人工湿地矿物填料研究综述
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摘要
通过综述传统人工湿地的主要填料,结合其物理、化学性质直接对人工湿地污水处理系统的植物生长和污水净化效果等影响因素,阐明了传统基质的人工湿地已逐渐被矿物填料基质所替代。分析表明人工湿地系统仅靠单一填料,往往无法达到污染物去除要求,应利用组合填料间的协同作用方可达到更好的污染物去除效果。同时本次提出人工湿地矿物填料的研究及应用现状、新型材料的快速发展与应用,以期为人工湿地矿物填料的选择过程提供参考。
In recent years, the application of mineral fillers is a great innovation in the field of constructed wetlands. In this paper, the main fillers of traditional constructed wetlands are summarized, along with the physical, chemical properties of the traditional constructed wetlands directly affect the plant growth and sewage purification effect of the constructed wetlands sewage treatment system. It is clarified that the traditional constructed wetlands have gradually been replaced by mineral fillers. The analysis shows that the constructed wetland system cannot meet the requirement of pollutant removal only by single filler, and better pollutant removal effect can be achieved by using the synergistic effect of the combined fillers. At the same time, the research and application status of mineral fillers in constructed wetlands, the rapid development and application of new materials are put forward in order to provide reference for the selection process of mineral fillers in constructed wetlands.
In recent years, the application of mineral fillers is a great innovation in the field of constructed wetlands. In this paper, the main fillers of traditional constructed wetlands are summarized, along with the physical, chemical properties of the traditional constructed wetlands directly affect the plant growth and sewage purification effect of the constructed wetlands sewage treatment system. It is clarified that the traditional constructed wetlands have gradually been replaced by mineral fillers. The analysis shows that the constructed wetland system cannot meet the requirement of pollutant removal only by single filler, and better pollutant removal effect can be achieved by using the synergistic effect of the combined fillers. At the same time, the research and application status of mineral fillers in constructed wetlands, the rapid development and application of new materials are put forward in order to provide reference for the selection process of mineral fillers in constructed wetlands.
引文
[1]乔厦,郑学良.表面流人工湿地对城市径流水质的净化研究[J].水土保持研究,2019,26(3):353-361.
[2]李华松.人工湿地污水处理技术的应用[J].资源节约与环保,2019(4):100.
[3]高晓丽,张书函,肖娟,等.雨水生物滞留设施中填料的研究进展[J].中国给水排水,2015,31(20):17-21.
[4]许浩浩,吕伟娅.人工湿地污水处理系统中填料的研究进展[J].人民珠江,2019,40(3):107-111,140.
[5] XU Rui,ZHANG Zong,LIU Rong,et al. Effects of different substrates on nitrogen and phosphorus removal in horizontal subsurface flow constructed wetlands[J].Environmental science and pollution research international,2019:16229-16238.
[6]李兆欣,周雪,黄炳彬,等.碳化缓释除磷填料的制备与吸附特性分析[J].环境科学与技术,2017,40(5):49-53.
[7] CHENG Houming, ZHU Qi, XING Zipeng. Adsorption of ammonia nitrogen in low temperature domestic wastewater by modification bentonite[J]. Journal of Cleaner Production,2019:720-730.
[8]黄伟,张荣新,傅金祥,等.基于煤矸石沸石自动改性的潜流人工湿地填料组合方案研究[J].环境污染与防治,2017,39(2):165-169.
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[11]成昊,叶芬,宋谋胜.表面水力负荷对锰渣陶瓷球填料人工湿地的影响研究[J].环境污染与防治,2017,39(6):594-597,603.
[12]赵林丽,邵学新,吴明,等.人工湿地不同基质和粒径对污水净化效果的比较[J].环境科学,2018,39(9):4236-4241.
[13]卢少勇,万正芬,李锋民,等. 29种湿地填料对氨氮的吸附解吸性能比较[J].环境科学研究,2016,29(8):1187-1194.
[14]万琼,雷茹,张波.强化除磷的人工湿地填料影响因素研究[J].清洗世界,2019,35(3):41-43,45.
[15]顾晨,李海翔,刘杰,等.人工湿地净化废水中污染物的机理研究进展[J].广东农业科学,2011,38(24):128-131.
[16] SUN Haishu,XU Shengjun,WU SHANGHUA,et al.Enhancement of facultative anaerobic denitrifying communities by oxygen release from roots of the macrophyte in constructed wetlands[J]. Journal of Environmental Management,2019:157-163.
[17]刘志浩.关于人工湿地中污染物去除机理研究[J].资源节约与环保,2017(4):95-96+98.
[18] MATOS M P,VON S M,MATOS A T,et al. Clogging in constructed wetlands:Indirect estimation of medium porosity by analysis of ground-penetrating radar images[J]. The Science of the total environment,2019:333-342.
[19] MOSTAFA R A,MOHAMED A S,ABDELRAHMAN M R,et al. Surface decoration of diatomite by Ni/NiO nanoparticles as hybrid composite of enhanced adsorption properties for malachite green dye and hexavalent chromium[J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects,2019:583-593.
[20]张翔凌,黄华玲,郭露,等. Zn系LDHs覆膜改性人工湿地沸石基质除磷机制[J].环境科学,2016,37(8):3058-3066.
