废水化学除磷的试验、理论与应用研究
|
摘要
本文主要研究了废水化学沉淀法除磷以使废水能达标排放的试验条件,化学除磷投药量的确定以及化学除磷的作用机理,并将研究成果应用于工程实践。
首先对废水中磷的污染及除磷技术,尤其是生物除磷和化学除磷技术进行了比较,总结和展望。文章认为,磷污染是废水富营养化的关键因素,废水中总磷通过生物法处理往往不能达到排放标准,所以有必要研究废水的化学法除磷。化学法除磷关键在于药剂的选择和沉淀条件的控制,化学法除磷要和生物法除磷综合起来进行考虑。
随后对污水处理厂的二级出水进行了化学除磷药剂筛选试验和条件试验。通过对铁盐、铝盐和钙盐分别做实验,认为铝盐的除磷效果要优于铁盐,铁盐的除磷效果要优于钙盐。在此基础上,对各药剂做了搅拌时间、pH值等的条件试验,并确立了各混凝剂的最佳混凝条件:搅拌时间为15分钟左右;铝盐的最佳pH范围是6.5左右,铁盐的最佳pH范围是9~10,钙盐在pH>10时能获得较好的处理效果。
为了了解混凝沉淀结构,对模拟含磷废水混凝后产生的沉淀物做了能谱分析,通过确定各主要元素的重量比和原子数之比而推测出沉淀物结构,为机理研究奠定基础。
为了寻找确定化学除磷药剂投加量的简单快捷的方法,通过大量实验作出了投药系数与投加量的关系图,从而可以方便的根据关系图估算出化学除磷,尤其是低磷废水的化学除磷药剂的投加量。
在以上试验的基础上,对化学除磷的作用过程机理进行了探讨,并分别分析了铁盐、铝盐和PAM的作用过程。分析结果表明,化学除磷包含以下过程:混凝剂的溶解与水解;金属离子与磷酸根离子形成不溶性磷酸盐;金属氢氧化物对磷酸盐沉淀的吸附,凝聚;助凝剂的架桥,捕罗,絮凝;沉淀物的沉降、分离。
在此基础上,我们对某工程的化学除磷进行了实际调试与研究,得到了较好的处理效果。
The technical conditions of phosphorus removal by chemistry precipitation and quantity of reagent used in the experiments as well as mechanism of phosphorus removal by chemical method were studied in this paper. And the result of experiments studied in the lab was applied in a case of wastewater treatment project.
At first, the paper compared, summarized and prospected the technology, especially microbial technology and chemical technology of phosphorus removal in wastewater. The paper deemed that the phosphorus pollution was a key factor of abundant nutrition in the water. But the standard of phosphorus in wastewater can't reach the standard of discharge only by microbial method. Thus, it is necessary to study the phosphorus removal by chemical method. The main part of the study was about the reagent selection, the controlling of precipitation conditions and the combination of chemical methods with biological methods.
Then we did the experiments of reagent selection and conditions of phosphorus removal by chemistry precipitation in the second effluence water. According to experiments, the paper considered that the aluminum ion was the best reagent in removing phosphorus and the iron ion followed it and then was the calcium ion. Based on this, we did experiments of conditions such as mill time and pH value of each reagent. The best precipitation conditions were: the mill time was about 15 minutes; the pH value of aluminum ion was about 6.5; the pH value of iron ion was from 9 to 10; the pH value of calcium ion was above 10.
In order to find out the form of the deposition, we did an energy spectrum analysis on deposition of chemistry precipitation in the simulate wastewater which includes phosphorus. According to this experiment, we conjectured the form of the deposition and made a base of mechanism analysis.
To find a simple shortcut of determining the quantity of reagent added, we did a lot of experiments and worked out a fig of relationship between the coefficient and the quantity of reagent added. It is easy to estimate the quantity of reagent to added in treating wastewater including phosphorus especially wastewater of low phosphorus standard.
We probed into the mechanism of process of phosphorus removal by chemistry precipitation on the base of the experiments discussed above. Then we analyzed the process of action of aluminum ion, iron ion and PAM. According to the analysis, the process of phosphorus removal by chemistry precipitation including: process of dissolve and hydrolyze of precipitation; reaction of metal ion and phosphoric acid ion; process of phosphate adsorbed by hydrate; process of bridging, catching and flocculating of PAM; process of sedimentation and separation of phosphate.
