Arrays of beating cilia emerged in nature as one of the most efficient propulsion mechanisms at a small scale, and are omnipresent in microorganisms. Previous attempts at mimicking these systems have foundered against the complexity of fabricating small-scale cilia exhibiting complex beating motions. In this paper, we propose for the first time arrays of pneumatically-actuated artificial cilia that are able to address some of these issues. These artificial cilia arrays consist of six highly flexible silicone rubber actuators with a diameter of 1 mm and a length of 8 mm that can be actuated independently from each other. In an experimental setup, the effects of the driving frequency, phase difference and duty cycle on the net flow in a closed-loop channel have been studied. Net fluid speeds of up to 19 mm s(-1) have been measured. Further, it is possible to invert the flow direction by simply changing the driving frequency or by changing the duty cycle of the driving block pulse pressure wave without changing the bending direction of the cilia. Using PIV measurements, we corroborate for the first time existing mathematical models of cilia arrays to measurements on prototypes.
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机译:跳动纤毛的阵列作为小规模上最有效的推进机制之一在自然界出现,并且在微生物中无处不在。模仿这些系统的先前尝试已经因制造显示出复杂的跳动运动的小规模纤毛的复杂性而失败。在本文中,我们首次提出了能够解决其中一些问题的气动人工纤毛阵列。这些人造纤毛阵列由六个直径为1 mm,长度为8 mm的高柔韧性硅橡胶致动器组成,可以彼此独立地致动。在实验设置中,研究了驱动频率,相位差和占空比对闭环通道中净流量的影响。已测量到最高19 mm s(-1)的净流体速度。此外,可以通过简单地改变驱动频率或通过改变驱动块脉冲压力波的占空比来改变流向,而不改变纤毛的弯曲方向。使用PIV测量,我们首次证实了纤毛阵列的现有数学模型用于原型测量。
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