Treatment of Cr, Ni and Zn from galvanic rinsing wastewater by electrocoagulation process using iron electrodes

Kobya, Mehmet; Erdem, Nur; Demirbaş, E.

doi:10.1080/19443994.2014.951692

Cited by 24 publications

(7 citation statements)

References 39 publications

(77 reference statements)

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“…However, there were some studies in literature about removals of heavy metals such as Ni, Cr, Cd, Zn, Cu, etc except for Zr and Al by the EC [65]. The comparisons and evaluations of removal efficiencies and operating costs from some studies were reported [66].…”

Section: Comparisons Of Removal Efficiencies For Aluminium Phosphatementioning

confidence: 98%

Evaluations of operating parameters on treatment of can manufacturing wastewater by electrocoagulation

Kobya

Demirbaş

2015

Journal of Water Process Engineering

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Section: Comparisons Of Removal Efficiencies For Aluminium Phosphatementioning

confidence: 98%

Evaluations of operating parameters on treatment of can manufacturing wastewater by electrocoagulation

Kobya

Demirbaş

2015

Journal of Water Process Engineering

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“…The efficiency of pollutant removal increases with increasing reaction time until it reaches the maximum value in the optimum reaction time. Many authors have found that the optimum time values in the literature for removal of heavy metals are between 10 and 60 minutes (Gomes et al, 2007;Song et al, 2016;Akbal and Camci, 2010;Hamdan and El-Naas, 2014;Kobya et al, 2015). Time optimization, it was determined that the optimal contact time was 20 minutes for the FE electrode and 30 minutes for the Cu electrode.…”

Section: Comparison Of Obtained Results With Literature Datamentioning

confidence: 99%

Pollutant removal from mining processing wastewater by electrochemical method

2021

Global NEST: The International Journal

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<p>Discharging wastewater from industries without any treatment causes environmental pollution and endangers biotic life. In this study, pollutant removal by electrocoagulation (EC) process was investigated using wastewater of the ore processing plant (magnesite crushing and screening plant). In the EC process, iron-iron and copper-copper electrodes were used in parallel in the reactor. Chemical oxygen demand (COD), Sulphate, Chromium (VI), Nickel, Zinc, Magnesium, and Total Suspended Solids (TSS) removals were investigated in the EC process of mineral processing industry wastewater with the iron electrode. These pollutants were calculated as %97.6, %95.1, %98.2, %98.1, %97.8, %88.2, and %98.9, respectively. COD, Sulphate, Chromium (VI), Nickel, Zinc, Magnesium, and TSS removals in the EC process of mineral processing industry wastewater with the copper electrode are %92.8, %94.9, %99.5, %98.7, %96.1, %91.6, and %96.9 respectively. It has been observed that high removal efficiency can be achieved by using the electrocoagulation process in the treatment of ore washing wastewater resulting from the crushing and screening processes in the Chrome Magnesite processing plant.</p>

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“…Removal of cations of metals e.g. Pb, Cd, Ni, Cu, Zn contained in various waters by EC has been investigated for the sake of a better understanding of the phenomena involved (Adhoum et al 2004;Heidmann and Calmano 2008;Kobya et al 2015;Al-Shannag et al 2015;Lu et al 2015), in addition to production of purified water. From the above investigations, removal of heavy metal cations Me 2+ is allowed by occurrence of (i) specific adsorption of the pollutants by complexation with soluble species, or by surface complexation on the Al /Fe hydroxides flocs; (ii) adsorption through electrical neutralization and electrostatic attraction between the pollutants and the charged flocs; (iii) formation of Me(OH)2 near the cathode surface upon water reduction to hydrogen and hydroxide ions, followed by co-precipitation of the two hydroxides.…”

Section: -Introductionmentioning

confidence: 99%

Removal of heavy metals by electrocoagulation from hydrogenocarbonate-containing waters: Compared cases of divalent iron and zinc cations

Doggaz

Attour

Mostefa

et al. 2019

Journal of Water Process Engineering

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Divalent iron and zinc cations can be removed from water by electrocoagulation (EC) with aluminium electrodes in a discontinuous system: the effect of hydrocarbonate HCO3-ion often present in liquid waste and in groundwater on the EC process has been investigated. For the two ions, the presence of hydrocarbonate strongly limits the pH variations by its buffering properties and reduces the rates of Al dissolution by corrosion. Removal of the two cations was then shown to require longer treatment times and larger amounts of dissolved aluminium. Whereas the local pH gradients near the electrode surface with HCO3free water was previously shown to allow local formation of stable Zn and Fe hydroxides, which actively contribute to their elimination, the presence of hydrocarbonate nearly suppresses this positive phenomenon, resulting in far less efficient EC treatment. Whereas removal of zinc cations from carbonated water can be considered as their simple adsorption on the Al flocs, Fe 2+ ions are oxidized to Fe(OH)3 by air oxidation after their adsorption. Use of an overall adsorption model allowed quantitative comparison of the EC treatments, with very different adsorption parameters for the two metal studied.

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Treatment of Cr, Ni and Zn from galvanic rinsing wastewater by electrocoagulation process using iron electrodes

Cited by 24 publications

References 39 publications

Evaluations of operating parameters on treatment of can manufacturing wastewater by electrocoagulation

Evaluations of operating parameters on treatment of can manufacturing wastewater by electrocoagulation

Pollutant removal from mining processing wastewater by electrochemical method

Removal of heavy metals by electrocoagulation from hydrogenocarbonate-containing waters: Compared cases of divalent iron and zinc cations

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