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Abstract: This study gathers the results of the operation and optimization of the thickening of microalgal biomass produced at demonstrative scale in photobioreactors fed with agricultural runoff and domestic wastewater. The optimization was conducted during two months. The system consisted in two gravity thickeners connected in series in a multi-stage approach. The objective of thickening was to concentrate the microalgae grown in photobioreactors (total solids (TS) concentration of 0.1?1 g/L) into a biomass with 20 g/L of TS, which was considered optimal for the subsequent anaerobic digestion process. First, the utilization of one single thickener alone allowed to achieve a concentration factor (CF) of 1.9 and recovery efficiency (RE) of 28%. However, the final concentration of TS in the thickened biomass (6.4 g/L) was still much lower than the target concentration. The installation of the second thickener connected in series with the first one significantly improved the overall performance. Indeed, a TS concentration of 26.5 g/L was finally achieved, with an overall CF of 3.6. The results of the study suggest that the multi-stage thickening process is a suitable strategy and it is highly advisable to achieve a successful microalgal biomass thickening at full-scale. In addition, other three points have been identified as key factors to be taken into account for biomass tickening: proper adjustment of the purge flowrate, coordination between purges times and volumes in the different stages, and proper adjustment of the operation of the scrapers.
Fuente: Separation and Purification Technology, 2022, 281, 119830
Publisher: Elsevier
Publication date: 15/01/2022
No. of pages: 11
Publication type: Article
DOI: 10.1016/j.seppur.2021.119830
ISSN: 1383-5866,1873-3794
Spanish project: RYC2018-025514-I
Publication Url: https://doi.org/10.1016/j.seppur.2021.119830
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ORTIZ, ANTONIO
GARCÍA, JOAN
UGGETTI, ENRICA
RUBEN DIEZ MONTERO
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