厌氧水解—生物接触氧化工艺处理低浓度城市污水试验研究
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摘要
本课题针对我国南方城市污水处理工艺现状及存在的问题,结合南方城市污水浓度普遍偏低的特点,提出“厌氧水解—生物接触氧化工艺”。并对该工艺处理低浓度城市污水的处理效果、运行特性、以及生物降解动力学等方面进行了试验研究。
试验研究表明,厌氧水解—生物接触氧化工艺启动快、抗冲击负荷能力强、污泥产率低,出水水质稳定。在常温下,当水力停留时间为6h时,系统对低浓度城市污水处理效果良好,对CODcr、BOD_5、SS、NH_3-N的平均去除率分别为77.6%、80.9%、88.6%、67.4%,其出水可达到国家《污水综合排放标准》(GB8978—1996)一级标准,在回流比为200%时,系统对总氮的去除率可达55.6%,随着回流比的增加,系统对有机物、氨氮、总氮的去除率有所增加。试验得出了厌氧水解段处理低浓度污水的基质降解动力学模型:U=0.002Se,生物接触氧化段处理低浓度污水的基质降解动力学模型:U=263·(S_e-S_n)/226+(S_e-S_n)。
此外,在经济上,厌氧水解—生物接触氧化工艺与传统工艺比较有较大优势,具有投资省、能耗低、处理效率高的特点,对南方城市污水处理厂的建设和工艺改造具有现实意义。
Aiming at the problems in municipal wastewater treatment process, this paper presents Hydrolysis and Bio-contact oxidation process based on the fact of the lower concentration wastewater in South China, and test was made on low concentration sewage treatment effect, operational property, kinetics, and so on.
The test result showed that Hydrolysis and Bio-contact oxidation process can start quickly, work steadily, have low sludge production and excellent ability of bearing high impact loads .Under the normal temperature, when the hydraulic retention time(HRT) is 6h, the general removal rate of CODcr BOD5 suspended solids and ammonia nitrogen are found to be 77.6% 80.9% 88.6% 67.4%. The effluent concentration can up to national primary emission standard of wastewater (GB8978-1996) When the recycle rate is 200%, the removal rate of total nitrogen is 55.6%, and with the increase of recycle rate, the removal rate of organic ammonia nitrogen and total nitrogen will increase. In the test, a kinetics model of organic biodegradation was established , in Hydrolysis tank , which is U=0.002Se , as is
in Bio-contact oxidation tank.
Comparing with traditional treatment process, the costs of construction and operation of Hydrolysis and Bio-contact oxidation process is much lower, Hydrolysis and Bio-contact oxidation has reality significance on the construction and process alteration of wastewater treatment plants in South China
试验研究表明,厌氧水解—生物接触氧化工艺启动快、抗冲击负荷能力强、污泥产率低,出水水质稳定。在常温下,当水力停留时间为6h时,系统对低浓度城市污水处理效果良好,对CODcr、BOD_5、SS、NH_3-N的平均去除率分别为77.6%、80.9%、88.6%、67.4%,其出水可达到国家《污水综合排放标准》(GB8978—1996)一级标准,在回流比为200%时,系统对总氮的去除率可达55.6%,随着回流比的增加,系统对有机物、氨氮、总氮的去除率有所增加。试验得出了厌氧水解段处理低浓度污水的基质降解动力学模型:U=0.002Se,生物接触氧化段处理低浓度污水的基质降解动力学模型:U=263·(S_e-S_n)/226+(S_e-S_n)。
此外,在经济上,厌氧水解—生物接触氧化工艺与传统工艺比较有较大优势,具有投资省、能耗低、处理效率高的特点,对南方城市污水处理厂的建设和工艺改造具有现实意义。
Aiming at the problems in municipal wastewater treatment process, this paper presents Hydrolysis and Bio-contact oxidation process based on the fact of the lower concentration wastewater in South China, and test was made on low concentration sewage treatment effect, operational property, kinetics, and so on.
