Modelling cavitation erosion using fluid–material interaction simulations

Chahine, Georges L.; Hsiao, Chao-Tsung

doi:10.1098/rsfs.2015.0016

Cited by 73 publications

(51 citation statements)

References 61 publications

(71 reference statements)

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“…and 3920 respectively. The first observed pressure peak is due to liquid jet impact and second peak due to the collapse of the bubble ring or torus, similar to the observations made in Chahine et al [7]. The corresponding pressure and density contours for the observed pressure peaks are shown next in figure 4 and figure 5.…”

Section: Resultssupporting

confidence: 84%

Numerical Investigation of the Dynamics of Pressure Loading on a Solid Boundary from a Collapsing Cavitation Bubble

2018

Proceedings of the 10th International Symposium on Cavitation (CAV2018)

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The motivation behind this research lies in understanding the physical mechanism of cavitation erosion in compressible liquid flows, with applications in the field of aerospace, hydrodynamics, diesel injectors etc. As a consequence of collapsing vapor cavities in cavitating flow near solid boundaries, high pressure impact loads are generated. These pressure loads are believed to be responsible for the erosive damages on solid surface observed in most applications. For our investigation, the initial geometry is a single vapor bubble near a solid boundary collapsing due to the pressure difference between the bubble and surrounding liquid. The numerical approach employs a simplified homogenous mixture or 'single fluid' model with barotropic assumption in a fully compressible finite-volume fluid solver. The numerical method is validated against the well-known Rayleigh collapse of a pure 3D vapour bubble. It is then used for the simulation of a 2D vapour bubble collapsing in the proximity of a solid boundary placed at a specified distance from the centre of the bubble. The pressure loads are computed from the evolving dynamics of collapsing bubble near a solid boundary which can be used to determine the resulting surface deformation. The developed compressible cavitation solver in the CFD code 2 can efficiently model small and large scale cavitating structures in a fully resolved three dimensional flow.

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Section: Resultssupporting

confidence: 84%

Numerical Investigation of the Dynamics of Pressure Loading on a Solid Boundary from a Collapsing Cavitation Bubble

2018

Proceedings of the 10th International Symposium on Cavitation (CAV2018)

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“…At P 01 , this maximum was due to constructive interference of pressure waves converging toward the axis from the toroidal collapse of the bubble ring, as previously described. 36 The maximum pressure spikes had durations $1 ns and quickly decayed off-axis. Longer ($30 ns) pulses covered larger areas and, regardless of the amount of gas in the bubble, had substantial pressure amplitudes [ Fig.…”

Section: Discussionmentioning

confidence: 99%

“…Second, the stone was modeled as a rigid surface, whereas the finite acoustic impedance and elasticity of urinary stones have been shown to affect the predicted pressure amplitudes. 24,[33][34][35][36] Third, the pressure during focusing events becomes nearly singular and, to remain finite, depends on actual dissipative mechanisms. The influence of viscosity on pressure generated by the collapsing bubbles was not investigated in this report.…”

Section: Discussionmentioning

confidence: 99%

High-speed video microscopy and numerical modeling of bubble dynamics near a surface of urinary stone

Pishchalnikov¹,

Behnke-Parks²,

Schmidmayer

et al. 2019

The Journal of the Acoustical Society of America

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Ultra-high-speed video microscopy and numerical modeling were used to assess the dynamics of microbubbles at the surface of urinary stones. Lipid-shell microbubbles designed to accumulate on stone surfaces were driven by bursts of ultrasound in the sub-MHz range with pressure amplitudes on the order of 1 MPa. Microbubbles were observed to undergo repeated cycles of expansion and violent collapse. At maximum expansion, the microbubbles' cross-section resembled an ellipse truncated by the stone. Approximating the bubble shape as an oblate spheroid, this study modeled the collapse by solving the multicomponent Euler equations with a two-dimensional-axisymmetric code with adaptive mesh refinement for fine resolution of the gas-liquid interface. Modeled bubble collapse and high-speed video microscopy showed a distinctive circumferential pinching during the collapse. In the numerical model, this pinching was associated with bidirectional microjetting normal to the rigid surface and toroidal collapse of the bubble. Modeled pressure spikes had amplitudes two-to-three orders of magnitude greater than that of the driving wave. Micro-computed tomography was used to study surface erosion and formation of microcracks from the action of microbubbles. This study suggests that engineered microbubbles enable stone-treatment modalities with driving pressures significantly lower than those required without the microbubbles.

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“…The weakly compressible potential flow is modelled here using a recently developed implementation of the boundary integral method (BIM) for a bubble in a compressible liquid (Wang & Blake 2010, Wang 2013, 2014. By the way, nonspherical bubble dynamics in a compressible liquid have been simulated using domain approaches coupled with various interface-capturing schemes (Johnsen & Colonius 2006, Turangan et al 2008, Terashima et al 2009, Fuster et al 2011, Hiao et al 2014, Chahine et al 2015, 2016.…”

Section: Introductionmentioning

confidence: 99%

Local energy of a bubble system and its loss due to acoustic radiation

Wang

2016

J. Fluid Mech.

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Energy concentration and loss due to a violent collapsing bubble are essential phenomena to many applications such as cavitation erosion, biomedical ultrasonics, sonochemistry, cavitation cleaning and underwater explosions. It has been generally known that the energy of a bubble system is radiated away as an acoustic wave and dissipated by viscosity. However, there is no study in the scientific literature on the time history of the energy of a bubble system in a compressible flow. Here we have introduced the local energy of a non-spherical bubble system, consisting of the energy of the interior gas, the interface and the exterior liquid in the inner asymptotic region. The local energy determines the local bubble and flow dynamics, including the concentration of energy, stress and momentum. We obtain a simple formula for the radiated energy associated with acoustic radiation in terms of the bubble volume history. We perform calculations of the energy history for a transient bubble in a compressible liquid in an infinite domain, subject to buoyancy and near a rigid boundary, respectively. Our calculations show that the local energy of a transient bubble follows a step function in time, being nearly conserved for most of each cycle of oscillation but decreasing rapidly and significantly at bubble inception and at the end of collapse, due to the emission of steep pressure waves or shock waves. The loss of the local energy of the bubble system due to the emission of steep pressure waves and the associated damping of the bubble oscillation are diminished by buoyancy effects and decrease with the buoyancy parameter. Similarly, the loss of the local energy of a bubble system is diminished by the presence of a rigid boundary and decreases with the proximity of the bubble to the boundary. We also analyse the energy concentration of single bubble sonoluminescence in a standing acoustic wave.

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Modelling cavitation erosion using fluid–material interaction simulations

Cited by 73 publications

References 61 publications

Numerical Investigation of the Dynamics of Pressure Loading on a Solid Boundary from a Collapsing Cavitation Bubble

Numerical Investigation of the Dynamics of Pressure Loading on a Solid Boundary from a Collapsing Cavitation Bubble

High-speed video microscopy and numerical modeling of bubble dynamics near a surface of urinary stone

Local energy of a bubble system and its loss due to acoustic radiation

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