Device for an endoscopic illumination apparatus comprising a heat pipe having a first end region and a second end region; a first heat source; a heat dissipation element for dissipating thermal energy from said first heat source; a heat sink spaced apart from the first heat source; and a clamping element, wherein the clamping element is reversibly detachably mounted on the heat dissipation element such that the first end region of the heat pipe is held between the heat dissipation element and the clamping element, wherein the heat pipe is adapted to conduct the thermal energy of the heat source to the heat sink, wherein the second end region of the heat pipe is spaced apart from the first end region, and wherein the second end region ends in the heat sink.

Systems and methods for embedding a thermal management system in an electric propulsion (EP) system is presented. According to one aspect, one or more oscillating heat pipes (OHPs) are provided within functional elements of the EP system. Each OHP includes channel segments that include a sealed working fluid. The channel segments are joined to form a continuous serpentine channel with a channel path that alternates between hot and cold regions of the EP system. According to another aspect, the functional elements of the EP system are reduced to a single monolithic structure with an embedded OHP. The single monolithic structure may be a single material or a multi material. According to yet another aspect, the functional elements are elements of a magnetic circuit of the EP system, including one or more of a backplate, an outer pole, an inner pole, or a center pole.

Provided herein is an example heat sink including a heat dissipation unit including a plurality of heat dissipation fin groups including a plurality of heat dissipation fins, the plurality of heat dissipation fin groups forming a laminated structure and a plurality of heat pipes, one end portions of which are thermally connected to a heating element and other end portions of which are inserted into a space provided between the plurality of heat dissipation fin groups forming the laminated structure and thermally connected to the heat dissipation unit.

A heating body, having multiple heat tubes filled with a working medium and run in parallel, and which have a first end and a second end, and having a heat source, which is thermally coupled to the first and/or second end of the heat tubes. To improve efficiency, reduce heating time, and achieve a homogeneous heat distribution, the first ends of the heat tubes are open and are fluidically connected to a first transverse connection tube and/or the second ends of the heat tubes are open and are fluidically connected to a second transverse connection tube, the heat tubes and the transverse connection tubes form a common cavity filled with the working medium, and the first or second transverse connection tube is thermally coupled to the heat source in order to absorb heat from the heat source.

A micro-channel pulsating heat pipe, preferably closed loop, includes a plate with micro-channels with obstructions along interior walls to increase surface area, add nucleation sites for the working fluid vaporization, and otherwise enhance fluid movement and heat transfer. Various shapes of obstructions are considered on one or more of the bottom wall, the side walls, and top wall of the channel. Plating may fit over or around the plate to enhance strength and heat transfer. Ribbing, of a thermally conductive material, may set on the exterior surface of the plate and/or plating to enhance surface area to encourage heat transfer and arranged to facilitate air movement across exterior surface.

A evaporator of a loop heat pipe includes a liquid inlet side portion that extends in a widthwise direction crossing with a lengthwise direction from a liquid inlet side to a vapor outlet side, a plurality of portions that continue to the liquid inlet side portion and extend in the lengthwise direction, a plurality of vapor flow paths that are provided between the plurality of portions and extend in the lengthwise direction, and a vapor outlet side vapor flow path that extends in the widthwise direction and continues to the vapor flow paths. Each of the plurality of portions includes a first groove communicating two adjacent ones of the vapor flow paths.

A heat exchange system for heat dissipation of an electronic control assembly includes: a first heat exchange portion including a first end having a first communication port and a second end having a second communication port; a second heat exchange portion including a first end having a third communication port and a second end having a fourth communication port, and at least a part of the second heat exchange portion being configured to be in contact with the electronic control assembly; a first connection tube communicating the first communication port with the third communication port; and a second connection tube communicating the second communication port with the fourth communication port. The first and second heat exchange portions and the first and second connection tubes constitute a loop, the loop has an opening, and the opening is closed when the heat exchange system is in an operative state.

A defrosting apparatus comprises a heater case comprising a heat pipe seating part formed to extend from one surface thereof in a recessed shape and a heater receiving part formed to extend to be parallel with the heat pipe seating part. The defrosting apparatus also includes a heater which is mounted in the heater receiving part so as to emit heat when power is applied thereto, a heat pipe which has a flow path through which a working fluid filled therein flows, which has a part seated on the heat pipe seating part, and which is disposed to be adjacent to a cooling pipe of an evaporator such that heat is radiated to the cooling pipe of the evaporator by means of the working fluid at a high temperature which is heated by the heater and then is transferred, and a holder which is detachably coupled to the heater case so as to cover the heat pipe seated on the heat pipe seating part.

A wind turbine, including a main gear box, which is lubricated and/or cooled by oil, and a thermosiphon cooling system for cooling the oil is provided. The thermosiphon cooling system solves the main challenges facing the oil cooling systems in wind turbines. The high efficiency of the evaporation heat transfer mechanism gives the capacity to transfer the required heat load in relatively smaller size system. In this way, installation space is reduced. The thermosiphon cooling system has no service requirements over the lifetime of the wind turbine since the thermosiphon cooling system has no moving parts. Costs are saved since the simplicity of the thermosiphon cooling system adds a big value to the system business case.

An enhanced gravity-driven, thin film condensation heat transfer condenser is disclosed for use in a thermosyphon performing in two perpendicular orientations, as well as orientations in between. The thermosyphon includes an evaporator fluidly coupled to a first condenser configured with a plurality of fins, with each of the plurality of fins having notches adjacent to flanges, the notches forming vapor flow channels through the plurality of fins. The first condenser is fluidly coupled to a second condenser, and vapor flowing from the evaporator must first pass through the first condenser before entering the second condenser.