Utilization of Semi-Continuous Algae Culture for the Treatment of Recycled Dairy Lagoon Wash Water

Current Biochemical Engineering Pub Date : 2021-06-22 DOI:10.2174/2212711907666210622153521

G. Schwartz, M. Ibekwe, T. Lundquist, S. Murinda, M. Murry

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引用次数: 0

Abstract

The utilization of animal wastes in algal culture has proven to be challenging. The utilization of “free” nutrients has drawn many researchers and industries to developing business models that call for the use of these free nutrients, which comes at a cost. Some of these costs include reduced productivity, increased contamination, lower-value target markets, and lower treatment capabilities (for wastewater treatment applications). This paper evaluates the impact of dairy lagoon effluent on productivity and wastewater treatment ability. Screened dairy lagoon wash water was fed to four three square meter outdoor open paddlewheel algal cultivation reactors. The units were operated semi-continuously for one and a half years. Seasonal productivity and nutrient uptake rates for nitrogen (N) and phosphorous (N) were measured against wastewater dilution requirements. Seasonal algal species dominance was also recorded. Wastewater was added at two levels, and the lower level was supplemented with synthetic fertilizer. Seasonal N uptake rates ranged from 0.5 to 1.2 grams of N uptake per square meter per day, while P uptake ranged from 0.17 to 0.3 grams of P per square meter per day depending on season and hydraulic residence time (HRT). N removal efficiency ranged at 40 to 70% for semicontinuous operation, depending on HRT, season, and dilution of influent wastewater, which was made up from 1.5% to 13% of the daily water exchange. Algal reactors tended to be N limited due to the inability to add enough dairy wastewater to mitigate the high turbidity and dark color. Treatments with lower levels of added dairy wastewater tended to show higher nutrient removal. Algal culture from dairy wash water could benefit from a pretreatment step to reduce turbidity and color, promoting algal growth and productivity.

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半连续藻培养法处理循环乳湖冲洗水的研究

在藻类培养中利用动物废物被证明是具有挑战性的。“免费”营养物质的利用吸引了许多研究人员和行业开发商业模式，要求使用这些免费营养物质，这是有代价的。其中一些成本包括生产力降低、污染增加、目标市场价值降低和处理能力降低(用于废水处理应用)。本文评价了乳湖出水对生产能力和废水处理能力的影响。筛选后的乳业泻湖冲洗水被送入4个3平方米的室外开放式桨轮藻培养反应器。这些装置半连续运行了一年半。根据废水稀释要求测定了氮和磷的季节生产力和养分吸收率。季节性藻类优势种也有记录。废水分两级添加，下一级添加合成肥料。季节氮素吸收量为每平方米每天0.5 ~ 1.2克，磷吸收量为每平方米每天0.17 ~ 0.3克，这取决于季节和水力停留时间(HRT)。半连续运行时，N去除率在40%到70%之间，取决于HRT、季节和进水废水的稀释程度，进水废水占每日换水量的1.5%到13%。由于无法添加足够的乳废水来缓解高浊度和深色，藻类反应器倾向于N限制。添加水平较低的乳制品废水处理往往表现出较高的营养去除率。从乳制品洗涤水中培养藻类可以受益于预处理步骤，以减少浊度和颜色，促进藻类生长和生产力。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Current Biochemical Engineering

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