A plate vapor chamber array assembly with a plurality of plate vapor chambers joined in an array and each chamber having an evaporation area and an evacuated sealed chamber. The plate vapor chambers may be in direct contact with adjacent plate vapor chambers. A vapor chamber clamp surrounding the array has an inner surface engaging an outer edge of at least two of the plate vapor chambers of the array to press a surface of the plate vapor chamber array directly against the heat source.

A thermal module includes a base seat and multiple heat pipes. The base seat has a heat absorption side and a heat conduction side. Each heat pipe has a heat absorption end and a heat dissipation end. The heat absorption end has a pair of long sides and a pair of short sides. The long sides and the short sides are connected with each other in the form of a loop to form the heat absorption end. The heat pipes are assembled with each other with the long sides attached to each other. The heat pipes are assembled with the base seat with the short sides attached to the heat conduction side of the base seat. By means of the above arrangement, the number of the heat pipes disposed in a limited area or space can be greatly increased to enhance the heat conduction efficiency.

According to various aspects, exemplary embodiments are disclosed of thermal interface materials, electronic devices, and methods for establishing thermal joints between heat spreaders or lids and heat sources. In exemplary embodiments, a method of establishing a thermal joint for conducting heat between a heat spreader and a heat source of an electronic device generally includes positioning a thermal interface material (TIM1) between the heat spreader and the heat source.

An electronic device having an improved heating state is disclosed. The disclosed electronic device can comprise: a housing including a first surface facing a first direction, and a second surface facing a second direction opposite to the first direction; a printed circuit board inserted between the first surface and the second surface; an electronic component disposed on the printed circuit board; a shielding structure mounted on the printed circuit board, and including a conductive structure for at least partially surrounding the electronic device; and a heat pipe including a first end portion and a second end portion, wherein the first end portion is thermally coupled to a portion of the shielding structure, and the first end portion is disposed closer to the shielding structure than the second end portion. Additionally, other examples are possible.

An electronic device having an improved heating state is disclosed. The disclosed electronic device can comprise: a housing including a first surface facing a first direction, and a second surface facing a second direction opposite to the first direction; a printed circuit board inserted between the first surface and the second surface; an electronic component disposed on the printed circuit board; a shielding structure mounted on the printed circuit board, and including a conductive structure for at least partially surrounding the electronic device; and a heat pipe including a first end portion and a second end portion, wherein the first end portion is thermally coupled to a portion of the shielding structure, and the first end portion is disposed closer to the shielding structure than the second end portion. Additionally, other examples are possible.

An optical communication system includes a co-packaged optical module and a heatsink mounted to the co-packaged optical module. The co-packaged optical module includes a processor disposed on a substrate and a plurality of light engines disposed at different locations around the processor on the substrate. The processor and the light engines generating different amounts of heat during operation. The heatsink includes a plurality of heat pipes non-uniformly distributed throughout the heatsink to remove the different amounts of heat generated at a location of the processor and respective locations of the different ones of the light engines.

An optical communication system includes a co-packaged optical module and a heatsink mounted to the co-packaged optical module. The co-packaged optical module includes a processor disposed on a substrate and a plurality of light engines disposed at different locations around the processor on the substrate. The processor and the light engines generating different amounts of heat during operation. The heatsink includes a plurality of heat pipes non-uniformly distributed throughout the heatsink to remove the different amounts of heat generated at a location of the processor and respective locations of the different ones of the light engines.

An information handling system with a cooling system may include a processor; a memory; a power management unit (PMU); a cooling system including: a fan; and a cooling system heat pipe; a detachable thermal module including: a first heat conductive element to be operatively coupled to a heat producing components such as a processor, a radio module, or other component; a second heat conductive element to be operatively coupled to the cooling system heat pipe of the cooling system; and a detachable thermal module heat pipe formed between the first heat conductive element and the second heat conductive element.

A heat conduction structure includes a shell, a wick structure, a separating sheet, and a working fluid. The shell includes a chamber. The chamber is divided into an evaporation room, a condensation room and a connection room formed between the evaporation room and the condensation room. The wick structure covers an inner bottom wall of the chamber. The separating sheet is received in the connection room and stacked on the wick structure. An airflow channel is formed between the separating sheet and the inner top wall of the connection room. The working fluid is disposed in the chamber. Therefore, the liquid working fluid and the gaseous working fluid are split by the separating sheet to increase the heat dissipating efficiency of the heat conduction structure.

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.