A Critical Review of the Factors Affecting Modeling Oxygen Transfer by Fine‐Pore Diffusers in Activated Sludge

Baquero-Rodríguez, Gustavo Andrés; Lara-Borrero, Jaime Andrés; Nolasco, Daniel; Rosso, Diego

doi:10.2175/106143017x15131012152988

Cited by 50 publications

(19 citation statements)

References 55 publications

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“…However, to keep the carriers suspended, the IFAS process requires stronger turbulence [6], which leads to the IFAS process requiring much more aeration than the CAS process; therefore, the IFAS process has the disadvantage of poor aeration energy efficiency [7]. The energy required for the electromechanical equipment used in aeration represents 50-80% of the total energy costs of WWTPs [8]. Therefore, improving the oxygen transfer efficiency (αOTE) of the aeration system can produce significant economic effects for the IFAS process.…”

Section: Introductionmentioning

confidence: 99%

“…Many factors affect the OTE of aeration systems, such as the airflow rate [9,10], diffuser density [11,12], contaminant concentration [13][14][15], and sludge characteristics [16,17]. However, the influence of these factors is not the same [8]. The aeration type and carrier filling ratio (CFR) are two significant impact factors among these factors due to the existence of carriers [18].…”

Section: Introductionmentioning

confidence: 99%

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The Changing and Distribution Laws of Oxygen Transfer Efficiency in the Full-Scale IFAS Process

Liu

Huang³

et al. 2021

Water

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The integrated fixed-film activated sludge (IFAS) process has been widely used in the upgrading of wastewater treatment plants (WWTPs). The oxygen transfer efficiency (αOTE) is of great significance to the design and operation of the IFAS process. The carrier filling ratio (CFR) and aeration type are two critical factors affecting αOTE and standard oxygen transfer efficiency (αSOTE). However, the distribution and changing laws of αOTE and αSOTE in the full-scale IFAS process areunclear. To optimize the operation of a WWTP and to improve the αOTE of the aeration systems, several off-gas tests were conducted under different aeration types and different CFRs. The results show that for the aerobic tank investigated (the ratio of length and width was 8:1), the αOTE and the αSOTE of the middle of the aeration systems were higher than those of the other two sides. However, the reason for the low αOTE at the beginning and the end of the tank may be different. Coarse-bubble aeration systems had a lower αOTE and almost the same oxygenation capacity (αSOTE) as the fine-bubble aeration systems under constant CFR (43%). The average αSOTE (18.7–28.9%) of the hybrid aeration systems increased with increasing CFR (7.7–57.7%), and different locations exhibited different degrees of change. The results reveal the distribution and changing law of the αOTE of aeration systems in the IFAS process, and attention should be paid to the improvement of the OTE of the plug-flow IFAS process.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Changing and Distribution Laws of Oxygen Transfer Efficiency in the Full-Scale IFAS Process

Liu

Huang³

et al. 2021

Water

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“…In the past, simple calculation of overall mass transfer effect was used to evaluate the performance of aeration system. Kim & Ra (2005), Anjali & Rubina (2015) and Sun et al (2016) calculated the total volumetric oxygen transfer coefficient (K L a) of fine bubble diffused aeration systems in different aeration tanks, Capela (1999), Gillot et al (2000) and Andrés et al (2018) study the specific standard oxygen transfer efficiency (SSOTE) of fine-pore diffusers in activated sludge reactors, and Capela et al (2001) and Gillot et al (2005) defined a transfer number N T of fine bubble diffused aeration systems. Although these methods are more direct and simple for evaluating the performance of fine bubble diffused aeration systems, they tend to focus on overall efficiency of oxygen mass transfer and fail to take account of distribution uniformity of dissolved oxygen(DO) concentration in aeration tanks (Kim & Ra 2005;Pittoors et al 2014;Anjali & Rubina 2015;Sun et al 2016).…”

