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污水系统基于污染的实时建模与控制综述。

A review of pollution-based real-time modelling and control for sewage systems.

作者信息

da Silva Gesser Rodrigo, Voos Holger, Cornelissen Alex, Schutz Georges

机构信息

University of Luxembourg, 29 Av. John F. Kennedy, Luxembourg City, 1855, Luxembourg.

RTC4Water, 62a Grand-Rue, Roeser, 3394, Luxembourg.

出版信息

Heliyon. 2024 May 31;10(11):e31831. doi: 10.1016/j.heliyon.2024.e31831. eCollection 2024 Jun 15.

DOI:10.1016/j.heliyon.2024.e31831
PMID:38947485
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11214442/
Abstract

Conventional solutions for wastewater collection focus on reducing overflow events in the sewage network, which can be achieved by adapting sewer infrastructure or, a more cost-effective alternative, by implementing a non-engineering management solution. The state-of-the-art solution is centered on Real-Time Control (RTC), which is already resulting in a positive impact on the environment by decreasing the volume of wastewater being discharged into receiving waters. Researchers have been continuing efforts towards upgrading RTC solutions for sewage systems and a new approach, although rudimentary, was introduced in 1997, known as Pollution-based RTC (P-RTC), which added water quality (concentration or load) information explicitly within the RTC algorithm. Formally, P-RTC is encompassed of several control methodologies using a measurement or estimation of the concentration (i.e. COD or ammonia) of the sewage throughout the network. The use of P-RTC can result in a better control performance with a reduction in concentration of overflowing wastewater observed associated with an increase of concentration of sewage arriving at the Wastewater Treatment Plant (WWTP). The literature revealed that P-RTC can be differentiated by: (1) implementation method; (2) how water quality is incorporated, and (3) overall control objectives. Additionally, this paper evaluates the hydrological models used for P-RTC. The objective of this paper is to compile relevant research in pollution-based modelling and real-time control of sewage systems, explaining the general concepts within each P-RTC category and their differences.

摘要

传统的污水收集解决方案侧重于减少污水管网中的溢流事件,这可以通过改造下水道基础设施来实现,或者采用一种更具成本效益的替代方案,即实施非工程管理解决方案。目前最先进的解决方案以实时控制(RTC)为核心,通过减少排入受纳水体的废水量,已经对环境产生了积极影响。研究人员一直在持续努力升级污水系统的实时控制解决方案,1997年引入了一种新方法,虽然还很初级,但被称为基于污染的实时控制(P-RTC),它在实时控制算法中明确添加了水质(浓度或负荷)信息。正式地说,P-RTC包含几种控制方法,这些方法使用对整个管网中污水浓度(即化学需氧量或氨)的测量或估计。使用P-RTC可以带来更好的控制性能,观察到溢流废水浓度降低,同时到达污水处理厂(WWTP)的污水浓度增加。文献表明,P-RTC可以通过以下方面进行区分:(1)实施方法;(2)水质的纳入方式;(3)总体控制目标。此外,本文评估了用于P-RTC的水文模型。本文的目的是汇编有关基于污染的污水系统建模和实时控制的相关研究,解释每个P-RTC类别中的一般概念及其差异。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ddfd/11214442/179b5f6d575a/gr011.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ddfd/11214442/b91f11557356/gr007.jpg
https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ddfd/11214442/a9f23f478c5b/gr008.jpg
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A critical review of wastewater quality variation and in-sewer processes during conveyance in sewer systems.
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A learning-based approach towards the data-driven predictive control of combined wastewater networks - An experimental study.基于学习的数据驱动联合污水管网预测控制方法——一项实验研究。
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