This work deals with the treatment of a tannery wastewater by a mixed-iron coated olive stone bio-sorbent particles. Olive stones were used as the support to zero-valent iron and magnetite nanoparticles to develop a new material for the removal of chromium, organic matter and total phenols from the wastewater. The optimal operating conditions were determined in batch reactors, after which the process was scaled-up using fixed-bed columns in series. The maximum adsorption capacity for both Cr(III) and Cr(VI), up to 8.37 and 4.29 mg g−1, was attained for a sorbent mass concentration of 4 g L−1, meaning a total chromium adsorption capacity of 12.66 mg g−1, whereas equilibrium contact time was found to be 120 min. The combination of coated olive stones and hydrogen peroxide allowed to develop an heterogeneous Fenton process, that led to reach a COD removal efficiency of 58.4% and a total phenols removal of 59.2%, at H2O2/COD (w/w) = 0.875. In addition, re-use of the coated olive stones by regeneration with NaOH and C2H2O4solutions after 5 cycles was reported. The column process was successfully described by BDST and Thomas models.
Fenton oxidation and chromium recovery from tannery wastewater by means of iron-based coated biomass as heterogeneous catalyst in fixed-bed columns / Vilardi, Giorgio; Ochando-Pulido, Javier Miguel; Stoller, Marco; Verdone, Nicola; Di Palma, Luca. - In: CHEMICAL ENGINEERING JOURNAL. - ISSN 1385-8947. - ELETTRONICO. - 351:(2018), pp. 1-11. [10.1016/j.cej.2018.06.095]
Fenton oxidation and chromium recovery from tannery wastewater by means of iron-based coated biomass as heterogeneous catalyst in fixed-bed columns
Vilardi, Giorgio
;Stoller, Marco;Verdone, Nicola;Di Palma, Luca
2018
Abstract
This work deals with the treatment of a tannery wastewater by a mixed-iron coated olive stone bio-sorbent particles. Olive stones were used as the support to zero-valent iron and magnetite nanoparticles to develop a new material for the removal of chromium, organic matter and total phenols from the wastewater. The optimal operating conditions were determined in batch reactors, after which the process was scaled-up using fixed-bed columns in series. The maximum adsorption capacity for both Cr(III) and Cr(VI), up to 8.37 and 4.29 mg g−1, was attained for a sorbent mass concentration of 4 g L−1, meaning a total chromium adsorption capacity of 12.66 mg g−1, whereas equilibrium contact time was found to be 120 min. The combination of coated olive stones and hydrogen peroxide allowed to develop an heterogeneous Fenton process, that led to reach a COD removal efficiency of 58.4% and a total phenols removal of 59.2%, at H2O2/COD (w/w) = 0.875. In addition, re-use of the coated olive stones by regeneration with NaOH and C2H2O4solutions after 5 cycles was reported. The column process was successfully described by BDST and Thomas models.File | Dimensione | Formato | |
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