Dimensionless analysis of valveless pumping in a thick-wall elastic tube: Application to the tubular embryonic heart

Pavel Kozlovsky, Moshe Rosenfeld, Ariel J. Jaffa, David Elad*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

14 Scopus citations

Abstract

The physical mechanism that drives blood flow in the valveless tubular embryonic heart is still debatable whether it is peristaltic flow or valveless dynamic suction. Previous studies of valveless pumping were concerned with either the role of the excitation parameters or the mechanisms that generate the unidirectional outflow. In this study, a dimensionless one-dimensional (1D) analysis of the valveless pumping due to local excitation at an asymmetric longitudinal location was performed for non-uniform thick-wall elastic tubes, including tubes with local bulging and tapering. A general tube law that accounts for wall thicknesses was implemented for describing the physically realistic dynamics of the tube and the two-step MacCormack algorithm was utilized for the numerical analysis. A comprehensive analysis was conducted to explore the affecting roles of the system (e.g., tube geometry) and the working (e.g., Strouhal number and flow friction parameter) parameters on the net outflow of the pump. The maximal positive net outflow in all the tested cases always occurred when the natural Strouhal number was about π. Flow reversals were observed only for relatively low friction parameters. A local bulging at the site of excitation and thick walls contributed to larger outflows, while tube tapering reduced the net outflow.

Original languageEnglish
Pages (from-to)1652-1661
Number of pages10
JournalJournal of Biomechanics
Volume48
Issue number9
DOIs
StatePublished - 25 Jun 2015

Funding

FundersFunder number
Israel Science Foundation405109
Tel Aviv University

    Keywords

    • Computational model
    • Impedance pump
    • Thick wall collapsible tubes
    • Tube law
    • Valveless pump

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