Optimization of Y-Shaped Micro-Mixers with a Mixing Chamber for Increased Mixing Efficiency and Decreased Pressure Drop

0 ENGINEERING, MECHANICAL ASME journal of heat and mass transfer Pub Date : 2024-01-06 DOI:10.1115/1.4064443
Umut Ege Samancioglu, Ali Kosar, E. Çetkin
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Abstract

In this study, Y-shaped micro-mixers with mixing chamber design optimized as rotation and chaotic advection in the fluid domain increases with the chamber. Motivated by the advantages of Y-shaped mixers, a parametric study was performed for inlet angles (α, β), inlet channel eccentricities (x-ecc, z-ecc) and length scale ratios (L1/L2, D1/D2 and Vsp). z-eccentricity is introduced in addition to x-eccentricity to create a design that further enhances the swirl and chaotic advection inside mixing chamber for the first time. The results reveal that the maximum mixing efficiency can be achieved for Reynolds number of 81 and α, β, x-ecc, z-ecc, D1/D2, and L1/L2 values of 210°, 60°, 20 µm, 20 µm, 1.8 and 4, respectively. In addition, the proposed Y-shaped micro-mixer leads to a lower the pressure drop (at least 50% reduction for all Reynolds numbers) in comparison to competing design. The maximum reduction in pressure drop is 72% less than the CSC (Re= 81) with mixing efficiency of 88% and pressure drop of 9244.4 Pa. Overall, an outstanding mixing efficiency was offered over a wide range of Reynolds numbers with distinctly low pressure drop and a compact micro-mixer design, which could be beneficial for a wide variety of applications where volume and pumping power are limited.
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优化带混合室的 Y 型微型搅拌器,提高混合效率并降低压降
在本研究中,Y 型微型混合器的混合室设计得到了优化,流体域中的旋转和混沌平流随混合室的增大而增大。基于 Y 型混合器的优势,我们对入口角(α、β)、入口通道偏心率(x-ecc、z-ecc)和长度比例(L1/L2、D1/D2 和 Vsp)进行了参数研究。结果表明,当雷诺数为 81,α、β、x-ecc、z-ecc、D1/D2 和 L1/L2 值分别为 210°、60°、20 µm、20 µm、1.8 和 4 时,可实现最大混合效率。此外,与同类设计相比,拟议的 Y 形微混合器可降低压降(在所有雷诺数下至少降低 50%)。压降的最大降幅比 CSC(Re= 81)小 72%,混合效率为 88%,压降为 9244.4 Pa。总之,在雷诺数范围很宽的情况下,微型混合器的混合效率很高,压降很低,而且设计紧凑,有利于体积和泵功率有限的各种应用。
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