At last, we debugged and studied the dephosphorization by chemistry precipitation in a case of wastewater treatment project on the base of the study and get a satisfactory result.
首先对废水中磷的污染及除磷技术,尤其是生物除磷和化学除磷技术进行了比较,总结和展望。文章认为,磷污染是废水富营养化的关键因素,废水中总磷通过生物法处理往往不能达到排放标准,所以有必要研究废水的化学法除磷。化学法除磷关键在于药剂的选择和沉淀条件的控制,化学法除磷要和生物法除磷综合起来进行考虑。
随后对污水处理厂的二级出水进行了化学除磷药剂筛选试验和条件试验。通过对铁盐、铝盐和钙盐分别做实验,认为铝盐的除磷效果要优于铁盐,铁盐的除磷效果要优于钙盐。在此基础上,对各药剂做了搅拌时间、pH值等的条件试验,并确立了各混凝剂的最佳混凝条件:搅拌时间为15分钟左右;铝盐的最佳pH范围是6.5左右,铁盐的最佳pH范围是9~10,钙盐在pH>10时能获得较好的处理效果。
为了了解混凝沉淀结构,对模拟含磷废水混凝后产生的沉淀物做了能谱分析,通过确定各主要元素的重量比和原子数之比而推测出沉淀物结构,为机理研究奠定基础。
为了寻找确定化学除磷药剂投加量的简单快捷的方法,通过大量实验作出了投药系数与投加量的关系图,从而可以方便的根据关系图估算出化学除磷,尤其是低磷废水的化学除磷药剂的投加量。
在以上试验的基础上,对化学除磷的作用过程机理进行了探讨,并分别分析了铁盐、铝盐和PAM的作用过程。分析结果表明,化学除磷包含以下过程:混凝剂的溶解与水解;金属离子与磷酸根离子形成不溶性磷酸盐;金属氢氧化物对磷酸盐沉淀的吸附,凝聚;助凝剂的架桥,捕罗,絮凝;沉淀物的沉降、分离。
在此基础上,我们对某工程的化学除磷进行了实际调试与研究,得到了较好的处理效果。
The technical conditions of phosphorus removal by chemistry precipitation and quantity of reagent used in the experiments as well as mechanism of phosphorus removal by chemical method were studied in this paper. And the result of experiments studied in the lab was applied in a case of wastewater treatment project.
At first, the paper compared, summarized and prospected the technology, especially microbial technology and chemical technology of phosphorus removal in wastewater. The paper deemed that the phosphorus pollution was a key factor of abundant nutrition in the water. But the standard of phosphorus in wastewater can't reach the standard of discharge only by microbial method. Thus, it is necessary to study the phosphorus removal by chemical method. The main part of the study was about the reagent selection, the controlling of precipitation conditions and the combination of chemical methods with biological methods.
Then we did the experiments of reagent selection and conditions of phosphorus removal by chemistry precipitation in the second effluence water. According to experiments, the paper considered that the aluminum ion was the best reagent in removing phosphorus and the iron ion followed it and then was the calcium ion. Based on this, we did experiments of conditions such as mill time and pH value of each reagent. The best precipitation conditions were: the mill time was about 15 minutes; the pH value of aluminum ion was about 6.5; the pH value of iron ion was from 9 to 10; the pH value of calcium ion was above 10.
In order to find out the form of the deposition, we did an energy spectrum analysis on deposition of chemistry precipitation in the simulate wastewater which includes phosphorus. According to this experiment, we conjectured the form of the deposition and made a base of mechanism analysis.
To find a simple shortcut of determining the quantity of reagent added, we did a lot of experiments and worked out a fig of relationship between the coefficient and the quantity of reagent added. It is easy to estimate the quantity of reagent to added in treating wastewater including phosphorus especially wastewater of low phosphorus standard.
We probed into the mechanism of process of phosphorus removal by chemistry precipitation on the base of the experiments discussed above. Then we analyzed the process of action of aluminum ion, iron ion and PAM. According to the analysis, the process of phosphorus removal by chemistry precipitation including: process of dissolve and hydrolyze of precipitation; reaction of metal ion and phosphoric acid ion; process of phosphate adsorbed by hydrate; process of bridging, catching and flocculating of PAM; process of sedimentation and separation of phosphate.
At last, we debugged and studied the dephosphorization by chemistry precipitation in a case of wastewater treatment project on the base of the study and get a satisfactory result.
