A circuit structure includes an electronic component, a circuit board having a conductive path, the electronic component being mounted on the circuit board, a heat dissipation member on top of which the circuit board is placed and which dissipates heat of the circuit board, a sheet-like spacer sheet provided in a predetermined region between the circuit board and the heat dissipation member, and a bonding portion for bonding the circuit board and the heat dissipation member to each other, the bonding portion having adhesive properties or tackiness and being provided in a region between the circuit board and the heat dissipation member where the spacer sheet is not provided.

According to various aspects, exemplary embodiments are provided of thermal interface material assemblies. In one exemplary embodiment, a thermal interface material assembly generally includes a thermal interface material having a first side and a second side and a dry material having a thickness of about 0.0001 inches or less. The dry material is disposed along at least a portion of the first side of the thermal interface material.

An electronic device includes an integrated circuit, a flexible heat spreader, an actuator, and a controller. The actuator is coupled to the flexible heat spreader and the controller is configured to control the actuator between a first actuation mode and a second actuation mode. When in the first actuation mode, the actuator positions the flexible heat spreader with an air gap between the flexible heat spreader and the integrated circuit such that the flexible heat spreader is thermally separated from the integrated circuit to increase a thermal impedance between the flexible heat spreader and the integrated circuit. When in the second actuation mode, the actuator positions the flexible heat spreader in thermal contact with the integrated circuit without the air gap there between to reduce the thermal impedance between the flexible heat spreader and the integrated circuit.

An electronic device includes a substrate, at least one electronic element and a heat dissipating electromagnetic shielding structure. The heat dissipating electromagnetic shielding structure is disposed on the substrate and covers the at least one electronic element, wherein the heat dissipating electromagnetic shielding structure includes a shielding frame and a heatsink. The shielding frame includes a plurality of spring members. The spring members are bent toward the substrate and partially abut against the heatsink. When the heatsink and the shielding frame are correspondingly arranged, a shielding space is defined, the electronic element is disposed in the shielding space, and a heat generated by the at least one electronic element is conducted out of the shielding space via the heatsink.

The present disclosure provides a heat dissipation module, a display device and an assembling method of the display device. In order to avoid the second windowing area from forming a sealed space during the defoaming treatment, an exhaust passage is formed between the second windowing area B and an edge of a heat dissipation film, and hot air formed in the second windowing area in a defoaming technology can be effectively released to the outside of the heat dissipation module through the exhaust passage, so that defects of the second windowing area can be effectively overcome, and increasing the attachment yield is facilitated.

A wireless LAN module as a composite module according to the present invention includes a first substrate 26 and a second substrate 28 that is so disposed as opposed to the other principal surface 48b of the first substrate 26. An external connector 66 for the connection with an electronic apparatus is mounted on one principal surface 48a of the first substrate 26. An electronic component device 76a is mounted on one principal surface of the second substrate 28 in a region opposing the external connector 66 sandwiching the first substrate 26 therebetween. A heat dissipation member 78 is disposed on a surface which is an opposite side to the mounting-surface of the electronic component device 76a.

Provided are a heat radiation member and a mobile terminal having the same, in which the heat radiation member includes: a heat radiation sheet configured to disperse and radiate transferred heat and block and insulate transferred heat; and a passage formed in the heat radiation sheet and configured to pass a communication radio signal, wherein the passage comprises at least one punching area penetrating the heat radiation sheet.

A module heatsink lifter for raising and lowering a heatsink enabling insertion and removal of a module includes a fixed base; a hinge connector of the fixed based coupled to the heatsink; and an actuator mechanism to raise and lower the heatsink through rotation about the hinge connector, wherein the actuator mechanism operates from a front faceplate based on push and pull movement to raise and lower the heatsink into a raised position and a lowered position. The heatsink includes a Thermal Interface Material (TIM) on a bottom portion which creates a thermal connection with the module when the heatsink is in the lowered position. The module can include a pluggable optical module.

A thermally conductive sheet has a high thermal conductivity and superior heat resistance. The thermally conductive sheet includes a rubber having flowability and a thermally conductive filler. The rubber is loaded with the thermally conductive filler and mixed and kneaded to form the thermally conductive sheet, and the thermally conductive filler includes a small particulate filler having an average particle size of not greater than 10 μm. The thermally conductive sheet has a thermal conductivity of not less than 1 W/m.Math.K and an Asker C hardness after heating of not greater than 60.

A solid state drive device is provided. The solid state drive device includes a lower plate which includes a lower flat part, and a lower side wall protruding from the lower flat part primarily in a first direction, an upper plate which includes an upper flat part facing the lower flat part, and an upper side wall protruding from the upper flat part primarily in a second direction opposite to the first direction. The solid state drive device further includes a gasket including a metal material formed in at least a part of a region in which the lower side wall and the upper side wall overlap each other.