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Oxygen‐transfer efficiency of fine‐pore diffused aeration systems: energy intensity as a unifying evaluation parameter

Newbry, Brooks W.

Assessing the clean‐water oxygen‐transfer characteristics of aeration devices is a critical step in the design and operation of aeration systems for activated‐sludge processes. A fundamental model has been developed for assessing the clean‐water oxygen‐transfer characteristics of fine‐bubble (fine‐pore) aeration devices. This model is based on a proposed fundamental parameter, energy intensity (E_I; kW/m³), which is the energy required to deliver air to the aerated volume per unit of aerated volume. The standard oxygen transfer rate (SOTR, g/m³ · s) is shown to be related to E_I through a second‐degree equation: SOTR = −11.5 E_I² + 2.27 E_I (r² = 0.951). The model applies over a wide range of diffuser types, diffuser densities, tank dimensions, and specific air flows. The results suggest that opportunities for increasing oxygen‐transfer efficiencies of fine‐bubble aeration systems remain, particularly by reducing mean bubble sizes and reducing E_I requirements.

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Oxygen‐transfer efficiency of fine‐pore diffused aeration systems: energy intensity as a unifying evaluation parameter

Newbry, Brooks W.

Assessing the clean‐water oxygen‐transfer characteristics of aeration devices is a critical step in the design and operation of aeration systems for activated‐sludge processes. A fundamental model has been developed for assessing the clean‐water oxygen‐transfer characteristics of fine‐bubble (fine‐pore) aeration devices. This model is based on a proposed fundamental parameter, energy intensity (E_I; kW/m³), which is the energy required to deliver air to the aerated volume per unit of aerated volume. The standard oxygen transfer rate (SOTR, g/m³ · s) is shown to be related to E_I through a second‐degree equation: SOTR = −11.5 E_I² + 2.27 E_I (r² = 0.951). The model applies over a wide range of diffuser types, diffuser densities, tank dimensions, and specific air flows. The results suggest that opportunities for increasing oxygen‐transfer efficiencies of fine‐bubble aeration systems remain, particularly by reducing mean bubble sizes and reducing E_I requirements.

Oxygen‐transfer efficiency of fine‐pore diffused aeration systems: energy intensity as a unifying evaluation parameter

Newbry, Brooks W.

Assessing the clean‐water oxygen‐transfer characteristics of aeration devices is a critical step in the design and operation of aeration systems for activated‐sludge processes. A fundamental model has been developed for assessing the clean‐water oxygen‐transfer characteristics of fine‐bubble (fine‐pore) aeration devices. This model is based on a proposed fundamental parameter, energy intensity (E_I; kW/m³), which is the energy required to deliver air to the aerated volume per unit of aerated volume. The standard oxygen transfer rate (SOTR, g/m³ · s) is shown to be related to E_I through a second‐degree equation: SOTR = −11.5 E_I² + 2.27 E_I (r² = 0.951). The model applies over a wide range of diffuser types, diffuser densities, tank dimensions, and specific air flows. The results suggest that opportunities for increasing oxygen‐transfer efficiencies of fine‐bubble aeration systems remain, particularly by reducing mean bubble sizes and reducing E_I requirements.

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Title:

Oxygen‐transfer efficiency of fine‐pore diffused aeration systems: energy intensity as a unifying evaluation parameter

Contributors:

Newbry, Brooks W. (author)

Published in:

Water Environment Research ; 70 ; 323-333

Publication date:

1998-05-01

Size:

11 pages

ISSN:

1554-7531 , 1061-4303

DOI:

https://doi.org/10.2175/106143098X124957

Type of media:

Article (Journal)

Type of material:

Electronic Resource

Language:

English

Keywords:

AERATION , FINE‐PORE DIFFUSERS , AERATOR TESTING , ACTIVATED SLUDGE , ENERGY INTENSITY , OXYGEN TRANSFER

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