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引用次数: 0
摘要
二级澄清池短路是一个众所周知的问题,可通过上流式或下流式途径发生。下流短路不像上流短路那么明显,但会影响澄清池的性能。消能进水口 (EDI) 是一种进水口结构,用于二级澄清池,以消散较大进水量的能量,从而使澄清池以更高的处理能力运行。在配备 EDI 的澄清池中,尤其会出现底流短路现象。随着进水量的增加,传统的引流管道无法处理高容量的污泥,污泥毯会变形,导致抽取的固体浓度降低。改造引流管的设计是缓解底流短路和提高处理性能的有效方法。在这项研究中,利用计算流体动力学工具设计了一种蜗牛形污泥引流管,并在两种类型的 EDI 中进行了测试,结果表明抽出的污泥浓度提高了 20%,并减轻了底流短路的可能性。最佳改造方案被确定为在澄清池中安装蜗牛形引流管和创新型 EDI(即多层 EDI 柱),这将节省生物处理过程近一半的能源和运营成本,同时还能满足排放限制要求。
Effects of using a specially designed sludge draw-off pipe for circular secondary clarifiers to mitigate underflow short-circuiting
Short-circuiting in secondary clarifiers is a well-known problem that can occur through up-flow or underflow routes. The underflow short-circuiting is not as visible as up-flow short-circuiting but can affect clarifier performance. The energy-dissipating inlet (EDI) is a type of inlet structure that is used in secondary clarifiers to dissipate the energy of larger influent volumes, allowing clarifiers to operate at higher treatment capacities. The underflow short-circuiting is encountered particularly in clarifiers equipped with EDIs. As influent volume increases, conventional draw-off pipes cannot handle high sludge capacities, deforming the sludge blanket and leading to lower concentration of solids being withdrawn. Retrofitting the design of draw-off pipes is an effective way to mitigate underflow short-circuiting and enhance treatment performance. In this study, a snail-shaped sludge draw-off pipe was designed and tested in two types of EDIs using computational fluid dynamics tools, showing a 20% increase in withdrawn sludge concentration and mitigating underflow short-circuiting potential. The optimal retrofit option was identified as equipping the clarifier with a snail-shaped draw-off pipe and an innovative EDI, known as multilayer EDI column, which would save almost half of the energy and operational costs of the biological processes while meeting discharge limits.
期刊介绍:
CLEAN covers all aspects of Sustainability and Environmental Safety. The journal focuses on organ/human--environment interactions giving interdisciplinary insights on a broad range of topics including air pollution, waste management, the water cycle, and environmental conservation. With a 2019 Journal Impact Factor of 1.603 (Journal Citation Reports (Clarivate Analytics, 2020), the journal publishes an attractive mixture of peer-reviewed scientific reviews, research papers, and short communications.
Papers dealing with environmental sustainability issues from such fields as agriculture, biological sciences, energy, food sciences, geography, geology, meteorology, nutrition, soil and water sciences, etc., are welcome.
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