Abstract
This paper summarizes the design, the construction and the preliminary results of a transient and steady state investigation of the heat transfer mechanisms of a horizontal heat pipe (HP). The experiments are performed using a custom-made HP constituted by copper tube with outer diameter and length as 35 mm and 510 mm, respectively, with the inner surface covered by three layers stainless steel mesh wick (100 mesh/inch). Water is used as a working fluid. The evaporator section is heated by electrical resistances wrapped around the tube and the cooling system consists of an insulated water manifold with inner diameter of 39 mm, connected to chilled water bath to maintain the inlet temperature of the circulating cooling water at 25 °C for various heat loads (30-100 W). The aims of this activity is to obtain data to verify the steady state HP analytical model already presented by authors at a fixed filling volume and to determine the effect of the heat transfer load on the heat transfer performance of screen mesh HPs. The heat transfer coefficients are determined using thermocouples on the outer wall and within the core of the HP. The agreement between the analytical results and the preliminary experimental data appears to be very good.
Highlights
Phase change heat transfer is suitable for transferring large amount of heat because of the high heat transfer coefficients associated with the evaporation and condensation processes
The study proposed in this paper presents a detailed experimental apparatus and preliminary experimental results about the heat transfer performances of a Heat pipe (HP) designed for a particular solar application
The experimental apparatus has been developed to investigate the thermal performance of a cylindrical copper HP using water as a working fluid
Summary
Phase change heat transfer is suitable for transferring large amount of heat because of the high heat transfer coefficients associated with the evaporation and condensation processes. Heat pipe (HP) is one of such a passive device, which utilize phase change of the working fluid inside of a sealed container (generally a pipe), efficiently transporting large amount of heat from evaporator section to the condenser section; The condensed liquid is drawn back to the evaporator by the capillary force in the wick structure laid at the internal periphery of the device [1,2,3]. The wide use of HPs has led to increased demand to study its thermal performance in order to efficiently designing them, mainly in connection with solar application for medium temperature (50150 ̊C).
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