Section: Introductionmentioning

confidence: 99%

“…Although these methods are more direct and simple for evaluating the performance of fine bubble diffused aeration systems, they tend to focus on overall efficiency of oxygen mass transfer and fail to take account of distribution uniformity of dissolved oxygen(DO) concentration in aeration tanks (Kim & Ra 2005;Pittoors et al 2014;Anjali & Rubina 2015;Sun et al 2016). The nonuniform distribution of DO concentration in aeration tanks often lead to the inconsistency of the biological treatment status of sewage in the different position of cylindrical aeration tanks and then affect the biological treatment efficiency of them (Temmerman et al 2015;Wang & Zhang 2017;Andrés et al 2018). Therefore it is necessary to study a new means for performance evaluation of fine bubble diffused aeration systems, which takes both overall efficiency of oxygen mass transfer and distribution uniformity of DO concentration in cylindrical aeration tanks into consideration.…”

Section: Introductionmentioning

confidence: 99%

Evaluating the performance of fine bubble diffused aeration systems in cylindrical aeration tanks by fuzzy c-means algorithm

Zeng

2021

Water Science and Technology

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In order to make a comprehensive evaluation of the performance of fine bubble diffused aeration systems in cylindrical aeration tanks, the following parameters are considered: distribution of DO concentration in the horizontal direction of the different water depth of an aeration tank, distribution of DO concentration in the vertical direction of the aeration tank, distribution of DO concentration in all the points of the aeration tank and ratio of total mass increment of DO in the aeration tank to total mass of oxygen in aeration air. The aeration characteristic criterion (ACC) is proposed to synthesize these parameters, and weighted sums of the similarity degrees derived from the extensions of fuzzy c-means (FCM) are used to construct ACC. The results show that compared with total volumetric oxygen transfer coefficient () and specific standard oxygen transfer efficiency (), ACC is demonstrated to be more remarkable and sensitive for the performance evaluation of the fine bubble diffused aeration systems equipped with fine-pore aeration tubes. Moreover the performance of aeration systems equipped with different layouts of fine-pore aeration tubes is comparatively studied, and their performance from good to bad is ring-type diffuser > square-type diffuser > parallel-lines-type diffuser >cross-type diffuser.

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“…Biological processes are the core components in wastewater treatment plants (WWTPs). Supplying air to biomass requires the highest energy use 1 , accounting for more than 50% of the net power demand 2 , which represents a significant fraction of total operating costs, ranging from 50% to 80% 3,4 . Since fine-pore diffusers have better performance in terms of specific energy consumption than coarse bubble diffusers 5 , they are extensively used for supplying oxygen to biomass in municipal WWTPs.…”

mentioning

confidence: 99%

Impact of scaling on aeration performance of fine-pore membrane diffusers based on a pilot-scale study

Wang

Liu

et al. 2020

Sci Rep

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Aeration systems consume a large amount of energy in wastewater treatment plants. Fine-pore membrane diffusers are most commonly used in aeration systems. Scaling and fouling on these membrane diffusers will lead to decreased performance in aeration and increase energy consumption. This pilot-scale study focused on the scaling of the three kinds of fine-pore membrane diffusers under different influent hardness conditions. The results showed that the diffusers were mainly polluted by calcium carbonate scaling. Scaling occurred on the outer surface, orifices and inner surface of the membranes. The dynamic wet pressure (DWP) of ethylene-propylenediene monomer (EPDM), silicone and polyurethane (PU) membrane diffusers increased by 126%, 34% and 304%, respectively, within 50 days when the hardness was 400 mg/L (as CaCO 3). However, the increase ratio became obviously slow during the subsequent 60-day operation, indicating a scaling rule of membrane diffusers. Considering that the standard aeration efficiency (SAE) acted as a comprehensive index for judging the aeration performance, the silicone diffuser had better performance than the other two diffusers when severe scaling occurred. This research also provides basic support for the design of membrane diffusers to improve their anti-scaling performance.

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A Critical Review of the Factors Affecting Modeling Oxygen Transfer by Fine‐Pore Diffusers in Activated Sludge

Cited by 50 publications

References 55 publications

The Changing and Distribution Laws of Oxygen Transfer Efficiency in the Full-Scale IFAS Process

The Changing and Distribution Laws of Oxygen Transfer Efficiency in the Full-Scale IFAS Process

Evaluating the performance of fine bubble diffused aeration systems in cylindrical aeration tanks by fuzzy c-means algorithm

Impact of scaling on aeration performance of fine-pore membrane diffusers based on a pilot-scale study

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