An information handling system may include an information handling resource, at least one fluidic conduit thermally coupled to the information handling resource and configured to convey a cooling liquid proximate to the information handling resource in order to cool the information handling resource, an air mover support infrastructure comprising a plurality of bays, each bay of the plurality of bays configured to receive an air mover for cooling components of the information handling system, and a liquid manifold sized and shaped to be received in at least one of the plurality of bays and received in a first bay of the plurality of bays and configured to enable at least one fluidic conduit to fluidically couple to an external cooling system, wherein the external cooling system is configured to deliver cooled cooling liquid to the information handling system, receive warmed cooling liquid from the information handling system, and cool the warmed cooling liquid.

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.

According to an example, a conduit sizeable in length and width comprises a first cover and a second cover. The first cover comprises a first interfacing area between a first component and a second component. The second cover comprises a second interfacing area between a third component and a fourth component. The first cover and the second cover comprise a third interfacing area.

A memory cooler includes a unitary thermal transfer device and a pair of endcaps. The unitary thermal transfer device includes heat transfer tubes, a first end block, a second end block, an inlet chamber, an outlet chamber, an inlet, and an outlet. The first and second end blocks are structurally integrated with each of the heat transfer tubes. The inlet and outlet chambers are partially defined by either the first end block or the second end block. Each of the inlet and outlet chambers are fluidly coupled with the respective liquid flow channel of the at least one heat transfer tube. The respective flow channels to which the inlet and outlet chambers are coupled may be the same or different to define either a direct or a serpentine flow path. Each endcap is affixed to a respective one of the first end block and the second end block to define, in conjunction with the first end block and second end block, the inlet chamber and the outlet chamber.

A system is provided for collection, detection and containment of leaked liquid. The system may include a spout connected to a liquid cooling manifold for channeling liquid. The system may also include a collection tray positioned under the spout and configured to contain the liquid from the spout. The system may further include a leak detection rope having a first end coupled to the liquid cooling manifold, a middle portion extending along the spout, and a second end placed inside the collection tray for detection of liquid.

A manifold assembly provided for a server rack. The manifold assembly can include a manifold tube with a port hole within a spotface that extends inward from an external surface of the manifold tube. A channel can be included having a channel aperture. A bushing can also be included with a throughbore extending along a bushing axis. The bushing can be coupled to the channel with the bushing axis in alignment with a center of the channel aperture. The channel can be rigidly secured to the manifold tube to provide structural support thereto relative to the server rack, with the bushing captivated between the channel and the manifold tube and the bushing received within the spotface.

An adaptable liquid connector structure includes a case, an intermediate member and a liquid connector main body. The case is a hollow frame. The intermediate member is located in the case and includes an opening formed at a front area thereof for mounting the liquid connector main body therein, a locating bore located below the opening, and a plurality of elastic elements mounted on outer sides and a rear side of thereof. The intermediate member is supported by the elastic elements to suspend in the case and the elastic elements absorb assembly tolerance of the adaptable liquid connector structure, such that the liquid connector main body mounted therein is allowed for a positional floating adjustment in and relative to the case upward, downward, leftward and rightward to be smoothly, correctly and securely connected to an adaptor connector.

A liquid cooling system includes a liquid coolant conduit in proximity to heat-generating electrical components within an enclosed space. The conduit allows circulation of a liquid coolant to extract heat from the heat-generating components. The heat-generating components includes at least one first heat-generating electrical component and at least one second heat-generating electrical component. The first heat-generating component produces greater heat than the second heat-generating component. The enclosed space includes an inlet and an outlet. The conduit includes a nozzle fluidly connected to the inlet. The nozzle is located within the enclosed space. The nozzle forms first and second aperture sets. The first aperture set directs the liquid coolant to the first heat-generating component. The second aperture set directs the liquid coolant to the second heat-generating component. The nozzle allows liquid coolant to pass the first heat-generating component at a faster rate than the second heat-generating component.

A cooling apparatus includes a cold plate with a first refrigerant channel through which refrigerant flows, and a pump to circulate the refrigerant. The cold plate includes a bottom wall and an upper wall. A lower surface of the bottom wall is in contact with a heating element. The upper wall is located in contact with the bottom wall. A lower surface of the upper wall and an upper surface of the pump directly oppose each other. A lower surface of the pump is exposed to an outside of the cooling apparatus.