引文
[1] Rusell D F,Woodcock C PN.Journal AWWA,1992,84(g):68~72.
[2] 国家环境保护局.石油石化工业废水治理.北京:中国环境科学出版社,1992
[3] 新华通讯社.参考消息.北京:参考消息报社,1998,3,24:7
[4] 马荣骏.工业废水的治理.长沙:中南工业大学出版社,1991
[5] 金瑞林.环境法学.北京:北京大学出版社,2002
[6] 许保玖.论水工业.工业水处理.1997,17(1):1~5
[7] 吴燕等.废水除磷方法的现状与展望.天津工业大学学报,2001,20(1):74~78.
[8] 唐云梯.实用环境保护数据大会.武汉:湖北人民出版社,1993.50~55.
[9] 邱慎初.化学强化一级处理(CEPT)技术.中国给水排水.2000,16(1):26~29
[10] 江大君,徐新华,宋爽.工业废水中专项污染物处理手册.北京:化学工业出版社,2000:236~246
[11] 唐建国,林洁梅.化学除磷的设计计算.给水排水.2000,26(9):17~21
[12] 郝晓地.欧洲水环境控磷策略与污水除磷技术(上)[J].给水排水.1998,24(8):69~73
[13] 徐乐中.PH值碱度对脱氮除磷效果的影响及其控制方法.给水排水.1996,22(1):10~13
[14] 计石祥.含磷洗涤剂仍是我国近期洗涤剂的主要品种[J],日用化学品科学.1998,98(1):32-34.
[15] 许景文.污水氮磷的去除技术.上海环境科学.1991,10(12):34~36.
[16] 郑兴灿,李亚新.污水除磷脱氮技术。北京:中国建筑工业出版社,1998
[17] 朱利中.酸性膨润土处理含重金属废水初探.环境污染与防治.1993,15(1):21
[18] 胡勇有等.镀铬废水治理、资源回用技术及进展.电镀与环保.1999,19(3):28
[19] 孙家寿.吸附法处理模拟翰林废水.上海环境科学.1993,12(3):12~17
[20] 彭跃莲.膜生物反应器在废水中的应用[J].水处理技术.1999,25(2):63-69.
[21] 陈汉辉.应用水网藻净化水源水质的初步试验[J].重庆环境科学.1998,20(4):19-21.
[22] 陈汉辉.利用藻类净化水源水质的实践与探讨[J].水资源保护.1999,(1):18-23.
[23] 王朝辉.应用水网藻在不同环境条件下对氮磷的吸收能力[J].中国环境科学.1999,19(3):257-261.
[24] 宋祥甫.浮床水稻对富营养水体中氮磷的去除效果及规律研究[J].环境科学学报.1998,18(5):489-494.
[25] 相崎守私.富营养化湖水净化水耕生物过滤法用人工湿地开发[J].水环境学会志(日),1997,20(9):622-628.
[26] 大森美香子.3种类水生植物生活排水处理水荣养盐除去特性[J].环境技术(日),1998,27(8):20-24.
[27] Donald W. Biotreatment System,Boca Raton Florida,CRC Press,1988,3:113
[28] 徐亚同.废水的生物除磷.环境科学研究.1994,7(5):1~6
[29] 翁酥颖等.环境微生物学.北京:科学出版社,1985,259~268
[30] 朱怀兰等.SBR生物除磷工艺的研究.上海环境科学.1993,12(8):8
[31] Roger L P,Roger J A.The mechanism of phosphate fixation by iron oxides.Soil Sci.Soc.Amer.Proc.1975,39:837~841
[32] Fytianos K,Voudrias E,Raikos N.Modelling of phosphorus removal from aqueous and wastewater samples using ferriciron.Environmental Pollution,1998,101:123~130
[33] Cheng Wenpo. Hydrolys is characteristic of polyferric sulfate coagulant and its optimal condition of preparation.Colloids and Surfaces A:Physicochem.Eng.Aspects,2001,182:57~63
[34] MORSE G K,BRETTSW, GUYJA,LESTERJN.Review:Phosphorus removal and recovery technologies[J].The Science of the Total Environment,1988,212:69-81
[35] Donald W.Biotreatment System, Boca Raton Florida,CRC Press,1988,3:113
[36] John Dedyo,Roland Dona,Jr.Reduced Energy Usage With Biologial Phosphorus Removal.Journal WPCF,1981,53(7):1166~1171
[37] Mervyn C.Goronszy,David Rigel.Biological Phosphorus Removal in A Fed-Batch Reactor Without Anoxic Mixing Sequences.Research Journal WPCF,1991,63(3):248~258
[38] D Jenkins,V Tanpoi.The Applied Microbiology of Enhanced Biologial Phosphate Removal-Accomplishments and Needs.Wat Res,1991,25(12):1471~1478
[39] 许晓明,申秀英,活性污泥生物除磷机制及影响因素,农业环境与发展,1994,11(3):25
[40] 黄晟,吴慧英等.城市污水除磷中的有关问题.重庆环境科学.2001,23(5):39~42,
[41] 陈华.化学沉淀法除磷和生物法除磷的比较.上海环境科学.1997,16(6):33~35
[42] 邱维,张智.城市污水化学除磷的探讨.重庆环境科学.2002,24(2):81~84
[43] ClarkT.Phosphate removal in anaero bicli quors by struvite crystallization addition of chemicals:preliminary results[J].WaterRes,1997,31(11):2925-2929.
