Gas bubble dynamics in airlift photo-bioreactors for microalgae cultivation by level set methods

• Published in: Fuel (Guildford) Vol. 292; p. 120402
• Main Authors: Neviani, Matteo, Bagnerini, Patrizia, Paladino, Ombretta
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier Ltd 15.05.2021; Elsevier BV
• Subjects: Aerodynamics; Airlift; Algae; Aquatic microorganisms; Biofuels; Bioreactors; Biorefineries; Bubble dynamics; Bubbles; Carbon dioxide; CO2 capture; Coalescence; Coalescing; Computational fluid dynamics; Computer applications; Cultivation; Experimental data; Fluid dynamics; Fluid flow; Hydrodynamics; Interfaces; Level set method; Mathematical models; Microalgae; Multiphase flow; Reynolds number; Spherical caps; Biorefineries; Bubble dynamics; Microalgae; CO2 capture; Level set method; Airlift
• ISSN: 0016-2361; 1873-7153
• DOI: 10.1016/j.fuel.2021.120402

[Display omitted] •Airlift photo-bioreactor for CO2 capture and biodiesel production by microalgae.•Use of level set method to dynamically track bubble interfaces.•Resolution of 2D incompressible Navier-Stokes equations to compute the velocity field.•Simulation of bubble trajectories and their shapes into the riser. Coupled level set and CFD (computational fluid dynamics) methods are adopted in this work to track the moving gas–liquid interfaces in the riser of an external loop airlift photobioreactor (ALR) in which microalgae are used to produce biofuels and capture CO2 from flue-gas. Modeling the behavior of gas bubbles is a crucial aspect for the fine-tuning of the operation of the reactor when inserted into a closed-loop biorefinery at the pilot-scale. The experimental data used for simulation were completely acquired or calculated from hydrodynamic experimental campaigns carried out on the ALRs. The rise, coalescence, and shape dynamics of the bubbles of the flue-gas are simulated in a rectangular domain representing the vertical section of the ALR riser. Different correction approaches, such as the conservative level set method (CLSM), are proposed to face the volume loss characteristic of LSM. Computational results evidenced strong agreement with the experimental data (bubble shapes and trajectories). The physically-based CLSM model was then effectively used for the fine-tuning of the multiphase flow regime inside the ALRs, suggesting operating conditions for the outdoor cultivation with Reynolds number = 10000 – 11000, Sherwood number between 1400 and 1800, and spherical-caps bubbles in the upper half of the riser, mildly churning the microalgae while avoiding damages to their cells.