A two‐phase partitioning airlift bioreactor for the treatment of BTEX contaminated gases

Littlejohns, Jennifer V.; Daugulis, Andrew J.

doi:10.1002/bit.22343

Cited by 39 publications

(26 citation statements)

References 27 publications

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“…The cell mass was maintained in the range of 9-11 g/L for 10 days and the fluctuation of cell mass may be due to intermittent loading of the compound for 10 h a day and 5 days a week to simulate an actual industry operating schedule. Interestingly, other research using polymers as a second phase instead of an organic solvent in a TPPB fed with a mixture of benzene, toluene, ethylbenzene and o-xylene to a microbial consortium showed biological steady state from 300 to 400 h of operation with a collective maintenance coefficient of 0.0103 h -1 at biological steady state [9]. We could prolong the biological steady state to about 1 month without medium change by refining medium formulation with the same microorganism, A. xylosoxidans Y234, for benzene degradation in a TPPB [32].…”

Section: Dynamics Of the Maintenance Coefficientmentioning

confidence: 95%

“…These difficulties led to the design of a two-phase partitioning bioscrubber (TPPB) in which aqueous and organic phases were completely mixed as a single homogenous phase [7,8]. We have recently shown the potential of replacing the liquid organic phase of TPPBs with inexpensive polymers as a second phase, which has the advantage of allowing the use of microbial consortia, while also eliminating operational challenges (e.g., emulsions) which sometimes arise in two-liquid phase TPPBs [9].…”

Section: Introductionmentioning

confidence: 99%

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Estimating the cellular maintenance coefficient and its use in the design of two-phase partitioning bioscrubbers

Yeom

Nielsen

2009

Bioprocess Biosyst Eng

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One of the key roles of an organic solvent has emerged to be the enhancement of oxygen transfer in two-phase partitioning bioscrubbers (TPPBs). In order to determine an optimum organic fraction for a given VOCs loading, the oxygen demand of the total cell mass must be estimated, which depends upon the magnitude of the cellular maintenance coefficient. We have estimated the dynamics of the maintenance coefficient for benzene degradation by Achromobacter xylosoxidans Y234 in a TPPB and found that the maintenance coefficient generally decreased as cells accumulated in the TPPB but converged to a specific value of 1.750 x 10(-2) h(-1) at biological steady state. Due to its important influence on all of the essential design parameters of the TPPB system, including optimum organic fraction, aeration rate and agitation speed, the maintenance coefficient should be considered as a key biological determinant for microorganism selection, as well as in overall TPPB design.

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Section: Dynamics Of the Maintenance Coefficientmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Estimating the cellular maintenance coefficient and its use in the design of two-phase partitioning bioscrubbers

Yeom

Nielsen

2009

Bioprocess Biosyst Eng

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“…A schematic of the airlift SL-TPPB used by Littlejohns and Daugulis,3 which is modeled in the current study, can be seen in Fig. 1.…”

Section: System Descriptionmentioning

confidence: 99%

“…3 Performance indicators (removal efficiency and elimination capacity) were predicted over various loadings and inlet gas flow rates. An estimability analysis of model parameters was completed in order to identify the parameters to which output is most sensitive.…”

Section: Introductionmentioning

confidence: 99%

Model for a solid‐liquid airlift two‐phase partitioning bioscrubber for the treatment of BTEX

Littlejohns

McAuley

2009

J of Chemical Tech & Biotech

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BACKGROUND: Airlift solid-liquid two-phase partitioning bioreactors (SL-TPPBs) have been shown to be effective for the treatment of gas streams containing benzene, toluene, ethylbenzene and o-xylene (BTEX). The airlift SL-TPPB is a low-energy system that utilizes a sequestering phase of solid silicone rubber beads (10%v/v) that will uptake and release large amounts of BTEX in order to maintain equilibrium conditions within the system. This increases mass transfer from the gas phase during dynamic loading periods and improves degradation performance. This study discusses the development and analysis of a steady-state, tanks-in-series mathematical model, arising from mass balances on BTEX and oxygen in the gas, aqueous and polymer phases to predict the performance of the airlift SL-TPPB over various gas flow rates and BTEX loadings.

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“…Silicone oil has been found to be the best second phase for two-phase partitioning bioreactors [1]. Littlejohns and Daugulis [4] reported a 30% increase in removal efficiency of BETX from air after inclusion of silicone oil (10%, v/v). Arriaga et al [5] reported large improvement in the elimination capacity of a biofilter after use of silicone oil.…”

Section: Introductionmentioning

confidence: 99%

The effect of starvation periods on the performance of a two-liquid-phase mixed tank bioreactor for removal of n-hexane from air streams

2011

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In this research the effect of silicone oil as a heavy organic solvent on the performance of a mixed tank bioreactor was investigated. In the first stage of the experiments, the response of a two-liquid-phase mixed tank bioreactor to periods of n-hexane starvation was compared with that of a control bioreactor. In the control bioreactor, after 3 days of starvation, approximately six days were needed to reach the removal efficiency it had before starvation. This figure was only 10 h for the silicone oil-containing bioreactor. The results confirmed that inclusion of a heavy organic solvent can increase the elimination capacity of a bioreactor and to help sustain high elimination capacity after starvation periods. In the second stage of the experiments, the effect of the amount of silicone oil on the performance of the bioreactor was investigated. Increasing the amount of oil from 5 to 10% (v/ v) increased the maximum elimination capacity from 106 to 117 g/m 3 h.

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A two‐phase partitioning airlift bioreactor for the treatment of BTEX contaminated gases

Cited by 39 publications

References 27 publications

Estimating the cellular maintenance coefficient and its use in the design of two-phase partitioning bioscrubbers

Estimating the cellular maintenance coefficient and its use in the design of two-phase partitioning bioscrubbers

Model for a solid‐liquid airlift two‐phase partitioning bioscrubber for the treatment of BTEX

The effect of starvation periods on the performance of a two-liquid-phase mixed tank bioreactor for removal of n-hexane from air streams

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