[44] 神代和幸.海水利用MAP法除去[J].下水道协会志(日),1997,34(420):60-64.
[45] 苏威.无机絮凝剂发展及建议.工业水处理.1993,13(1):3~7
[46] 阮复昌,莫炳禄,徐国想等.铁系净水剂混凝过程的计算机模拟.化学反应工程与工艺.1997,13(4):413~418
[47] 徐乐中.生活污水化学除磷投药量的计算.苏州城建环保学院学报.2001,7(2):60~76
[48] 徐国想,阮复昌.铁系和铝系无机混凝剂的性能分析.重庆环境科学.2001,23(3):52~55
[49] 稻森悠平.投加凝聚剂活性污泥法.学术书刊出版社,1990,181-204
[50] 周克钊.城市污水高负荷活性污泥和化学助凝(BC法)处理技术[A].水和废水技术研究[C].北京:中国建筑工业出版社,1992,291-299.
[51] 周克钊.生物化学(B C)法处理城市污水研究.中国给水排水.2000,16(10):13~17
[52] 国家环保局《水和废水监测分析方法》编委会.水和废水监测分析方法(第三版).北京:中国环境科学出版社,1989:281~285
[53] 施汉昌,柯细勇,徐丽婕.用化学法强化生物除磷的优化控制.中国给水排水.2002,18(7):35~38
[54] 徐亚同.废水中氮磷的处理.上海:华东师范大学出版,2000,284~301
[55] Hahn.Waster technologie.Spfinger-Vefiag Berlin,1987,125~130
[56] 万亚珍,刘金盾.用复合沉淀剂从废水中除磷的理论计算.无机盐工业.2000,32(3):9~11
[57] 李亚峰,刘国瑞,刘仁勇.高浓度含氟含磷化工废水处理.沈阳黄金学院学报.1997,16(3):231~235
[58] 万亚珍.工业含磷废水除磷研究.IM&P化工矿物与加工.2002,19(3):19~21
[59] 陈华等.化学沉淀法除磷和生物法除磷的比较.上海环境科学.1997,16(6):33~35
[60] 王立立等.生活污水二级生物处理后的铁盐混凝除磷试验研究.环境污染与防治.2002,24(6):361~364
[61] 常望霓,扬华南.城市污水脱氮除磷方法探讨.环境保护.2000,11(4):19~20
[62] 李红山,黎松强.赤潮形成与富营养化及生化防治机理.海洋技术.2002,21(2):69~72
[63] Henze M.eral Activated Sludge Model No.2 IAWQ Task Group on Mathematical Modeling for Design and Opration of Biological Wastewater Treatment London:IAWQ Scientific and Technical Report No.3,1995
[64] 胡大卫,姚念民,冯生华.除磷脱氮新工艺的生产应用.天津市政工程.1996,8(3):10~14
[65] 张建,黄霞等.地下渗滤污水处理系统的氮磷去除机理.中国环境科学.2002,22(5):438~441
[66] 华中师大.东北师大等.分析化学(第二版).北京:高等教育出版社,1990:185~223
[67] 戴树桂.环境化学.北京:高等教育出版社,1995:118~189
[68] 陈立,杨坤,鲍宪枝.二段法改良工艺处理高浓度难降解城市污水.中国给水排水.2001,17(8):50~52
[69] Mogens Henze,etal. Wastewater Treatment[M],New York:Springer Verlag Berlin Heidelberg,1995.
