Gas–liquid mass transfer studies in inverse fluidized bed biofilm reactor for the biodegradation of industrial effluent rich in phenolic compounds

Begum, S. Sabarunisha; Radha, K. V.

doi:10.1002/ep.12256

Cited by 9 publications

(3 citation statements)

References 27 publications

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“…When the increase rate of ε g dominates over that of d b , the k L a increases. Because of these two competing effects, the increasing trend of k L a becomes insignificant with increasing U g [24]. Thus at the optimal condition of U g , ε g dominates over the bubble size d b and have a significant effect in increasing the mass transfer rate and thereby the COD removal efficiency.…”

Section: Effect Of Superficial Air Flow Velocity and (V B /V R ) Ratimentioning

confidence: 98%

“…During the bio-treatment of biomedical wastewater in IFBBR, samples were collected at regular intervals of time to determine COD, pH, oxygen transfer rate (OTR), volumetric mass transfer coefficient (k L a), biofim thickness, biofilm dry density and pH. All the determinations were done according to standard procedures and methods [19] whereas the biofilm thickness and dry density of biofilm were estimated from the net weight of the bioparticles [24][25][26]. uniform concentration of bio-particles throughout the reactor [27][28][29].…”

Section: Measurement and Analysis For Degradation Experimentsmentioning

confidence: 99%

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Investigation of flow dynamic characteristics of inverse fluidized bed biofilm reactor for degrading pharmaceutical based biomedical wastewater

Begum¹,

Sikkandar

Prakash³

et al. 2020

Environmental Engineering Research

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The paper investigates the flow dynamic behaviour of inverse fluidized bed biofilm reactor (IFBBR) for the treatment of pharmaceutical based biomedical wastewater. The residence time distribution (RTD) study has been employed as a tool to investigate the flow dynamic behaviour of wastewater within the reactor. The biofilm reactor is operated using Pseudomonas fluorescens for various ratios of settled bed volume to reactor working volume (V b /V r) with different superficial air velocities and examined their impact on flow dynamics. The outcomes of this study demonstrate the presence of dead volume and short circuiting in the reactor were reduced for the optimized (V b /V r) ratio of 0.20 and optimum superficial air velocity (U g) m of 0.220 m/s. The potential of IFBBR was experimentally validated by analysing the chemical oxygen demand (COD) removal efficiency, total dissolved solids (TDS) and total suspended solids (TSS) emanating from the wastewater. Findings of this study reveals that maximum COD reduction of about 92% was achieved when the reactor was operated with (V b /V r) m of 0.20 with superficial air velocity, U gm of 0.220 m/s showing the optimal operating parameters for IFBBR which has good mixing and less back mixing condition inside the reactor.

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Section: Effect Of Superficial Air Flow Velocity and (V B /V R ) Ratimentioning

confidence: 98%

Section: Measurement and Analysis For Degradation Experimentsmentioning

confidence: 99%

Investigation of flow dynamic characteristics of inverse fluidized bed biofilm reactor for degrading pharmaceutical based biomedical wastewater

Begum¹,

Sikkandar

Prakash³

et al. 2020

Environmental Engineering Research

View full text Add to dashboard Cite

show abstract

“…The size of the activated carbon particles modified with MnO 2 is a relevant property required for the operation of an FBR [54]. The Geldart classification is one of the most useful ways of classifying solids [1], and it is usually applied to an FBR in group B (with a size between 100 and 800 µm) and group D (larger than 1 mm) particles [62]. Figure 4 shows the particle-size distribution assessed by laser diffraction spectrometry.…”

Section: Catalyst Characterisationmentioning

confidence: 99%

Removal of Aniline and Benzothiazole Wastewaters Using an Efficient MnO2/GAC Catalyst in a Photocatalytic Fluidised Bed Reactor

et al. 2021

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This work presents an efficient method for treating industrial wastewater containing aniline and benzothiazole, which are refractory to conventional treatments. A combination of heterogeneous photocatalysis operating in a fluidised bed reactor is studied in order to increase mass transfer and reduce reaction times. This process uses a manganese dioxide catalyst supported on granular activated carbon with environmentally friendly characteristics. The manganese dioxide composite is prepared by hydrothermal synthesis on carbon Hydrodarco® 3000 with different active phase ratios. The support, the metal oxide, and the composite are characterised by performing Brunauer, Emmett, and Teller analysis, transmission electron microscopy, X-ray diffraction analysis, X-ray fluorescence analysis, UV–Vis spectroscopy by diffuse reflectance, and Fourier transform infrared spectroscopy in order to evaluate the influence of the metal oxide on the activated carbon. A composite of MnO2/GAC (3.78% in phase α-MnO2) is obtained, with a 9.4% increase in the specific surface of the initial GAC and a 12.79 nm crystal size. The effect of pH and catalyst load is studied. At a pH of 9.0 and a dose of 0.9 g L−1, a high degradation of aniline and benzothiazole is obtained, with an 81.63% TOC mineralisation in 64.8 min.

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Biofilm reactors for value-added products production: An in-depth review

Germeç

Demirci

Turhan

2020

Biocatalysis and Agricultural Biotechnology

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Gas–liquid mass transfer studies in inverse fluidized bed biofilm reactor for the biodegradation of industrial effluent rich in phenolic compounds

Cited by 9 publications

References 27 publications

Investigation of flow dynamic characteristics of inverse fluidized bed biofilm reactor for degrading pharmaceutical based biomedical wastewater

Investigation of flow dynamic characteristics of inverse fluidized bed biofilm reactor for degrading pharmaceutical based biomedical wastewater

Removal of Aniline and Benzothiazole Wastewaters Using an Efficient MnO2/GAC Catalyst in a Photocatalytic Fluidised Bed Reactor

Biofilm reactors for value-added products production: An in-depth review

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