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Industrial-Scale Wastewater Nano-Aeration and -Oxygenation and Dissolved Air Flotation: Electric Field Nanobubble and Machine Learning Approaches to Enhanced Nano-Aeration and Flotation

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Publicado en:Environments vol. 12, no. 7 (2025), p. 228-247
Autor principal: English, Niall J
Publicado:
MDPI AG
Materias:
Organic chemicals
Aeration
Wastewater treatment plants
Flotation
Bubbles
Water treatment
Dissolved oxygen
Electric contacts
Reactive oxygen species
Municipal wastewater
Separation techniques
Machine learning
Activated sludge
Electric fields
Dependent variables
Learning algorithms
Efficiency
Batch processing
Biochemical oxygen demand
Batch flotation
Sludge
Gases
Oxygen
Influent water
Particulates
Oxygenation
Process water
E coli
Wastewater treatment
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Resumen:Substantial boosts in the low-energy nano-oxygenation of incoming process water were achieved at a municipal wastewater treatment plant (WWTP) upstream of activated sludge (AS) aeration lanes on a single-pass basis by means of an electric field nanobubble (NB) generation method (with unit residence times of the order of just 10–15 s). Both ambient air and O2 cylinders were used as gas sources. In both cases, it was found that the levels of dissolved oxygen (DO) were maintained far higher for much longer than those of conventionally aerated water in the AS lane—and at DO levels in the optimal operational WWTP oxygenation zone of about 2.5–3.5 mg/L. In the AS lanes themselves, there were also excellent conversions to nitrate from nitrite, owing to reactive oxygen species (ROS) and some improvements in BOD and E. coli profiles. Nanobubble-enhanced Dissolved Air Flotation (DAF) was found to be enhanced at shorter times for batch processes: settlement dynamics were slowed slightly initially upon contact with virgin NBs, although the overall time was not particularly affected, owing to faster settlement once the recruitment of micro-particulates took place around the NBs—actually making density-filtering ultimately more facile. The development of machine learning (ML) models predictive of NB populations was carried out in laboratory work with deionised water, in addition to WWTP influent water for a second class of field-oriented ML models based on a more narrow set of more easily and quickly measured data variables in the field, and correlations were found for a more facile prediction of important parameters, such as the NB generation rate and the particular dependent variable that is required to be correlated with the efficient and effective functioning of the nanobubble generator (NBG) for the task at hand—e.g., boosting dissolved oxygen (DO) or shifting Oxidative Reductive Potential (ORP).
ISSN:2076-3298
DOI:10.3390/environments12070228
Fuente:Publicly Available Content Database