[70] 邓雁希,许虹.非金属矿物及工业废弃物在含磷废水处理中的应用.中国非金属矿工业导刊.2002,27(3):30~33
[71] 尤彩真等.废水中磷的吸附研究.环境工程.10(2):15~18
[72] R.A.Mann and H.J.Baver.Phosphorus Removal in Constructed Wetlands using Gravel Industrial Waste Substrata.Wat.Sci.Tech.1993,27(1):107~113
[73] 魏琛,张晚凉.废水除磷工艺中聚磷菌及其缺氧态下吸磷现象.重庆环境科学.2000,22(4):44~46
[74] 徐亚同,史家梁,张大鹏.废水处理.上海化工.2000,23(22):39~41
[75] 沈耀良,王宝贞.废水生物除磷工艺中聚磷菌的作用机制及运行控制要点.环境科学与技术.1995,69(2):11~15
[76] 王弘宁,扬开等.废水生物除磷技术及其研究进展.环境技术.2002,20(8):38~42
[77] 丁文明,黄霞.废水吸附法除磷的研究进展.环境污染治理技术与设备.2002,10(3):23~27
[78] L.Johansson.The use of leca for the removal of phosphorus from wastewater.Wat.Sci.Tech.1997,35(5):87—93
[79] 艾志敏.废水中磷的监测和处理.云南环境科学.2000,19(2):62~64
[80] 田玉红,霍杰,张恩仁.富营养化水体中氮磷的去除.广西工学院学报.2000,11(3):89~92
[81] 魏群.关于城市污水中氮磷去除的探讨.湖南城建高等专科学校学报.2001,10(4):51~52
[82] 顾小红,黄种买,虞启义.污水除磷技术的现状及发展趋势.中国资源综合利用.2002,12(5):26~28
[83] 赵乐军 曹金亮.中小城镇污水处理厂的除磷脱氮.天津市政工程.2001,13(4):27~29
[84] 邹笑蓉等,威海高区污水处理厂设计与运行.给水排水.2002,28(4):13~14
[85] 王家玲等.环境微生物.北京:高等教育出版社,1998,170~171
[2] 国家环境保护局.石油石化工业废水治理.北京:中国环境科学出版社,1992
[3] 新华通讯社.参考消息.北京:参考消息报社,1998,3,24:7
[4] 马荣骏.工业废水的治理.长沙:中南工业大学出版社,1991
[5] 金瑞林.环境法学.北京:北京大学出版社,2002
[6] 许保玖.论水工业.工业水处理.1997,17(1):1~5
[7] 吴燕等.废水除磷方法的现状与展望.天津工业大学学报,2001,20(1):74~78.
[8] 唐云梯.实用环境保护数据大会.武汉:湖北人民出版社,1993.50~55.
[9] 邱慎初.化学强化一级处理(CEPT)技术.中国给水排水.2000,16(1):26~29
[10] 江大君,徐新华,宋爽.工业废水中专项污染物处理手册.北京:化学工业出版社,2000:236~246
[11] 唐建国,林洁梅.化学除磷的设计计算.给水排水.2000,26(9):17~21
[12] 郝晓地.欧洲水环境控磷策略与污水除磷技术(上)[J].给水排水.1998,24(8):69~73
[13] 徐乐中.PH值碱度对脱氮除磷效果的影响及其控制方法.给水排水.1996,22(1):10~13
[14] 计石祥.含磷洗涤剂仍是我国近期洗涤剂的主要品种[J],日用化学品科学.1998,98(1):32-34.
[15] 许景文.污水氮磷的去除技术.上海环境科学.1991,10(12):34~36.
[16] 郑兴灿,李亚新.污水除磷脱氮技术。北京:中国建筑工业出版社,1998
[17] 朱利中.酸性膨润土处理含重金属废水初探.环境污染与防治.1993,15(1):21
[18] 胡勇有等.镀铬废水治理、资源回用技术及进展.电镀与环保.1999,19(3):28
[19] 孙家寿.吸附法处理模拟翰林废水.上海环境科学.1993,12(3):12~17
[20] 彭跃莲.膜生物反应器在废水中的应用[J].水处理技术.1999,25(2):63-69.
