A heat dissipation member dissipates heat generated at a heat source. The heat dissipation member may include a substrate having a porosity ratio of 5 volume % or less; and an inorganic porous layer disposed on a surface of the substrate, wherein the inorganic porous layer may have a porosity ratio ranging from 25 volume % or more to 85 volume % or less and have lower thermal conductivity than the substrate. In this heat dissipation member, 15 mass % or more of constituents of the inorganic porous layer may be alumina.

Implementations for heat structure for thermal mitigation are described. The described heat structures, for instance, provide a multi-layered structure that optimizes heat spreading and dissipation, as well as wireless performance of wireless devices. A heat structure, for instance, is installed internally in a wireless device adjacent various internal components to absorb heat generated by the components, and to dissipate the heat. According to various implementations, a heat structure is implemented as a thermally conductive layer surrounded by layers of electrically conductive material. Electrically conductive vias can be formed that traverse the thermally conductive layer and form an electrical connection between different electrically conductive layers to mitigate current flow in the thermally conductive layer.

Implementations for heat structure for thermal mitigation are described. The described heat structures, for instance, provide a multi-layered structure that optimizes heat spreading and dissipation, as well as wireless performance of wireless devices. A heat structure, for instance, is installed internally in a wireless device adjacent various internal components to absorb heat generated by the components, and to dissipate the heat. According to various implementations, a heat structure is implemented as a thermally conductive layer surrounded by layers of electrically conductive material. Electrically conductive vias can be formed that traverse the thermally conductive layer and form an electrical connection between different electrically conductive layers to mitigate current flow in the thermally conductive layer.

A heat dissipation module is provided and includes a cold plate having a housing, and a frame body disposed on the housing and having two sidewalls and at least one first rib, where the two sidewalls are positioned at two sides of the housing, respectively, and the first rib is used to provide a deformation resistance so that the heat dissipation module will not be seriously deformed when secured.

A heat exchanger includes: first layers each including first flow channels that are microchannels; and second layers each including second flow channels that are microchannels. The first layers and the second layers constitute a lamination. Heat is exchanged by performing either of: liquid evaporation in the first flow channels and gas condensation in the second flow channels, or liquid evaporation in the second flow channels and gas condensation in the first flow channels. The lamination includes: a first liquid transport pore that is in fluid communication with the first flow channels; and a second liquid transport pore that is in fluid communication with the second flow channels.

Embodiments of the disclosure relate generally to thermal control and management in hardware devices. A thermal control system includes a thermal node, a thermal bridge, and a thermal controller. The thermal node is configured to receive heat generated in a device. The thermal controller is configured to in response to an environment temperature of the thermal controller being greater than a first threshold temperature, cause heat transfer from the thermal node to a first heat sink and prevent heat transfer from the thermal node to a second heat sink. The thermal controller is also configured to, in response to the environment temperature of the thermal controller being greater than a second threshold temperature, cause heat transfer from the thermal node to the second heat sink and prevent heat transfer from the thermal node to the first heat sink.

Embodiments of the disclosure relate generally to thermal control and management in hardware devices. A thermal control system includes a thermal node, a thermal bridge, and a thermal controller. The thermal node is configured to receive heat generated in a device. The thermal controller is configured to in response to an environment temperature of the thermal controller being greater than a first threshold temperature, cause heat transfer from the thermal node to a first heat sink and prevent heat transfer from the thermal node to a second heat sink. The thermal controller is also configured to, in response to the environment temperature of the thermal controller being greater than a second threshold temperature, cause heat transfer from the thermal node to the second heat sink and prevent heat transfer from the thermal node to the first heat sink.

A device for transferring heat from a device component to an environment includes a heat plate connected to a spring. A first fastener attaches the spring to the heat plate at a first location. A second fastener, such as a rivet, attaches the spring to the heat plate at each of a second and a third location. The second fastener includes a tab on and extending above the heat plate and corresponding tab slot on the spring. The spring is riveted to the heat plate at the first location and a second spring member accepts the tab at each of the second location and the third location. Ribs on a top surface of spring facilitate thermal coupling of the spring to the component when the device is assembled. One or more spring curvatures facilitate vertical deflection and horizontal extension of the spring during device assembly.

A device for transferring heat from a device component to an environment includes a heat plate connected to a spring. A first fastener attaches the spring to the heat plate at a first location. A second fastener, such as a rivet, attaches the spring to the heat plate at each of a second and a third location. The second fastener includes a tab on and extending above the heat plate and corresponding tab slot on the spring. The spring is riveted to the heat plate at the first location and a second spring member accepts the tab at each of the second location and the third location. Ribs on a top surface of spring facilitate thermal coupling of the spring to the component when the device is assembled. One or more spring curvatures facilitate vertical deflection and horizontal extension of the spring during device assembly.

The present invention addresses the problem of providing a sheet for heat exchange elements which has high gas-barrier properties, has high fungal resistance, and has water resistance such that the sheet can be used even under high-humidity conditions. The sheet for heat exchange elements has a multilayer structure comprising a porous base and a resin layer, and has a first surface and a second surface. The outermost layer of the sheet for heat exchange elements on the first-surface side is the resin layer. The resin layer comprises polyvinylpyrrolidone and/or a vinylpyrrolidone copolymer, and contains a fungicide.