A heat dissipation device includes at least a temperature plate and a cooling fin assembly. The temperature plate includes a plate body and a supporter. The plate body includes a vacuum chamber and a first external surface. The plate body is bent to form at least a bent portion with the first external surface being a compressive side, and the supporter is disposed at the bent portion. The supporter is disposed inside the vacuum chamber and connected to an inner wall of the vacuum chamber. The cooling fin assembly is disposed on the first external surface.

A combined heat sink has multiple dissipation fins serially mounted together. Each one of the dissipation fins has a body and two flanges. The body has at least one through hole formed through the body. The two flanges are respectively formed on one of two surfaces of the body, and have at least one connecting arm. Multiple protrusions protrude on the at least one connecting arm, and a width of the at least one through hole is smaller than a total width of the at least one connecting arm and the multiple protrusions. When the multiple dissipation fins are mounted together, the protrusions of the at least one connecting arm of each dissipation fin pass through the at least one through hole of an adjacent one of the dissipation fins, and abut an area near the at least one through hole to avoid separations of the dissipation fins.

Heat transfer between a fluid-bearing flexible tube and a heat-conducting surface is improved by fixing a flexible heat-conducting sheath to the flexible tube and by compressive fixing that distorts the tube and deforms the sheath and/or the surface. The tube can be made of cross-linked polythene (PEX). The sheath can be spirally wound high-purity aluminum wire. The sheath enables efficient heat transfer between the outer surface of the tube and the heat-conducting surface. Applications include radiant heating and cooling. Tube layout can be customized and variable tube spacing is possible, for example by using a castellated layer to support the tube.

A radiating fin and a connection structure composed of multiple radiating fins. Each radiating fin has a main body formed with a first plane face. A first bending edge and a second bending edge extend from two sides of the first plane face. The first plane face is formed with a first perforation and a second perforation and a third perforation and a fourth perforation. A first extension section and a second extension section respectively from the first and second bending edges. Two front ends of the first extension section are bent and formed with a first latch plate and a second latch plate.

Two front ends of the second extension section are bent and formed with a third latch plate and a fourth latch plate. The latch plates of a forward radiating fin are correspondingly passed through and latched in the perforations of an adjacent rearward radiating fin.

A compliant heating system includes a dynamic component including a heat exchanger; a pressure vessel shell encompassing at least a portion of the heat exchanger; and a accessible and detachable compressive seal expansion that connects the dynamic component and the pressure vessel shell.

An electronic device includes a printed circuit board (PCB). One or more components mounted on at least one of a first side and a second side of the PCB. The first side and the second side are two opposite sides of the PCB. A plurality of solder blades mounted on the second side of the PCB one or more heatsinks inserted onto the plurality of solder blades mounted on the second side of the PCB.

A positioning assembly for a computer radiator contains: multiple first shank members, multiple resilient elements, and multiple second shank members. Each of the multiple first shank members includes a first head knob, a first extension, a locking rib, a shoulder, a slot, and an orifice, wherein an outer diameter of the first extension is less than the first head knob, and the locking rib is in a conical cylinder shape. Each of the multiple resilient elements is fitted on the first extension. Each of the multiple shank members includes a second head knob and a second extension extending downward from a bottom of the second head knob, wherein an outer diameter of the second extension is less than an inner diameter of the orifice so that the second extension is located on a lower end of the orifice after inserting into a top of the orifice.

The invention concerns a support device (1) for a tube, in particular a tube of a heat exchanger designed to come into contact with a vehicle battery for cooling thereof, the device (1) comprising a base (13) on which the tube is designed to be mounted, an element (15) for compressing the tube against the battery, and one or more elements (17) for connecting the compression element (15) to the base (13), the connecting elements (17) being configured to engage with a face (19) of the compression element (15) opposite said base (13) while being in contact with the base (13) on either side of said compression element (15).

A heat exchanger for cooling a flow of charge air includes a heat exchanger core that is inserted through an aperture of a housing. A leak-free seal is maintained along the periphery of the aperture by the compression of a gasket between a top plate of the heat exchanger core and a planar bearing surface of the housing. Compression of the gasket is maintained by one or more deformable retaining members that are disposed against the top plate.

A compliant heating system includes a dynamic component including a heat exchanger; a pressure vessel shell encompassing at least a portion of the heat exchanger; and a compressive seal expansion that connects the dynamic component and the pressure vessel shell.