Electrocoagulation of kraft pulp bleaching filtrates to improve biotreatability

[Display omitted] •Kraft pulp mill bleaching filtrates contain highly recalcitrant organic loads.•Filtrate electrocoagulation was optimized using response surface methodology.•Electrocoagulation increased biodegradability and decreased toxicity and color.•Electrocoagulation has potential to improve...

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Bibliographic Details
Published in:Process safety and environmental protection 2021-03, Vol.147, p.346-355
Main Authors: Coimbra, Eder Carlos Lopes, Mounteer, Ann H., do Carmo, Andreiva Lauren Vital, Michielsen, Marc Jaqueline Frank, Tótola, Lucas Alcântara, Guerino, Júlia Pires Fujiara, Gonçalves, Júlia Gabriela Alves Nogueira, da Silva, Priscila Romana
Format: Article
Language:English
Subjects:
Biodegradability
Biodegradation
Biological activity
Biological treatment
Bleaching
Current density
Dissolved organic carbon
Effluent treatment
Electrocoagulation
Electrodes
Electrolysis
Estrogenic activity
Filtrate
Industrial wastewater
Iron
Kraft pulp
Organic constituents
pH effects
Phenols
Pulp & paper mills
Pulp wastes
Reaction time
Response surface
Response surface methodology
Toxicity
Wastewater
Wastewater treatment
Xenoestrogens
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Summary:[Display omitted] •Kraft pulp mill bleaching filtrates contain highly recalcitrant organic loads.•Filtrate electrocoagulation was optimized using response surface methodology.•Electrocoagulation increased biodegradability and decreased toxicity and color.•Electrocoagulation has potential to improve pulp mill biological treatment. Bleached kraft pulp mills generate large volumes of effluents usually treated by biological processes that don´t remove recalcitrant organic constituents. The present study was undertaken to evaluate the potential of electrocoagulation of acid (AcF) and alkaline (AlF) kraft pulp bleaching filtrates with Al and Fe electrodes to improve their biotreatability. Response surface methodology was used to predict the effects of initial pH, current density, and electrolysis time on biodegradability (BOD/COD). Biodegradability increases of 1.7–2.1-fold were obtained using optimized experimental conditions for each electrode-filtrate combination: AcF-Al (pH 7.9, 128 A/m², 49 min), AcF-Fe (pH 4.6, 104 A/m², 40 min), AlF-Al (pH 3.8, 150 A/m², 52 min) and AlF-Fe (pH 6.3, 101 A/m², 42 min). Electrocoagulation with Al electrodes was more efficient in removing color, phenols and estrogenic activity, but required longer reaction time and higher current density, while treatment with Fe electrodes resulted in lower toxicity to Daphnia similis. Electrocoagulation of both filtrates before combining them for biological treatment led to 88 % dissolved organic carbon (DOC) removal in a five-day biodegradability test, compared to only 27 % DOC removal from combined raw filtrates. The potential to increase overall pulp mill wastewater treatment efficiency using electrocoagulation prior to biological treatment was demonstrated.
ISSN:0957-5820
1744-3598
DOI:10.1016/j.psep.2020.09.039