溶解氧对生物滤柱中氨氮、铁、锰去除效果的影响

doi:10.16085/j.issn.1000-6613.2019-1656

摘要/Abstract

摘要：

为了研究溶解氧变化对生物滤柱中氨氮、铁、锰去除效果的影响，将进水溶解氧从约10.5mg/L逐步降到7mg/L，本文考察了氨氮、铁、锰的变化规律。结果表明：当溶解氧为约10.5mg/L时，出水氨氮、总铁、锰分别为0.050mg/L、0.065mg/L、0.022mg/L，氨氮、铁、锰分别主要在滤层的0～1.2m、0～0.4m、0～1.2m去除。当溶解氧降到约9mg/L、8mg/L、7mg/L时，出水总铁均低于0.1mg/L；出水锰先明显升高，后又降到了0.05mg/L以下；出水氨氮分别升高到0.17mg/L、0.41mg/L、0.61mg/L。溶解氧不足时，铁主要在溶解氧充足的上部滤层去除；锰氧化菌优先利用溶解氧氧化二价锰，并且锰的氧化速率没有明显降低；氨氮的氧化速率明显降低。生物滤柱可以在较低溶解氧条件下运行，从而降低运行成本。

关键词: 生物滤柱, 氨氮、铁、锰, 溶解氧, 地下水

Abstract:

In order to study the influence of dissolved oxygen (DO) on the removal efficiency in biofilter, as well as the variation rule of ammonia, iron and manganese, the DO was gradually reduced from about 10.5mg/L to 7mg/L. The results showed that when DO was about 10.5mg/L, the concentration of ammonia, total iron and manganese in effluent were 0.050mg/L, 0.065mg/L and 0.022mg/L, respectively, and ammonia, iron and manganese were mainly removed at 0—1.2m, 0—0.4m and 0—1.2m of the filter layer, respectively. When DO was reduced to about 9mg/L, 8mg/L and 7mg/L, total iron in effluent was lower than 0.1mg/L; manganese in effluent increased significantly at first, then decreased to below 0.05mg/L; and ammonia in effluent increased to 0.17mg/L, 0.41mg/L and 0.61mg/L, respectively. When DO was insufficient, iron was mainly removed in the upper filter layer where DO was sufficient; DO was preferentially used by manganese oxidizing bacteria to oxidize manganese dioxide, and the oxidation rate of manganese was not significantly reduced; the oxidation rate of ammonia was significantly reduced. Thus, biofilter could be operated under lower DO conditions to reduce the operation cost.

Key words: biofilter, ammonia, iron and manganese, dissolved oxygen, groundwater

中图分类号:

能子礼超, 胡金朝, 邓雪梅, 曾景江, 钟林, 余茜茹, 江道澳. 溶解氧对生物滤柱中氨氮、铁、锰去除效果的影响[J]. 化工进展, 2020, 39(7): 2900-2906.

Lichao NENGZI, Jinzhao HU, Xuemei DENG, Jingjiang ZENG, Lin ZHONG, Qianru YU, Dao’ao JIANG. Influence of dissolved oxygen on removal efficiency of ammonia,iron and manganese in biofilter[J]. Chemical Industry and Engineering Progress, 2020, 39(7): 2900-2906.

