Numerical and Experimental Analysis on the Hydrodynamic Behaviors of Nanoparticle Agglomerates at Moderate Reynolds Numbers

Abstract: In this study, the hydrodynamic characteristics of agglomerates are studied experimentally for the Reynolds numbers (Re) up to ∼200, and their fluid dynamic behaviors are analyzed numerically taking their nonhomogeneous structures into account as 50 ≤ Re ≤ 400. The results show that both the Reynolds number and the fractal dimension (D f) of agglomerates significantly affect the flow field around and through the agglomerate. The drag ratios obtained from the numerical simulation show good agreement with the ex… Show more

“…This phenomenon has been discussed in our previous work. [40] From the related literature, [5,29] similar to that in our previous work, this phenomenon often occurs in the range of relatively high Re and low permeability. We thought that the fluid at moderate Re is more capable of penetrating into the agglomerate compared with that at low Re, but the agglomerate with low permeability is not easy for the fluid to pass through, which will result in more energy consumption It should be noted that at d a = 1500 μm, the fluid collection efficiency also increases as Re increases, which indicates that the fluid can enter the agglomerate easily.…”

Hydrodynamics of inhomogeneous agglomerates for a fractal dimension of 2.5 at intermediate Reynolds numbers: Effect of agglomerate sizes and Reynolds numbers

“…This phenomenon has been discussed in our previous work. [40] From the related literature, [5,29] similar to that in our previous work, this phenomenon often occurs in the range of relatively high Re and low permeability. We thought that the fluid at moderate Re is more capable of penetrating into the agglomerate compared with that at low Re, but the agglomerate with low permeability is not easy for the fluid to pass through, which will result in more energy consumption It should be noted that at d a = 1500 μm, the fluid collection efficiency also increases as Re increases, which indicates that the fluid can enter the agglomerate easily.…”

Hydrodynamics of inhomogeneous agglomerates for a fractal dimension of 2.5 at intermediate Reynolds numbers: Effect of agglomerate sizes and Reynolds numbers

Numerical study on the drag and flow characteristics of porous particles at intermediate Reynolds numbers

Progressive bridge collapse analysis under both scour and floods by coupling simulation in structural and hydraulic fields. Part Ⅰ: Numerical solver