石河子市城市污水处理及农业回用研究
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摘要
根据新疆石河子市目前水资源及水环境的现状,分析了城市污水回用于农业(包括林业、草业)灌溉的可行性与必要性。针对该市城市污水浓度高的水质特点以及污水处理后既考虑农业回用,又考虑排入水库的实际情况。通过比较,选择SBR工艺进行了污水处理试验。试验表明:SBR工艺可有效地应用于处理高浓度城市污水,在试验条件下,COD、TP的去除率高达90%左右,TN、氨氮的去除率可达70%左右。另外,本工艺可根据污水不同的出路,调整运行方式,使出水达到污水综合一级排放标准和农田灌溉水质标准。得出了污水回用于农业灌溉和排放天然水体的运行参数。
城市污水回用于农业的最大障碍是重金属污染等问题,但活性污泥法对污水中重金属的去除率试验国内尚无报道。因此,试验还对SBR法去除重金属的情况进行了探讨。研究表明:SBR法对重金属汞、镉、铅均有较好的去除效果。当进水浓度满足城市下水道排放标准时,处理后,汞、铅的出水浓度可满足农灌标准,但镉的出水浓度仍不能满足农灌标准,尚需进一步处理。六价铬及总铬在其进水浓度满足城市下水道水质排放标准时,虽去除率不高,但其出水浓度仍可满足农田灌溉要求。
According to the present conditions of the water resousce and water environment in Shehezi City, Xingjian, the thesis analyzes the feasibility and necessity of the wasterwater reuse in agriculture (including forestry and grassland ) irrigation. In the light of the high water contaminant level and the practical situation that after the wasterwater treatment, the agriculture reuse and the discharge into the reservoir should be considered, the sequencing batch reacater (SBR) technics is used in the wastewater treatment after comparison. The experiment indicates that the SBR technics functions effectively in the treatment of the heavy concentration wastewater. The reduction rate of chemical oxygen demanded (COD) and total phosphate (TP) could up to 90%, and that of total nitrogen (TN) and ammonial nitrogen (NH4-N) could reach 70% under experiment. In addition, the SBR technics can adjust the operation patterns on the basis of the different drainage ways of the wastewater, and so the treated water can meet the gr
ade one of Integrate Wastewater Discharge Standard and the Standards for Irrigation Water Quality. The operational parameter, which is used when the wastewater reused in agriculture irrigation or discharged into reservoir, is also worked out there.
The greastest obstacle to the wastewater's reuse in agriculture irrigation is the heavy metal pollution and etc. But till now, there havan't any report about the reduction rate experiment of the activated sludge process used to eliminate the heavy metal. Thus, this experiment also reasearched that the SBR technics functions to eliminate the heavy metal. The research states that the SBR technics can work well in the elimination of these heavy metal, such as mercury (Hg), cdmium (Cd) and lead (Pb), when the inflow concentration meets the standards for municipal wastewater discharge into sewer drainage, after treatment, mercury's and lead's outlet water concentration could reach the agriculture irrigation standards; But cdmium's can't, and it needs to be treated further. And so does the hexavalent chromium (Cr6+) and total chromium (Tr); even if their reduction rate are not so hige, their outlet water concentration still could reach the agriculture irrigation standards.
城市污水回用于农业的最大障碍是重金属污染等问题,但活性污泥法对污水中重金属的去除率试验国内尚无报道。因此,试验还对SBR法去除重金属的情况进行了探讨。研究表明:SBR法对重金属汞、镉、铅均有较好的去除效果。当进水浓度满足城市下水道排放标准时,处理后,汞、铅的出水浓度可满足农灌标准,但镉的出水浓度仍不能满足农灌标准,尚需进一步处理。六价铬及总铬在其进水浓度满足城市下水道水质排放标准时,虽去除率不高,但其出水浓度仍可满足农田灌溉要求。
According to the present conditions of the water resousce and water environment in Shehezi City, Xingjian, the thesis analyzes the feasibility and necessity of the wasterwater reuse in agriculture (including forestry and grassland ) irrigation. In the light of the high water contaminant level and the practical situation that after the wasterwater treatment, the agriculture reuse and the discharge into the reservoir should be considered, the sequencing batch reacater (SBR) technics is used in the wastewater treatment after comparison. The experiment indicates that the SBR technics functions effectively in the treatment of the heavy concentration wastewater. The reduction rate of chemical oxygen demanded (COD) and total phosphate (TP) could up to 90%, and that of total nitrogen (TN) and ammonial nitrogen (NH4-N) could reach 70% under experiment. In addition, the SBR technics can adjust the operation patterns on the basis of the different drainage ways of the wastewater, and so the treated water can meet the gr
ade one of Integrate Wastewater Discharge Standard and the Standards for Irrigation Water Quality. The operational parameter, which is used when the wastewater reused in agriculture irrigation or discharged into reservoir, is also worked out there.
