Liquid submersion cooled electronic devices and systems are described that use one or more cooling liquids, for example one or more dielectric cooling liquids, to submersion cool individual electronic devices or an array of electronic devices. A clamshell or sandwich construction of the device housing is used to define a wet zone containing heat producing electronic components of the electronic device to be cooled by the dielectric cooling liquid, and a dry zone where input/output and power connectors are provided.

According to an aspect of the disclosure, an example microelectronic device assembly includes a substrate, a microelectronic element electrically connected to the substrate, a stiffener element overlying the substrate, and a heat distribution device overlying the rear surface of the microelectronic element. The stiffener element may extend around the microelectronic element. The stiffener element may include a first material that has a first coefficient of thermal expansion (“CTE”). A surface of the stiffener element may face toward the heat distribution device. The heat distribution device may include a second material that has a second CTE. The first material may be different than the second material. The first CTE of the first material of the stiffener element may be greater than the second CTE of the second material of the heat distribution device.

A cold plate may include a plate body having a thermal conductive side; a plurality of parallel hollow fluid channels running inside the plate body; at least one fluid inlet in direct fluid communication with a first subset of the plurality of parallel hollow fluid channels; at least one fluid outlet in direct fluid communication with a second subset of the plurality of parallel hollow fluid channels; and a porous thermal conductive structure which fluidly connect the first subset of the plurality of parallel hollow fluid channels to the second subset of the plurality of parallel hollow fluid channels, and which is in thermal contact with the thermal conductive side of the plate body. The porous thermal conductive structure may include a plurality of elongate fluid contact surface regions, each may be extending continuously lengthwise along a longitudinal side of respective fluid channel to serve as a fluid interface.

A heat sink for use in drawing heat away from electronic devices such as solid state drives (SSDs) includes microchannels formed along its length. The microchannels may have a triangular cross-section and may be formed by additive manufacturing. Two pairs of microchannels are provided, with coolant fluid running in a first direction through the first pair, and in a second opposite direction in the second pair to minimize thermal gradients along the length of the SSD and heat sink. The walls of the microchannel may be formed with a roughness that provides turbulent flow through the microchannels. The turbulent flow together with the large surface area of the three sides of the triangular microchannels increases the heat transfer coefficient of the microchannels, while the triangular shape and pumping fluid through a pair of microchannels reduces pressure drop along the microchannels.

A liquid cooled server chassis comprising a chassis, at least one electronics module having at least one heat generating component mounted thereon, and a liquid cooling unit, having at least one liquid plate heat exchanger, a liquid row heat sink, an inlet chassis manifold, and an outlet chassis manifold, is provided. The at least one liquid plate heat exchanger, mounted and thermally coupled to the at least one heat generating component, is in fluid communication with the inlet chassis manifold and outlet chassis manifold, transporting heat away from the at least one heat generating component. The liquid row heat sink, in fluid communication with the inlet chassis manifold and outlet chassis manifold, is configured to lower a flowthrough temperature of ambient airflow flowing through the liquid row heat sink. The at least one electronics module and liquid row heat sink are parallel arranged, whereby cooling power is evenly distributed thereamong.

An energy management unit (EMU) is disclosed. The EMU including: a cold plate sandwiched between a first printed circuit board (PCB) and a second PCB, the cold plate comprising one or more magnetics; wherein the cold plate is configured to cool both the first PCB and the second PCB.

According to several aspects of the present disclosure, a battery module housing cooling assembly is disclosed. The battery module housing cooling assembly can include an endwall including a first polymer plate and a second polymer plate that define a slot therebetween. At least one of the first polymer plate or the second polymer plate define a channel therein that is configured to receive a coolant fluid, and the slot is configured to receive an electrical connector. The battery module housing cooling assembly can also include a cooling plate defining a first connection port and a second connection port, wherein the first connection port and a second connection port are configured to provide the coolant fluid to the channel.

A semiconductor package is provided. The semiconductor package includes a segmented inset lid that is divided into a primary component and one or more secondary components, with each secondary component being coupled to the primary component by a compliant liquid-tight adhesive; wherein the primary component is a continuous region including i) a first surface, ii) a second surface, and iii) a boundary surface, the first surface including one or more integrated heat sink surfaces or one or more routing features to promote coolant distribution, the second surface contacting one or more semiconductor dies, and the boundary surface forming a sealing surface with a semiconductor substrate; wherein each secondary component contacts at least one other semiconductor die and forms a water-tight seal with the primary component; and a removable flow cover coupled with the segmented inset lid to form a seal along the boundary surface.

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.

Systems and methods for cooling in a datacenter are disclosed. In at least one embodiment, a thermal load bank (TLB) system to test a hybrid datacenter cooling system includes one or more thermal features to generate heat within a TLB system and includes one or more hybrid cooling features to provide air and liquid cooling responses to such heat generated by one or more thermal features.