Biofilm characterization and dynamic simulation of advanced rope media reactor for the treatment of primary effluent.

IF 2.5 4区 环境科学与生态学 Q3 ENGINEERING, ENVIRONMENTAL
Wudneh A Shewa, Lin Sun, Kevin Bossy, Martha Dagnew
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引用次数: 0

Abstract

Biofilm modeling is inherently complex, often requiring multiple assumptions and simplifications. In biofilm modeling, default or literature-based values in biofilm systems are usually used to estimate biofilm parameters, including boundary layer, biofilm density, thickness, attachment, and detachment rates. This study aimed to characterize and model the biofilm of a specific rope-type fixed media system, removing carbon and total inorganic nitrogen, coupled with sensitivity analysis. Among the five model parameters, the sensitivity analysis of this study showed that boundary layer thickness is the most influential parameter for predicting effluent ammonia and nitrate concentrations, and biofilm density is most sensitive with respect to effluent chemical oxygen demand (COD). The least sensitive parameter is the detachment rate. Based on the calculated mean absolute error (MAE) and root mean squared error (RMSE), the calibrated BioCord fixed-film reactor (BFFR) model accurately predicted effluent ammonium and dissolved oxygen (DO) in the continuously aerated bench-scale reactor (R1) and failed to predict well in the intermittently aerated bench-scale reactor (R2). RMSE values calculated for NH3-N and DO in R1 are 0.95 and 0.53 mg/L, respectively. In the BioCord pilot plant's case, ammonium-N predicted by the model fit the measured values well, while it overpredicted DO concentrations. PRACTITIONER POINTS: Fixed biofilm BioCord reactors were studied for primary effluent treatment. A methodology was developed to characterize biofilms. Boundary layer thickness is the most influential parameter for predicting effluent ammonia and nitrate concentrations. Biofilm density is the most sensitive parameter with respect to effluent COD. The calibrated BFFR model can predict effluent ammonium, nitrite, and nitrate-nitrogen.

用于处理一级污水的先进绳状介质反应器的生物膜特征和动态模拟。
生物膜建模本身就很复杂,往往需要多种假设和简化。在生物膜建模中,通常使用生物膜系统的默认值或基于文献的值来估算生物膜参数,包括边界层、生物膜密度、厚度、附着率和脱离率。本研究旨在对特定绳索型固定介质系统的生物膜进行特征描述和建模,去除碳和无机氮总量,并结合灵敏度分析。本研究的灵敏度分析表明,在五个模型参数中,边界层厚度是对预测出水氨氮和硝氮浓度影响最大的参数,而生物膜密度对出水化学需氧量(COD)最为敏感。最不敏感的参数是脱落率。根据计算得出的平均绝对误差 (MAE) 和均方根误差 (RMSE),校准过的 BioCord 固定膜反应器 (BFFR) 模型在连续通气的台式反应器 (R1) 中准确预测了出水氨氮和溶解氧 (DO),而在间歇通气的台式反应器 (R2) 中未能很好地预测。R1 中计算的 NH3-N 和溶解氧的 RMSE 值分别为 0.95 和 0.53 mg/L。在 BioCord 试验工厂的案例中,模型预测的铵-氮与测量值非常吻合,但对溶解氧浓度的预测过高。实践点:研究了用于一级污水处理的固定生物膜 BioCord 反应器。开发了一种表征生物膜的方法。边界层厚度是预测出水氨氮和硝氮浓度的最有影响力的参数。生物膜密度是对出水化学需氧量最敏感的参数。经过校准的 BFFR 模型可以预测出水氨氮、亚硝酸盐氮和硝酸盐氮。
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来源期刊
Water Environment Research
Water Environment Research 环境科学-工程:环境
CiteScore
6.30
自引率
0.00%
发文量
138
审稿时长
11 months
期刊介绍: Published since 1928, Water Environment Research (WER) is an international multidisciplinary water resource management journal for the dissemination of fundamental and applied research in all scientific and technical areas related to water quality and resource recovery. WER''s goal is to foster communication and interdisciplinary research between water sciences and related fields such as environmental toxicology, agriculture, public and occupational health, microbiology, and ecology. In addition to original research articles, short communications, case studies, reviews, and perspectives are encouraged.
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