Sewer sediment adhesion reduction and hydraulic floating promotion by alkaline treatment

Deposition of sediment in sewers decreased flow capacity, with harmful gases and pipe erosion. Sediment floating and removal remained challenges due to its gelatinous structure, which induced strong erosion resistance. This study pro-posed an innovative alkaline treatment for destructuring gelatinous organic matters and improving hydraulic flushing capacity of sediments. At the optimal pH 11.0 condition, the gelatinous extracellular polymeric substance (EPS) and mi-crobial cells were disrupted, with numerous outward migration and solubilization of proteins, polysaccharides and humus. The aromatic protein solubilization (tryptophan-like and tyrosine-like proteins) and humic acid-like substance deconstruction were the major driving factors for sediment cohesion reduction, which disintegrated the bio-aggregation and increased the surface electronegativity. Meanwhile, the variations of functional groups (C=C, C=O, COO-, C\\N, N\\H, C-O-C, C-OH, O\\H) also contributed to the interaction breakage and glutinous structure disruption of sediment particles. It was found that the rising pH conditions reduced sediment adhesion and promoted particle floating. Solubi-lizations of total suspended solids and volatile suspended solids were increased by 12.8 and 9.4 times, respectively, while the sediment adhesion was reduced by 3.8 fold. The alkaline treatment greatly improved sediment erosion and flushing capacities under shear stress of gravity sewage flow. Such sustainable strategy only cost 36.4 CNY per sewer meter length, which was 29.5-55.0 % of the high-pressure water jet flushing and perforated tube flushing approaches.

Automated summary

This study proposed an innovative alkaline treatment to destruct the gelatinous organic matters and improve the hydraulic flushing capacity of sediments. Under optimal pH 11.0 condition, the gelatinous extracellular polymeric substance (EPS) and microbial cells were disrupted, leading to the solubilization of proteins, polysaccharides, and humus. The alkaline treatment reduced sediment adhesion and promoted particle floating, greatly improving sediment erosion and flushing capacities.