Evaluation of activated sludge properties’ changes in industrial-wastewater pre-treatment: role of residual aluminum hydrolyzed species with different polymerization degree

doi:10.1007/s11783-023-1675-3

Front. Environ. Sci. Eng.

2023, Vol. 17

Issue (6) : 75 https://doi.org/10.1007/s11783-023-1675-3

RESEARCH ARTICLE

Evaluation of activated sludge properties’ changes in industrial-wastewater pre-treatment: role of residual aluminum hydrolyzed species with different polymerization degree

Ziqi Zhao¹, Meng Li¹, Wansong Huang², Nuowei Guo³, Qian Zhang^1,⁴(

)

¹. School of Civil Engineering and Architecture, Wuhan University of Technology, Wuhan 430070, China
². Hubei Jianke International Construction Ltd. Co, Wuhan 430070, China
³. Wuhan Hanyang Municipal Construction Group Co. Ltd., Wuhan 430000, China
⁴. Shenzhen Research Institute of Wuhan University of Technology, Shenzhen 518000, China

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Abstract

● Medium poly Al salts dominated the PAC residual salts with a rational dosage.

● Settlement flocculation effect under medium poly Al salts showed a better trend.

● Complex of medium poly Al salts and enzymes promoted cell activity.

● Medium poly Al salts were beneficial to the effluent indexes.

With the widespread introduction of pre-coagulation prior to the biological unit in various industrial wastewater treatments, it is noteworthy that long-term accumulation of residual coagulants has certains effect on both micro and macro characteristics of activated sludge (AS). In this study, the morphology distributions of residual aluminum salts (RAS) and their effects on the removal efficiency of AS were investigated under different PAC concentrations. The results showed that the dominance of medium polymeric RAS, formed under an appropriate PAC dose of 20 mg/L enhanced the hydrophobicity, flocculation, and sedimentation performances of AS, as well as the enzymatic activity in cells in the sludge system, improving the main pollutants removal efficiency of the treatment system. Comparatively the species composition with monomer and dimer / high polymer RAS as the overwhelming parts under an over-dosed PAC concentration of 55 mg/L resulted in excessive secretion of EPS with loose flocs structure and conspicuous inhibition of cellular activity, leading to the deterioration of physico-chemical and biological properties of AS. Based on these findings, this study can shed light on the role of the RAS hydrolyzed species distributions, closely relevant to Al dosage, in affecting the comprehensive properties of AS and provide a theoretical reference for coagulants dosage precise control in the pretreatment of industrial wastewater.

Keywords Coagulation/flocculation Hydroxyl-aluminum Hydrolysis reaction Reactor performance Activated sludge property Surface properties

Corresponding Author(s): Qian Zhang

Issue Date: 03 January 2023

Cite this article:

Ziqi Zhao,Meng Li,Wansong Huang, et al. Evaluation of activated sludge properties’ changes in industrial-wastewater pre-treatment: role of residual aluminum hydrolyzed species with different polymerization degree[J]. Front. Environ. Sci. Eng., 2023, 17(6): 75.

URL:

https://academic.hep.com.cn/fese/EN/10.1007/s11783-023-1675-3
https://academic.hep.com.cn/fese/EN/Y2023/V17/I6/75

Fig.1 (a) The effluent concentration of COD and total phosphorus under different PAC dosages; (b) The distribution of aluminum in the three solutions.

Fig.2 Changes during the reaction operation (a) COD; (b) NH₄⁺-N; (c) NO₃^–-N, NO₂^–-N; (d) TN.

Fig.3 SEM morphology of sludge (2000 times) and EDS of sludge under different aluminum salt concentrations (a) R1-85 d; (b) R2-85 d; (c) R3-85 d; (d) R3-120 d.

Fig.4 Changes in sludge EPS, (a)–(c): R1–R3.

Tab.1 Protein secondary structure curve fitting table

Fig.5 Changes in surface charge of sludge (a) relative hydrophobicity of sludge (b); flocculation (c); and sedimentation (d); of each reactor.

Fig.6 (a) Changes in the electrolyte exudation rate of microbial cell membranes; (b) sludge respiration rate; (c) sludge dehydrogenase.

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