Biofilm detachment mechanisms in a liquid‐fluidized bed

Abstract

Bed fluidization offers the possibility of gaining the advantages of fixed-film biological processes without the disadvantage of pore clogging. However, the biofilm detachment rate, due to hydrodynamics and particle-to-particle attrition, is very poorly understood for fluidized-bed biofilm processes. In this work, a two-phase fluidized-bed biofilm was operated under a constant surface loading (0.09 mg total organic carbon/cm² day) and with a range of bed height (H), fluid velocities (U), and support-particle concentrations (C_p). Direct measurements were made for the specific biofilm loss rate coefficient (b_s)and the total biofilm accumulation (X_fL_f). A hydrodynamic model allowed independent determination of the biofilm density (X_f), biofilm thickness (L_f), liquid shear stress (τ), and Reynolds number (Re). Multiple regression analysis of the results showed that increased particle-to-particle attrition, proportional to C_p and increased turbulence, described by Re, caused the biofilms to be denser and thinner. The specific detachment rate coefficient (b_s) increased as C_p and Re increased. Almost all of the 6, values were larger than predicted by a previous model derived for smooth biofilms on a nonfluidized surface. Therefore, the turbulence and attrition of bed fluidization appear to be dominant detachment mechanisms.