An improved baffle assembly for heat exchanger tubes comprising a shaft and at least one opposing pair of expanding baffles positioned coaxially on the shaft, each expanding baffle comprising a central hub portion and a plurality of extension portions each radiating outward from the hub portion at complementary oblique angles so that the central hub portions of each baffle are spaced apart along the shaft and the distal ends of the extension portions of each baffle are brought into physical contact.

The present invention comprises: a base receiving heat from a heat source; a hollow cylinder-shaped fixed cylinder fixedly receiving the heat from the base, an opening thereof being closed by the base; fixed fins fixedly provided at the fixed cylinder to receive the heat from the fixed cylinder; a piston slidably blocking the inside of the fixed cylinder forming an accommodation chamber for a phase change material; and an elastic member for applying force toward the base with respect to the piston, wherein at low temperature heat, the phase change material changes a phase in a volume reducing direction, and the piston is returned to a backward position at the side of the base, and at high temperature heat, the phase change material changes the phase in a volume increasing direction, and the piston is operated to move from the backward position to a forward position.

A heat exchanger comprises a base, and a plurality of deformable fins connected to a surface of the base. Some deformable fins have a free end configured to move away from the surface of the base as a function of a local temperature increase of the base. The deformable fins are distributed on the surface of the base to be exposed to a coolant flowing over the surface of the base, wherein a distribution of the deformable fins on the surface of the base is non-uniform.

A cooling structure includes a plurality of heat radiation parts configured to cool a heat generating component and a holding member configured to hold the plurality of heat radiation parts. Moreover, the heat radiation parts of the cooling structure each include a base portion located on the side of the heat generating component and a fin portion extending from the base portion and radiating heat. Furthermore, the base portions of the heat radiation parts abut on each other.

The present disclosure relates to a fin heat exchanger, including a header, a set of tubes fluidly coupled to the header, and a mount configured to engage with and disengage from the set of tubes. The mount includes a fin section configured to extend between adjacent tubes of the set of tubes in an engaged mount configuration, and configured to be separated from the set of tubes in an unengaged mount configuration.

The invention relates to a heat exchanger (10) for heat-exchange between a first fluid and a second fluid, comprising a membrane separating the two fluids and a heat-conductive element (17) in thermal contact with the membrane and with the first fluid, characterised in that said heat-conductive element (17) moves between an active position and an inactive position, such that the capacity of heat exchange with the first fluid is weaker in the inactive position than in the active position. The exchanger is applied, in particular, for the cooling of fluid in the secondary stream of a turbofan.

A method for cooling a satellite system comprising configuring a plurality of fins to absorb and emit thermal radiation, wherein the ratio of absorptivity/emissivity is less than one; mechanically coupling the plurality of fins to the outside surface of a satellite, wherein the angle of the plurality of fins can be adjusted and controlled such that they can be stowed against the surface of the satellite or deployed; deploying the fins as necessary to expel heat from the satellite.

A surface cooler includes a conduit, a body having an external surface, and a plurality of fin members arranged in an array of fin members. The conduit defines an inlet, an outlet, and an internal flow path extending between the inlet and the outlet. The conduit is configured to channel a flow of fluid to be cooled from the inlet to said outlet. The conduit extends through the body. Each fin member of the array of fin members extends from the external surface of the body. Each fin member is fabricated from a thermally conductive, resilient, and pliable material.

A shape-morphing fin includes a fixed portion, a multistable portion, a coupling portion, and a vibration source. The multistable portion functions as a negative stiffness element. The multistable portion is selectively movable between a first position and a second position. The movement between first position and the second position is configured to remove the ice formation from the structure. The coupling portion couples the fixed portion to the multistable portion. The vibration source is configured to produce a resonant vibration to engage the movement of the multistable portion from the first position to the second position.

An improved baffle assembly for heat exchanger tubes comprising a shaft and at least one opposing pair of expanding baffles positioned coaxially on the shaft, each expanding baffle comprising a central hub portion and a plurality of extension portions each radiating outward from the hub portion at complementary oblique angles so that the central hub portions of each baffle are spaced apart along the shaft and the distal ends of the extension portions of each baffle are brought into physical contact.