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Main Authors: Kurihara, Chihiro, Kiyama, Akihito, Tagawa, Yoshiyuki
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2403.09929
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author Kurihara, Chihiro
Kiyama, Akihito
Tagawa, Yoshiyuki
author_facet Kurihara, Chihiro
Kiyama, Akihito
Tagawa, Yoshiyuki
contents This study experimentally investigates the pressure fluctuations of liquids in a column under short-time acceleration and demonstrates that the Strouhal number $St$ [$=L/(cΔt)$, where $L$, $c$, and $Δt$ are the liquid column length, speed of sound, and acceleration duration, respectively] provides a measure of the pressure fluctuations both for limiting cases (i.e. $St\ll1$ or $St = \infty$) and for intermediate $St$ values. Incompressible fluid theory and water hammer theory respectively imply that the magnitude of the averaged pressure fluctuation $\overline{P}$ becomes negligible for $St\ll1$ (i.e., in the condition where the duration of acceleration $Δt$ is large enough compared to the acoustic timescale) and tends to $ρcu_0$ (where $u_0$ is the change in the liquid velocity) for $St\geq O(1)$ (i.e., in the condition where $Δt$ is small enough). For intermediate $St$ values, there is no consensus on the value of $\overline{P}$. In our experiments, $L$, $c$, and $Δt$ are varied so that $0.02 \leq St \leq 2.2$. The results suggest that the incompressible fluid theory holds only up to $St\sim0.2$ and that $St$ governs the pressure fluctuations under different experimental conditions for higher $St$ values. The data relating to a hydrogel also tend to collapse to a unified trend. The inception of cavitation in the liquid starts at $St\sim 0.2$ for various $Δt$, indicating that the liquid pressure becomes negative. To understand this mechanism, we employ a one-dimensional wave propagation model with a pressure wavefront of finite thickness that scales with $Δt$. The model provides a reasonable description of the experimental results as a function of $St$. The slight discrepancy between the model and experimental results reveals additional contributing factors such as the container motion and the profile of the pressure wavefront.
format Preprint
id arxiv_https___arxiv_org_abs_2403_09929
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Pressure fluctuations of liquids under short-time acceleration
Kurihara, Chihiro
Kiyama, Akihito
Tagawa, Yoshiyuki
Fluid Dynamics
This study experimentally investigates the pressure fluctuations of liquids in a column under short-time acceleration and demonstrates that the Strouhal number $St$ [$=L/(cΔt)$, where $L$, $c$, and $Δt$ are the liquid column length, speed of sound, and acceleration duration, respectively] provides a measure of the pressure fluctuations both for limiting cases (i.e. $St\ll1$ or $St = \infty$) and for intermediate $St$ values. Incompressible fluid theory and water hammer theory respectively imply that the magnitude of the averaged pressure fluctuation $\overline{P}$ becomes negligible for $St\ll1$ (i.e., in the condition where the duration of acceleration $Δt$ is large enough compared to the acoustic timescale) and tends to $ρcu_0$ (where $u_0$ is the change in the liquid velocity) for $St\geq O(1)$ (i.e., in the condition where $Δt$ is small enough). For intermediate $St$ values, there is no consensus on the value of $\overline{P}$. In our experiments, $L$, $c$, and $Δt$ are varied so that $0.02 \leq St \leq 2.2$. The results suggest that the incompressible fluid theory holds only up to $St\sim0.2$ and that $St$ governs the pressure fluctuations under different experimental conditions for higher $St$ values. The data relating to a hydrogel also tend to collapse to a unified trend. The inception of cavitation in the liquid starts at $St\sim 0.2$ for various $Δt$, indicating that the liquid pressure becomes negative. To understand this mechanism, we employ a one-dimensional wave propagation model with a pressure wavefront of finite thickness that scales with $Δt$. The model provides a reasonable description of the experimental results as a function of $St$. The slight discrepancy between the model and experimental results reveals additional contributing factors such as the container motion and the profile of the pressure wavefront.
title Pressure fluctuations of liquids under short-time acceleration
topic Fluid Dynamics
url https://arxiv.org/abs/2403.09929