[21] 陈汉辉.应用水网藻净化水源水质的初步试验[J].重庆环境科学.1998,20(4):19-21.
[22] 陈汉辉.利用藻类净化水源水质的实践与探讨[J].水资源保护.1999,(1):18-23.
[23] 王朝辉.应用水网藻在不同环境条件下对氮磷的吸收能力[J].中国环境科学.1999,19(3):257-261.
[24] 宋祥甫.浮床水稻对富营养水体中氮磷的去除效果及规律研究[J].环境科学学报.1998,18(5):489-494.
[25] 相崎守私.富营养化湖水净化水耕生物过滤法用人工湿地开发[J].水环境学会志(日),1997,20(9):622-628.
[26] 大森美香子.3种类水生植物生活排水处理水荣养盐除去特性[J].环境技术(日),1998,27(8):20-24.
[27] Donald W. Biotreatment System,Boca Raton Florida,CRC Press,1988,3:113
[28] 徐亚同.废水的生物除磷.环境科学研究.1994,7(5):1~6
[29] 翁酥颖等.环境微生物学.北京:科学出版社,1985,259~268
[30] 朱怀兰等.SBR生物除磷工艺的研究.上海环境科学.1993,12(8):8
[31] Roger L P,Roger J A.The mechanism of phosphate fixation by iron oxides.Soil Sci.Soc.Amer.Proc.1975,39:837~841
[32] Fytianos K,Voudrias E,Raikos N.Modelling of phosphorus removal from aqueous and wastewater samples using ferriciron.Environmental Pollution,1998,101:123~130
[33] Cheng Wenpo. Hydrolys is characteristic of polyferric sulfate coagulant and its optimal condition of preparation.Colloids and Surfaces A:Physicochem.Eng.Aspects,2001,182:57~63
[34] MORSE G K,BRETTSW, GUYJA,LESTERJN.Review:Phosphorus removal and recovery technologies[J].The Science of the Total Environment,1988,212:69-81
[35] Donald W.Biotreatment System, Boca Raton Florida,CRC Press,1988,3:113
[36] John Dedyo,Roland Dona,Jr.Reduced Energy Usage With Biologial Phosphorus Removal.Journal WPCF,1981,53(7):1166~1171
[37] Mervyn C.Goronszy,David Rigel.Biological Phosphorus Removal in A Fed-Batch Reactor Without Anoxic Mixing Sequences.Research Journal WPCF,1991,63(3):248~258
[38] D Jenkins,V Tanpoi.The Applied Microbiology of Enhanced Biologial Phosphate Removal-Accomplishments and Needs.Wat Res,1991,25(12):1471~1478
[39] 许晓明,申秀英,活性污泥生物除磷机制及影响因素,农业环境与发展,1994,11(3):25
[40] 黄晟,吴慧英等.城市污水除磷中的有关问题.重庆环境科学.2001,23(5):39~42,
[41] 陈华.化学沉淀法除磷和生物法除磷的比较.上海环境科学.1997,16(6):33~35
[42] 邱维,张智.城市污水化学除磷的探讨.重庆环境科学.2002,24(2):81~84
[43] ClarkT.Phosphate removal in anaero bicli quors by struvite crystallization addition of chemicals:preliminary results[J].WaterRes,1997,31(11):2925-2929.
[44] 神代和幸.海水利用MAP法除去[J].下水道协会志(日),1997,34(420):60-64.
[45] 苏威.无机絮凝剂发展及建议.工业水处理.1993,13(1):3~7
[46] 阮复昌,莫炳禄,徐国想等.铁系净水剂混凝过程的计算机模拟.化学反应工程与工艺.1997,13(4):413~418
[47] 徐乐中.生活污水化学除磷投药量的计算.苏州城建环保学院学报.2001,7(2):60~76
[48] 徐国想,阮复昌.铁系和铝系无机混凝剂的性能分析.重庆环境科学.2001,23(3):52~55
[49] 稻森悠平.投加凝聚剂活性污泥法.学术书刊出版社,1990,181-204
[50] 周克钊.城市污水高负荷活性污泥和化学助凝(BC法)处理技术[A].水和废水技术研究[C].北京:中国建筑工业出版社,1992,291-299.
