose each other and that are joined to each other in a peripheral region of the housing; a working liquid enclosed within the housing; and a wick structure on an inside surface of the first sheet or the second sheet. In the vapor chamber, the wick structure includes multiple protruding portions and a grid portion integral with the protruding portions. In addition, surfaces of the protruding portions and a surface of the grid portion opposite the inside surface of the first sheet or the second sheet are positioned on a same flat surface.

A forming assembly for forming a wick is disclosed. The forming assembly includes a tube inflatable to an inflated configuration. A wick mesh is configured to be wrapped about the tube. The forming assembly further includes a sheath positionable about the tube and the wick mesh. The tube and the sheath are configured to compress the wick mesh and form the wick based on the tube inflating towards the inflated configuration.

An integrated vapor chamber includes an outer shell and a plurality of composite capillary structures. The outer shell includes a flat casing and a plurality of partitions integrally formed. The flat shell includes a chamber, and the partitions are disposed in the chamber to separate the chamber into a plurality of flow channels. Each composite capillary structure is extended along each flow channel and distributed in the chamber. The composite capillary structure includes a metal mesh and a plurality of sintered powder uniformly sintered in the metal mesh. Furthermore, this disclosure also discloses a manufacturing method of the integrated vapor chamber. Therefore, the manufacturing method of the thin vapor chamber is simplified to improve the yield rate.

A method for manufacturing a heat exchanger includes: providing a porous material that has a porosity of about 30% to about 80%; forming an oxide layer on a surface of the porous material by heat treating the porous material at a temperature in a range of 600° C. to 900° C. for a time period in a range of 8 hours to 12 hours in air; and integrating the porous material into a cold side flow passage of the heat exchanger.

A vapor chamber includes a working fluid in an internal space formed between a first metal sheet and a second metal sheet, in which the first metal sheet includes a recessed channel, at least one projecting part, and at least one flow channel groove. The recessed channel is provided at an inner surface of the first metal sheet, the projecting part projects from the inner surface of the first metal sheet toward an inner surface of the second metal sheet, and a top face of the projecting part abuts the inner surface of the second metal sheet. The flow channel groove has a bottom groove part, a side face groove part and a top face groove part. The bottom groove part is provided at a bottom face of the recessed channel, the side face groove part is provided at a side face of the projecting part, and is connected to the bottom groove part, and the top face groove part is provided at the top face of the projecting part, and is connected to the side face groove part.

A evaporator of a loop heat pipe includes a liquid inlet side portion that extends in a widthwise direction crossing with a lengthwise direction from a liquid inlet side to a vapor outlet side, a plurality of portions that continue to the liquid inlet side portion and extend in the lengthwise direction, a plurality of vapor flow paths that are provided between the plurality of portions and extend in the lengthwise direction, and a vapor outlet side vapor flow path that extends in the widthwise direction and continues to the vapor flow paths. Each of the plurality of portions includes a first groove communicating two adjacent ones of the vapor flow paths.

A method for producing a heat pipe includes the steps: providing a pipe-shaped casing element having a length and an interior; filling a powder with particles into the casing element to form a capillary structure in the casing element; connecting the particles of the powder to one another, wherein the interior enclosed by the casing element is filled with the powder partially or in its entirety at least across a partial area of the length of the casing element, and subsequently the connection of the particles of the powder to one another and preferably also to the casing element in a layer lying against the casing element is established from the outside by inductive heat generation.

A conformal thermal ground plane is disclosed according to some embodiments along with a method of manufacturing a conformal thermal ground plane according to other embodiments. The method may include forming a first planar containment layer into a first non-planar containment layer having a first non-planar shape; forming a second planar containment layer into a second non-planar containment layer having a second non-planar shape; disposing a liquid cavity and a vapor cavity between the first non-planar containment layer and the second non-planar containment layer; sealing at least a portion of the first non-planar containment layer and at least a portion of the second non-planar containment layer; and charging at least the liquid cavity with a working fluid.

The disclosure relates to a heat dissipation module and a manufacturing method thereof. The heat dissipation module includes a heat pipe, multiple heat dissipation fins and multiple rings. The heat pipe has a peripheral wall. Each heat dissipation fin has a through hole and an annular wall disposed on an outer edge of the through hole. The heat dissipation fins are adapted to sheathe the heat pipe in a spacedly stacked manner through the through hole. Each ring annularly is adapted to sheathe each annular wall in a compressive manner to embed and compressedly connect each annular wall to the peripheral wall. Therefore, efficiency of heat dissipation and structural strength of the heat dissipation structure are improved.