参考文献

1	曾辉平. 含高浓度铁锰及氨氮的地下水生物净化效能与工程应用研究[D]. 哈尔滨: 哈尔滨工业大学, 2010.
1	ZENG H P. Biological purification of iron, manganese and ammonia with high concentration in groundwater and engineering application[D]. Haerbin: Harbin Institute of Technology, 2010.
2	TEKERLEKOPOULOU A G, VAYENAS D V. Simultaneous biological removal of ammonia, iron and manganese from potable water using a trickling filter[J]. Biochemical Engineering Journal, 2008, 39: 215-220.
3	AZHER N E, GOURICH B, VIAL C, et al. Study of ferrous iron oxidation in Morocco drinking water in an airlift reactor[J]. Chemical Engineering and Processing, 2008, 47: 1877-1886.
4	ZENG X P, XIA J, WANG Z Z, et al. Removal of iron and manganese in steel industry drainage by biological activated carbon[J]. Desalination Water Treatment, 2015, 56: 2543-2550.
5	CHENG Q, HUANG Y, NENGZI L C, et al. Performance and microbial community profiles in pilot-scale biofilter for the simultaneous removal of ammonia, iron and manganese at different manganese concentrations[J]. Bioprocess and Biosystems Engineering, 2019, 42(5): 741-752.
6	HASAN H A, ABDULLAH S R S, KAMARUDIN S K, et al. On-off control of aeration time in the simultaneous removal of ammonia and manganese using a biological aerated filter system[J]. Process Safety and Environmental Protection, 2013, 91: 415-422.
7	CAI Y, LI D, LIANG Y, et al. Effective start-up biofiltration method for Fe, Mn, and ammonia removal and bacterial community analysis[J]. Bioresource Technology, 2015, 176: 149-155.
8	HAN M,ZHAO Z,GAO W, et al. Study on the factors affecting simultaneous removal of ammonia and manganese by pilot-scale biological aerated filter (BAF) for drinking water pre-treatment[J]. Bioresource Technology, 2013, 145: 17-24.
9	LI X, CHU Z, LIU Y, et al. Molecular characterization of microbial populations in fullscale biofilters treating iron, manganese and ammonia containing groundwater in Harbin[J]. China Bioresource Technology, 2013, 147: 234-239.
10	程庆锋, 李冬, 李相昆, 等. 反冲洗周期对生物除锰滤池去除效果的影响[J]. 环境工程学报, 2014, 8(1): 72-76.
10	CHENG Q F, LI D, LI X K, et al. Influence of backwashing period on removal efficiency in a biological manganese removal filter[J]. Chinese Journal of Environmental Engineering, 2014, 8(1): 72-76.
11	李冬, 张杰, 王洪涛, 等. 除铁除锰生物滤层内铁的氧化去除机制探讨[J]. 哈尔滨工业大学学报, 2007, 39(8): 1323-1326．
11	LI D, ZHANG J, WANG H T, et al.Study on the mechanism of Fe²⁺ oxidation and removal in the biological filter for iron and manganese removal[J]. Journal of Harbin Institute of Technology, 2007, 39(8): 1323-1326.
12	李冬, 曹瑞华, 杨航, 等. 硝化耦合CANON的铁锰氨生物净化工艺启动与运行[J]. 环境科学, 2018, 39(3): 1264-1271.
12	LI D, CAO R H, YANG H, et al. Start-up and operation of biofilter coupled nitrification and CANON for the removal of iron, manganese and ammonia nitrogen[J]. Environmental Science, 2018, 39(3): 1264-1271.
13	CHENG Q F, NENGZI L C, BAO L, et al. Distribution and genetic diversity of microbial populations in the pilot-scale biofilter for simultaneous removal of ammonia, iron and manganese from real groundwater[J]. Chemosphere, 2017, 182: 450-457.
14	CHENG Q F, HUANG Y, NENGZI L C, et al. Performance and microbial community profiles in pilot-scale biofilter for ammonia, iron and manganese removal at different dissolved oxygen concentrations[J]. World Journal of Microbiology and Biotechnology, 2019, 35: 43.
15	CHENG Q F, NENGZI L C, BAO L, et al. Interactions between ammonia, iron and manganese removal using pilot-scale biofilters[J]. Journal of Water Supply: Research and Technology-AQUA, 2017, 66(3): 157-165.
16	TEKERLEKOPOULOU A G, VAYENAS D V. Ammonia, iron and manganese removal from potable water using trickling filters[J]. Desalination, 2007, 210: 225-235.
17	HASAN H A, ABDULLAH A R S, KOFLI N T, et al. Effective microbes for simultaneous bio-oxidation of ammonia and manganese in biological aerated filter system[J]. Bioresource Technology, 2012, 124: 355-363.
18	HASAN H A, ABDULLAH S R S, KAMARUDIN S K, et al. Effective curves of completing simultaneous ammonium and manganese removal in polluted water using a biological aerated filter[J]. Journal of Industrial & Engineering Chemistry, 2015, 30: 153-159.
19	程庆锋, 能子礼超, 徐冬莹, 等. 两级生物滤柱同时去除地下水中铁、锰、氨氮和浊度[J]. 中国给水排水, 2016, 32(21): 50-54.
19	CHENG Q F, NENGZI L C, XU D Y, et al. Simultaneous removal of iron, manganese, ammonia and turbidity from groundwater using two-stage biofilters[J]. China Water & Wastewater, 2016, 32(21): 50-54.
20	程庆锋, 李冬, 李相昆, 等. 高铁锰氨氮地下水生物净化滤池的快速启动[J]. 哈尔滨工业大学学报, 2013, 45(8): 41-44.
20	CHENG Q F, LI D, LI X K, et al. Rapid start-up of biological purifying filter of groundwater containing high concentration of iron and manganese associated ammonia nitrogen[J]. Journal of Harbin Institute of Technology, 2013, 45(8): 41-44.
21	HASAN H A, ABDULLAH S R S, KAMARUDIN S K, et al. Effective curves of completing simultaneous ammonium and manganese removal in polluted water using a biological aerated filter[J]. Journal of Industrial & Engineering Chemistry, 2015, 30: 153-159.
22	DU X, LIU G Y, QU F S, et al. Removal of iron, manganese and ammonia from groundwater using a PAC-MBR system: the anti-pollution ability, microbial population and membrane fouling[J]. Desalination, 2017, 403: 97-106.
23	CHENG Q F, NENGZI L C, XU D, et al. Influence of nitrite on the removal of Mn(Ⅱ) using pilot-scale biofilters[J]. Journal of Water Reuse and Desalination, 2017, 7(3): 264-271.
24	程庆锋, 李冬, 李相昆, 等. 净化高铁锰伴生氨氮地下水的生物滤池快速启动[J]. 中国给水排水, 2013, 29(7): 41-44.
24	CHENG Q F, LI D, LI X K, et al. Rapid start-up of biofilter purifying groundwater containing high concentrations of iron, manganese and ammonia nitrogen[J]. China Water & Wastewater, 2013, 29(7): 41-44.
25	程庆锋, 余静, 能子礼超, 等. 氨氮对生物净化滤柱中铁锰氨氮去除效果的影响[J]. 环境工程学报, 2016, 10(11): 6371-6377.
25	CHENG Q F, YU J, NENGZI L C, et al. Effects of ammonia on efficiency of iron，manganese and ammonia removal in biological purifying filter[J]. Chinese Journal of Environmental Engineering, 2016, 10(11): 6371-6377.
26	HASAN H A, ABDULLAH S R S, KAMARUDIN S K, et al. Kinetic evaluation of simultaneous cod, ammonia and manganese removal from drinking water using a biological aerated filter system[J]. Separation & Purification Technology, 2014, 130: 56-64.
27	TEKERLEOPOULOU A G, PAVLOU S, VAYENAS D V. Removal of ammonium, iron and manganese from potable water in biofiltration units: a review[J]. Journal of Chemical Technology and Biotechnology, 2013, 88: 751-773.
28	CHENG Q F. Competitive mechanism of ammonia, iron and manganese for dissolved oxygen using pilot-scale biofilter at different dissolved oxygen concentrations[J]. Water Science & Technology: Water Supply, 2016, 16(3): 766-774.

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