Boosting biogas production through innovative data-driven modeling and optimization methods at NJWTP.

IF 3.9 2区综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES

Scientific Reports Pub Date : 2025-02-09 DOI:10.1038/s41598-025-88337-1

Jingsong Duan, Guohua Cao, Guoqing Ma, Bayram Yazdani

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Abstract

This study presents an innovative approach to enhancing biogas production through the anaerobic digestion of Nanjing Jiangnan Wastewater Treatment Plant (NJWTP). Utilizing data-driven modeling and optimization methods, the research focuses on improving the sustainability and cost-effectiveness of waste-to-energy conversion processes. The core of the study involves the comparison of three distinct models: Deep Belief Network (DBN), DBN with Osprey Optimization Algorithm (DBN-OOA), and DBN with Boosted Osprey Optimization Algorithm (DBN-BOOA). In total, 180 data points were gathered from 2016 to 2018 for the purpose of the current study. Among the models evaluated, the Deep Belief Network (DBN) coupled with Boosted Osprey Optimization Algorithm (BOOA) emerged as the superior method, demonstrating high accuracy and optimization capabilities. The DBN-BOOA model achieved remarkable performance metrics, including a correlation coefficient (R) of 0.98, a root mean square error (RMSE) of 0.41 m³/min, and an index of agreement (IA) of 0.99, significantly outperforming the standalone DBN and DBN-OOA models. Furthermore, the DBN-BOOA model identified optimal operational parameters that maximized biogas production to 31.35 m³/min, surpassing the outputs of the other models. This method's success is attributed to its robust optimization algorithm, which efficiently navigates a diverse search space to locate the global optimum without necessitating input variable pre-processing. Consequently, the DBN-BOOA model offers a practical and user-friendly solution for MWTP operators, enabling real-time adjustments to operational parameters for increased biogas yields and reduced sludge production.

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通过创新的数据驱动建模和优化方法促进NJWTP的沼气产量。

本研究提出了一种通过南京江南污水处理厂（NJWTP）厌氧消化提高沼气产量的创新方法。利用数据驱动的建模和优化方法，研究重点是提高废物转化为能源过程的可持续性和成本效益。研究的核心是比较三种不同的模型：深度信念网络（DBN）、DBN与鱼鹰优化算法（DBN- ooa）和DBN与增强鱼鹰优化算法（DBN- booa）。本研究从2016年到2018年共收集了180个数据点。在评估的模型中，深度信念网络（DBN）与助推鱼鹰优化算法（BOOA）相结合的方法具有较高的精度和优化能力。DBN- booa模型取得了显著的性能指标，包括相关系数(R)为0.98，均方根误差（RMSE）为0.41 m³/min，一致性指数（IA）为0.99，显著优于独立DBN和DBN- ooa模型。此外，DBN-BOOA模型确定了最佳操作参数，使沼气产量达到31.35 m³/min，超过了其他模型的产量。该方法的成功归功于其鲁棒优化算法，该算法在不需要输入变量预处理的情况下有效地导航不同的搜索空间以定位全局最优。因此，DBN-BOOA模型为MWTP运营商提供了一种实用且用户友好的解决方案，可以实时调整操作参数，以提高沼气产量并减少污泥产量。

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来源期刊

Scientific Reports Natural Science Disciplines-

CiteScore

7.50

自引率

4.30%

发文量

19567

审稿时长

3.9 months

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