A dual-helmet magnetoencephalography measuring apparatus includes: an internal container storing a liquid refrigerant; an external container disposed to surround the internal container and including a first external helmet and a second external helmet disposed to be spaced apart from each other; a first sensor-mounted helmet disposed to surround the first external helmet between the external container and the internal container; a second sensor-mounted helmet disposed to surround the second external helmet between the externa container and the internal container; a plurality of first SQUID sensor module disposed on the first sensor-mounted helmet; and a plurality of second SQUID sensor module disposed on the second sensor-mounted helmet.

An electronic apparatus includes an interface unit including a connection unit, a heat transfer unit, a heat dissipation unit, and a fixation member. The connection unit is attachable to an interface terminal of an external apparatus. The fixation member is couplable to a fixation unit of the external apparatus. When the electronic apparatus is attached to the external apparatus, the heat dissipation unit, the heat transfer unit, and the interface unit are arranged in a layered manner in this order and are thermally coupled, and, along therewith, the fixation member is thermally coupled to the heat dissipation unit and the fixation unit.

The present disclosure relates to an electric circuit system. The system includes a housing, a printed circuit board mounted within the housing, an electric component conductively mounted to the printed circuit board, and a cooling system for transferring heat away from of the electric component. The printed circuit board is compartmentalizing the inside of the housing into a first compartment and a second compartment, and the electric component is situated in the first compartment. The cooling system includes at least one first heat transferring element located adjacent to the electric component. The at least one first heat transferring element is secured to the housing surrounding the second compartment capable of forming a heat flowing path defined to transfer heat from the electric component to the housing via the at least one first heat transferring element.

Systems and methods for detecting an incorrectly attached heat sink component on an electronic device. The system includes one or more temperature sensors secured to the electronic device and a controller unit comprising one or more processors and one or more computer-readable media, the computer-readable media having stored thereon executable instructions that are executable by the one or more processors to perform a method for detecting incorrectly attached heat sink components. The method includes receiving temperature data, calculating a thermal ramp rate, comparing the thermal ramp rate to a predetermined threshold ramp rate, and transmitting a fault signal when the calculated thermal ramp rate exceeds the predetermined threshold ramp rate.

A cooling system for a datacenter device is disclosed. Fins are provided between a first plate and a second plate to dissipate a first amount of heat to an environment in a first configuration of the fins. The first plate is movable relative to the second plate to expose a surface area of the fins to the environment in a second configuration of the fins.

An electronic device according to various embodiments of the disclosure may include: a housing which includes a first plate facing a first direction, a second plate facing a second direction opposite to the first direction, and a lateral member covering at least part of the space between the first and second plates; a display disposed to be visible in at least part of the first plate; a first circuit board which includes a first face facing the first direction and a second face facing the second direction, and which is disposed in the second direction of the display; a second circuit board which is disposed not to overlap at least in part with the first printed circuit board, and which is electrically coupled with the first circuit board; a socket mounted to the second circuit board; at least one or more metal structures disposed on the first circuit board to transfer, to another component, heat of at least one or more exothermic elements mounted on the first circuit board; and a ground path constructed in at least part of the second circuit board so as to be electrically coupled to the first circuit board or the metal member or the first circuit board and the metal structure.

A central compute unit, configured as a vehicle central compute unit, to a pocket module, to an electronic module, and to a printed circuit board, to a cooling blade, and to a main frame. The printed circuit board for an electronic vehicular component includes a thermal distribution layer in the printed circuit board and one or more thermal coupling areas on the surface of the printed circuit board. The one or more thermal coupling areas are configured for heat dissipation away from the printed circuit board, and the one or more thermal coupling areas are thermally coupled to the thermal distribution layer in the printed circuit board.

The present invention is a thermally conductive sheet comprising a plurality of unit layers, each comprising a silicone resin and a thermally conductive filler, the plurality of unit layers being laminated such that the plurality of unit layers are adhered to each other, wherein a volume content of the silicone resin is 32% by volume or less, and a compressive load at a sheet area of 25.4 mm×25.4 mm when the thermally conductive sheet is 30% compressed from a direction perpendicular to an adhesion plane on which the plurality of unit layers are adhered to each other is 7.0 kgf or less. According to the present invention, it is possible to improve the thermal conductivity and enhance the softness of a thermally conductive sheet using a silicone resin as a matrix component and composed of a large number of unit layers laminated as compared with the conventional one.

An electronic device according to various embodiments may include: a circuit board; an electrical element disposed on an upper surface of the circuit board; a shield can surrounding at least a portion of the electrical element and having a first opening provided through a portion of the shield can facing the electrical element; a shielding sheet including a shielding layer disposed on at least a portion of the shield can and a support layer disposed on an upper surface of the shielding layer and including a second opening corresponding to the first opening; and a first heat transfer member comprising a heat dissipating material having at least a portion disposed inside the second opening and at least one surface in contact with the shielding layer.

A multisided heat spreader includes a base, a first wall, and a second wall. A proximal end of the first wall is connected to a first end of the base. A proximal end of the second wall is connected to a second end of the base which is opposite to the first end of the base. A space is defined adjacent to a first surface of the base and between the first wall and the second wall such that the multisided heat spreader is open between a distal end of the first wall and a distal end of the second wall. The first wall and the second wall are configured to receive an electronic component in the space therebetween. A second surface of the base is configured to be attached to a heat generation component. The first surface of the base is opposite to the second surface of the base.