Toward smart wastewater treatment plants: a novel data-driven sludge blanket model based on stochastic differential equations

Water Science & Technology Pub Date : 2024-07-13 DOI:10.2166/wst.2024.234

P. B. Vetter, P. A. Stentoft, T. Munk-Nielsen, Henrik Madsen, J. Møller

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Abstract

A novel data-driven model for forecasting the sludge blanket height in secondary clarifiers is presented. The model is trained on sensor measurements of the sludge blanket height and used as inputs such as (1) the clarifier feed flow rate, (2) feed suspended solids concentration, and (3) the clarifier recycle flow rate. The model’s prediction accuracy is evaluated based on data from two Danish wastewater treatment plants by means of root-mean-square errors (RMSEs), and results are compared against a persistence model. We demonstrate that the developed model is superior to the persistence forecast at both plants during high blanket dynamics. In the best scenario, the model improves the RMSE by 0.1/0.4 m at prediction horizons of 2.5/10 h, assuming known inputs. The model performance is subsequently considered with forecasted inputs using two different forecast scenarios. We discuss differences in the two plants’ performance and requirements to achieve good model performance. The model is well-suited for a model predictive control strategy, whose purpose ultimately is to improve clarifier control, increasing hydraulic capacity and reducing overflow suspended solids.

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迈向智能污水处理厂：基于随机微分方程的新型数据驱动污泥毯模型

本文介绍了一种新型数据驱动模型，用于预测二级澄清池中的污泥毯高度。该模型根据污泥毯高度的传感器测量数据进行训练，并使用以下数据作为输入：(1) 澄清池进料流速；(2) 进料悬浮固体浓度；(3) 澄清池循环流速。根据丹麦两家污水处理厂的数据，通过均方根误差（RMSE）对模型的预测精度进行了评估，并将结果与持久性模型进行了比较。结果表明，在高毯子动态情况下，所开发的模型在两个污水处理厂都优于持久性预测。在最好的情况下，假设输入已知，在 2.5/10 小时的预测范围内，模型的均方误差提高了 0.1/0.4 米。随后，我们采用两种不同的预测方案，考虑了预测输入的模型性能。我们讨论了两个工厂性能的差异以及实现良好模型性能的要求。该模型非常适合模型预测控制策略，其最终目的是改善澄清池控制、提高水力容量和减少溢流悬浮固体。

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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Water Science & Technology

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