We use high-speed video imaging to study the capillary-driven motion of a micro-droplet along the outside of a pre-wetted conical fiber. The cones are fabricated on a glass-puller with tip diameters as small as 1 μm, an order of magnitude smaller than in previous studies. The liquid is fed through the hollow fiber accumulating at the fiber tip to form droplets. The droplets are initially attached to the opening as they grow in size before detaching and traveling up the cone. This detachment can produce a transient oscillation of high frequency. The spatial variation of the capillary pressure drives the droplets towards the wider side of the cone. Various liquids were used to change the surface tension by a factor of 3.5 and viscosity by a factor of 1500. Within each droplet size and viscous-dissipation regime, the data for climbing speeds collapse on a single curve. Droplets traveling with and against gravity allow us to pinpoint the absolute strength of the driving capillary pressure and viscous stresses and thereby determine the prefactors in the dimensionless relationships. The motions are consistent with earlier results obtained from much larger cones. Translation velocities up to 270 mm/s were observed and overall the velocities follow capillary-viscous scaling, whereas the speed of the fastest droplets is limited by inertia following their emergence at the cone tip.
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机译:我们使用高速视频成像来研究微滴沿着预先润湿的圆锥形纤维外部的毛细管驱动运动。圆锥体是在玻璃拉拔器上制造的,其尖端直径小至1μm,比以前的研究小一个数量级。液体通过聚集在纤维尖端的中空纤维进料形成液滴。随着液滴尺寸的增长,液滴最初会附着在开口上,然后脱离并向上移动。这种脱离会产生高频的瞬时振荡。毛细管压力的空间变化将液滴推向圆锥的较宽侧。使用各种液体将表面张力更改为3.5倍,将粘度更改为1500倍。在每个液滴尺寸和粘滞耗散范围内,爬升速度的数据会在一条曲线上崩溃。液滴在重力作用下和在重力作用下行进,使我们能够精确确定驱动毛细压力和粘性应力的绝对强度,从而确定无因次关系中的因素。这些运动与从更大的圆锥体获得的早期结果一致。观察到最高270 mm / s的平移速度,总体速度遵循毛细管-粘稠垢,而最快的液滴的速度受其在锥顶出现后的惯性限制。
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