A numerical study on temperature destratification induced by bubble plumes in idealized reservoirs

TL;DR

This study develops and validates a comprehensive 3D numerical model to analyze how bubble plumes induce temperature destratification in reservoirs, providing insights into optimal aeration strategies for water quality improvement.

Contribution

The paper introduces a validated three-dimensional numerical model that captures the physical processes of bubble-induced destratification, including effects of turbulence, temperature, and gas concentration.

Findings

Validated the numerical model against experimental data.

Identified optimal aeration rates for effective destratification.

Analyzed the impact of aeration location and bubble plume dynamics.

Abstract

An in-house numerical model has been developed to study the temperature destratification induced by bubble plumes in reservoirs. The mean flow of the mixed fluid phase is solved using the Reynolds-Averaged Navier-Stokes Equations, while the bubble phase is calculated by employing the advection-diffusion equation of air concentration. The change of water temperature is tracked by solving the energy equation. The two-equation turbulence model, considering the effect of bubble buoyancy and the change of temperature, is adopted to model the turbulent dissipation in two-phase fluid. To validate the accuracy of the numerical model, the numerical results are compared with available experimental data. In addition, the destratification of temperature-layered water in a tank by bubble plumes is simulated by the numerical model, which is also validated by experimental data and the numerical results of another model. This three-dimensional model can reflect various physical quantities in the entire computed filed, such as thermal structure, gas concentration distribution, velocity distribution and turbulence intensity. Furthermore, by utilizing the validated model, a series of factors on reservoir destratification, including the aeration rate and the aeration location are analyzed and discussed in this study. A non-dimensional number Nt is introduced to determine the optimal aeration rate of the fasted destratification. The extent to which bubble plumes can affect the destratification is also simulated and discussed. Meanwhile, the mechanism of destratification in a large water area is described in detail. Suggestions on how to apply bubble plumes to improve the water quality of a reservoir are given.