Computational fluid dynamics techniques are used to study the performance of an axial flow bioaerosol sampling cyclone that continuously collects particles onto a flowing liquid film. A special shell-volume concept was developed to study formation and development of the liquid film on the inner wall of the cyclone. For a previous version of the cyclone, simulations demonstrated the presence of a ring of liquid in the region just upstream of the liquid skimmer that was suspected of causing liquid carryover into the exhaust air stream and degradation in aerosol collection efficiency. This ring was eliminated by re-design of the cyclone. For the upgraded version of the cyclone, CFD was used to successfully predict aerosol collection efficiency and cyclone pressure drop. The simulations reveal a complex flow evolution inside the cyclone. Stream-tubes are used to describe a significant narrowing of the width of the airflow as it enters the cyclone and an inward displacement of the flow as it travels in the axial direction. The particle deposition occurs primarily in a region that is subtended approximately by the length of the rectangular entrance slot and the first half turn of the flow in the cyclone. Outpoint Stokes number is about 0.05 and the cutpoint particle size is about 1 mu m aerodynamic diameter. At a flow rate of 1250 L/min, the pressure drop across the cyclone is 5.6 kPa (22 inches of water).
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机译:计算流体动力学技术用于研究轴流生物气溶胶采样旋流器的性能,该旋流器将颗粒连续收集到流动的液膜上。为了研究旋风分离器内壁上液膜的形成和发展,提出了一种特殊的壳体积概念。对于先前版本的旋风分离器,模拟表明在液体分离器的上游区域中存在一个液体环,该环被怀疑导致液体残留到废气流中并降低了气溶胶收集效率。通过重新设计旋风分离器消除了该环。对于旋风的升级版本,CFD用于成功预测气溶胶收集效率和旋风压降。模拟显示旋风分离器内部复杂的流动演变。流管用于描述气流进入旋风分离器时气流宽度的显着变窄以及气流沿轴向行进时向内的位移。颗粒沉积主要发生在一个区域中,该区域大致由矩形入口缝隙的长度和旋风分离器中气流的前半圈所包围。斯托克斯点数约为0.05,切点粒径约为1微米空气动力学直径。在1250 L / min的流速下,旋风分离器上的压降为5.6 kPa(22英寸水柱)。
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