Parametric study on the dynamic behavior of natural convection from horizontal rectangular fin arrays

A parametric study on the dynamic natural convection from long horizontal fin arrays (L = 128, 254 and 380 mm) is made using a 3-D unsteady numerical analysis. The investigated range of height H is 6.4–38 mm and that of spacing S is 6.4–20 mm. Increasing L tends to enhance the oscillating sliding-chimney flow, whereas increasing S weakens it. The time-averaged overall convection heat transfer coefficients image are larger for high and short fin arrays, due to the stronger buoyancy and thinner boundary layers. The image–S relation exhibits a steep drop when S is narrowed below a threshold, which is larger for lower and longer fins. The optimum fin spacing Sopt occurs near the threshold S, below which the benefit of increasing heat transfer area surrenders to the decrease of image caused by excessive viscous drag. The heat transfer rate per unit base area Q/Ab decreases with increasing L and decreasing H. The predicted dependence of Sopt on H and L agrees well with experimental results and is explained based on numerical results of flow and heat transfer characteristics. The present predictions of Nu agree well with the correlations in the literature which use S as the characteristic length.