Design of a micromixer with alternating flattened tubesMorteza Bayareh, Narges Jafari Ghahfarokhi, and Zahra Ghorbani Kharaji Department of Mechanical Engineering, Shahrekord University, Shahrekord, Iran
E-mail: m.bayareh@sku.ac.ir Received: 13 May 2024 Accepted: 11 June 2024 Abstract: The present paper proposes a novel design for a chaotic micromixer utilizing alternating flattened tubes (AFTs). Three-dimensional Navier–Stokes equations and a convection–diffusion transport equation are solved to perform numerical simulations for a broad Reynolds number (Re) range of 0.1–150. The impact of alternating pitch angle (θ = 30°–75°), Re, and dynamic viscosity (μ = 10−3–10−1) on the performance of the AFT micromixer is assessed. The results reveal that the mixing index is improved with θ due to an enhancement in the molecular diffusion and induced chaotic advection. When Re = 0.1, the AFT micromixer can provide excellent mixing quality compared to a T-shaped micromixer while its pressure drop (Δp) is less than 7 Pa. It is found that molecular diffusion is a dominant mechanism of micromixing when Re is low (0.1) and chaotic advection plays a major role when Re is an order of 10 and 100. The results demonstrate that mixing energy cost is reduced by increasing θ when Re is kept constant, meaning that higher mixing quality can be achieved by enhancing θ while Δp increases slightly. Keywords: Microfluidics; AFT micromixer; Mixing index; Pressure drop; Mixing energy cost Full paper is available at www.springerlink.com. DOI: 10.1007/s11696-024-03564-6
Chemical Papers 78 (11) 6663–6670 (2024) |
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