利用藻生物膜光生物反应器减少藻类培养的水和能源需求。

Reduction of water and energy requirement of algae cultivation using an algae biofilm photobioreactor.

机构信息

Civil, Architectural, and Environmental Engineering Department, Cockrell School of Engineering, The University of Texas at Austin, Austin, TX 78712, USA.

出版信息

Bioresour Technol. 2012 Jun;114:542-8. doi: 10.1016/j.biortech.2012.03.055. Epub 2012 Mar 28.

DOI:10.1016/j.biortech.2012.03.055

PMID:22503193

Abstract

This paper reports the construction and performance of an algae biofilm photobioreactor that offers a significant reduction of the energy and water requirements of cultivation. The green alga Botryococcus braunii was cultivated as a biofilm. The system achieved a direct biomass harvest concentration of 96.4 kg/m(3) with a total lipid content 26.8% by dry weight and a productivity of 0.71 g/m(2) day, representing a light to biomass energy conversion efficiency of 2.02%. Moreover, it reduced the volume of water required to cultivate a kilogram of algal biomass by 45% and reduced the dewatering energy requirement by 99.7% compared to open ponds. Finally, the net energy ratio of the cultivation was 6.00 including dewatering. The current issues of this novel photobioreactor are also identified to further improve the system productivity and scaleup.

摘要

本文报告了一种藻类生物膜光生物反应器的构建和性能，该反应器显著降低了培养的能源和水需求。将绿色藻类 Botryococcus braunii 培养为生物膜。该系统实现了 96.4 kg/m³的直接生物质收获浓度，总脂质含量为干重的 26.8%，生产力为 0.71 g/m²天，代表了 2.02%的光到生物质能量转换效率。此外，与开放池塘相比，它将培养一公斤藻类生物质所需的水量减少了 45%，并将脱水能耗降低了 99.7%。最后，包括脱水在内，该培养的净能量比为 6.00。还确定了这种新型光生物反应器的当前问题，以进一步提高系统的生产力和扩大规模。

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利用藻生物膜光生物反应器减少藻类培养的水和能源需求。

Reduction of water and energy requirement of algae cultivation using an algae biofilm photobioreactor.

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