Numerical study of interacting vapor bubble trains in microchannel flow boiling finds frequency rises and growth falls with higher vapor-liquid volume ratio, while growth rises with heat flux or lower latent heat, plus upstream vaporization drives downstream expansion and periodic fluctuations in wa
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physics.flu-dyn 2years
2026 2verdicts
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Simulations demonstrate that interactions among multiple vapor bubbles in microchannels lead to smaller leading bubbles due to heat uptake by rear bubbles, modulated by volume ratio, Reynolds number, and wall thickness.
citing papers explorer
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Dynamics of vapor bubble train in flow boiling heat transfer in microchannels
Numerical study of interacting vapor bubble trains in microchannel flow boiling finds frequency rises and growth falls with higher vapor-liquid volume ratio, while growth rises with heat flux or lower latent heat, plus upstream vaporization drives downstream expansion and periodic fluctuations in wa
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Interaction between vapor bubbles during flow boiling heat transfer in microchannels
Simulations demonstrate that interactions among multiple vapor bubbles in microchannels lead to smaller leading bubbles due to heat uptake by rear bubbles, modulated by volume ratio, Reynolds number, and wall thickness.