湘江水源低温低浊度水处理试验研究
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摘要
目前的水资源面临的问题有很多是水资源水质的问题。我国人均水资源占有量较低,由于水质问题,中国1m~3水的使用价值很低。面对水源水质的变化,常规处理工艺已显得力不从心。在各种改善水质的深度处理技术中,开发一种适合低温低浊度水质特征的混凝剂是最经济、最有效的方法。
本实验对低温低浊度情况下的混凝特征进行了初步试验研究,对各种混凝剂的性能进行了试验研究,试验的内容包括:
(1)小试实验:通过混凝烧杯试验,筛选适合低温低浊度湘江株洲河段水处理的混凝剂和助凝剂,探讨和研究典型混凝剂和助凝剂的混凝机理,确定适合低温低浊度的湘江源水的最佳混凝剂投加量。
(2)中试试验:将小试试验所获得的试验参数运用到中试试验,通过对聚合氯化铝和聚硅硫酸铁处理低温低浊度水进行对比研究,全面考察聚硅硫酸铁对低温低浊度湘江源水的处理效果,进一步确定聚硅硫酸铁在不同浊度和温度下的投加量。
试验结果表明:在对受到微污染的湘江源水的处理时,聚硅酸铁混凝剂的预先聚合作用可明显消除混凝条件,如pH值、碱度、混合时间等因素对混凝的影响。铁的水解产物可发生电中和及吸附凝聚作用。聚硅酸大分子表现出明显的吸附架桥和粘附卷扫作用。聚硅酸铁絮凝体粗大、密实,沉降快,能够深入滤料,增大滤料的吸附容量。聚硅酸铁对浊度、有机物的去除效果明显,对色度的去除效果欠佳。
Many problems which water source is facing are the quality of water source. The average available quantity of water source per people is extremly low in China. The water quality is even worse. By now, the tradiontial process of water treatment is not suitable. Finding a new floccutant for low temperature and low turbidity water is an economy method among all kinds of water purification technologies.
This experiment made some primary lab reserches about the characteristics of flocculants. The followings are the contents:
(1) Jar experiment: through jar experiment, flocculants are screened out for low temperature and low turbidity water taken from Xiangjiang river; discussing and research on coagulation mechanism; determining the quantity of flocculant.
(2) Production experiment: make sure of the dates acquired from lab experiment and jar test to run the typical water plant. By contrasting the effect of polyaluminum chloride and polymeric ferric silicate-sulfate, it can be concluded that polymeric ferric silicate-sulfate is suitable for low template and low turbidity water.
The results indicates that when treating slightly polluted source water of XiangJiang river, pre- polymerization can eliminate the influence of ingredients in water. Ferric hydrolysate have neutralisation and adsorption. Silicic giant molecule behave flocculation and bridge. It is found that the sizes and density of the floe was increasing and the residual turbidity of the settled water was reduced evidently.
本实验对低温低浊度情况下的混凝特征进行了初步试验研究,对各种混凝剂的性能进行了试验研究,试验的内容包括:
(1)小试实验:通过混凝烧杯试验,筛选适合低温低浊度湘江株洲河段水处理的混凝剂和助凝剂,探讨和研究典型混凝剂和助凝剂的混凝机理,确定适合低温低浊度的湘江源水的最佳混凝剂投加量。
(2)中试试验:将小试试验所获得的试验参数运用到中试试验,通过对聚合氯化铝和聚硅硫酸铁处理低温低浊度水进行对比研究,全面考察聚硅硫酸铁对低温低浊度湘江源水的处理效果,进一步确定聚硅硫酸铁在不同浊度和温度下的投加量。
试验结果表明:在对受到微污染的湘江源水的处理时,聚硅酸铁混凝剂的预先聚合作用可明显消除混凝条件,如pH值、碱度、混合时间等因素对混凝的影响。铁的水解产物可发生电中和及吸附凝聚作用。聚硅酸大分子表现出明显的吸附架桥和粘附卷扫作用。聚硅酸铁絮凝体粗大、密实,沉降快,能够深入滤料,增大滤料的吸附容量。聚硅酸铁对浊度、有机物的去除效果明显,对色度的去除效果欠佳。
Many problems which water source is facing are the quality of water source. The average available quantity of water source per people is extremly low in China. The water quality is even worse. By now, the tradiontial process of water treatment is not suitable. Finding a new floccutant for low temperature and low turbidity water is an economy method among all kinds of water purification technologies.
This experiment made some primary lab reserches about the characteristics of flocculants. The followings are the contents:
(1) Jar experiment: through jar experiment, flocculants are screened out for low temperature and low turbidity water taken from Xiangjiang river; discussing and research on coagulation mechanism; determining the quantity of flocculant.
(2) Production experiment: make sure of the dates acquired from lab experiment and jar test to run the typical water plant. By contrasting the effect of polyaluminum chloride and polymeric ferric silicate-sulfate, it can be concluded that polymeric ferric silicate-sulfate is suitable for low template and low turbidity water.
The results indicates that when treating slightly polluted source water of XiangJiang river, pre- polymerization can eliminate the influence of ingredients in water. Ferric hydrolysate have neutralisation and adsorption. Silicic giant molecule behave flocculation and bridge. It is found that the sizes and density of the floe was increasing and the residual turbidity of the settled water was reduced evidently.
