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Publication type
Wissenschaftlicher Artikel
Date
2023
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Pilot-scale vanadium adsorption onto in-situ biogenic amorphous ferric hydroxide

Editor
Containing Item
Journal of Water Process Engineering
56 (2023)
Keywords
Trinkwasseraufbereitung
Citation
Mahringer, Daniel, Aki Sebastian Ruhl and Sami Sofiene Zerelli, 2023. Pilot-scale vanadium adsorption onto in-situ biogenic amorphous ferric hydroxide. Journal of Water Process Engineering [online]. 2023. vol. 56 (2023). DOI 10.60810/openumwelt-283. Verfügbar unter: https://openumwelt.de/handle/123456789/1666
Abstract english
In order to reach 4 (micro)g l-1 vanadium in drinking water adsorption onto in-situ biogenic amorphous ferric hydroxide (AFH) is identified as robust new treatment. The evaluation of its technical feasibility and robustness was the aim of this study. As approach at pilot-scale, Fe(II) and oxygen was dosed before pilot waterworks and Fe(II) subsequently biotically oxidized and precipitated in a filter bed. The so in-situ generated biogenic AFH served as adsorbent for vanadium removal. Results show that an initial vanadium concentration of 30 (micro)g l-1 was removed to below 4 (micro)g l-1, if at least 3 mg l-1 Fe(II) were dosed, resulting in a loading of 8.7 mg V per g AFH. A vanadium concentration of 60 (micro)g l-1 with a dosage of 3 mg l-1 Fe(II) was the upper limit for sufficient removal. Vanadium removal increased with increasing pH in the technical setup, due to faster oxidation of Fe(II) in the supernatant, even though adsorption capacity of AFH decreases with increasing pH. A filtration velocity of 20 m h -1 represented the highest velocity to undercut 4 (micro)g l-1 vanadium in the effluent. By mixing Fe(II) containing groundwater with oxygen and vanadium containing water prior to an adsorption filter with AFH sufficient removal was reached, however dependent on the resulting Fe(II) concentration. © 2023 by the authors