The test result showed that Hydrolysis and Bio-contact oxidation process can start quickly, work steadily, have low sludge production and excellent ability of bearing high impact loads .Under the normal temperature, when the hydraulic retention time(HRT) is 6h, the general removal rate of CODcr BOD5 suspended solids and ammonia nitrogen are found to be 77.6% 80.9% 88.6% 67.4%. The effluent concentration can up to national primary emission standard of wastewater (GB8978-1996) When the recycle rate is 200%, the removal rate of total nitrogen is 55.6%, and with the increase of recycle rate, the removal rate of organic ammonia nitrogen and total nitrogen will increase. In the test, a kinetics model of organic biodegradation was established , in Hydrolysis tank , which is U=0.002Se , as is
in Bio-contact oxidation tank.
Comparing with traditional treatment process, the costs of construction and operation of Hydrolysis and Bio-contact oxidation process is much lower, Hydrolysis and Bio-contact oxidation has reality significance on the construction and process alteration of wastewater treatment plants in South China
引文
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[3]李克国.城市污水处理厂建设的环境经济政策分析.环境保护,2001.2:11~12
[4]朱国伟.城市污水处理设施的可持续运行研究.城市环境与城市生态,2000,13(5):46~48
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[7]邵林广.南方城市污水处理工艺的选择.给水排水,2000,26(6):32~34
[8]傅德龙.兼氧接触工艺处理造纸中段水中间试验的研究.环境污染与防治,1994,16(3):19~22
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[18]方建章等.水解-好氧-混凝沉淀工艺处理涤纶厂聚酯废水.环境污染与防治,1997,19(6):9~11
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[22]王彩霞.城市污水处理新技术.北京:建筑工业出版社,1990
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[32] Wang Baozhen,Li Jun,el at. Mechanism of phosphorus removal by SBR submerged biofilm system.Water Research 1998,9:2633-2638
[33] Yun, Yeoung-Sang; Lee, Min Woo; Park, Jong Moon; Lee, Choog-Il; Huh, Jae-Sun; Chun, Hee-Dong Reclamation ofwastewater from a steel-making plant using an airlift submerged biofilm reactor Joumal of Chemical Technology and Biotechnology.-1998.73(2).-162-168
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[36] 杜茂安等.生物接触氧化过滤处理生活污水的试验研究.哈尔滨建筑大学学报,2001,34(4):34~36
[37] 吴慧英 黄晟 等.加压生物接触氧化法处理生活污水的试验研究.给水排水,2003,29(6):36~37
[38] 李鑫钢等.生物膜法处理炼油废水.化学工程,2000,28(4):41~43
[39] 陈洪斌等.悬浮填料生物接触氧化法处理炼油废水.中国给水排水,2002,18(9):42~44
[40] Delfin C.Evaluation of the rate of hydrolysis of slowly biodegradable COD(SBCOD) using starch as substrate under anaerobic, anoxic and aerobic conditions. Wat. Sci. Tech, 1994, 30(11):191~199
[41] 周焕祥.水解酸化—生物接触氧化法处理啤酒废水.工业水处理,1998,18(2):36~38
[42] 杨健 王士芬.水解酸化—好氧工艺处理感光材料有机废水研究.环境科学与技术,1999,10(1):34~37
[43] 马汉泽温恒志.水解—生物接触氧化法处理粘合剂废水.环境工程,1999,17(5):11~13
[44] 胡锋平刘建斌.水解酸化—生物接触氧化—气浮工艺处理肉类加工废水.给水排水,2001,27(9):54~55
[45] 古杏红.厌氧水解—生物接触氧化法处理苯胺类化工废水.给水排水,2002,28(1):69~70
[46]姜安玺 李德强等.水解酸化—生物接触氧化工艺在抗生素废水处理中的应用.安全与环境学报,2002,2(2):3~6
[47]胡龙兴等.水解—接触氧化—絮凝工艺处理植物制药废水的试验研究.上海大学学报:自然科学版,2002,8(4):341~344
[48]刘帅霞 何松 水解酸化—生物接触氧化工艺处理印染废水.中国给水排水,2002,18(11):75~76
[49]石金田 张士金.水解酸化—接触氧化—混凝气浮工艺处理高浓度漂染废水.环境污染治理技术与设备,2002,3(12):70~72
[50]国家环保局.水和废水监测分析方法(第三版). 中国环境科学出版社,1989.5
[51]刘军等.厌氧水解生物法处理城市污水的研究.给水排水,2000,26(7):10~13
[52]P.Sauvegrain et al. Anaerobic biofiltration versus aerobic membran filtraion comparison on a difficult substrate. Wat. Sci. Tech,1992,25(10):211~218
[53]李军 王淑莹.水科学与工程实验技术.化学工业出版社,2002
[54]郑俊 等 曝气生物滤池污水处理新技术及工程实例.化学工业出版社,2002
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[2]国家环境保护总局.2001年中国环境状况公报.环境保护,2002,296(6):3~10
[3]李克国.城市污水处理厂建设的环境经济政策分析.环境保护,2001.2:11~12
[4]朱国伟.城市污水处理设施的可持续运行研究.城市环境与城市生态,2000,13(5):46~48
[5]建设部,国家环境保护总局,科技部.城市污水处理及污染防治技术政策.
