Laminar heat transfer simulations for periodic zigzag semicircular channels: Chaotic advection and geometric effects

Abstract

The flow and heat transfer characteristics of zigzag channels with a semi-circular cross-section are studied numerically in the steady, laminar flow regime for different Reynolds numbers (50<Re<320) and Prandtl numbers (0.7<Pr<20). The computational domain consists of 10 repeating zigzag units with smoothly joined inlet and outlet sections to investigate the effect of chaotic advection. The simulation results show that chaotic advection can occur for Reynolds numbers above 200 with the zigzag unit geometrical parameters of Rc/d=0.51, Lz/d=1.75 and θ=45° and this leads to the disappearance of the spatial periodicity of the flow pattern. The pressure drop and heat transfer coefficient fluctuate from one unit to the next in the chaotic flow regime. The results show that the mean heat transfer rate increases smoothly with increasing Reynolds number, even as the flow changes from being periodic to chaotic. In the regime of chaotic advection, the local characteristics vary from unit to unit and are very sensitive to small changes of the inlet conditions; a proportional relation is found between the mean Nusselt number and Pr1/3. The geometric parameter ranges of 1.75<Lz/d<3.5, 0.51<Rc/d<1.0 and 5°<θ<45° are studied numerically with chaotic advection present in much of the parameter range.