A heat sink structure includes a plurality of radiation fins and a base. Each of the radiation fins has a connecting end and a free end, and internally defines a chamber extended between the connecting end and the free end for filling a working fluid therein. The base has an upper connecting surface provided with a plurality of connecting sections and a lower heat receiving surface in contact with a heat source. The connecting ends of the radiation fins are integrally connected to the connecting sections of the base in one-to-one correspondence through overmolding, so as to eliminate thermal resistance between the radiation fins and the base.

A heat sink for use in an immersion cooling system that includes a sintered powder structure enclosed in a porous enclosure. The porous enclosure has openings, e.g., formed by a mesh, with a size to help contain sintered powder particles that may be dislodged during operation of the heat sink.

A heat sink for use in an immersion cooling system that includes a sintered powder structure enclosed in a porous enclosure. The porous enclosure has openings, e.g., formed by a mesh, with a size to help contain sintered powder particles that may be dislodged during operation of the heat sink.

Cooling device for cooling a separate object to be cooled, in particular a technical component, wherein the cooling device comprises at least one cooling-rib body comprising a plurality of cooling ribs, and at least one main body that is open on at least one side, in particular when viewed in cross section, and defines a receiving space configured to receive at least one cooling-rib body, wherein the at least one cooling-rib body comprises at least one fastening element, which is configured to interact with the at least one main-body-side fastening element to form a fastening between the at least one cooling-rib body received in the receiving space and the main body, and the main body comprises at least one fastening element, which is configured to interact with at least one cooling-rib-body-side fastening element to form a fastening between the at least one cooling-rib body received in the receiving space and the main body.

Cooling device for cooling a separate object to be cooled, in particular a technical component, wherein the cooling device comprises at least one cooling-rib body comprising a plurality of cooling ribs, and at least one main body that is open on at least one side, in particular when viewed in cross section, and defines a receiving space configured to receive at least one cooling-rib body, wherein the at least one cooling-rib body comprises at least one fastening element, which is configured to interact with the at least one main-body-side fastening element to form a fastening between the at least one cooling-rib body received in the receiving space and the main body, and the main body comprises at least one fastening element, which is configured to interact with at least one cooling-rib-body-side fastening element to form a fastening between the at least one cooling-rib body received in the receiving space and the main body.

The present disclosure provides a thermal management device comprising a vapor chamber, a heat pipe in fluid communication with the vapor chamber, and a fin in thermal contact with the heat pipe. The vapor chamber may contain a first working fluid and may facilitate transfer of thermal energy from a source of thermal energy to the first working fluid. The fin may comprise a fluid flow path configured to direct a second working fluid from a first opening to a second opening. The first opening may be oriented along a first direction of flow towards the fin, and the second opening may be oriented along a second direction different than the first direction. The heat pipe may direct the first working fluid from the vapor chamber through the heat pipe and may facilitate transfer of thermal energy from the first working fluid to the fin or the second working fluid.

The present disclosure provides a thermal management device comprising a vapor chamber, a heat pipe in fluid communication with the vapor chamber, and a fin in thermal contact with the heat pipe. The vapor chamber may contain a first working fluid and may facilitate transfer of thermal energy from a source of thermal energy to the first working fluid. The fin may comprise a fluid flow path configured to direct a second working fluid from a first opening to a second opening. The first opening may be oriented along a first direction of flow towards the fin, and the second opening may be oriented along a second direction different than the first direction. The heat pipe may direct the first working fluid from the vapor chamber through the heat pipe and may facilitate transfer of thermal energy from the first working fluid to the fin or the second working fluid.

A heat exchanger includes a fluid flow passage with a wavy fin turbulizer. The turbulizer includes sidewalls extending lengthwise along a fluid flow direction between its first and second ends, and the sidewalls are spaced apart across the width of the turbulizer. Each flow channel of the turbulizer is defined between two adjacent sidewalls. Each sidewall has a smoothly and continuously curved profile with repeating wave forms being defined along the length of the turbulizer. The continuously curved profile of the sidewalls is defined by a non-circular shape, such as elliptical, sinusoidal, parabolic and hyperbolic shapes. The radius of curvature changes constantly and reaches a maximum at or near the inflection point between adjacent crests and troughs of the profile, to provide improved particle pass-through, lower pressure drop, and enhanced plateability of internal surfaces.

A heat exchanger assembly includes a first heat exchange fluid conduit and at least one fin. The first heat exchange fluid conduit defines a passageway therethrough and is configured to receive a flow of a first heat exchange fluid. At least one fin is disposed to receive a flow of a second heat exchange fluid. The fin(s) is/are coupled to the heat exchange fluid conduit at an interface that is configured to reduce accumulation of debris entrained in the second heat exchange fluid.

A heat exchanger assembly includes a first heat exchange fluid conduit and at least one fin. The first heat exchange fluid conduit defines a passageway therethrough and is configured to receive a flow of a first heat exchange fluid. At least one fin is disposed to receive a flow of a second heat exchange fluid. The fin(s) is/are coupled to the heat exchange fluid conduit at an interface that is configured to reduce accumulation of debris entrained in the second heat exchange fluid.