[51] 周克钊.生物化学(B C)法处理城市污水研究.中国给水排水.2000,16(10):13~17
[52] 国家环保局《水和废水监测分析方法》编委会.水和废水监测分析方法(第三版).北京:中国环境科学出版社,1989:281~285
[53] 施汉昌,柯细勇,徐丽婕.用化学法强化生物除磷的优化控制.中国给水排水.2002,18(7):35~38
[54] 徐亚同.废水中氮磷的处理.上海:华东师范大学出版,2000,284~301
[55] Hahn.Waster technologie.Spfinger-Vefiag Berlin,1987,125~130
[56] 万亚珍,刘金盾.用复合沉淀剂从废水中除磷的理论计算.无机盐工业.2000,32(3):9~11
[57] 李亚峰,刘国瑞,刘仁勇.高浓度含氟含磷化工废水处理.沈阳黄金学院学报.1997,16(3):231~235
[58] 万亚珍.工业含磷废水除磷研究.IM&P化工矿物与加工.2002,19(3):19~21
[59] 陈华等.化学沉淀法除磷和生物法除磷的比较.上海环境科学.1997,16(6):33~35
[60] 王立立等.生活污水二级生物处理后的铁盐混凝除磷试验研究.环境污染与防治.2002,24(6):361~364
[61] 常望霓,扬华南.城市污水脱氮除磷方法探讨.环境保护.2000,11(4):19~20
[62] 李红山,黎松强.赤潮形成与富营养化及生化防治机理.海洋技术.2002,21(2):69~72
[63] Henze M.eral Activated Sludge Model No.2 IAWQ Task Group on Mathematical Modeling for Design and Opration of Biological Wastewater Treatment London:IAWQ Scientific and Technical Report No.3,1995
[64] 胡大卫,姚念民,冯生华.除磷脱氮新工艺的生产应用.天津市政工程.1996,8(3):10~14
[65] 张建,黄霞等.地下渗滤污水处理系统的氮磷去除机理.中国环境科学.2002,22(5):438~441
[66] 华中师大.东北师大等.分析化学(第二版).北京:高等教育出版社,1990:185~223
[67] 戴树桂.环境化学.北京:高等教育出版社,1995:118~189
[68] 陈立,杨坤,鲍宪枝.二段法改良工艺处理高浓度难降解城市污水.中国给水排水.2001,17(8):50~52
[69] Mogens Henze,etal. Wastewater Treatment[M],New York:Springer Verlag Berlin Heidelberg,1995.
[70] 邓雁希,许虹.非金属矿物及工业废弃物在含磷废水处理中的应用.中国非金属矿工业导刊.2002,27(3):30~33
[71] 尤彩真等.废水中磷的吸附研究.环境工程.10(2):15~18
[72] R.A.Mann and H.J.Baver.Phosphorus Removal in Constructed Wetlands using Gravel Industrial Waste Substrata.Wat.Sci.Tech.1993,27(1):107~113
[73] 魏琛,张晚凉.废水除磷工艺中聚磷菌及其缺氧态下吸磷现象.重庆环境科学.2000,22(4):44~46
[74] 徐亚同,史家梁,张大鹏.废水处理.上海化工.2000,23(22):39~41
[75] 沈耀良,王宝贞.废水生物除磷工艺中聚磷菌的作用机制及运行控制要点.环境科学与技术.1995,69(2):11~15
[76] 王弘宁,扬开等.废水生物除磷技术及其研究进展.环境技术.2002,20(8):38~42
[77] 丁文明,黄霞.废水吸附法除磷的研究进展.环境污染治理技术与设备.2002,10(3):23~27
[78] L.Johansson.The use of leca for the removal of phosphorus from wastewater.Wat.Sci.Tech.1997,35(5):87—93
[79] 艾志敏.废水中磷的监测和处理.云南环境科学.2000,19(2):62~64
[80] 田玉红,霍杰,张恩仁.富营养化水体中氮磷的去除.广西工学院学报.2000,11(3):89~92
[81] 魏群.关于城市污水中氮磷去除的探讨.湖南城建高等专科学校学报.2001,10(4):51~52
[82] 顾小红,黄种买,虞启义.污水除磷技术的现状及发展趋势.中国资源综合利用.2002,12(5):26~28
[83] 赵乐军 曹金亮.中小城镇污水处理厂的除磷脱氮.天津市政工程.2001,13(4):27~29
[84] 邹笑蓉等,威海高区污水处理厂设计与运行.给水排水.2002,28(4):13~14
[85] 王家玲等.环境微生物.北京:高等教育出版社,1998,170~171