Evaluation of three granular activated carbon filters for the treatment of collections foul air entering a water resource recovery facility.

IF 2.5 4区 环境科学与生态学 Q3 ENGINEERING, ENVIRONMENTAL
Tadeo G Vitko, Scott Cowden, Zhihang Yin, Irwin H Mel Suffet
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引用次数: 0

Abstract

The treatment of raw foul air that could escape to the atmosphere from the head space of the incoming wastewater sewer lines into a Southern California Water Resource Recovery Facility was evaluated by using a 1/20th scale pilot unit consisting of three different granular activated carbon filter technologies, operating side by side, under similar operating conditions, each having an average 3.8-s contact time. The three activated carbon filters contained each 0.07 m3 of coconut, coal, and coconut mixed with permanganate media. The foul air entering the granular activated carbon filters contained 82% to 83% relative humidity. No moisture removal mechanism was used prior to treatment. The removal of six different odor characters from eight chemical odorants present in the foul air were assessed. These were rotten egg (hydrogen sulfide), rotten vegetables (methyl mercaptan), canned corn (dimethyl sulfide), rotten garlic (dimethyl disulfide), earthy/musty (2-methyl isoborneol and 2-isopropyl 3-methoxy pyrazine), and fecal (skatole and indole). This is the first time a study evaluates the removal of specific odors by simultaneously employing sensory analyses using the odor profile method, which defines the different odor characters and intensities, together with chemical analyses of the odorants causing these odors. The results show that the three granular activated carbon filters, before hydrogen sulfide breakthrough, provided significant improvement in odor intensity and odorant removal. Breakthrough was reached after 57 days for the coconut mixed with permanganate, 107 days for the coconut, and 129 days for the coal granular activated carbon filter. Breakthrough (the critical saturation point of the activated carbon media) was considered reached when the hydrogen sulfide percentage removal diminished to 90% and continued downward. The coconut mixed with permanganate granular activated carbon filter provided the best treatment among the media tested, achieving very good reduction of odorants, as measured by chemical analyses, and reasonable removal of odor intensities, as measured by the odor profile method. The coconut mixed with permanganate granular activated carbon is recommended for short-term odor control systems at sewer networks or emergency plant maintenance situations given its shorter time to breakthrough compared with the other granular activated carbons. The coal and coconut granular activated carbon filters are generally used as the last stage of an odor treatment system. Because of the observed poor to average performance in removing odorants other than hydrogen sulfide, the treatment stage(s) prior to the use of these granulated activated carbons should provide a good methyl mercaptan removal of at least 90% in order to avoid the formation of dimethyl disulfide, which, in the presence of moisture in the carbon filter, emit the characteristic rotten garlic odor. The differences observed between the performances based on odorant removal by chemical analysis compared with those based on sensorial analyses by the odor profile method indicate that both analyses are required to understand more fully the odor dynamics. PRACTITIONER POINTS: Three virgin granulated activated carbon media were evaluated in a field pilot unit using raw collections foul air. Coal, coconut, and coconut mixed with permanganate were tested until breakthrough. Samples were analyzed both chemically (odorants) and sensorially (odors). Coconut mixed with permanganate proved to be the media that better reduced odorants and odors.

评估用于处理进入水资源回收设施的收集污气的三种颗粒活性炭过滤器。
在南加州水资源回收设施中,使用了一个 1/20 级的试验装置,该装置由三种不同的颗粒活性炭过滤技术组成,在相似的操作条件下并排运行,每种技术的平均接触时间为 3.8 秒。这三种活性炭过滤器分别含有 0.07 立方米的椰子、煤和椰子混合高锰酸盐介质。进入颗粒活性炭过滤器的污浊空气中含有 82% 至 83% 的相对湿度。处理前未使用除湿机制。评估了从污浊空气中存在的八种化学臭味剂中去除六种不同臭味特征的效果。它们分别是臭鸡蛋(硫化氢)、烂蔬菜(甲硫醇)、玉米罐头(二甲基硫醚)、烂大蒜(二甲基二硫化物)、泥土味/霉味(2-甲基异龙脑和 2-异丙基 3-甲氧基吡嗪)以及粪便味(臭鼬鼠粪和吲哚)。这是首次通过同时使用气味特征法(该方法定义了不同的气味特征和强度)进行感官分析,以及对导致这些气味的气味剂进行化学分析,来评估去除特定气味的效果。结果表明,在硫化氢突破之前,三种颗粒活性炭过滤器在气味强度和气味剂去除方面都有显著改善。与高锰酸盐混合的椰子颗粒活性炭过滤器在 57 天后达到突破,椰子颗粒活性炭过滤器在 107 天后达到突破,煤质颗粒活性炭过滤器在 129 天后达到突破。当硫化氢去除率降至 90% 并继续下降时,即认为达到了突破点(活性炭介质的临界饱和点)。椰子与高锰酸盐混合颗粒活性炭过滤器的处理效果是所有测试介质中最好的,通过化学分析可以很好地减少臭味物质,通过臭味曲线法可以合理地去除臭味强度。与其他颗粒状活性碳相比,椰壳与高锰酸盐混合颗粒状活性碳的突破时间更短,因此建议用于污水管网的短期臭味控制系统或紧急工厂维护情况。煤质和椰壳颗粒活性炭过滤器通常用作臭味处理系统的最后一个阶段。由于观察到除硫化氢以外的臭味剂的去除效果较差或一般,因此在使用这些粒状活性碳之前的处理阶段应能很好地去除至少 90% 的甲硫醇,以避免形成二甲基二硫,二甲基二硫在碳过滤器中存在水分的情况下会散发出特有的腐烂大蒜臭味。根据化学分析得出的气味去除效果与根据气味曲线法得出的感官分析效果之间的差异表明,要想更全面地了解气味的动态变化,就必须同时进行这两种分析。实践点:在现场试验装置中,使用原始收集的污浊空气对三种原始颗粒活性炭介质进行了评估。煤炭、椰子和椰子与高锰酸盐混合后进行了测试,直至取得突破。对样品进行了化学分析(气味物质)和感官分析(气味)。事实证明,与高锰酸盐混合的椰子是能更好地减少臭味剂和气味的介质。
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来源期刊
Water Environment Research
Water Environment Research 环境科学-工程:环境
CiteScore
6.30
自引率
0.00%
发文量
138
审稿时长
11 months
期刊介绍: Published since 1928, Water Environment Research (WER) is an international multidisciplinary water resource management journal for the dissemination of fundamental and applied research in all scientific and technical areas related to water quality and resource recovery. WER''s goal is to foster communication and interdisciplinary research between water sciences and related fields such as environmental toxicology, agriculture, public and occupational health, microbiology, and ecology. In addition to original research articles, short communications, case studies, reviews, and perspectives are encouraged.
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