[6]邵林广.南方城市污水处理厂实际运行水质远小于设计值的原因及对策.给水排水,1999,25(2):11~13
[7]邵林广.南方城市污水处理工艺的选择.给水排水,2000,26(6):32~34
[8]傅德龙.兼氧接触工艺处理造纸中段水中间试验的研究.环境污染与防治,1994,16(3):19~22
[9]张希衡.废水厌氧生物处理工程.北京,中国环境科学出版社,1996
[10]J.B..le Hy, et al.Anaerobic/aerobic treatment of piggery and cheese-dairy wastewater -a case study. Wat. Sci. Tech.1989,21:1861~1864
[11]Collivignarelli C Et al. Anaerobic/aerobic treatment attached biofilm reactors. Wat. Sci. Tech. 1990,22(1): 475~482
[12]G.Garuti et al. Anaerobic/aerobic combined process for the treatment for sewage with nutrient removal:the ANNOX process. Wat. Sci. Tech.1992,25(7):383~394
[13]郑元景等.污水厌氧生物处理.北京:中国建筑工业出版社,1988
[14]王凯军等.城市污水水解(酸化)好氧生物处理工艺研究.环境工程,1991,9(4):32
[15]王聪亮等.水解-好氧系统处理生活污水的特性研究.环境科学与技术,2001,12(2):28~31
[16]李武.水解.好氧生物处理工艺在制药废水处理上的应用.环境工程,1997,15(3):23~26
[17]陶涛等.水解-稳定塘工艺对难降解有机物的去除.环境科学,1993,14(5):47~50
[18]方建章等.水解-好氧-混凝沉淀工艺处理涤纶厂聚酯废水.环境污染与防治,1997,19(6):9~11
[19]李旭东等.水解酸化-好氧生物处理天然脱硫废水的试验研究.环境工程,1999,17(2):19~21
[20]郑元景等.生物膜法处理污水.北京:建筑工业出版社,1983
[21]国家环保局.生物接触氧化处理废水.北京:环境科学出版社,1990
[22]王彩霞.城市污水处理新技术.北京:建筑工业出版社,1990
[23]沈耀良等.固定化微生物污水处理技术.化学工业出版社,2002
[24]F. FdzPolanco, E. Méndez, M.A. Uruena, S. Villaverde and EA. Garcia. Spatial distrbution of heterotrophs and nitrifiers in a submerged biofilter for nitrification. Water. Research.-2000.34(16).-4081-4089
[25]S. González-Martínez, E. Lippert-Heredia, M. Hernández-Esparza, C. Doria-Serrano Reactor kinetics for submerged aerobic biofilms. Bioprocess Engineering.-2000.23(1).-57-61
[26] Vitlaverde, S.; Garcia-Encina, P.A.; Fdz-Polanco, F.. Influence of PH over nitrifying biofilm activity in submergedbiofilters Water Research. 1997.31(5).-1180-1186
[27] S. Villaverde, F. FdzPolanco and P.A. Garcia Nitrifying biofilm acclimation to free ammonia in submerged biofilters. Start-up influence. Water Research.-2000.34(2).-602-610
[28] Charmot-Charbonnel, Marie-Louise; Herment, Sandrine; Roche, Nicolas; Prost, Christian Nitrification of high strength ammonium wastewater in an aerated submerged fixed bed Environmental Progress.- 1999.18(2).- 123-129
[29] Goncalves, Ricardo Franci; de Araujo, Vera Lucia; Chernicharo, Carlos Augusto L.Association of a UASB reactor and a submerged aerated biofilter for domestic sewage treatment Wat. Sci. Tech..- 1998.38(8-9).-189-195
