An immersion cooling assembly comprises at least one primary heat-generating electronic component and a flow-through cooling module mounted near the at least one primary heat-generating component. The flow-through cooling module comprises at least one inlet conduit to accept an inflow of pressurized dielectric coolant, a fluid chamber through which fluid flows to provide targeted, direct cooling to a heat-generating component, and exit passageways to facilitate flow-through of the dielectric coolant into a surrounding immersion bath for cooling of other components. As it flows out of the cooling module and over the heat-generating component, the coolant fluid absorbs heat from the heat-generating electronic component. In certain embodiments, the assembly may also comprise at least one periphery heat-generating electronic component, which may also be cooled by the dielectric coolant as it exits the vicinity of the flow-through cooling module. The cooling module may include impingement nozzles to accelerate and direct the flow of coolant fluid toward the high-heat-generating electronic component.

A cooling device of a projection display apparatus includes a first heat receiving unit including an opening that is rectangular. The first heat receiving unit includes a flow path part that forms the opening. An image display element of the projection display apparatus includes a first front face located in front of a reflective image display, a second front face parallel to the first front face and located behind and outside the first front face, and a first side face located between the first front face and the second front face. The first front face is inserted into the opening, and the flow path part is in contact with the first side face and the second front face via a heat conductive member. The flow path part includes a front face that is flush with or in front of the first front face of the image display element.

A heat exchanger includes a plurality of fins that are spaced from each other and are arranged to divide a heat medium flow passage into a plurality of narrow passages. Each fin incudes a plurality of thick wall portions and a plurality of thin wall portions which are alternately arranged in a passage longitudinal direction. Each adjacent two of the plurality of fins, which are adjacent to each other, are defined as one fine and another fin, and each of the plurality of thick wall portions of the one fin is opposed to an adjacent one of the plurality of thin wall portions of the another fin in a fin arrangement direction, and each of the plurality of thin wall portions of the one fin is opposed to an adjacent one of the plurality of thick wall portions of the another fin in the fin arrangement direction.

An electronic device includes a first housing and a second housing connected to the first housing. An accommodation cavity is formed between the first housing and the second housing. The electronic device further includes a heat generation member arranged in the accommodation cavity and a flow channel arranged in the first housing. The flow channel is configured to accommodate heat exchange liquid and dissipate heat for the heat generation member through the heat exchange liquid.

A system for cooling computer hardware includes a first heat exchanger and a pump. The first heat exchanger includes a computer hardware contact surface configured to be in thermal contact with the computer hardware on a first side and to be in thermal contact with a cooling liquid on a second side. The first heat exchanger also includes a liquid chamber having a pump interface with at least one chamber inlet and at least one chamber outlet. The pump includes a chamber interface with at least one pump outlet and at least one pump inlet. The pump is configured to: detachably connect at the chamber interface to the pump interface, and drive the cooling liquid from a second heat exchanger to the at least one pump outlet and from the at least one a pump inlet to the second heat exchanger.

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 connector that includes a contact, a connection piece, and a cooling unit. The connection piece is received by the contact, and the cooling unit is connected to the connection piece. The cooling unit includes a heat sink spaced from the contact, a first heat exchanger section between the contact and the connection piece, a second heat exchanger section positioned in the heat sink and in communication with the first heat exchanger section, and a heat transfer medium that circulates between the first heat exchanger section and the second heat exchanger section.

The present disclosure is directed to examples of modular data centers configured to provide cooling to liquid-cooled electronics equipment stored within the modular data centers. In one aspect, a modular data center can be configured to provide cooling without requiring the use of mechanical refrigeration (e.g. vapor-compression or absorption refrigeration), through the use of a dry cooler in combination with an optional evaporative cooler.

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 wearable electronic device is disclosed. The device can include a support structure and an electronic component disposed in or on the support structure. A heat exchanger element can be thermally coupled with the electronic component, the heat exchanger element comprising a fluid inlet port and a fluid outlet port. A first conduit can be fluidly connected to the fluid inlet port of the heat exchanger, the first conduit configured to convey, to the heat exchanger, liquid at a first temperature. A second conduit can be fluidly connected to the fluid outlet port of the heat exchanger, the second conduit configured to convey, away from the heat exchanger, liquid at a second temperature different from the first temperature.