The flow of liquids in centrifugal microfluidics is unidirectional and dominated by centrifugal and Coriolis forces (i.e., effective only at T-junctions). Developing mechanisms and discovering efficient techniques to propel liquids in any direction other than the direction of the centrifugal force has been the subject of a large number of studies. The capillary force attained by specific surface treatments, pneumatic energy, active and passive flow reciprocation and Euler force have been previously introduced in order to manipulate the liquid flow and push it against the centrifugal force. Here, as a new method, the moment of inertia of the liquid inside a chamber in a centrifugal microfluidic platform is employed to manipulate the flow and propel the liquid passively towards the disc center. Furthermore, the effect of the moment of inertia on the liquid in a rectangular chamber is evaluated, both in theory and experiments, and the optimum geometry is defined. As an application of the introduced method, the moment of inertia of the liquid is used in order to mix two different dyed deionized (DI) waters; the mixing efficiency is evaluated and compared to similar mixing techniques. The results show the potential of the presented method for pumping liquids radially inward with relatively high flow rates (up to 23 mm3/s) and also efficient mixing in centrifugal microfluidic platforms.
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机译:离心微流体中的液体流动是单向的,并且受离心力和科里奥利力的支配(即,仅在T型结处有效)。开发机制和发现有效的技术以在除离心力的方向以外的任何方向上推动液体一直是许多研究的主题。先前已经引入了通过特定的表面处理,气动能,主动和被动流动往复运动以及欧拉力获得的毛细作用力,以便操纵液体流并将其推向离心力。在这里,作为一种新方法,采用了离心微流体平台中腔室内液体的惯性矩来控制流量并将液体被动地推向圆盘中心。此外,无论是在理论上还是在实验上,都评估了惯性矩对矩形腔室内液体的影响,并定义了最佳几何形状。作为引入方法的一种应用,使用液体的惯性矩来混合两种不同的染色去离子(DI)水。评估混合效率并将其与类似的混合技术进行比较。结果表明,该方法具有以较高的流速(最高23 mm 3 / s)径向向内泵送液体以及在离心微流体平台中有效混合的潜力。
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