高级搜索

黑臭底泥处理余水的强化絮凝脱氮

downloadPDF

上一篇

下一篇

程玲, 赵华章, 邓灿, 李金波, 谢勇, 王爱德, 张丽娟, 陶虎春. 黑臭底泥处理余水的强化絮凝脱氮[J]. 环境工程学报, 2018, 12(3): 796-803. doi: 10.12030/j.cjee.201709190
引用本文: 程玲, 赵华章, 邓灿, 李金波, 谢勇, 王爱德, 张丽娟, 陶虎春. 黑臭底泥处理余水的强化絮凝脱氮[J]. 环境工程学报, 2018, 12(3): 796-803. doi: 10.12030/j.cjee.201709190
shu
CHENG Ling, ZHAO Huazhang, DENG Can, LI Jinbo, XIE Yong, WANG Aide, ZHANG Lijuan, TAO Huchun. Nitrogen removal by enhanced coagulation of dredging water from black and odor river sediment[J]. Chinese Journal of Environmental Engineering, 2018, 12(3): 796-803. doi: 10.12030/j.cjee.201709190
Citation: CHENG Ling, ZHAO Huazhang, DENG Can, LI Jinbo, XIE Yong, WANG Aide, ZHANG Lijuan, TAO Huchun. Nitrogen removal by enhanced coagulation of dredging water from black and odor river sediment[J]. Chinese Journal of Environmental Engineering, 2018, 12(3): 796-803. doi: 10.12030/j.cjee.201709190
shu

黑臭底泥处理余水的强化絮凝脱氮

  • 1.

    北京大学深圳研究生院环境与能源学院,深圳市重金属污染控制与资源化重点实验室,深圳 518055

  • 2.

    北京大学环境工程系,教育部水沙科学重点实验室,北京 100871

  • 3.

    中电建水环境治理技术有限公司,深圳518100

  • 基金项目:

    深圳市战略新兴产业发展专项资金(JSKF20150828173756275)

    深圳市科技研发应用示范项目(KJYY20160429140840457)

    流域生态工程学学科建设资金(深发改[2017]542号)

Nitrogen removal by enhanced coagulation of dredging water from black and odor river sediment

  • 1.

    Shenzhen Key Laboratory for Heavy Metal Pollution Control and Reutilization, School of Environment and Energy, Peking University Shenzhen Graduate School, Shenzhen 518055, China

  • 2.

    Key Laboratory of Water and Sediment Sciences, Ministry of Education, Department of Environmental Engineering, Peking University, Beijing 100871, China

  • 3.

    Power China Water Environment Governance, Shenzhen 518100, China

  • Fund Project:

