Mesoscopic Characterization of Bubble Dynamics in Flow Boilling following A Pseudopotential-based Approach

TL;DR

This study demonstrates a mesoscopic pseudopotential-based lattice Boltzmann model effectively simulates bubble dynamics and flow regimes in subcooled flow boiling within narrow channels, capturing key thermohydrodynamic behaviors.

Contribution

It introduces a mesoscopic LB approach that naturally handles phase separation without initial interface assumptions, improving simulation of flow boiling phenomena.

Findings

Successfully reproduces bubble nucleation and flow regimes.

Captures pressure drop and heat transfer characteristics.

Results align with existing literature on flow boiling behavior.

Abstract

Present study explores the capability of the pseudopotential-based thermal lattice Boltzmann (LB) model in emulating the underlying thermohydrodynamics of flow boiling in a narrow fluidic channel. In contrary to the conventional Eulerian-averaging-based approach, it adheres to the mesoscopic Boltzmann statistical averaging, which allows natural phase separation and no need of assuming the initial interface. A narrow fluidic channel, with specified inlet temperature and flow rate, and exit pressure, housing a microheater at the bottom wall is considered as the computational domain of interest. Adopted boundary conditions ensures subcooled flow boiling through the channel, and the present algorithm successfully emulates the corresponding characteristics. The complete dynamics of bubble ebullition at the nucleation site, and subsequent flow regimes are adequately reproduced. Both bubbly and slug flow patterns are illustrated through the temporal evolution of the interface, and associated pressure drop and heat transport characteristics. Dependence of the departure characteristics on the flow rate, wall superheat and surface wettability is found to be consistent with available literature, which substantiates the competence of the present algorithm.