机器学习在有机固体废物资源化的应用进展

Advances in the Application of Machine Learning in Resource Technology for Organic Solid Waste

  • 摘要: 机器学习(Machine learning, ML)方法,以其卓越的数据解析和模式识别能力,已在有机固体废物(Organic solid waste, OSW)处理领域展现出显著的应用潜力。随着对OSW处理需求的日益增长及技术革新的推进,ML在该领域的应用正迅速普及。本研究聚焦于ML技术在OSW资源化处理中的应用。文章首先界定了OSW的范畴,针对OSW处理中存在的异质性和复杂性问题,指出了传统处理技术在进行OSW产量预测和条件优化的局限性。通过对2018-2023年间的学术成果进行检索分析,揭示了ML在OSW处理中的研究趋势和热点领域。尤其是人工神经网络(ANN)、支持向量机(SVM)、决策树(DT)、随机森林(RF)和遗传算法(GA)这四种常用模型在提高OSW处理效率和资源回收率方面的潜力,包括在源头产生和分类、热化学转化处理、厌氧生物处理和好氧堆肥等方面的应用现状及应用频率。同时评估了它们的优缺点及适用性。研究发现,ML技术能够有效提高OSW处理的预测精度和工艺优化能力,尤其是在废物特性预测和生物处理过程模拟方面展现出显著优势。数据质量、模型泛化能力及算法选择仍是ML技术应用中需要解决的关键问题。为此,本文提出了综合模型开发、跨学科技术融合等一系列解决策略,以期为OSW资源化提供科学指导和技术支持。

     

    Abstract: Machine learning (ML) methods, with their excellent data parsing and pattern recognition capabilities, have shown significant application potential in the field of organic solid waste (OSW) treatment. With the increasing demand for OSW treatment and the advancement of technological innovation, the application of ML in this field is rapidly becoming popular. This study systematically explores the application of ML methods in the treatment and resource recovery of OSW, highlighting the potential of ML to address the heterogeneity and complexity inherent in OSW. The research initially defines the scope of OSW, demonstrated the limitations of traditional treatment technologies when confronted with the diverse origins and heterogeneous compositions of OSW. Through an exhaustive review of academic literature from 2018 to 2023, this study identifies research trends and hotspots in the application of ML to OSW treatment. It particularly focuses on the potential of four commonly used ML models—Artificial Neural Networks (ANN), Support Vector Machines (SVM), Decision Trees (DT), Random Forests (RF), and Genetic Algorithms (GA)—in enhancing the efficiency and resource recovery rate of OSW treatment. The strengths, weaknesses, and applicability of these models across various stages of OSW management, including source reduction, classification, thermochemical conversion, anaerobic digestion, and aerobic composting were discussed. The findings indicate that ML techniques significantly improve the predictive accuracy and process optimization capabilities in OSW treatment. Notably, ML models have demonstrated remarkable advantages in predicting waste characteristics and simulating biological treatment processes. However, key challenges remain, including data quality, model generalization ability, and algorithm selection. To address these challenges, the study proposes a series of strategies, such as the development of integrated models and the integration of interdisciplinary technologies. These strategies aim to provide scientific guidance and technical support for the resourceful utilization of OSW. The study concludes by emphasizing the importance of selecting the appropriate ML model based on data structure and size, as well as the specific nature of the OSW treatment process. It also suggests that further research should focus on real-time process monitoring and control using ML technologies to enhance product yield in process systems and explore the potential of algorithms combination or combining trained ML models with other data-driven control strategies for comprehensive and automated process optimization.

     

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