Abstract
The results of experimental investigation of free convection heat transfer in a rectangular container are presented. The ability of the commonly accepted correlation equations to reproduce present experimental data was tested as well. It was assumed that the examined geometry fulfils the requirement of no-interaction between heated cylinder and bounded surfaces. In order to check this assumption recently published correlation equations that jointly describe the dependence of the average Nusselt number on Rayleigh number and confinement ratios were examined. As a heat source served electrically heated horizontal tube immersed in an ambient fluid. Experiments were performed with pure ethylene glycol (EG), distilled water (W), and a mixture of EG and water at 50%/50% by volume. A set of empirical correlation equations for the prediction of Nu numbers for Rayleigh number range 3.6 × 104 < Ra < 9.2 × 105 or 3.6 × 105 < Raq < 14.8 × 106 and Pr number range 4.5 ≤ Pr ≤ 160 has been developed. The proposed correlation equations are based on two characteristic lengths, i.e., cylinder diameter and boundary layer length.
Highlights
Free convection heat transfer from heated horizontal cylinders immersed in an extensive, quiescent fluid has been intensively studied for decades [1]
Free convection flows generated by a heated body immersed in a bulk of fluid are bounded by the side walls, ceiling or free surface of the liquid, and bottom wall
Numerical and experimental studies have been conducted in order to clarify the impact of confinement on free convection heat transfer performance from horizontal, heated cylinders immersed in a fluid
Summary
Free convection heat transfer from heated horizontal cylinders immersed in an extensive (infinite, unbounded), quiescent fluid has been intensively studied for decades [1]. In industry as well as in laboratory practice, the condition of no-interaction between the heated cylinder and bounded surfaces is often not fulfilled. Free convection flows generated by a heated body immersed in a bulk of fluid are bounded by the side (horizontal) walls, ceiling (vertical confinement) or free surface of the liquid, and bottom wall. Morgan [2] suggests that discrepancy between experimental data presented in literature may be attributed to “an undersized containment volume”. Numerical and experimental studies have been conducted in order to clarify the impact of confinement on free convection heat transfer performance from horizontal, heated cylinders immersed in a fluid. Following the model proposed by Churchill and Usagi [3], Churchill and Chu [4]
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