Tesla turbine and its applications in power generation and fluid flow were demonstrated by Nicholas Tesla in 1913. However, its real-world implementations were limited by the difficulty to maintain laminar flow between rotor disks, transient efficiencies during rotor acceleration, and the lack of other applications that fully utilize the continuous flow outputs. All of the aforementioned limits of Tesla turbines can be addressed by scaling to the microfluidic flow regime. Demonstrated here is a microscale Tesla pump designed and fabricated using a Digital Light Processing (DLP) based 3D printer with 43 μm lateral and 30 μm thickness resolutions. The miniaturized pump is characterized by low Reynolds number of 1000 and a flow rate of up to 12.6 mL/min at 1200 rpm, unloaded. It is capable of driving a mixer network to generate microfluidic gradient. The continuous, laminar flow from Tesla turbines is well-suited to the needs of flow-sensitive microfluidics, where the integrated pump will enable numerous compact lab-on-a-chip applications.
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机译:尼古拉斯·特斯拉(Nicholas Tesla)在1913年证明了特斯拉涡轮机及其在发电和流体流动中的应用。然而,其实际应用受到以下因素的限制:难以保持转子盘之间的层流,转子加速期间的瞬态效率以及缺乏其他优点充分利用连续流量输出的应用。特斯拉涡轮机的所有上述限制都可以通过调整为微流体流态来解决。此处展示的是使用基于数字光处理(DLP)的3D打印机设计和制造的微型Tesla泵,横向分辨率为43μm,厚度分辨率为30μm。小型化泵的特征在于低雷诺数为1000,空载时的流速在1200 rpm时高达12.6 mL / min。它能够驱动混合器网络以产生微流体梯度。来自特斯拉涡轮机的连续层流非常适合对流量敏感的微流体的需求,其中集成的泵将使众多紧凑的芯片实验室应用成为可能。
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