A continuous flocculants-free electrolytic flotation system for microalgae harvesting

Shanshan Luo; Richard Griffith; Wenkui Li; Peng Peng; Yanling Cheng; Paul L Chen; Min M Addy; Yuhuan Liu; R. R Ruan

doi:10.1016/j.biortech.2017.04.061

A continuous flocculants-free electrolytic flotation system for microalgae harvesting

Shanshan Luo, Richard Griffith, Wenkui Li, Peng Peng, Yanling Cheng, Paul L Chen, Min M Addy, Yuhuan Liu, R. R Ruan

Bioproducts and Biosystems Engineering

Research output: Contribution to journal › Article › peer-review

34 Scopus citations

Abstract

High harvesting cost and reusing of post-harvest water are the major challenges in commercial production of microalgae. In this work, a flocculants-free electrolytic flotation harvest process was investigated. The electrode design and materials were evaluated in terms of harvesting efficiency. Stainless steel as the cathode and carbon as the anode were selected based on the harvesting efficiency data and non-sacrificial feature for construction of a pilot scale harvesting system. In the pilot scale experiments, 23.72 g/h biomass yield was achieved at the power consumption of 2.73 kWh/kg. With the advantages of no chemical flocculent contamination and relatively low energy requirement, this continuous system is promising for food or feed applications.

Original language	English (US)
Pages (from-to)	439-449
Number of pages	11
Journal	Bioresource Technology
Volume	238
DOIs	https://doi.org/10.1016/j.biortech.2017.04.061
State	Published - 2017

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Publisher Copyright:
© 2017 Elsevier Ltd

Keywords

Chlorella vulgaris
Electrode design
Electrolytic flotation
Flocculants-free
Harvesting efficiency

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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title = "A continuous flocculants-free electrolytic flotation system for microalgae harvesting",

abstract = "High harvesting cost and reusing of post-harvest water are the major challenges in commercial production of microalgae. In this work, a flocculants-free electrolytic flotation harvest process was investigated. The electrode design and materials were evaluated in terms of harvesting efficiency. Stainless steel as the cathode and carbon as the anode were selected based on the harvesting efficiency data and non-sacrificial feature for construction of a pilot scale harvesting system. In the pilot scale experiments, 23.72 g/h biomass yield was achieved at the power consumption of 2.73 kWh/kg. With the advantages of no chemical flocculent contamination and relatively low energy requirement, this continuous system is promising for food or feed applications.",

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AU - Luo, Shanshan

AU - Griffith, Richard

AU - Li, Wenkui

AU - Peng, Peng

AU - Cheng, Yanling

AU - Chen, Paul L

AU - Addy, Min M

AU - Liu, Yuhuan

AU - Ruan, R. R

PY - 2017

Y1 - 2017

N2 - High harvesting cost and reusing of post-harvest water are the major challenges in commercial production of microalgae. In this work, a flocculants-free electrolytic flotation harvest process was investigated. The electrode design and materials were evaluated in terms of harvesting efficiency. Stainless steel as the cathode and carbon as the anode were selected based on the harvesting efficiency data and non-sacrificial feature for construction of a pilot scale harvesting system. In the pilot scale experiments, 23.72 g/h biomass yield was achieved at the power consumption of 2.73 kWh/kg. With the advantages of no chemical flocculent contamination and relatively low energy requirement, this continuous system is promising for food or feed applications.

AB - High harvesting cost and reusing of post-harvest water are the major challenges in commercial production of microalgae. In this work, a flocculants-free electrolytic flotation harvest process was investigated. The electrode design and materials were evaluated in terms of harvesting efficiency. Stainless steel as the cathode and carbon as the anode were selected based on the harvesting efficiency data and non-sacrificial feature for construction of a pilot scale harvesting system. In the pilot scale experiments, 23.72 g/h biomass yield was achieved at the power consumption of 2.73 kWh/kg. With the advantages of no chemical flocculent contamination and relatively low energy requirement, this continuous system is promising for food or feed applications.

KW - Chlorella vulgaris

KW - Electrode design

KW - Electrolytic flotation

KW - Flocculants-free

KW - Harvesting efficiency

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A continuous flocculants-free electrolytic flotation system for microalgae harvesting

Abstract

Bibliographical note

Keywords

UN SDGs

Access

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