The greastest obstacle to the wastewater's reuse in agriculture irrigation is the heavy metal pollution and etc. But till now, there havan't any report about the reduction rate experiment of the activated sludge process used to eliminate the heavy metal. Thus, this experiment also reasearched that the SBR technics functions to eliminate the heavy metal. The research states that the SBR technics can work well in the elimination of these heavy metal, such as mercury (Hg), cdmium (Cd) and lead (Pb), when the inflow concentration meets the standards for municipal wastewater discharge into sewer drainage, after treatment, mercury's and lead's outlet water concentration could reach the agriculture irrigation standards; But cdmium's can't, and it needs to be treated further. And so does the hexavalent chromium (Cr6+) and total chromium (Tr); even if their reduction rate are not so hige, their outlet water concentration still could reach the agriculture irrigation standards.
引文
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[32].羊寿生.一体化活性污泥法UNITANK工艺及其应用.给水排水,1998,24(11):16~17.
[33].李探微等.一种新的污水处理技术—MSBR法.给水排水,1999,25(6):10~12.
[34].熊建英等.连续流SBR法处理城市污水试验研究.中国给水排水,1999,15(8):9~15.
[35].彭永臻等.两段SBR法处理石油化工废水.给水排水,1996,22(6):26~28.
[36].詹伯君等.膜法SBR工艺处理印染废水工程设计.给水排水,1997,23(7):25~28.
[37].段雨.序批式活性污泥法综述.设计与研究,1995,239~253.
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[39].吕锡武等.溶解氧及活性污泥浓度对同步硝化反硝化的影响.城市环境与城市生态.2001,14(1):33-35.
[40].赵旭涛.城市污水生物脱氮技术研究[J],上海环境科学,1995,14(9):17-20.
[41].高廷耀等.一种适合当前国情的城市污水脱氮除磷新工艺[J],同济大学学报,1996,24(6):647-651.
[42].陈永祥.SBR运行控制与处理生活污水的试验研究:[学位论文].武汉:武汉大学土建学院,2002.
[43].徐亚同等.不同碳源对生物反硝化的影响.环境科学,1993,15(2):29~32.
[44].赵旭涛.强化反硝化作用及机理分析.中国给水排水,1997,13(5):15~16.
[45].朱淑琴等.间歇式活性污泥硝化与反硝化的试验研究,1999,17(1):11~13.
[46].郑兴灿等.污水除磷脱氮技术.北京:中国建筑工业出版社,1999.
[47]. Rensink J H 等, Phosphorus Removal at Low Sludge Loading. War Sci Tech, 1985, 17(11~12):
177~186.
[48].刘俊新等.高浓度氨氮废水生物脱氮最佳运行条件控制.哈尔滨建筑大学学报,1995,28(5):69~71
[49].曾薇等.pH值与温度对SBR法反应时间控制的影响,中国环境科学.2002,22(5):456~459.
[50].高景锋等.不同碳源及投加量对SBR法反硝化速率的影响.给水排水,2001,27(5):55~58.
[51].沈振荣等编.中国农业水危机对策研究[M].北京:中国农业科技出版社,1998:49,61-62.
[52].刘昌明等编.中国水资源现状评价和供需发展趋势分析[M].北京:中国水利水电出版社,2001:2,32-34.182.
[53]. Koeppe D E. Lead: Understanding the minimal toxic of lead in plants[A]. In Effect of Heavy Metal Pollution on Plants[M]. (ed by L W Lepp), App Sci Pub London and New Jersey, 1981, 1: 55~75.
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[56].冯绍元等.重金属在小麦作物体中残留特征的田间试验研究.农业工程学报,2002,18(4):113~115.
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[64].刘坤一.论北京城市污水资源化的开发利用及其对策,北京建筑工程学院学报,2001,17:74~78.
[2].姚枫.我区城市污水处理程度探讨.干旱环境监测,1999,13(4):219~221.
[3].王德荣等.水资源与农业可持续发展[M].北京:北京出版社,2000,263-328.
[4].张晶心.城市污水再生与农业再用.重庆环境科学,1994,16(2):35-37.
[5].古智生.以色列水资源的开发与利用.节水灌溉,1999,6:34~35.
[6].曾令芳等.国外污水灌溉新技术.节水灌溉,2002,3:34~42.
[7].李芳柏等.城市污水处理与农业回用辨析.农业环境保护,1998,17(5):237-239.
[8].刘润堂等.我国污水灌溉现状、问题及其对策.中国水利,2002,10:123~125.
[9].张自杰主编.排水工程(第三版,下册)[M].北京:中国建筑工业出版社,1996.
[10].耿安朝等.废水生物处理发展与实践[M].沈阳:东北大学出版社,1997.
[11]. Irvine R. L.等, Investigation of Fill and Batch Periods of Sequencing Batch Biological Reactors. Wat. Res. 1977, 11: 713~717.
[12]. Irvine R.L.等, Sequencing Batch Biological Reactors-Sn Overview. JWPCF, 1979, 51 : 235
[13]. Irvine R. L.等, Municipal Application of Sequencing Batch Treatment at Culver. JWPCF, 1983, 55: 484.
[14]. Irvine R. L.等, Sequencing Batch Reactor for Biological Wastewater Treatmeng. CRC Crit. Rev. Environ Control. 1988, 18: 255.
