A semiconductor component system includes a motherboard and a cooling system mounted to the motherboard. The cooling system includes sidewalls projecting from the motherboard. A sub-motherboard extends between the sidewalls and is spaced apart from the motherboard. The sidewalls and the sub-motherboard define a cooling channel over the motherboard. A connector is attached to the sub-motherboard and is configured to receive a semiconductor device daughterboard. The connector has contacts to electrically couple the semiconductor device daughterboard to the sub-motherboard.

Provided are a heat sink capable of suppressing overcooling of an electronic component which should not be overcooled and highly efficiently cooling only an electronic component which should be cooled, and a circuit device including the same. A heat sink includes a pipe and a cooling block. At least one projection is formed in the cooling block. The pipe is in contact with the projection. The pipe is arranged with a spacing from a portion of the cooling block other than the projection.

A thermal management system that include an electronic circuit boards having at least two circuit boards with a space in between and further includes one or more air tubes or conduits. The electronic circuit board and air tubes are configured for drawing air into the space to facilitate cooling of the electronic circuit board concurrent with cooling of a heat sink of a heat pump connected with the electronic circuit board. The system can further include a partition to isolate airflow from the heat sink from airflow through the electronics circuit board, and can further include one or more interface components for maintaining isolation and control of air flow, improving air intake and/or supporting auxiliary components.

The present disclosure relates to the field of printed circuit board technologies. A printed circuit board with good heat dissipation performance is provided and includes a substrate serving as a board body of the printed circuit board, a heating component embedded in the substrate, and a cooling liquid channel disposed in the substrate. The cooling liquid channel is disposed in the printed circuit board, and passes around the heating component to exchange heat with the heating component, so that a heat dissipation path is shortened and heat dissipation efficiency is improved, thereby quickening heat dissipation of the printed circuit board, and prolonging a service life of the printed circuit board.

An apparatus, such as a sensor device, may include a housing. The housing may include a top wall, bottom wall, and one or more side walls that define a cavity. A circuit board may be positioned within the housing. One or more chamber side walls may surround a portion of the circuit board and define a chamber within the cavity of the housing. A pathway may be provided that defines a fluid communication channel between the portion of the circuit board and an exterior of the housing. For example, a portion of the pathway may be provided along a perimeter of or through an activation member, such as a push-button or switch positioned along an exterior of the housing.

In an electronic device, a circuit board connects different systems or structures such that heat of a system with a relatively large amount of heat can be transferred to a position or a heat dissipation structure with a relatively small amount of heat, thereby mitigating local high temperatures in the electronic device and distributing heat more evenly throughout the electronic device.

A electronic device includes: a plurality of substrates each including a substrate main body and a heat generating element, the plurality of substrates being provided side by side in a plate thickness direction; a cooler which is provided between the substrates adjacent to each other, and configured to cool the heat generating element; and a piping which is made of metal, and is connected to the cooler. The piping includes: an inner piping portion which is arranged in an inter-substrate region, and is connected to the cooler; an inner piping extending portion provided so as to extend from the inner piping portion to an outer side of the inter-substrate region; and an outer piping portion which is arranged to be shifted from the inter-substrate region, and is connected to the inner piping extending portion. The outer piping portion includes a movable piping portion that is deformable.

A circuit board includes: an electrically insulating part and an electrically conductive part; at least one semiconductor chip embedded into the electrically insulating part in a part of the circuit board; and a cooling area above and below the at least one semiconductor chip. The electrically conductive part includes a first outer conductive layer on the first surface, a second outer conductive layer on the second surface, and a first inner conductive layer which is electrically connected to the semiconductor chip. The first inner conductive layer is electrically insulated from the first outer conductive layer and from the second outer conductive layer by the electrically insulating part in the cooling area, or is electrically connected to the first outer conductive layer outside the cooling area.

A circuit device capable of significantly improving heat dissipation performance of a printed circuit board without increasing the size includes a printed circuit board, a mounted component, a non-solid metal spacer, a cooler, and a resin layer. The mounted component is at least partially disposed on at least one main surface of printed circuit board. The non-solid metal spacer is disposed at least on one main surface of the printed circuit board. The cooler is disposed at the non-solid metal spacer on the opposite side to the printed circuit board. The resin layer is disposed between the non-solid metal spacer and the cooler. The non-solid metal spacer has a shape that allows at least one hollow portion to be formed between the printed circuit board and the cooler.

A combined liquid and air cooling system is provided over a printed circuit board (PCB) of an electronic device, where the PCB includes an integrated circuit package including an application specific integrated circuit (ASIC) die and a plurality of high bandwidth memory (HBM) modules located proximate the ASIC die, and the combined liquid and air cooling system includes a liquid cooling system located over the integrated circuit package and an air cooling system integrated with the liquid cooling system and a portion of the PCB. The system operates in a normal mode, where both liquid and air cooling systems provide cooling to components of the PCB, and a fail-safe mode, where the liquid cooling system is not operating (e.g., due to a detected condition) but the air cooling system operation is adjusted such that it provides sufficient cooling to PCB components which facilitates continuous operation of the electronic device.