Numerical Assessments on Flow Topology and Heat Transfer Behavior in a Round Tube Inserted with Three Sets of V-Ribs

Abstract

Simulation of f luid-f low topology and thermal behavior in a round tube heat exchanger (RTHX) installed by three V-rib sets is reported. The expected phenomena for the rib installation are the generated vortex f low, impinging f low, greater f luid blending and thermal boundary layer disturbance (TBLD). These phenomena are key causes of the augmentation of heat transfer potentiality and thermal efficiency of the RTHX. Effects of rib height (b1 = 0.05D – 0.25D and b2 = 0.05D – 0.25D), rib pitch or rib spacing (P = D, 1.5D and 2D) and f luid directions (positive x (+x f low direction) and negative x (–x f low direction)) on f luid-f low behavior and thermo-hydraulic characteristic are considered. The laminar air f low under Reynolds numbers between 100 to 2000 calculated by the inlet condition is focused. The current numerical problem of the RTHX fitted with V-ribs can be solved by a commercial code/program (the finite volume analysis). Firstly, the tested-tube model is carefully validated. The preliminary results of the validation show that the numerical model has great consistency for f luid f low and thermal structure prediction. The simulated outcomes are plotted in features of streamlines f low, local Nusselt number contours and temperature contours which explain the mechanism within the RTHX. The thermal assessments within the RTHX are performed with dimensionless variables, which include the Nusselt number, the friction factor and the thermal enhancement factor. The important mechanisms: vortex f low, impinging f low, better f luid blending and TBLD, are observed when the RTHX are installed with ribs. The maximum heat transfer potentiality is 19 times upper than that of the RTHX without ribs and the optimum thermal enhancement factor is around 4.10.