种植4种植物的模拟人工湿地对污水中4种重金属的去除效果
|
摘要
利用黑龙江三江国家级自然保护区中4种常见植物——臌囊薹草(Carex schmidtii)、芦苇(Phragmites australis)、水葱(Scirpus validus)和香蒲(Typha orientalis),构建模拟人工湿地,研究种植了4种植物的人工湿地对当地稻田废水和被污染河水中Cr、Pb、Cu和Zn的去除效果。研究结果表明,在28 d的实验期内,随着实验时间推移,两种污水中的Cr、Pb、Cu、Zn含量都在减小,延长污水在人工湿地中的停留时间,Cr、Pb、Cu、Zn的累积去除率持续增大;实验结束后,种植了4种植物的人工湿地对稻田废水中Cr、Pb、Cu和Zn的平均累积去除率分别为89.56%、55.15%、12.57%和68.17%,对被污染河水中Cr、Pb、Cu和Zn的平均累积去除率分别为86.62%、54.50%、2.74%和44.21%。对稻田废水中的4种重金属,种植臌囊薹草的人工湿地对Cr的去除率(95.45%)最大,种植芦苇的人工湿地对Pb和Cu的去除率(Pb:67.75%;Cu:15.81%)最大,种植水葱的人工湿地对Zn的去除率(75.86%)最大;对被污染河水中的4种重金属,种植芦苇的人工湿地对Cr的去除率(95.48%)最大,种植水葱的人工湿地对Pb的去除率(69.49%)最大,种植香蒲的人工湿地对Cu的去除率(3.46%)最大,种植臌囊薹草的人工湿地对Zn的去除率(64.98%)最大。
In order to study the removal efficiency of Cr, Pb, Cu, and Zn in paddy wastewater and polluted river water, Carex schmidtii, Phragmites australis, Scirpus validus, and Typha orientalis, which were common plants in Heilongjiang Sanjiang National Nature Reserve were selected to set up constructed wetlands. The results showed that the contents of Cr, Pb, Cu, and Zn in two kinds of wastewater decreased over the 28 days experiment. Extending residential time of the wastewater in the constructed wetlands, cumulative removal rates of Cr, Pb, Cu, and Zn increased continuously. At the end of the experiment, the cumulative removal rates of Cr, Pb, Cu, and Zn in paddy wastewater were 89.56%, 55.15%, 12.57%, and 68.17%, whereas the cumulative removal rates of Cr, Pb, Cu, and Zn in polluted river water were 86.62%, 54.50%, 2.74%, and 44.21%, respectively. For the 4 kinds of heavy metals in paddy wastewater, the removal rate of Cr was the highest(95.45%)by the constructed wetlands planting Carex schmidtii, whereas the removal rates of Pb and Cu were the highest(Pb: 67.75%; Cu: 15.81%) by the constructed wetlands planting Phragmites australis, and the removal rate of Zn was the highest(75.86%) by the constructed wetlands planting Scirpus validus. For the 4 kinds of heavy metals in polluted river water, the removal rate of Cr was the highest(95.48%) by the constructed wetlands planting Phragmites australis, whereas the removal rate of Pb was the highest(69.49%) by the constructed wetlands planting Scirpus validus, the removal rate of Cu was the highest(3.46%) by the constructed wetlands planting Typha orientalis, the removal rate of Zn was the highest(64.98%) by the constructed wetlands planting Carex schmidtii.
In order to study the removal efficiency of Cr, Pb, Cu, and Zn in paddy wastewater and polluted river water, Carex schmidtii, Phragmites australis, Scirpus validus, and Typha orientalis, which were common plants in Heilongjiang Sanjiang National Nature Reserve were selected to set up constructed wetlands. The results showed that the contents of Cr, Pb, Cu, and Zn in two kinds of wastewater decreased over the 28 days experiment. Extending residential time of the wastewater in the constructed wetlands, cumulative removal rates of Cr, Pb, Cu, and Zn increased continuously. At the end of the experiment, the cumulative removal rates of Cr, Pb, Cu, and Zn in paddy wastewater were 89.56%, 55.15%, 12.57%, and 68.17%, whereas the cumulative removal rates of Cr, Pb, Cu, and Zn in polluted river water were 86.62%, 54.50%, 2.74%, and 44.21%, respectively. For the 4 kinds of heavy metals in paddy wastewater, the removal rate of Cr was the highest(95.45%)by the constructed wetlands planting Carex schmidtii, whereas the removal rates of Pb and Cu were the highest(Pb: 67.75%; Cu: 15.81%) by the constructed wetlands planting Phragmites australis, and the removal rate of Zn was the highest(75.86%) by the constructed wetlands planting Scirpus validus. For the 4 kinds of heavy metals in polluted river water, the removal rate of Cr was the highest(95.48%) by the constructed wetlands planting Phragmites australis, whereas the removal rate of Pb was the highest(69.49%) by the constructed wetlands planting Scirpus validus, the removal rate of Cu was the highest(3.46%) by the constructed wetlands planting Typha orientalis, the removal rate of Zn was the highest(64.98%) by the constructed wetlands planting Carex schmidtii.
