Production of microalgal concentrates by flocculation and their assessment as aquaculture feeds

Knuckey, Richard; Brown, Malcolm R.; Robert, R.; Frampton, Dion M. F.

doi:10.1016/j.aquaeng.2006.04.001

Cited by 309 publications

(177 citation statements)

References 27 publications

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“…5 Selection of cost-effective technologies for biomass harvesting and drying Given the relatively low biomass concentration obtainable in microalgal cultivation systems due to the limit of light penetration (typically in the range of 1-5 g/L) and the small size of microalgal cells (typically in the range of 2-20 lm in diameter), costs and energy consumption for biomass harvesting are a significant concern needs to be addressed properly. Different technologies, including chemical flocculation, 75 biological flocculation, 76 filtration, 77 centrifugation, 78 and ultrasonic aggregation 79 have been investigated for microalgal biomass harvesting. In general, chemical and biological flocculation require only low operating costs; however, they have the disadvantage of requiring long processing period and having the risk of bioreactive product decomposition.…”

Section: Design Of Advanced Photobioreactorsmentioning

confidence: 99%

Biofuels from Microalgae

Horsman

et al. 2008

Biotechnology Progress

676

390

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Microalgae are a diverse group of prokaryotic and eukaryotic photosynthetic microorganisms that grow rapidly due to their simple structure. They can potentially be employed for the production of biofuels in an economically effective and environmentally sustainable manner. Microalgae have been investigated for the production of a number of different biofuels including biodiesel, bio-oil, bio-syngas, and bio-hydrogen. The production of these biofuels can be coupled with flue gas CO 2 mitigation, wastewater treatment, and the production of high-value chemicals. Microalgal farming can also be carried out with seawater using marine microalgal species as the producers. Developments in microalgal cultivation and downstream processing (e.g., harvesting, drying, and thermochemical processing) are expected to further enhance the costeffectiveness of the biofuel from microalgae strategy.

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Section: Design Of Advanced Photobioreactorsmentioning

confidence: 99%

Biofuels from Microalgae

Horsman

et al. 2008

Biotechnology Progress

676

390

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“…However, flocculation caused by alkaline adjustment has been used to effectively remove Dunalliella testolata (Horiuchi et al 2003) and Chaetoceros sp. from fluids (Csordas & Wang 2004;Knuckey et al 2006).…”

Section: Cell Harvestingmentioning

confidence: 99%

“…Figure 7 illustrates such a concept in which oil is produced together with other valuable extracts and where nutrients and process water are recycled. Products derived from microalgal biomass can include commodity materials destined for a range of chemical products such as pharmaceuticals and platform chemicals including other fuels (by conversion to ethanol and methane); highly unsaturated fatty acids such as docosahexaenoic acid ); proteins and carbohydrates, which can be used as gross nutrients (Knuckey et al 2006); specific compounds such as pigments (Lorenz & Cysewski 2000); or silica derived from diatom cell walls (Gordon et al 2009). Each of these components could have considerable value; many could be simultaneously harvested, with contributions between them adjusted by modulation of growth conditions.…”

Section: Harvesting and Processing Of Biomass Fractionsmentioning

confidence: 99%

Placing microalgae on the biofuels priority list: a review of the technological challenges

Greenwell

Laurens

Shields

et al. 2009

J. R. Soc. Interface.

704

358

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Microalgae provide various potential advantages for biofuel production when compared with 'traditional' crops. Specifically, large-scale microalgal culture need not compete for arable land, while in theory their productivity is greater. In consequence, there has been resurgence in interest and a proliferation of algae fuel projects. However, while on a theoretical basis, microalgae may produce between 10-and 100-fold more oil per acre, such capacities have not been validated on a commercial scale. We critically review current designs of algal culture facilities, including photobioreactors and open ponds, with regards to photosynthetic productivity and associated biomass and oil production and include an analysis of alternative approaches using models, balancing space needs, productivity and biomass concentrations, together with nutrient requirements. In the light of the current interest in synthetic genomics and genetic modifications, we also evaluate the options for potential metabolic engineering of the lipid biosynthesis pathways of microalgae. We conclude that although significant literature exists on microalgal growth and biochemistry, significantly more work needs to be undertaken to understand and potentially manipulate algal lipid metabolism. Furthermore, with regards to chemical upgrading of algal lipids and biomass, we describe alternative fuel synthesis routes, and discuss and evaluate the application of catalysts traditionally used for plant oils. Simulations that incorporate financial elements, along with fluid dynamics and algae growth models, are likely to be increasingly useful for predicting reactor design efficiency and life cycle analysis to determine the viability of the various options for largescale culture. The greatest potential for cost reduction and increased yields most probably lies within closed or hybrid closed -open production systems.

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“…A major drawback of using mineral salts is that higher flocculant doses are required, ranging from 120 to 1000 g·m −3 , compared to 1-10 g·m −3 for organic flocculants [17]. The harvesting recovery efficiency of flocculation-assisted sedimentation ranges from 50% to 90% [56,71,72] and the concentration factor from 35 to 800, although concentration factors of 800 are generally not achievable for microalgae [21,73].…”

Section: Microalgal Biogas Production With Flocculation Harvestingmentioning

confidence: 99%

Energy Balance of Biogas Production from Microalgae: Effect of Harvesting Method, Multiple Raceways, Scale of Plant and Combined Heat and Power Generation

Milledge

Heaven

2017

JMSE

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Abstract:A previously-developed mechanistic energy balance model for production of biogas from the anaerobic digestion of microalgal biomass grown in open raceway systems was used to consider the energetic viability of a number of scenarios, and to explore some of the most critical parameters affecting net energy production. The output demonstrated that no single harvesting method of those considered (centrifugation, settlement or flocculation) produced an energy output sufficiently greater than operational energy inputs to make microalgal biogas production energetically viable. Combinations of harvesting methods could produce energy outputs 2.3-3.4 times greater than the operational energy inputs. Electrical energy to power pumps, mixers and harvesting systems was 5-8 times greater than the heating energy requirement. If the energy to power the plant is generated locally in a combined heat and power unit, a considerable amount of "low grade" heat will be available that is not required by the process, and for the system to show a net operational energy return this must be exploited. It is concluded that the production of microalgal biogas may be energetically viable, but it is dependent on the effective use of the heat generated by the combustion of biogas in combined heat and power units to show an operational energy return.

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Production of microalgal concentrates by flocculation and their assessment as aquaculture feeds

Cited by 309 publications

References 27 publications

Biofuels from Microalgae

Biofuels from Microalgae

Placing microalgae on the biofuels priority list: a review of the technological challenges

Energy Balance of Biogas Production from Microalgae: Effect of Harvesting Method, Multiple Raceways, Scale of Plant and Combined Heat and Power Generation

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