Reshaping the activated sludge process: has the time come or passed?

Orhon, Derin; Sözen, Seval

doi:10.1002/jctb.6290

Cited by 13 publications

(8 citation statements)

References 71 publications

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“…In fact, initial studies with MBR systems operated at a sludge age range of 0.5–5.0 days reported stable system operation all while securing high COD removals, and obviously, with no particulate matter in the effluent 50,51 . A recent review on the performance of super‐fast MBRs (θ X lower than 2.0 days) designed for organic carbon removal and conducted with different substrates provided reliable experimental results that ‘… high sludge age values merely represent a design luxury for the MBR systems since complete removal of soluble biodegradable substrate could be achieved at θ X < 2.0 days .’ 52 . A new study proposed a novel model, MASM, for the membrane activated sludge process, which disclosed a significant but so far overlooked system attribute of much lower effluent COD levels; this was experimentally justified by means of entrapment and recycling of larger size particles compared to the effective filtration size of the membrane module 53 …”

Section: Discussionmentioning

confidence: 99%

Anatomy of super‐fast activated sludge process with gravity settling for biodegradation and energy recovery potential ‐ a review

Orhon

Sözen

Çokgör

et al. 2022

J of Chemical Tech & Biotech

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This study reviewed the conceptual basis and the application of extremely high rate activated sludge configurations with gravity settling. It evaluated the modified aeration process, as the historical pioneering development, and the A process (adsorption), which was inspired by the traditional AB process (adsorption/biological oxidation) promulgated in the seventies. For this purpose, a modelling framework was established to simulate the expected performance and the energy recovery potential of these processes using the currently applicable data base. The model evaluation was also extended to cover the Yenikapı plant in Istanbul as a current case study. The modelling results were discussed in view of the handicaps of gravity settling and the merit of high‐rate membrane bioreactors where gravity settling would be replaced by membrane filtration. © 2021 Society of Chemical Industry (SCI).

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Section: Discussionmentioning

confidence: 99%

Anatomy of super‐fast activated sludge process with gravity settling for biodegradation and energy recovery potential ‐ a review

Orhon

Sözen

Çokgör

et al. 2022

J of Chemical Tech & Biotech

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“…Later, relevant microbial mechanisms of super‐fast MAS systems for organic carbon removal could be assessed by means of model analysis for domestic sewage and selected industrial wastewaters 48,49 . A review, after evaluating all existing information, argued that in the near future, the activated sludge process will be reshaped and ‘the novel AS configuration shall not include gravity settling and it will be operated at extremely low θ X levels of <2.0 d’ 50 …”

Section: Evaluation and Discussionmentioning

confidence: 99%

“…48,49 A review, after evaluating all existing information, argued that in the near future, the activated sludge process will be reshaped and 'the novel AS configuration shall not include gravity settling and it will be operated at extremely low ⊔ X levels of <2.0 d'. 50 The evaluation focused on the energy conservation aspect mainly because it constituted the rate-limiting step of the energy recovery mechanism. The paper under discussion adopted a biochemical technologyanaerobic digestion of conserved sludge for biogas generation.…”

Section: Effective Energy Conservationmentioning

confidence: 99%

Efficient energy recovery from wastewater with high rate activated sludge process: oversights and misguidances

Orhon

Çokgör

Sözen

2022

J of Chemical Tech & Biotech

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Background The major aim of the study was to define a scientific framework to evaluate energy recovery from domestic wastewater, based on model assessment of process stoichiometry and kinetics using relevant experimental data. The evaluation was tailored to reveal and explain all the oversights and misconceptions on the subject. A new approach was adopted to focus specifically on a paper by Liang et al. (2022) to better visualize and indicate scientific ways to remedy the key misguidances. The alternative appraisal utilized the latest available support in terms of the database for chemical oxygen demand (COD) fractionation and process kinetics. Results The evaluation first demonstrated the inherent deficiencies of high rate activated sludge (HRAS) configurations such as the sequencing batch reactor and contact stabilization; then, it presented a new way to define excess sludge components in terms of fractions of the influent COD, indicating the major handicap for energy recovery and biomass loss in the effluent due to gravity settling. Effective energy conservation was computed to remain between 17% and 37% when the sludge age was reduced from 2.0 d down to 0.5 d. Conclusions The study offered conclusive proof that the contact stabilization process with gravity settling was, in fact, inherently unsuitable for energy conservation. Instead, the emerging scientific approach proposed a single‐volume HRAS system with membrane filtration replacing gravity settling. An equally valid suggestion was to replace anaerobic technology for energy recovery with thermochemical technologies, such as high‐rate pyrolysis, with a much higher energy recovery potential. © 2022 Society of Chemical Industry (SCI).

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“…Membrane filtration of biomass should be recognized as a cutting-edge landmark that would perhaps reshape the future of the activated sludge process. It took over the function of gravity settling, which accompanied the process since its discovery [1]. Gravity settling has always been the weak spot in the process, mainly because it could not cope with excessive biomass escape under conditions of filamentous bulking; it imposed limitations restricting biomass concentration in the reactor; and most importantly, it distorted system design, as the main concern had to be sustaining good settling conditions for biomass based on empirical experience, often leading to higher footprints [2].…”

Section: Introductionmentioning

confidence: 99%

Appraisal of Super-Fast Membrane Bioreactors by MASM—A New Activated Sludge Model for Membrane Filtration

Orhon¹,

Yücel

İnsel

et al. 2021

Water

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The structure of existing activated models is inherently deficient in reflecting the major role of the membrane filtration. The study developed a novel model, MASM, for the membrane activated process. The effective filtration size imposed by the membrane module, entrapping larger particles, was adopted as the basis of the proposed model. The model defines a modified form of COD fractionation that accounts for the captured COD fractions as additional model components and utilizes related mass-balance relationships. It was implemented to test the fate of soluble hydrolyzable COD and the system performance of super-fast membrane activated sludge based on real data for the characterization and process kinetics of domestic sewage and denim processing effluents. Model evaluation was carried out for parallel systems with gravity settling and membrane filtration operated at a sludge age range of 0.5–2.0 d. Results reflected significantly better performance by the super-fast membrane activated sludge system for both wastewaters, underlining that it was crucially important to account for the captured COD fractions to provide an accurate evaluation of system behavior and effluent quality. This should also be identified as the major shortcoming of the ASM models for evaluating and predicting the system performance of activated sludge configurations with membrane separation.

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Reshaping the activated sludge process: has the time come or passed?

Cited by 13 publications

References 71 publications

Anatomy of super‐fast activated sludge process with gravity settling for biodegradation and energy recovery potential ‐ a review

Anatomy of super‐fast activated sludge process with gravity settling for biodegradation and energy recovery potential ‐ a review

Efficient energy recovery from wastewater with high rate activated sludge process: oversights and misguidances

Appraisal of Super-Fast Membrane Bioreactors by MASM—A New Activated Sludge Model for Membrane Filtration

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