  • 摘要: 针对黑臭水体疏浚余水氮素难去除问题,在聚合氯化铝(poly aluminum chloride,PAC)为絮凝剂、聚丙烯酰胺(polyacrylamide,PAM)为助凝剂的基础上,采用新型共价键型絮凝剂(hybrid covalent coagulant,HCC)强化疏浚余水絮凝脱氮过程,并通过超磁分离技术进行固液分离,实现氮素的快速与高效脱除。在优化的复合絮凝剂投加量条件下,该强化絮凝过程可达到氨氮的完全脱除和总氮80%的去除率。动力学研究结果表明,在较短的15 min絮凝操作时间内,即可达到较好的氮素去除效果。当初始pH为7.0时,絮凝分散体系具有较低的Zeta电位值,利于有效降低水体浊度。FTIR图谱验证了羟基参与的氨氮絮凝反应,表明NH3+为氨氮被絮凝剂絮凝后的主要存在形式。
    Abstract: This study aimed to address the difficulties in nitrogen removal from dredging water. As an efficiently and economically feasible protocol, poly aluminum chloride (PAC) was employed as the coagulant and polyacrylamide (PAM) as the aiding agent for enhanced coagulation of nitrogen pollutants. With the implementation of a novel hybrid covalent coagulant (HCC) combined with certain magnetic addictive, an efficient and rapid separation of solid chemicals from aqueous solution was proven applicable under an ultra-magnetic field. At optimal dosage of coagulant, aiding and enhancing agents, complete ammonia removal and up to 80% elimination of total nitrogen were obtained successfully. The kinetic studies showed that higher removal efficiency could be achieved for nitrogen removal within a short operating period of 15 min. The flocculation system had a lower Zeta potential which facilitated a higher removal efficiency of turbidity at the initial pH of 7.0. FTIR analysis indicated that NH3+ was involved as the major form of ammonia to interact with hydroxyl groups in the flocculation process.
  • 加载中
  • [1] 王旭, 王永刚, 孙长虹, 等. 城市黑臭水体形成机理与评价方法研究进展[J].应用生态学报,2016,27(4):1331-1340 10.13287/j.1001-9332.201604.014
    [2] 皮科武, 陈文文, 时压飞, 等. 钙基聚合硫酸铁对河道富磷底泥固磷脱水的研究[J].工业安全与环保,2017,43(3):99-102 10.3969/j.issn.1001-425X.2017.03.026
    [3] LU X M, HUANG M S.Nitrogen and phosphorus removal and physiological response in aquatic plants under aeration conditions[J].International Journal of Environmental Science & Technology,2010,7(4):665-674
    [4] 唐云飞, 王荣昌, 马利民, 等. 河道疏浚底泥余水强化絮凝处理工艺优化与机理[J].净水技术,2012,31(3):93-97 10.3969/j.issn.1009-0177.2012.03.022
    [5] 胡保安. 环保疏浚泥浆脱水干化技术研究进展[J].水资源与水工程学报,2009,20(4):132-136
    [6] 曾德芳, 袁继祖. 一种新型环保型污泥脱水絮凝剂的研制与应用[J].工业水处理,2007,27(1):17-20 10.3969/j.issn.1005-829X.2007.01.005
    [7] 王秋阳. 无机高分子絮凝剂的混凝特性试验研究[D].北京:中国地质大学(北京),2009
    [8] 秦墨涵, 赵华章, 任丽梅, 等. 共价键型有机硅铝复合絮凝剂的混凝效果[J]. 环境工程学报,2014,8(4):1262-1266
    [9] 陈燕. 共价键型有机硅铝复合絮凝剂的制备及其混凝性能研究[D].西安:西安建筑科技大学,2014
    [10] 彭建雄, 赵华章. 共价键型硅铝复合絮凝剂的铝形态分布及其絮凝性能研究[J].环境科学,2009,30(6):1705-1710
    [11] 陈燕, 赵华章, 王文东. 共价键型有机硅铝复合絮凝剂及混凝效果研究[J].水处理技术,2014,40(12):35-38
    [12] ZHAO H, PENG J, LIN S, et al.Covalently bound organic silicate aluminum hybrid coagulants: Preparation, characterization, and coagulation behavior[J].Environmental Science & Technology,2009,43(6):2041-2046 10.1021/es802965v
    [13] 陈卫, 袁哲, 陶辉, 等.SUVA值与超滤膜污染的关系[J].华中科技大学学报(自然科学版),2011,39(2):129-132
    [14] 郑怀礼, 陆兰英, 范伟, 等. 聚合氯化铝的制备及在微污染水处理中的应用[J].化学研究与应用,2012,24(4):626-629
    [15] 李风亭, 何艳, 潘宏杰, 等. 聚合氯化铝混凝性能的影响因素研究[J].工业水处理,2008,28(10):40-43
    [16] 李志伟, 孙力平, 吴立.PAC和PAM复合混凝剂处理垃圾渗滤液的研究[J].中国给水排水,2009,25(23):85-87
    [17] 李海燕, 徐国想, 曹静雅, 等. 关于3种典型絮凝剂去除水中浊度性能的探讨[J].淮海工学院学报(自然科学版),2006,15(4):45-47
    [18] 王伟. 聚丙烯酰胺在净水处理中的应用[J].中国矿山工程,2005,34(5):42-46
    [19] WICKRAMASINGHE R S, LEONG Y, MONDAL S, et al.Influence of cationic flocculant properties on the flocculation of yeast suspensions[J].Advanced Powder Technology,2010,21(4):374-379 10.1016/j.apt.2010.02.006
    [20] MCGUIRE M J, ADDAI-MENSAH J, BREMMELL K E.The effect of polymer structure type, pH and shear on the interfacial chemistry, rheology and dewaterability of model iron oxide dispersions[J].Colloids and Surfaces A: Physicochemical and Engineering Aspects,2006,275(1/2/3):153-160 10.1016/j.colsurfa.2005.09.034
    [21] 王哲晓, 吕志国, 张勤. 超磁分离水体净化技术在水环境领域的典型应用[J].中国给水排水,2016,32(12):34-37
    [22] 罗延歆. 矿井水超磁分离净化技术研究与应用[J]. 煤炭工程,2017,49(6):72-74
    [23] 栾兆坤, 汤鸿霄, 于忱非. 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[J].环境科学学报,1997,17(3):65-71
    [24] 许小洁, 吴纯德, 叶健,等. 基于Zeta电位的硅藻土复配剂强化混凝研究[J].环境科学与技术,2010,33(10):151-153
  • 加载中
WeChat 点击查看大图
计量
  • 文章访问数:  3794
  • HTML全文浏览数:  3317
  • PDF下载数:  532
  • 施引文献:  0
出版历程
  • 刊出日期:  2018-03-22

黑臭底泥处理余水的强化絮凝脱氮

  • 1. 北京大学深圳研究生院环境与能源学院,深圳市重金属污染控制与资源化重点实验室,深圳 518055
  • 2. 北京大学环境工程系,教育部水沙科学重点实验室,北京 100871
  • 3. 中电建水环境治理技术有限公司,深圳518100
基金项目:

深圳市战略新兴产业发展专项资金(JSKF20150828173756275)

深圳市科技研发应用示范项目(KJYY20160429140840457)

流域生态工程学学科建设资金(深发改[2017]542号)

摘要: 针对黑臭水体疏浚余水氮素难去除问题,在聚合氯化铝(poly aluminum chloride,PAC)为絮凝剂、聚丙烯酰胺(polyacrylamide,PAM)为助凝剂的基础上,采用新型共价键型絮凝剂(hybrid covalent coagulant,HCC)强化疏浚余水絮凝脱氮过程,并通过超磁分离技术进行固液分离,实现氮素的快速与高效脱除。在优化的复合絮凝剂投加量条件下,该强化絮凝过程可达到氨氮的完全脱除和总氮80%的去除率。动力学研究结果表明,在较短的15 min絮凝操作时间内,即可达到较好的氮素去除效果。当初始pH为7.0时,絮凝分散体系具有较低的Zeta电位值,利于有效降低水体浊度。FTIR图谱验证了羟基参与的氨氮絮凝反应,表明NH3+为氨氮被絮凝剂絮凝后的主要存在形式。

English Abstract

参考文献 (24)

目录

/

返回文章
返回

Copyright © 2019 中国科学院生态环境研究中心