引文
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[2] 马军,刘伟,李圭白.高铁酸盐复合药剂强化混凝处理低温低浊度水的试验研究.给水排水,1997,23(11):9~11
[3] 王占生,刘文君.微污染水源饮用水处理.北京:中国建筑工业出版社,2001:99~120
[4] 吴亚淮,低温低浊水净化技术的应用及发展.中国给水排水,1989,5(5):9~11
[5] 王晶.机械加速澄清池处理低温低浊水一例.给水排水.1979(3):8~11
[6] 袁辉洲.反冲洗废水回流处理工艺试验研究:[硕士学位论文].长沙:湖南大学,1999
[7] AWWA Research Foundation Report, Disposal of Wates from Water Treatment Plants Part Ⅱ, JAWWA, Nov, 1969:619~638
[8] 黄勤.气浮法处理低温低浊度水的生产性试验.给水排水.1978(4):10~15
[9] 张雍.微絮凝接触过滤工艺处理低温低浊水.给水排水.1980(2):20~24
[10] 胡江泳,方振东,王占生.低温低浊微污染水源水的生物净化技术研究.环境科学,1996,17(1):54~59
[11] 王绍文,姜安玺,孙詰.混凝动力学的涡旋理论探讨(上).中国给水排水.1991,7(1):4~7
[12] 王绍文,姜安玺,孙詰.混凝动力学的涡旋理论探讨(下).中国给水排水,1991,7(4):8~11
[13] 赫俊国,宋学锋,金昌锦等.微涡旋混凝低脉动沉淀技术处理低温低浊水.中国给水排水,1999,15(4):17~19
[14] 王建龙,杨基先.旋流—网格混凝设备处理低温低浊水的试验研究.中国给水排水,1998,14(2):32~34
[15] Clarification with microsand seeding: A state of the art, Water Research Vol15:12 81~1290
[16] 李镜明,姚志强.低浊度水絮凝新工艺的初步研究.给水排水,1991,5(4):2~5
[17] 瞿明晰,刘馨远.低温低浊水滞特性的分析.中国给水排水,1998,14(6):33~34
[18] 许保玖,龙腾锐.当代给水与废水处理原理.北京:高等教育出版社,2000,P203~236
[19] 陈宗淇,戴闽光.胶体化学.北京:高等教育出版社,1984:P120~140
[20] 汪光焘.城市供水行业 2000 年技术进步发展规划.北京:中国建筑工业出版社,1993,P203~222
[21] 谭德先.微污染湘江源水强化混凝试验研究:[硕士学位论文].长沙:湖南大学,2000
[22] 王峰,闻人勤.水的浊度和悬浮物.华东电力,1996(4):27~28
[23] Dentel S K, Grosset J M. Mechanism of coagulation with aluminum. JAWWA salt[J],1988,80(4):187
[24] Hahn H H, Stumm W. Kinetics of coagulation with hydrolyzed aluminum. J Colloid & Inter Sci,1968,28:133
[25] 何慧琴,童仕唐.水处理中絮凝剂的研究进展.应用化工,2001,30(6):14~16
[26] 高宝玉,岳钦艳,王占生.聚硅氯化铝的混凝效果及在处理水中的残留铝研究.中国给水排水,1999,15(7):1~3
[27] Hasegawa T, Hashimeto K, Onitsuka T. Characteristic of metal-polysilicate coagula~nts. Water Sci Tech,1991:23(7):1713~1722
[28] 栾兆坤,汤鸿霄,于枕非.混凝过程中铝与聚合铝水解形态的动力学转化及其稳定性.环境科学学报.1997,17(3):322~326
[29] 张天辰.国产聚丙烯酰胺毒性的初步研究.给水排水,1977(4):38~38
[30] Carl-Erik Nielson. Recycling of wasterwaters from textile dyeling using crossflow membrane filtration. Filtration & Separation,1994(31):593~595
[31] O. R. Pal, A. K. Vanjara. Removal of malathion and butachlor from aqueous solution by clays and organoclays. Separation and Purification Technology, 2001(24):167~172
[32] Hmffman M R. Environmental application of semiconductor photocatalysis[J]. Chem Rev,1995,95(7):69~72
[33] Hagfeldt A. Light~induced redox reaction in nanocrystalline systems[J]. Chem Rev, 1995,95(6):49~68
[34] 岳钦艳,刘玉真,高宝玉等.聚合硅酸氯化铝铁混凝剂的制备及其特性.山东大学学报,2001,36(4):425~428
[35] 高宝玉,于慧,岳钦艳等.聚合氯化铝铁絮凝剂的性能及应用.山环境工程,1995,13(6):12~16
[36] 许佩瑶,卢素焕,张振声等.聚硅酸金属盐类混凝剂的絮凝机理研究.环境科学研
究,20002,13(6):26~29
[37] 高宝玉,岳钦艳,王占生等.聚合氯化铝的混凝效果及在水处理中的残留铝研究.中国给水排水,1999,15(7):1~3
[38] 于水利,刘立,刘馨远.水处理助剂—活化硅酸(Ⅰ).哈尔滨建筑大学学报,1997,30(4):62~65
[39] 于水利,刘馨远,刘立.活化硅酸聚合机理探讨.哈尔滨建筑大学学报,1996,29(5):111~114
[40] 高宝玉,宋永会,岳钦艳.聚硅酸硫酸铁混凝剂的性能研究.环境科学,1997,18(2):46~48
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