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.

Design and packaging of wide bandgap (WBG) power electronic power stages are disclosed herein. An example apparatus includes a first printed circuit board (PCB) including: a first voltage phase circuit cluster; a second voltage phase circuit cluster; and a cluster of traces, the cluster of traces routed substantially perpendicular to the second voltage phase circuit cluster; a second PCB positioned below the first PCB; and a connector to connect the first PCB to the second PCB, the connector electrically coupled to the first voltage phase circuit cluster by the cluster of traces.

A system for cooling a mobile phone and method for using the system are described. The system includes an active piezoelectric cooling system, a controller and an interface. The active piezoelectric cooling system is configured to be disposed in a rear portion of the mobile phone distal from a front screen of the mobile phone. The controller is configured to activate the active piezoelectric cooling system in response to heat generated by heat-generating structures of the mobile phone. The interface is configured to receive power from a mobile phone power source when the active piezoelectric cooling system is activated.

A modular liquid cooling block is described for cooling high current devices deployed in power flow control systems. The liquid cooling blocks may have separate shower heads which may be configured for direct impingement, indirect impingement, or parallel flow cooling configurations. Voltage isolation of liquid cooling blocks from an enclosure of the power flow control system and from associated equipment enables serial or parallel connected power flow control units to inject substantial reactive power that may be configurable into a power transmission line. Associated power flow control systems are monitored for temperature, flow rate and pressure gradient. Redundant pumps and fan radiators contribute to reliable operation. Automatic shutdown and alarm may be provided.

A heat exchange module, comprising an array of microchannels, where the array of microchannels extends in a first direction, and are separated from one another by a first sidewall. The array of microchannels is over a cold plate. A first array of fluid distribution channels is stacked over the array of microchannels and extend in a second direction that is substantially orthogonal to the first direction. The first array of fluid distribution channels extends from the first manifold and terminate between a first manifold and a second manifold. A second array of fluid distribution channels is stacked over the array of microchannels. The first array of fluid distribution channels and the second array of the fluid distribution channels are fluidically coupled to the microchannel array. A wall extends into the microchannel array below a second sidewall separating ones of the first array and ones of the second array of fluid distribution channels.

A system for cooling a mobile phone and method for using the system are described. The system includes an active piezoelectric cooling system, a controller and an interface. The active piezoelectric cooling system is configured to be disposed in a rear portion of the mobile phone distal from a front screen of the mobile phone. The controller is configured to activate the active piezoelectric cooling system in response to heat generated by heat-generating structures of the mobile phone. The interface is configured to receive power from a mobile phone power source when the active piezoelectric cooling system is activated.

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 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 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.

Disclosed herein are integrated circuit (IC) packages with a heat generating electronic component and a fluid impingement cooling apparatus having a plurality of rotatable nozzles, as well as related devices and methods. In some embodiments, an IC device assembly may include a plurality of rotatable nozzles disposed in a nozzle plate, wherein the plurality of rotatable nozzles are rotatable individually; a microcontroller to identify a hotspot on a target surface of an IC device, wherein the hotspot has a temperature that is greater than a threshold temperature; and a motor coupled to the plurality of rotatable nozzles, wherein the motor causes one or more of the rotatable nozzles to rotate to impinge fluid on the hotspot.