引文
[1]陈莹,陈永华,宋胡,等.表面流—潜流—潜流串联人工湿地对排入星月水库污水的处理效果[J].湿地科学, 2018, 1166(1):59-66.
[2]蒋永荣,莫德清,段钧元,等.不同植物配置人工湿地冬季生活污水净化效果比较[J].水资源保护, 2009, 2255(3):25-28.
[3]谢龙,汪德爟,戴昱.水平潜流人工湿地氮转化模型研究[J].水力发电学报, 2009, 2288(6):151-156.
[4]赵兰,辜夕容,邢新婷. 3种植物对人工模拟三峡库区富营养化水体的净化研究[J].西南大学学报:自然科学版, 2010, 3322(7):113-118.
[5]廖颉,刘迎云,陈小明.水平潜流人工湿地在工业废水处理中的应用[J].市政技术, 2010, 2288(3):130-132.
[6]Gill L W, Ring P, Casey B, et al. Long term heavy metal removal by a constructed wetland treating rainfall runoff from a motorway[J]. Science of the Total Environment, 2017, 660011-602:32-44.
[7]Fazal S, Zhang B P, Mehmood Q. Biological treatment of combined industrial wastewater[J]. Ecological Engineering, 2015, 8844:551-558.
[8]梁雪,贺锋,徐栋,等.人工湿地植物的功能与选择[J].水生态学杂志, 2012, 3333(1):131-138.
[9]尹炜,李培军,叶闽,等.复合潜流人工湿地处理城市地表径流研究[J].中国给水排水, 2006, 2222(1):5-8.
[10]成先雄,周丹,赵永红.污水湿地处理系统中植物研究现状[J].环境科学与技术, 2010, 3333(8):94-99.
[11]秦蕾蕾,李嘉,李春玲,等. 3种沉水植物对不同浓度生活污水净化效果试验研究[J].四川大学学报:工程科学版, 2013, 45(S2):96-101.
[12]阳承胜,蓝崇钰,束文圣.宽叶香蒲人工湿地对铅/锌矿废水净化效能的研究[J].深圳大学学报, 2000, 1177(2):51-57.
[13]苏芳莉,隋丹,李海福,等.芦苇根茎和根对造纸废水中铜的吸收[J].湿地科学, 2017, 1155(5):753-757.
[14]郭成久,周欣,苏芳莉,等.双台河口湿地芦苇对造纸废水中重金属净化效果研究[J].沈阳农业大学学报, 2012, 4433(2):206-210.
[15]韦菊阳,陈章和.梭鱼草和芦苇人工湿地对重金属和营养的去除率比较[J].应用与环境生物学报, 2013, 1199(1):179-183.
[16]冯培勇,陈兆平,靖元孝.人工湿地及其去污机理研究进展[J].生态科学, 2002, 2211(3):264-268.
[17]张洪刚,洪剑明.人工湿地中植物的作用[J].湿地科学, 2006, 4(2):146-154.
[18]梁雪,贺锋,徐栋,等.人工湿地植物的功能与选择[J].水生态学杂志, 2012, 3333(1):131-138.
[19]周桑扬,杨凯,吴晓芙,等.人工湿地植物去除废水中重金属的作用机制研究进展[J].湿地科学, 2016, 1144(5):717-724.
[20]Iamchaturapatr J, Su W Y, Rhee J S. Nutrient removals by 21aquatic plants for vertical free surface-flow(VFS)constructed wetland[J]. Ecological Engineering, 2007, 299(3):287-293.
[21]陈晓艺,徐德福,李映雪,等.三种水生植物枯落物分解特征与人工湿地渗透系数[J].湿地科学, 2017, 1155(5):740-746.
[22]董小霞,颜昌宙,王灶生,等.组合式水生植物净化系统对Cu、Pb和Cd的去除与生物富集特征[J].环境工程学报, 2014, 8(4):1447-1453.
[23]谢丹超.湿地修复生态工程中水生植物对重金属Cu、Zn污染废水的净化研究[D].杭州:浙江大学, 2005.
