Biodegradable dissolved organic carbon profiling reveals capacity of carbon-based potable reuse treatment over a range of operating conditions

AWWA water science Pub Date : 2023-10-05 DOI:10.1002/aws2.1355

Matthew F. Blair, Ramola Vaidya, Germano Salazar-Benites, Larry Schimmoller, Tyler Nading, Christopher Wilson, Amy Pruden, Charles Bott

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Abstract

Biological treatment is gaining ground as a means to enhance removal of total organic carbon (TOC) as part of a multi-barrier treatment train for water reuse. Here we applied biodegradable dissolved organic carbon (BDOC) analysis to evaluate the extent of removal of various TOC fractions through a pilot-scale water reuse train employing flocculation/sedimentation, ozone, biologically active carbon (BAC), and granular activated carbon (GAC). BDOC analysis highlighted GAC and ozone treatments as critical to non-biodegradable dissolved organic carbon removal and the need to optimize BAC performance to maximize GAC adsorption capacity. BDOC analysis was further applied to benchmark process performance to operational conditions, such as empty bed contact time (EBCT), occurrence of nitrification, and operational upsets. The lower EBCT proved to be less resilient to nonideal conditions. Overall, BDOC analysis proved an asset for understanding and improving operation of ozone/BAC/GAC treatments for water reuse.

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可生物降解溶解有机碳分析揭示了在一系列操作条件下基于碳的饮用水再利用处理的能力

作为水再利用的多屏障处理系列的一部分，生物处理作为提高总有机碳（TOC）去除率的一种手段正在取得进展。在这里，我们应用可生物降解的溶解有机碳（BDOC）分析，通过采用絮凝/沉淀、臭氧、生物活性炭（BAC）和颗粒活性炭（GAC）的中试规模水再利用系统来评估各种TOC组分的去除程度。BDOC分析强调，GAC和臭氧处理对去除不可生物降解的溶解有机碳至关重要，需要优化BAC性能以最大限度地提高GAC吸附能力。BDOC分析被进一步应用于将工艺性能与操作条件进行比较，如空床接触时间（EBCT）、硝化作用的发生和操作故障。较低的EBCT被证明对非理想条件的弹性较小。总的来说，BDOC分析被证明是理解和改进臭氧/BAC/GAC水再利用处理操作的一项资产。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

AWWA water science

CiteScore

4.40

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0.00%

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