Valveless Pumping at Low Reynolds Numbers

Gabriel Amselem; Christophe Clanet; Michael Benzaquen

doi:10.1103/PhysRevApplied.19.024017

Valveless Pumping at Low Reynolds Numbers

Research output: Contribution to journal › Article › peer-review

Abstract

Pumping at low Reynolds number is a ubiquitously encountered feature, both in biological organisms and engineered devices. Generating net flow requires the presence of an asymmetry in the system, which traditionally comes from geometric flow rectifiers. Here, we study a valveless system of N oscillating pumps in series, where the asymmetry comes not from the geometry but from time, that is, the phase shifts between the pumps. Experimental and theoretical results are in very good agreement. We provide the optimal phase shifts leading to the maximal net flow in the continuous N→∞ limit. The maximal flow rate is larger by 25% than that of a traditional peristaltic sinusoidal wave, for the same amplitude of actuation. Our results hopefully pave the way for the design of more efficient microfluidic pumps.

Original language	English
Article number	024017
Journal	Physical Review Applied
Volume	19
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevApplied.19.024017
Publication status	Published - 1 Feb 2023

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10.1103/PhysRevApplied.19.024017

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title = "Valveless Pumping at Low Reynolds Numbers",

abstract = "Pumping at low Reynolds number is a ubiquitously encountered feature, both in biological organisms and engineered devices. Generating net flow requires the presence of an asymmetry in the system, which traditionally comes from geometric flow rectifiers. Here, we study a valveless system of N oscillating pumps in series, where the asymmetry comes not from the geometry but from time, that is, the phase shifts between the pumps. Experimental and theoretical results are in very good agreement. We provide the optimal phase shifts leading to the maximal net flow in the continuous N→∞ limit. The maximal flow rate is larger by 25\% than that of a traditional peristaltic sinusoidal wave, for the same amplitude of actuation. Our results hopefully pave the way for the design of more efficient microfluidic pumps.",

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AB - Pumping at low Reynolds number is a ubiquitously encountered feature, both in biological organisms and engineered devices. Generating net flow requires the presence of an asymmetry in the system, which traditionally comes from geometric flow rectifiers. Here, we study a valveless system of N oscillating pumps in series, where the asymmetry comes not from the geometry but from time, that is, the phase shifts between the pumps. Experimental and theoretical results are in very good agreement. We provide the optimal phase shifts leading to the maximal net flow in the continuous N→∞ limit. The maximal flow rate is larger by 25% than that of a traditional peristaltic sinusoidal wave, for the same amplitude of actuation. Our results hopefully pave the way for the design of more efficient microfluidic pumps.

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Valveless Pumping at Low Reynolds Numbers

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