污水处理厂的设计和操作改进,以改善生物固体的管理:再生、气味和指示生物的突然增加

M. Higgins, S. Murthy
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引用次数: 1

摘要

本项目的总体目标是研究处理高剪切脱水(如离心机)下生物固体饼中指示菌和致病菌的再生、气味和突然增加(ROSI)的方法。这个项目分为两个阶段。第一阶段的重点是填补关键的研究空白,为开发这些问题的解决方案提供了基本的见解,包括方法开发。第二阶段侧重于评估现场解决方案。这项工作的结果支持了突然增加是指示细菌不完全失活的结果的假设。结果表明,美国EPA方法1680可能低估了热处理后某些样品中指示菌的活密度,并且表明,为了实现指示菌的完全失活,可能需要稍高的时间-温度制度。项目团队提出了一个新的最佳实践时间-温度曲线。此外,还确定了具有相对较高的突然增加(SI)和再生长风险的过程。采用气相色谱-嗅觉法鉴别离心生物固体中的持久/长期气味。造成蛋糕气味的主要持久性气味剂是吲哚、甲酚、对甲酚和丁酸。所有这些化合物都是有机物(主要是蛋白质、碳水化合物和脂肪)的分解产物,这表明去除这些易被生物利用的前体形式的过程将有助于减少生物固体中的气味。结果表明,长期储存后测量的气味水平与短期总挥发性有机化合物(TVOSC)浓度相关。添加到离心饼中的几种修正剂能够显著减少气味和/或再生。厌氧消化的生物固体与蛋白质降解酶的孵育导致额外的气体产生以及脱水后气味的减少。此外,更好的消化与较低的气味有关,初级固体比次级固体产生更大的气味浓度。在环境温度(15-30°C)下长期储存生物固体超过20天,在现场试验中生产了一种低气味的产品,满足B类生物固体粪便大肠菌群的要求。没有测量室外和室内储存的好处。本文归属于WERF研究报告丛书ISBN: 9781780404578(电子书)
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Wastewater Treatment Plant Design and Operation Modifications to Improve Management of Biosolids: Regrowth, Odors, and Sudden Increase in Indicator Organisms
The overall goal of this project was to investigate approaches to manage regrowth, odors, and sudden increase (ROSI) of indicator and pathogenic bacteria in biosolids cake exposed to high-shear dewatering such as centrifuges. The project entailed two phases. The first phase was focused on filling critical research gaps that provided the fundamental insights for developing solutions to these issues and included method development. The second phase focused on evaluating field solutions. The results from this work supported the hypothesis that sudden increase was a result of incomplete inactivation of indicators bacteria. Results suggested that U.S. EPA Method 1680 likely underestimated the viable density of indicators in some samples after thermal treatment, and showed that, to achieve complete inactivation of indicator bacteria, a slightly higher time-temperature regime is likely needed. The project team proposed a new best-practices time-temperature curve. In addition, processes were identified that had a relatively high risk of sudden increase (SI) and regrowth. Gas chromatography-olfactometry was used to identify the persistent/long-term odorants in centrifuged biosolids. The main persistent odorants contributing to cake odors were indole, skatole, p-cresol, and butyric acid. All of these compounds are breakdown products of organics mainly protein as well as carbohydrates and fats, suggesting that processes that remove the readily bioavailable form of these precursors will help reduce odors in biosolids. The results showed that the level of odorants measured after longer-term storage was correlated to the shorter-term total volatile organic compound (TVOSC) concentrations. Several amendments added to centrifuge cake were able to reduce odors and/or regrowth significantly. Incubation of anaerobically digested biosolids with protein-degrading enzymes resulted in additional gas production as well as in a reduction in odorants after dewatering. Also, better digestion was associated with lower odorants, and primary solids produced greater odorant concentrations compared with secondary solids. Longer term storage of biosolids, greater than 20 days at ambient temperatures (15–30°C), was shown in a field trial to produce a product with low odors that met the fecal coliform requirements for Class B biosolids. No benefits between outdoor and indoor storage were measured. This title belongs to WERF Research Report Series ISBN: 9781780404578 (eBook)
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