[30] R.F. Gon alves and F. Rogalla Optimising the A/O cycle for phosphorus removal in a submerged biofilter under continuous feed. Wat. Sci. Tech.-2000.41(4-5).-503-508
[31] P.A. Castillo, S. González-Martínez. Observations during start-up of biological phosphorus removal in biofilm reactors Water Science and Technology.-2000.41(4-5).-425-432
[32] Wang Baozhen,Li Jun,el at. Mechanism of phosphorus removal by SBR submerged biofilm system.Water Research 1998,9:2633-2638
[33] Yun, Yeoung-Sang; Lee, Min Woo; Park, Jong Moon; Lee, Choog-Il; Huh, Jae-Sun; Chun, Hee-Dong Reclamation ofwastewater from a steel-making plant using an airlift submerged biofilm reactor Joumal of Chemical Technology and Biotechnology.-1998.73(2).-162-168
[34] 刘贯一.超滤膜作载体的生物接触氧化工艺研究.中国给水排水,2000,16(8):4~7
[35] 李正凯.高负荷生物接触氧化法处理污水的特性.水处理技术,1994,20(1):45~50
[36] 杜茂安等.生物接触氧化过滤处理生活污水的试验研究.哈尔滨建筑大学学报,2001,34(4):34~36
[37] 吴慧英 黄晟 等.加压生物接触氧化法处理生活污水的试验研究.给水排水,2003,29(6):36~37
[38] 李鑫钢等.生物膜法处理炼油废水.化学工程,2000,28(4):41~43
[39] 陈洪斌等.悬浮填料生物接触氧化法处理炼油废水.中国给水排水,2002,18(9):42~44
[40] Delfin C.Evaluation of the rate of hydrolysis of slowly biodegradable COD(SBCOD) using starch as substrate under anaerobic, anoxic and aerobic conditions. Wat. Sci. Tech, 1994, 30(11):191~199
[41] 周焕祥.水解酸化—生物接触氧化法处理啤酒废水.工业水处理,1998,18(2):36~38
[42] 杨健 王士芬.水解酸化—好氧工艺处理感光材料有机废水研究.环境科学与技术,1999,10(1):34~37
[43] 马汉泽温恒志.水解—生物接触氧化法处理粘合剂废水.环境工程,1999,17(5):11~13
[44] 胡锋平刘建斌.水解酸化—生物接触氧化—气浮工艺处理肉类加工废水.给水排水,2001,27(9):54~55
[45] 古杏红.厌氧水解—生物接触氧化法处理苯胺类化工废水.给水排水,2002,28(1):69~70
[46]姜安玺 李德强等.水解酸化—生物接触氧化工艺在抗生素废水处理中的应用.安全与环境学报,2002,2(2):3~6
[47]胡龙兴等.水解—接触氧化—絮凝工艺处理植物制药废水的试验研究.上海大学学报:自然科学版,2002,8(4):341~344
[48]刘帅霞 何松 水解酸化—生物接触氧化工艺处理印染废水.中国给水排水,2002,18(11):75~76
[49]石金田 张士金.水解酸化—接触氧化—混凝气浮工艺处理高浓度漂染废水.环境污染治理技术与设备,2002,3(12):70~72
[50]国家环保局.水和废水监测分析方法(第三版). 中国环境科学出版社,1989.5
[51]刘军等.厌氧水解生物法处理城市污水的研究.给水排水,2000,26(7):10~13
[52]P.Sauvegrain et al. Anaerobic biofiltration versus aerobic membran filtraion comparison on a difficult substrate. Wat. Sci. Tech,1992,25(10):211~218
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