[24]Soltan M E, Rashed M N. Laboratory study on the survival of water hyacinth under several conditions of heavy metal concentrations[J]. Advances in Environmental Research, 2003, 77(2):321-334.
[25]李峰平,魏红阳,马喆,等.人工湿地植物的选择及植物净化污水作用研究进展[J].湿地科学, 2017, 1155(6):849-854.
[2]蒋永荣,莫德清,段钧元,等.不同植物配置人工湿地冬季生活污水净化效果比较[J].水资源保护, 2009, 2255(3):25-28.
[3]谢龙,汪德爟,戴昱.水平潜流人工湿地氮转化模型研究[J].水力发电学报, 2009, 2288(6):151-156.
[4]赵兰,辜夕容,邢新婷. 3种植物对人工模拟三峡库区富营养化水体的净化研究[J].西南大学学报:自然科学版, 2010, 3322(7):113-118.
[5]廖颉,刘迎云,陈小明.水平潜流人工湿地在工业废水处理中的应用[J].市政技术, 2010, 2288(3):130-132.
[6]Gill L W, Ring P, Casey B, et al. Long term heavy metal removal by a constructed wetland treating rainfall runoff from a motorway[J]. Science of the Total Environment, 2017, 660011-602:32-44.
[7]Fazal S, Zhang B P, Mehmood Q. Biological treatment of combined industrial wastewater[J]. Ecological Engineering, 2015, 8844:551-558.
[8]梁雪,贺锋,徐栋,等.人工湿地植物的功能与选择[J].水生态学杂志, 2012, 3333(1):131-138.
[9]尹炜,李培军,叶闽,等.复合潜流人工湿地处理城市地表径流研究[J].中国给水排水, 2006, 2222(1):5-8.
[10]成先雄,周丹,赵永红.污水湿地处理系统中植物研究现状[J].环境科学与技术, 2010, 3333(8):94-99.
[11]秦蕾蕾,李嘉,李春玲,等. 3种沉水植物对不同浓度生活污水净化效果试验研究[J].四川大学学报:工程科学版, 2013, 45(S2):96-101.
[12]阳承胜,蓝崇钰,束文圣.宽叶香蒲人工湿地对铅/锌矿废水净化效能的研究[J].深圳大学学报, 2000, 1177(2):51-57.
[13]苏芳莉,隋丹,李海福,等.芦苇根茎和根对造纸废水中铜的吸收[J].湿地科学, 2017, 1155(5):753-757.
[14]郭成久,周欣,苏芳莉,等.双台河口湿地芦苇对造纸废水中重金属净化效果研究[J].沈阳农业大学学报, 2012, 4433(2):206-210.
[15]韦菊阳,陈章和.梭鱼草和芦苇人工湿地对重金属和营养的去除率比较[J].应用与环境生物学报, 2013, 1199(1):179-183.
[16]冯培勇,陈兆平,靖元孝.人工湿地及其去污机理研究进展[J].生态科学, 2002, 2211(3):264-268.
[17]张洪刚,洪剑明.人工湿地中植物的作用[J].湿地科学, 2006, 4(2):146-154.
[18]梁雪,贺锋,徐栋,等.人工湿地植物的功能与选择[J].水生态学杂志, 2012, 3333(1):131-138.
[19]周桑扬,杨凯,吴晓芙,等.人工湿地植物去除废水中重金属的作用机制研究进展[J].湿地科学, 2016, 1144(5):717-724.
[20]Iamchaturapatr J, Su W Y, Rhee J S. Nutrient removals by 21aquatic plants for vertical free surface-flow(VFS)constructed wetland[J]. Ecological Engineering, 2007, 299(3):287-293.
[21]陈晓艺,徐德福,李映雪,等.三种水生植物枯落物分解特征与人工湿地渗透系数[J].湿地科学, 2017, 1155(5):740-746.
[22]董小霞,颜昌宙,王灶生,等.组合式水生植物净化系统对Cu、Pb和Cd的去除与生物富集特征[J].环境工程学报, 2014, 8(4):1447-1453.
[23]谢丹超.湿地修复生态工程中水生植物对重金属Cu、Zn污染废水的净化研究[D].杭州:浙江大学, 2005.
[24]Soltan M E, Rashed M N. Laboratory study on the survival of water hyacinth under several conditions of heavy metal concentrations[J]. Advances in Environmental Research, 2003, 77(2):321-334.
[25]李峰平,魏红阳,马喆,等.人工湿地植物的选择及植物净化污水作用研究进展[J].湿地科学, 2017, 1155(6):849-854.
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |