A chassis includes top rails extending along a top side of the chassis, bottom rails extending along a bottom side of the chassis, a fluid inlet connected to the chassis that is configured to receive a thermal transfer fluid, and a fluid outlet connected to the chassis that is configured to discharge the thermal transfer fluid. The chassis further includes a thermal transfer fluid path extending between and fluidly coupled to the fluid inlet and the fluid outlet, wherein the thermal transfer fluid is configured to flow through the thermal transfer fluid path, and wherein the thermal transfer fluid path extends in a serpentine pattern through at least one of the top rails and through at least one of the bottom rails.

Phased array antennas, such as a multi-function aperture, are limited in performance and reliability by traditional air-cooled thermal management systems. A fuel-cooled multi-function aperture passes engine fuel through channels within the ribs of the multi-function aperture to provide better heat transfer than can be achieved through air cooled systems. The increased heat transfer and thermal management results in a multi-function aperture with improved performance and reliability.

Presented herein is a plurality of arrangements of cold plates having interior chambers. The interior chamber includes a plurality of fins with a first fin zone and a second fin zone. The cold plate further includes a first fluid inlet and a first fluid outlet. The cold plates can be connected such that each cold plate allows unidirectional flow or counter flow configurations. Unidirectional flow or counter flow cold plates can be arranged in rows and in combination of rows.

Systems and methods for cooling an electronic device via interface of a heat-transfer conduit of the electronic device to a cold plate assembly are disclosed. According to an aspect, a system includes an electronic device including one or more electronic components. Further, the electronic device includes a heat-transfer conduit including a first end and a second end. The first end of the heat-transfer conduit is positioned to receive heat from the electronic component(s). The heat-transfer conduit is configured to conduct heat from the first end to the second end. Further, the system includes a cold plate assembly including a cold plate and a mechanism configured to permit movement of the cold plate. At the first position, the cold plate may contact the second end for receipt of heat from the heat-transfer conduit at the second end. At the second position, the cold plate is apart from the second end.

The disclosure relates to a housing comprising at least one composite wall comprising woven or braided carbon fibers covered with a thermoplastic or thermosetting resin, an electronic card carrying electronic components, and a heat transfer device having at least one portion facing an electronic component to be cooled of the electronic card, said heat transfer device being inserted inside the composite wall, the heat transfer device comprising at least one cooling conduit containing a cooling fluid.

Presented herein is a plurality of arrangements of cold plates having interior chambers. The interior chamber includes a plurality of fins with a first fin zone and a second fin zone. The cold plate further includes a first fluid inlet and a first fluid outlet. The cold plates can be connected such that each cold plate allows unidirectional flow or counter flow configurations. Unidirectional flow or counter flow cold plates can be arranged in rows and in combination of rows.

Phased array antennas, such as a multi-function aperture, are limited in performance and reliability by traditional air-cooled thermal management systems. A fuel-cooled multi-function aperture passes engine fuel through channels within the ribs of the multi-function aperture to provide better heat transfer than can be achieved through air cooled systems. The increased heat transfer and thermal management results in a multi-function aperture with improved performance and reliability.

A cooling system including a cooling unit that cools a heat-generating component; a supply connection tube that is connected to the cooling unit and that supplies a cooling medium to the cooling unit; and a discharge connection tube that is connected to the cooling unit and that discharges the cooling medium from the cooling unit, wherein the supply connection tube and the discharge connection tube have different lengths.

In one embodiment, an apparatus includes an enclosure configured for connection to a printed circuit board, a substrate within the enclosure, a plurality of components mounted on the substrate, a fluid inlet connector, a fluid outlet connector, and a plurality of flow channels within the enclosure, at least one of the components disposed in each the flow channels and segregated from other components in another of the flow channels. The enclosure is configured for immersion cooling of the components.

In one embodiment, an apparatus includes an enclosure configured for connection to a printed circuit board, a substrate within the enclosure, a plurality of components mounted on the substrate, a fluid inlet connector, a fluid outlet connector, and a plurality of flow channels within the enclosure, at least one of the components disposed in each the flow channels and segregated from other components in another of the flow channels. The enclosure is configured for immersion cooling of the components.