A heat spreader with a liquid-vapor separation structure includes a first panel, a second panel bonded with the first panel and defining therebetween an enclosed accommodation chamber, multiple spacer members arranged spaced apart from one another in the accommodation chamber and abutted between the first panel and the second panel and defining multiple vapor passages and liquid passages therebetween and dividing the accommodation chamber into a heat-absorbing zone and a condensing zone that are disposed in communication with each other through the vapor passages and the liquid passages, a first wick material partially disposed in the liquid passages and partially disposed in the heat-absorbing zone and the condensing zone, and a working fluid filled in the accommodation chamber.

A heat dissipation device includes a base, fins and strip-shaped plates. The fins protrude side by side from the base, and the fins respectively include first end edges and second end edges opposite to each other. The first end edges are connected to the base. The strip-shaped plates are parallel to the base and connected to at least a part of the second end edges of the fins, and strip-shaped openings are formed between the strip-shaped plates. The base, the fins and the strip-shaped plates collectively surround chambers in a non-closed manner, and each of the strip-shaped openings is connected to the corresponding chamber. A distance between two adjacent fins of the fins is S, a width of any one of the strip-shaped openings is d, and d/S is between 0.01 and 0.4.

A three-dimensional heat transfer device includes a vapor chamber and a plurality of flatten heat pipes. The flatten heat pipes are disposed on the vapor chamber and arranged along an extension direction of a short side of the vapor chamber. Major axes of cross-sections of the flatten heat pipes are parallel to a long side of the vapor chamber.

A liquid cooling apparatus includes a heat exchange module and a cooling module. The heat exchange module includes a liquid outlet and a liquid outlet. The cooling module includes a first body, a second body, a first cooling component and a cooling duct. The first body is connected to the liquid outlet. The second body is connected to the liquid outlet, and the first body is disposed above the second body. The first cooling component is disposed between the first body and the second body. The cooling duct is connected to the first body and the second body, and the cooling duct is in thermal contact with the first cooling component.

An integrated heat dissipation device includes at least one first case, a second case and multiple third cases. The first and second cases respectively have a first case chamber and a second case chamber. Each third case has a third case chamber. Each third case is connected to the second case via a first heat pipe. The first case is connected to the corresponding third case via a second heat pipe passing through the second case. Accordingly, the working fluid in the third case chambers can flow through the respectively connected first and second heat pipes to the first and second case chambers to achieve the vapor-liquid circulation effect and dissipate the heat.

The present invention relates to a heat dissipating module which comprises a first flat shell body and a plurality of second flat shell bodies. The first flat shell body has a first chamber and a first wick structure formed on an inner wall of the first chamber. Each of the second flat shell bodies defines a second chamber which is provided with a working fluid and a second wick structure therein. Each of the second flat shell bodies has a heat pipe plugged and connected to the first flat shell body. Therefore, the working fluid in each of the second chambers flows into the first chamber through the corresponding heat pipes to perform heat dissipation by liquid-vapor circulation.

A heat dissipation component includes: a first main body having a first chamber; a second main body having a second chamber; a third main body having a third chamber; a first tubular body having a first flow way, two ends of the first tubular body being respectively connected with the first and second main bodies; and a second tubular body having a second flow way. The second tubular body is passed through the second main body and the first flow way. Two ends of the second tubular body are respectively connected with the first and third main bodies. A working fluid is filled in the first, second and third chambers.

A heat dissipation device includes a first and a second housing, at least one pipe, and a working fluid. The first and the second housing internally respectively defines a first and a second chamber, in which a first and a second wick structure is respectively formed, and has at least one first and second opening communicated with the first and the second chamber respectively. The pipe has a pipe body, and a first and second extended portion, which respectively has a first and a second open end, and a first and a second through opening, and is inserted into and connected to the first and the second chamber via the first and the second opening respectively. The pipe internally defines a pipe chamber, in which a pipe wick structure is formed. The working fluid is provided in the first and the second, and the pipe chamber.

In a heat spreading module, a plurality of hollow paths is formed in a thin plate-shaped main body so as to pass though the heating portion, and the hollow paths communicate with each other in a heating portion, a working fluid is enclosed in the hollow paths, a wick is disposed in each of the hollow paths such that a vapor flow path in which vapor of the working fluid flows is formed in each of the hollow paths, a part of each wick is positioned at the heating portion, and the vapor flow paths formed in the hollow paths communicate with each other in the heating portion.

A heat pipe including a vapor line having a flow path through which a working fluid vapor flows, wherein the vapor line includes walls opposite to each other across the flow path, and a support post disposed in the flow path and spaced apart from the walls, wherein the walls are made of a plurality of metal layers stacked one over another, and the support post is made of a single seamless member having the same thickness as the walls.