[15]. Irvine R. L.等, Controlled Unsteady State Processes and Technologies-An Overview. Wat. Sci. Tech., 1997, (1): 1~10.
[16].何耘等.序批式活性污泥法(SBR)的研究综述.安徽建筑工业学报(自然科学版).1998,6(1):47~49.
[17].诸国红.SBR技术综述.交通环保,1997,16(2);34~35.
[18].刘建林.序批式活性污泥工艺(SBR)运行模式和设计方法研究:[硕士论文],1994.
[19].张大群.序批式活性污泥法(SBR)技术及关健设备研究探讨.中国环保产业,1996,12:30~32.
[20].任立斌.一种新型水处理方法——SBR法.北京轻工业学院学报,1998,16(2):11~15.
[21].彭永臻.SBR法的五大优点.中国给水排水,1993,9(2):29~31.
[22].王文标等.SBR法在埋地式小型污水处理中的应用.化工给排水设计,1998,1:21~22.
[23].严煦世.水和废水技术研究.北京:中国建筑工业出版社,1992.257~264.
[24].浜本洋一等.间歇式活性污泥法废水处理技术.国外环境科学技术,1987(1):19~24.
[25].张自杰等.三废处理实用技术.北京:中国环境出版社,1999.533~537
[26].Goronszy M.C.等.循环式活性污泥法(CAST)的应用及其发展.中国给水排水,1996,12(6):4~6.
[27].周雹.SBR工艺的分类和特点.给水排水,2001,27(2):31~33.
[28].陈庆星等.昆明市第三污水处理厂(ICEAS)工艺简介.给水排水,1994,20(8):17~20.
[29].邱慎初.循环式活性污泥法(CAST).中国土木工程学会排水委员会三届二次年会论文集,1997.
[30].冯生华.澳大利亚IDEA工艺污水处理厂工艺简介.给水排水,1996,22(11):26~27.
[31].张大群等.SBR工艺新DAT-IAT法及新型滗水器.中国给水排水,1996,12(1):26~29.
[32].羊寿生.一体化活性污泥法UNITANK工艺及其应用.给水排水,1998,24(11):16~17.
[33].李探微等.一种新的污水处理技术—MSBR法.给水排水,1999,25(6):10~12.
[34].熊建英等.连续流SBR法处理城市污水试验研究.中国给水排水,1999,15(8):9~15.
[35].彭永臻等.两段SBR法处理石油化工废水.给水排水,1996,22(6):26~28.
[36].詹伯君等.膜法SBR工艺处理印染废水工程设计.给水排水,1997,23(7):25~28.
[37].段雨.序批式活性污泥法综述.设计与研究,1995,239~253.
[38].国家环保总局.水和废水监测分析方法(第四版)[M].北京:中国环境科学出版社,2002.
[39].吕锡武等.溶解氧及活性污泥浓度对同步硝化反硝化的影响.城市环境与城市生态.2001,14(1):33-35.
[40].赵旭涛.城市污水生物脱氮技术研究[J],上海环境科学,1995,14(9):17-20.
[41].高廷耀等.一种适合当前国情的城市污水脱氮除磷新工艺[J],同济大学学报,1996,24(6):647-651.
[42].陈永祥.SBR运行控制与处理生活污水的试验研究:[学位论文].武汉:武汉大学土建学院,2002.
[43].徐亚同等.不同碳源对生物反硝化的影响.环境科学,1993,15(2):29~32.
[44].赵旭涛.强化反硝化作用及机理分析.中国给水排水,1997,13(5):15~16.
[45].朱淑琴等.间歇式活性污泥硝化与反硝化的试验研究,1999,17(1):11~13.
[46].郑兴灿等.污水除磷脱氮技术.北京:中国建筑工业出版社,1999.
[47]. Rensink J H 等, Phosphorus Removal at Low Sludge Loading. War Sci Tech, 1985, 17(11~12):
177~186.
[48].刘俊新等.高浓度氨氮废水生物脱氮最佳运行条件控制.哈尔滨建筑大学学报,1995,28(5):69~71
[49].曾薇等.pH值与温度对SBR法反应时间控制的影响,中国环境科学.2002,22(5):456~459.
[50].高景锋等.不同碳源及投加量对SBR法反硝化速率的影响.给水排水,2001,27(5):55~58.
[51].沈振荣等编.中国农业水危机对策研究[M].北京:中国农业科技出版社,1998:49,61-62.
[52].刘昌明等编.中国水资源现状评价和供需发展趋势分析[M].北京:中国水利水电出版社,2001:2,32-34.182.
[53]. Koeppe D E. Lead: Understanding the minimal toxic of lead in plants[A]. In Effect of Heavy Metal Pollution on Plants[M]. (ed by L W Lepp), App Sci Pub London and New Jersey, 1981, 1: 55~75.
[54].陈怀满等.土壤-植物系统中的重金属污染[M].北京:科学出版社,1996.
[55].杨景辉.土壤污染与防治[M].北京:科学出版社,1995,167~181.
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