焦化废水处理过程中新兴的 VOCs 和 SVOCs 关注点:分布特征、排放特性和健康风险评估。
Emerging concerns of VOCs and SVOCs in coking wastewater treatment processes: Distribution profile, emission characteristics, and health risk assessment.
机构信息
State Key Laboratory of Environmental Aquatic Chemistry, Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing, 100085, China; University of Chinese Academy of Sciences, Beijing, 100049, China; Pesticide Residues and Environmental Pollution Department, Central Agricultural Pesticide Laboratory, Agricultural Research Center, Dokki, Giza, 12618, Egypt.
State Key Laboratory of Environmental Aquatic Chemistry, Research Center for Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing, 100085, China; University of Chinese Academy of Sciences, Beijing, 100049, China.
出版信息
Environ Pollut. 2020 Oct;265(Pt B):114960. doi: 10.1016/j.envpol.2020.114960. Epub 2020 Jun 8.
In this study, the distribution profiles, emission characteristics, and health risks associated with 43 volatile and semi-volatile organic compounds, including 15 phenols, 18 polycyclic aromatic hydrocarbons (PAHs), 6 BTEX, and 4 other compounds, were determined in the wastewater treatment plant (WWTP) of a coking factory (plant C) and the succeeding final WWTP (central WWTP). Total phenols with a concentration of 361,000 μg L were the predominant compounds in the influent wastewater of plant C, whereas PAHs were the major compounds in the final effluents of both coking WWTPs (84.4 μg L and 30.7 μg L, respectively). The biological treatment process in plant C removed the majority of volatile organic pollutants (94.1%-99.9%). A mass balance analysis for plant C showed that biodegradation was the main removal pathway for all the target compounds (56.6%-99.9%) except BTEX, chlorinated phenols, and high molecular weight (MW) PAHs. Chlorinated phenols and high MW PAHs were mainly removed via sorption to activated sludge (51.8%-73.2% and 60.2%-75.9%, respectively). Air stripping and volatilization were the dominant mechanisms for removing the BTEX compounds (59.8%-73.8%). The total emission rates of the detected volatile pollutants from plant C and the central WWTP were 1,640 g d and 784 g d, respectively. Benzene from the equalization basins of plant C and the central WWTP corresponded to the highest inhalation carcinogenic risks (1.4 × 10 and 3.2 × 10, respectively), which exceeded the acceptable level for human health (1 × 10) recommended by the United States Environmental Protection Agency. The results showed that BaP exhibited the highest inhalation non-cancer risk, with a hazard index ratio of 70 and 30 for plant C and the central WWTP, respectively. Moreover, the excess sludge generated during wastewater treatment should also be carefully handled because it adsorbed abundant PAHs and chlorinated phenols at coking plant C (58,000 μg g and 3,500 μg g) and the central WWTP (622 μg g and 54 μg g).
在这项研究中,测定了焦化厂污水处理厂(C 厂)和后续的最终污水处理厂(中央污水处理厂)中 43 种挥发性和半挥发性有机化合物(包括 15 种酚类化合物、18 种多环芳烃(PAHs)、6 种 BTEX 和 4 种其他化合物)的分布特征、排放特征和与健康相关的风险。C 厂进水废水中,以总酚(浓度为 361,000μg/L)为主,焦化污水处理厂最终出水则以 PAHs(分别为 84.4μg/L 和 30.7μg/L)为主。C 厂的生物处理过程去除了大部分挥发性有机污染物(94.1%-99.9%)。对 C 厂的质量平衡分析表明,除 BTEX、氯化酚和高分子量(MW)PAHs 外,生物降解是所有目标化合物(56.6%-99.9%)的主要去除途径。氯化酚和高分子量 PAHs 主要通过吸附到活性污泥中去除(51.8%-73.2%和 60.2%-75.9%)。汽提和挥发是去除 BTEX 化合物的主要机制(59.8%-73.8%)。C 厂和中央污水处理厂检测到的挥发性污染物的总排放量分别为 1,640g/d 和 784g/d。C 厂和中央污水处理厂均衡池中的苯分别对应最高的吸入致癌风险(分别为 1.4×10 和 3.2×10),超过了美国环境保护署(United States Environmental Protection Agency)推荐的人类健康可接受水平(1×10)。结果表明,BaP 具有最高的吸入非致癌风险,对于 C 厂和中央污水处理厂,危害指数比分别为 70 和 30。此外,在污水处理过程中产生的剩余污泥也应谨慎处理,因为它在焦化厂 C 厂(58,000μg/g 和 3,500μg/g)和中央污水处理厂(622μg/g 和 54μg/g)中吸附了大量的 PAHs 和氯化酚。
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