[21]吴鹏,陆爽君,徐乐中,等.改性沸石湿地脱氮除磷效能及机制[J].环境科学,2017,38(2):580-588.
[22] TAHERI G S, BOROOMANDNASAB S, MOAZED H, et al. The effects of substrate type, HRT and reed on the lead removal in horizontal subsurface-flow constructed wetland[J]. Desalination and Water Treatment,2015,56(12):3357-3367.
[23] SHI Pengbo, JIANG Yingbo, ZHU Hongtao, et al.Impact of steel slag on the ammonium adsorption by zeolite and a new configuration of zeolite-steel slag substrate for constructed wetlands[J]. Water Science and Technology,2017,76(3):584-593.
[24] MICHAEL B R,SKAGGS R W,CHARLES L R,et al. Substrate organic matter to improve nitrate removal in surface-flow constructed wetlands[J]. Journal of Environmental Quality,2007,36(1):194-207.
[2]李华松.人工湿地污水处理技术的应用[J].资源节约与环保,2019(4):100.
[3]高晓丽,张书函,肖娟,等.雨水生物滞留设施中填料的研究进展[J].中国给水排水,2015,31(20):17-21.
[4]许浩浩,吕伟娅.人工湿地污水处理系统中填料的研究进展[J].人民珠江,2019,40(3):107-111,140.
[5] XU Rui,ZHANG Zong,LIU Rong,et al. Effects of different substrates on nitrogen and phosphorus removal in horizontal subsurface flow constructed wetlands[J].Environmental science and pollution research international,2019:16229-16238.
[6]李兆欣,周雪,黄炳彬,等.碳化缓释除磷填料的制备与吸附特性分析[J].环境科学与技术,2017,40(5):49-53.
[7] CHENG Houming, ZHU Qi, XING Zipeng. Adsorption of ammonia nitrogen in low temperature domestic wastewater by modification bentonite[J]. Journal of Cleaner Production,2019:720-730.
[8]黄伟,张荣新,傅金祥,等.基于煤矸石沸石自动改性的潜流人工湿地填料组合方案研究[J].环境污染与防治,2017,39(2):165-169.
[9]赵占军,王玉杰,王云琦.人工湿地不同级配填料净水效果研究[J].湖南农业科学,2011,(13):83-85.
[10]刘珂,葛大兵,徐丽,等.湖南低温地区人工湿地基质的筛选及基质堵塞性能研究[J].环境科技,2013,26(4):5-8.
[11]成昊,叶芬,宋谋胜.表面水力负荷对锰渣陶瓷球填料人工湿地的影响研究[J].环境污染与防治,2017,39(6):594-597,603.
[12]赵林丽,邵学新,吴明,等.人工湿地不同基质和粒径对污水净化效果的比较[J].环境科学,2018,39(9):4236-4241.
[13]卢少勇,万正芬,李锋民,等. 29种湿地填料对氨氮的吸附解吸性能比较[J].环境科学研究,2016,29(8):1187-1194.
[14]万琼,雷茹,张波.强化除磷的人工湿地填料影响因素研究[J].清洗世界,2019,35(3):41-43,45.
[15]顾晨,李海翔,刘杰,等.人工湿地净化废水中污染物的机理研究进展[J].广东农业科学,2011,38(24):128-131.
[16] SUN Haishu,XU Shengjun,WU SHANGHUA,et al.Enhancement of facultative anaerobic denitrifying communities by oxygen release from roots of the macrophyte in constructed wetlands[J]. Journal of Environmental Management,2019:157-163.
[17]刘志浩.关于人工湿地中污染物去除机理研究[J].资源节约与环保,2017(4):95-96+98.
[18] MATOS M P,VON S M,MATOS A T,et al. Clogging in constructed wetlands:Indirect estimation of medium porosity by analysis of ground-penetrating radar images[J]. The Science of the total environment,2019:333-342.
[19] MOSTAFA R A,MOHAMED A S,ABDELRAHMAN M R,et al. Surface decoration of diatomite by Ni/NiO nanoparticles as hybrid composite of enhanced adsorption properties for malachite green dye and hexavalent chromium[J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects,2019:583-593.
[20]张翔凌,黄华玲,郭露,等. Zn系LDHs覆膜改性人工湿地沸石基质除磷机制[J].环境科学,2016,37(8):3058-3066.
[21]吴鹏,陆爽君,徐乐中,等.改性沸石湿地脱氮除磷效能及机制[J].环境科学,2017,38(2):580-588.
[22] TAHERI G S, BOROOMANDNASAB S, MOAZED H, et al. The effects of substrate type, HRT and reed on the lead removal in horizontal subsurface-flow constructed wetland[J]. Desalination and Water Treatment,2015,56(12):3357-3367.
[23] SHI Pengbo, JIANG Yingbo, ZHU Hongtao, et al.Impact of steel slag on the ammonium adsorption by zeolite and a new configuration of zeolite-steel slag substrate for constructed wetlands[J]. Water Science and Technology,2017,76(3):584-593.
[24] MICHAEL B R,SKAGGS R W,CHARLES L R,et al. Substrate organic matter to improve nitrate removal in surface-flow constructed wetlands[J]. Journal of Environmental Quality,2007,36(1):194-207.
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