Full-scale in-line hydrolysis and simulation for potential energy and resource savings in activated sludge – a case study

Tobias Hey; Karin Jönsson; Jes la Cour Jansen

doi:10.1080/09593330.2011.650217

Full-scale in-line hydrolysis and simulation for potential energy and resource savings in activated sludge – a case study

Tobias Hey, Karin Jönsson, Jes la Cour Jansen

Division of Chemical Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

The potential effects of altering primary settlers during biological in-line hydrolysis and converting a nitrifying activated sludge process into a partial pre-denitrification process for the purpose of resource conservation were evaluated. A full-scale primary sludge hydrolysis experiment was performed at a wastewater treatment plant and implemented in a dynamic modelling tool based on ASM2d. The full-scale hydrolysis experiment achieved a volatile fatty acid (VFA) production of 43 g CODHAc·m−3 with no release of ammonium. Additional nitrogen removal of 44 t N·a−1 was simulated, and the produced hydrolysate was able to replace 50% of the annual ethanol usage. Furthermore, 196 MWh of electricity per annum could be saved through the reduction of ethanol production and the optimization of the operation strategy of the activated sludge tank by operating a different number of anoxic zones.

Original language	English
Pages (from-to)	1819-1825
Journal	Environmental Technology
Volume	33
Issue number	15
DOIs	https://doi.org/10.1080/09593330.2011.650217
Publication status	Published - 2012

Subject classification (UKÄ)

Chemical Engineering

Free keywords

ASM2d
energy savings
full scale
hydrolysis
internal carbon source

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10.1080/09593330.2011.650217

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title = "Full-scale in-line hydrolysis and simulation for potential energy and resource savings in activated sludge – a case study",

abstract = "The potential effects of altering primary settlers during biological in-line hydrolysis and converting a nitrifying activated sludge process into a partial pre-denitrification process for the purpose of resource conservation were evaluated. A full-scale primary sludge hydrolysis experiment was performed at a wastewater treatment plant and implemented in a dynamic modelling tool based on ASM2d. The full-scale hydrolysis experiment achieved a volatile fatty acid (VFA) production of 43 g CODHAc·m−3 with no release of ammonium. Additional nitrogen removal of 44 t N·a−1 was simulated, and the produced hydrolysate was able to replace 50% of the annual ethanol usage. Furthermore, 196 MWh of electricity per annum could be saved through the reduction of ethanol production and the optimization of the operation strategy of the activated sludge tank by operating a different number of anoxic zones.",

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author = "Tobias Hey and Karin J{\"o}nsson and {la Cour Jansen}, Jes",

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doi = "10.1080/09593330.2011.650217",

language = "English",

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journal = "Environmental Technology",

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TY - JOUR

T1 - Full-scale in-line hydrolysis and simulation for potential energy and resource savings in activated sludge – a case study

AU - Hey, Tobias

AU - Jönsson, Karin

AU - la Cour Jansen, Jes

PY - 2012

Y1 - 2012

N2 - The potential effects of altering primary settlers during biological in-line hydrolysis and converting a nitrifying activated sludge process into a partial pre-denitrification process for the purpose of resource conservation were evaluated. A full-scale primary sludge hydrolysis experiment was performed at a wastewater treatment plant and implemented in a dynamic modelling tool based on ASM2d. The full-scale hydrolysis experiment achieved a volatile fatty acid (VFA) production of 43 g CODHAc·m−3 with no release of ammonium. Additional nitrogen removal of 44 t N·a−1 was simulated, and the produced hydrolysate was able to replace 50% of the annual ethanol usage. Furthermore, 196 MWh of electricity per annum could be saved through the reduction of ethanol production and the optimization of the operation strategy of the activated sludge tank by operating a different number of anoxic zones.

AB - The potential effects of altering primary settlers during biological in-line hydrolysis and converting a nitrifying activated sludge process into a partial pre-denitrification process for the purpose of resource conservation were evaluated. A full-scale primary sludge hydrolysis experiment was performed at a wastewater treatment plant and implemented in a dynamic modelling tool based on ASM2d. The full-scale hydrolysis experiment achieved a volatile fatty acid (VFA) production of 43 g CODHAc·m−3 with no release of ammonium. Additional nitrogen removal of 44 t N·a−1 was simulated, and the produced hydrolysate was able to replace 50% of the annual ethanol usage. Furthermore, 196 MWh of electricity per annum could be saved through the reduction of ethanol production and the optimization of the operation strategy of the activated sludge tank by operating a different number of anoxic zones.

KW - ASM2d

KW - energy savings

KW - full scale

KW - hydrolysis

KW - internal carbon source

U2 - 10.1080/09593330.2011.650217

DO - 10.1080/09593330.2011.650217

M3 - Article

SN - 1479-487X

VL - 33

SP - 1819

EP - 1825

JO - Environmental Technology

JF - Environmental Technology

IS - 15

ER -

Full-scale in-line hydrolysis and simulation for potential energy and resource savings in activated sludge – a case study

Abstract

Subject classification (UKÄ)

Free keywords

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