A thermosiphon includes a condenser; an evaporator that includes a fluid channel and a heat transfer surface, the heat transfer surface defining a plurality of fluid pathways in the fluid channel that extend through the fluid channel, the evaporator configured to thermally couple to one or more heat-generating electronic devices; and a transport member that fluidly couples the condenser and the evaporator, the transport member including a liquid conduit that extends through the transport member to deliver a liquid phase of a working fluid into the fluid pathways, the transport member further including a surface to vertically enclose the plurality of fluid pathways.

An apparatus for cooling one or more heat generating components comprises: a sealable enclosure defining a volume for containing a first coolant and one or more heat generating components; a conduit surrounded by the volume, the conduit enabling a second coolant to enter and leave the enclosure, the conduit providing a fluid-tight seal between the first coolant and the second coolant when the first coolant within the volume surrounds the conduit; and a pump within the enclosure configured to direct the first coolant to the conduit such that heat is exchanged between the first coolant and the second coolant.

Embodiments of this application relate to a heat dissipator including a cover plate, an orifice plate, and a base plate that are stacked in sequence. A distribution cavity is disposed between the orifice plate and the cover plate, a heat exchange cavity is disposed between the orifice plate and the base plate, and the distribution cavity communicates with the heat exchange cavity by using through holes disposed on the orifice plate. A plurality of pin fins facing the orifice plate are disposed on a surface of the base plate in the heat exchange cavity, gaps between the plurality of pin fins constitute a fluid passage, and the pin fins include a combination pin fin in contact with the orifice plate, and a flow guiding pin fin that corresponds to the through hole and that has a gap with the through hole.

Heat sink and heat sink arrangements are provided for an electronic device immersed in a liquid coolant. A heat sink may comprise: a base for mounting on top of a heat-transmitting surface of the electronic device and transferring heat from the heat-transmitting surface;

and a retaining wall extending from the base and defining a volume. A heat sink may have a wall arrangement to define a volume, in which the electronic device is mounted. A heat sink may be for an electronic device to be mounted on a surface in a container, in an orientation that is substantially perpendicular to a floor of the container. Heat is transferred from the electronic device to liquid coolant held in the heat sink volume. A cooling module comprising a heat sink is also provided. A nozzle arrangement may direct liquid coolant to a base of the heat sink.

A multi-layer cooling structure comprising a first substrate layer comprising an array of cooling channels, a second substrate layer comprising a nozzle structure that includes one or more nozzles, an outlet, and an outlet manifold, a third substrate layer comprising an inlet manifold and an inlet, and one or more TSVs disposed through the first substrate layer, second substrate layer, and third substrate layer. At least one of the one or more TSVs is metallized. The first substrate layer and the second substrate layer are directly bonded, and the second substrate layer and the third substrate layer are directly bonded.

A driver board assembly includes first and second substrates, one or more power device assemblies and a cooling manifold. At least one jet impingement assembly is formed on a first surface of the first substrate and includes an impingement receiving portion that is at least partially circumferentially surrounded by a plurality of fluid microchannels that extend radially from the impingement receiving portion along the first surface. The second substrate is bonded onto the first substrate. The second substrate surface has a recess. The plurality of receiving contours are etched within the first surface of the first substrate. The one or more power device assemblies are bonded into the recess of the second substrate. A first cooling surface of the cooling manifold is bonded to the first surface such that the first cooling surface bonds within the plurality of receiving contours within the first surface of the first substrate.

Systems and methods for chip cooling with near edge jets in a direct liquid cooled module are disclosed. One of the functions of a direct liquid cooled module is to provide cooling liquid to components located on a chip. Jet impingement directly onto the back side of a chip is one cooling method that can provide more efficient cooling. An orifice plate includes an array of small diameter holes that correspond to high velocity jet locations and large diameter holes for the insertion of tubes to connect to lower pressure cavities.

A cooling apparatus for an electronic or computing device includes a base for thermal coupling to a surface of the electronic or computing device and a cover spaced from the base. A nozzle plate is disposed between the base and the cover to partially define an inlet volume and an outlet volume. Cooling fluid enters the inlet volume and passes through the nozzle plate to the outlet volume and out of the apparatus. The nozzle plate includes a plurality of flow paths through which the cooling fluid passes from the inlet volume to the outlet volume. The flow paths cause the fluid to exit the nozzle plate as transversely expanding fluid jets.

A system including a tile and a hood is described. The tile includes a plurality of cooling cells. Each of the cooling cells includes a support structure and a cooling element. The cooling element is supported by the support structure and is configured to undergo vibrational motion when actuated to drive a fluid toward a heat-generating structure. The hood is coupled to the tile and directs the fluid around the plurality of cooling cells.

A driver board assembly includes first and second substrates, one or more power device assemblies and a cooling manifold. At least one jet impingement assembly is formed on a first surface of the first substrate and includes an impingement receiving portion that is at least partially circumferentially surrounded by a plurality of fluid microchannels that extend radially from the impingement receiving portion along the first surface. The second substrate is bonded onto the first substrate. The second substrate surface has a recess. The plurality of receiving contours are etched within the first surface of the first substrate. The one or more power device assemblies are bonded into the recess of the second substrate. A first cooling surface of the cooling manifold is bonded to the first surface such that the first cooling surface bonds within the plurality of receiving contours within the first surface of the first substrate.