There is disclosed a mobile terminal including a case comprising an electric control unit in which electronic components are loaded; a display unit coupled to a front surface of the case; a frame coupled to the case and supporting a rear surface of the display unit, the frame comprising a metallic material; a mainboard loaded in the case; a drive chip loaded in the mainboard; a shield can covering components loaded in the mainboard, the shied comprising a hole formed, corresponding to the drive chip; a thermal conductivity sheet comprising one surface in contact with a top surface of the drive chip and the other surface in contact with an inner surface of the frame; and a flexible material insertedly filling in a space formed between the thermal conductivity sheet and the frame, so that the heat generated in the drive chip of the mobile terminal may be effectively emitted and that only the portion of the mobile terminal, where the drive chip is loaded, may be prevented from being heated when the user is using the mobile terminal and the other components may be prevented from being damaged by the heat.

A thermal pad and an electronic device comprising the thermal pad includes a first heat conducting layer and a second heat conducting layer. The first heat conducting layer is deformable under compression, and a heat conduction capability of the first heat conducting layer in a thickness direction of the first heat conducting layer is greater than a heat conduction capability of the first heat conducting layer in a plane direction of the first heat conducting layer. The second heat conducting layer is not deformable under compression, and a heat conduction capability of the second heat conducting layer in a plane direction of the second heat conducting layer is greater than or equal to a heat conduction capability of the second heat conducting layer in a thickness direction of the second heat conducting layer.

A heat dissipation structure assembly includes an elastic limiting member, a paste-type heat dissipation wall, a fitting member, a phase-change metal, and an assembling plate. The elastic limiting member is adapted to be disposed at a periphery of a heat source. The paste-type heat dissipation wall is adapted to be in contact with the periphery of the heat source. The fitting member is in contact with the paste-type heat dissipation wall and engaged with the elastic limiting member. The phase-change metal is adapted to be filled into a region among the fitting member, the paste-type heat dissipation wall, and the heat source. When a temperature of the phase-change metal exceeds a critical temperature, a state of the phase-change metal is changed to a liquid state. The assembling plate is connected to the fitting member, and the assembling plate is in contact with the paste-type heat dissipation wall.

A set of electronic package elements intended to be mounted on an electronic board having a component to be cooled including: a chassis, a heatsink fixed by a retaining piece inside the chassis, a cover configured to be fixed on the chassis so as to retain the electronic board in the package. The heatsink is configured to be fixed on the electronic board while maintaining a predetermined distance between a lower face of the heatsink and the component. The cover is configured to be able to be fixed by a fixing point to the heatsink. The retaining piece is connected to the heatsink so as to allow the heatsink a translational movement relative to the chassis in three orthogonal directions.

A vehicle includes an integrated controller equipped with an advanced driver assistance system (ADAS). An air conditioner is configured to introduce air into the inside of the vehicle and to adjust a flow of the air. The air conditioner is configured to transmit the air to the integrated controller by branching an air conditioning duct that is a passage for transmitting air into the inside of the vehicle.

Integrated Thermal Interface Detachment Mechanism for Inaccessible Interfaces are disclosed. According to an aspect, an exemplary device for an electronic component having a thermal interface material, comprising a heat sink configured to contact the thermal interface material and configured to heat transfer interface with the electronic component while the thermal interface material is in contiguous contact with both the heat sink and the electronic component, and a separator mechanism configured to advance a separator ram with respect to the heat sink and effect a force upon the thermal interface material, such that advancing the ram breaks the contiguous contact of the thermal interface material with at least one of the heat sink and the electronic component.

The heatsink cooling arrangement, fitted to cool a semiconductor component, is transferring heat to a backplate heatsink and secures a mechanical stabile assembly of PCBA, encapsulation, heatsink cooling arrangement to a backplate heatsink, which is fast and easy to assemble with usage of few- or no tools.

A heat dissipation structure includes a heat sink, a first thermal interface material, a second thermal interface material, a circuit board and a circuit element. The first thermal interface material is connected to the heat sink and has fluidity. The second thermal interface material is connected to the first thermal interface material and has no fluidity. The circuit board is connected to the second thermal interface material and has an opening, a top board surface and a bottom board surface. The circuit element includes a convex portion and a base portion. The convex portion has a top convex surface and is disposed in the opening. The base portion is connected to the convex portion and the bottom board surface. The second thermal interface material is connected to the top board surface and the top convex surface.

An optical transceiver includes a housing, a heat source accommodated in the housing, and a thermal interface material accommodated in the housing. The housing is in thermal contact with the heat source through the thermal interface material, and the thermal interface material is in physical contact with an uneven surface of the housing.

An optical transceiver includes a circuit board having a first side and a first edge; a thermal conductive member configured to be attached on the first side of the circuit board; the thermal conductive member having a first thermal conductive face inclined with respect to the first side of the circuit board and parallel to the first direction; a filling material having a thermal conductivity; and a housing having an inner face and an inner space, the housing being configured to house the circuit board, the circuit component, the thermal conductive member, and the filling material, and configured to hold the electrical connector at an end thereof in the first direction, the housing having a second thermal conductive face facing the first thermal conductive face with a spacing. The filling material adheres to the first thermal conductive face and the second thermal conductive face.