Embodiments described herein may include apparatus, system and/or processes to provide an adjustable thermal coupling between cold plate coupled to a first heat source and a liquid-cooled cold plate cooling a second heat source. In embodiments, the adjustable thermal coupling may provide a degree of freedom along an access in accommodating a dimension requirement of the second heat source. Other embodiments may be described and/or claimed.

Embodiments described herein may include apparatus, system and/or processes to provide an adjustable thermal coupling between cold plate coupled to a first heat source and a liquid-cooled cold plate cooling a second heat source. In embodiments, the adjustable thermal coupling may provide a degree of freedom along an access in accommodating a dimension requirement of the second heat source. Other embodiments may be described and/or claimed.

The present invention relates to a lightweight liquid-cooling-plate assembly having a plastic frame and a heat dissipation system using the same. The liquid-cooling-plate assembly includes a plastic frame and at least one coolant chamber unit. The plastic frame includes a plurality of lateral walls, at least one accommodation opening, and a plurality of fastening elements. The lateral walls are connected with each other to form and define the at least one accommodation opening. The fastening elements are disposed on a part of the lateral walls. The coolant chamber unit is connected with the plastic frame and embedded in the at least one accommodation opening, and includes at least one surface exposed.

The present invention relates to a lightweight liquid-cooling-plate assembly having a plastic frame and a heat dissipation system using the same. The liquid-cooling-plate assembly includes a plastic frame and at least one coolant chamber unit. The plastic frame includes a plurality of lateral walls, at least one accommodation opening, and a plurality of fastening elements. The lateral walls are connected with each other to form and define the at least one accommodation opening. The fastening elements are disposed on a part of the lateral walls. The coolant chamber unit is connected with the plastic frame and embedded in the at least one accommodation opening, and includes at least one surface exposed.

A cooling mechanism of high mounting flexibility includes a heat sink including a heat sink body defining an accommodation portion and position-limit sliding grooves and stop blocks fastened to the heat sink body, heat pipes positioned in the position-limit sliding grooves and stopped against the stop blocks, each heat pipe having a hot interface accommodated in the accommodation portion and an opposing cold interface positioned in one position-limit sliding groove, heat transfer blocks each defining a recessed insertion passage for accommodating the hot interfaces of the heat pipes and an opposing planar contact surface for the contact of a heat source of an external circuit board, and an elastic member elastically positioned between the heat sink and the heat transfer blocks.

A liquid-cooling radiator includes a heat sink. The heat sink has a heat pipe opening on a surface of the heat sink and a heat pipe chamber inside the heat sink which communicates with the heat pipe opening. A pressure device is disposed in the heat pipe chamber. A heat pipe is disposed between the heat pipe opening and the pressure device. The heat pipe has a flexible pipe body. The pipe body has a flow channel therein. A part of the pipe body protrudes from the heat pipe opening and is exposed from the surface of the heat sink.

The present disclosure provides a retaining structure and an assembling method therefor. The retaining structure includes a main body portion, a retaining portion, an actuating portion and a radiator. The radiator can be connected to a heating element on an object, or the radiator is separated from the heating element, so as to quickly couple and separate at least two objects, achieving effects of coupling together and separating repeatedly and quickly.

A kit for joining a fluid conduit to a fluid-based heat-transfer device includes a hose and a port body with a port-body-hose end with a port-body-hose opening, a port-body-connector end with a port-body-connector opening, and a port-body bore extending between the port-body-hose opening and the port-body-connector opening. A port aperture passes through an exterior wall and in fluid communication with the port-body bore. The port-body-hose opening is sealingly, non-rotatably, and non-removably joined to the first hose end. A first connector nut is rotatably and non-removably coupled to the port-body-connector opening. A second connector nut rotatably and non-removably coupled to the second hose end. Upstream and downstream tailpieces each have a conduit end sealingly connectable to respective upstream-fluid and downstream-fluid conduits and each have a connector end removably and selectively connectable to the first connector nut and the second connector nut. A system and method are also disclosed.