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*陈源高1,2 吴献花3 李文朝2 孔志明1**(1,210093;2,210008;3,653100)【】 ,1hm2.、,.,.7.75%~81.10%,54.9%.265mg·m-2·d-1,,26.1mg·m-2·d-1,10%,,.,. 1001-9332(2005)10-1913-05 X171.4 APhosphorusremovalefficiencyofYaonigouconstructedwetlandonFuxianlakeshore.CHENYuangao1,2,WUXianhua3,LIWenchao2,KONGZhiming1(1StateKeyLaboratoryofPollutionControlandResourceReuse,En-vironmentalSchoolofNanjingUniversity,Nanjing210093,China;2NanjingInstituteofGeographyandLimnology,ChineseAcademyofSciences,Nanjing210008,China;3YuxiNormalCollege,Yuxi653100,Chi-na).-Chin.J.Appl.Ecol.,2005,16(10):1913~1917.TomitigateandcontroltheeutrophicationofthewatersinFuxianLakebay,1hm2Yaonigouconstructedwet-landwasbuiltonthenorthFuxianlakeshore,andthePremovalofthewastewaterfromYaonigouRiverwasin-vestigatedbythetechniquesofprecipitationpond,oxidationpond,andsubsurface-andsurfaceflowconstructedwetland.Theresultsdemonstratedthatthisconstructedwetlandhadaverystrongcapacity(7.8%~81.1%)oftotalphosphorus(TP)removal.TheaverageremovalrateofTPwas54.9%,andtheTPretentioninthecon-structedwetlandwas265mg·m-2·d-1,ofwhich,plantassimilationwas26.1mg·m-2·d-1,about10%ofthetotal.TheTPremovalwasmainlythroughadsorptionandsedimentation,buttheseasonalgrowthdynamicsofmainplantOenanthejavanicacouldhaveadefiniteeffectontheefficiencyofTPremoval.Duringtheexamina-tion,theTPretentioncapacitywasinorderofsubsurfaceflowconstructedwetlandoxidationpondprecipita-tionpondsurfaceflowconstructedwetland.Keywords FuxianLake,Constructedwetland,Phosphorousremovalefficiency.*“863”(2002AA601013).**.2004-06-17,2004-09-10.1 ,N、P,N、P99.1%98.5%.,N、P、CODcrSS81.4%、86%、68%、61%,,,.,,,,.[1,2,14,16,19].,、、[8,9,12,18,26].、、,[4,5,10,25,27,28].,,,,.,.2 2.1 ,1.5hm2.,、、 200510 16 10 CHINESEJOURNALOFAPPLIEDECOLOGY,Oct.2005,16(10)∶1913~1917DOI:10.13287/j.1001-9332.2005.0264,1hm2;、,0.5hm2.313.3hm2,,、、,.1.1 Fig.1SchematicdiagramofYaonigouconstructedwetland. ,(Oenanthejavanica),5700m2,57%.,415m×15m,60cm.1:3~5cm,(Typhalatifolia);2:0.2~0.5cm,(Phragmitescommunis);3:1~2cm,;4:,.1.1 Table1DesignofcharacteristicsinconstructedwetlandFunctionregionArea(m2)Depth(m)PlantspeciesPurificationmethod Precipitationtank9001.0~1.5、CannaindicaandTyphalatifoliaSalvageanddepositOxidationpondsPond1:17001.5~1.8Oenanthejavanica3ThreepondsinseriesPond2:17001.5~1.8OenanthejavanicaPond3:12601.5~1.8、TrapaceaeandNenupharHorizontalsubsurfaceflowconstructedwetland9000.4~0.6、、TyphalatifoliaandPhragmitescommunisFourcellsinparallelconnectionSurfaceflow(SF)constructedwetlandSF1:2300SF2:13000.2~0.30.2~0.3Oenanthejavanica、NelumbonuciferaandSagittiariasagittifoliaTwoterracesinse-ries2.2 20023~12,,710,[6]P、N.1m2.3 3.1 ,,,0~78000m3·d-1.5000m3·d-1,48h.,15.6,3h,,,,;,6d,,;,1500~11000m3·d-1,4400m3·d-1,51.8h,.,TP0.53~2.20mg·L-1,1.10mg·L-1,2.2 Table2Concentrationofinletpollutantsinconstructedwetland(mg·L-1)SSBOD5CODcrTPPO-4-PTNConcentration19~1229.5~64.126.9~1940.68~2.200.31~0.885.13~14.93Average6051.276.81.100.699.003.2 ,,,750t,0.238%,179kg.,,,,.,TP2.7%,P147mg·m-2·d-1,15.6kg·m-2,1.44kg.SS,62%,,、.C、N、P(3).3.3 3,123 C、N、PTable3ContentofC,NandPintheinletandoutletsedimentofpre-cipitationtank(%)Jul.10InletOutletOct.29InletOutletC2.2231.2914.5461.454N0.1900.1370.5760.246P0.1090.1010.1760.1031914 16,80%,3.,.,TP,70%;,,TP,30%.,TP、0.68~2.180.31~1.50mg·L-1,3.0%~68.5%,27.8%(2),283mg·m-2·d-1.,45kg·m-2,57kg;12.8kg·m-2,6.8kg.13%.,SS,20%~90.32%,60%.2 TPFig.2ConcentrationandremovalrateofTPintheoxidationpond.3.4 TP0.31~1.50mg·L-1,11.19%~60.00%,24%(3),896mg·m-2·d-1,3.1,7.6.,,1.1kg,1.4kg,1%,TP.4,.TP1(42.23%)4(36.19%)2(33.49%)3(21.14%).,131,,,,3 TPFig.3ConcentrationandremovalrateofTPinsubsurfaceflowcon-structedwetland.,3~5cm1,.,,,.3.5 .TN40%,2,4,CODCr,TP,15.2%,4.117mg·m-2·d-1,28kg,18%,.4 Table4Concentrationofpollutantsintheoutletofsurfaceflowcon-structedwetland(mg·L-1)SSBOD5CODCrTPTNNH3-NOutletconcentration0.8~103.0~5.34.1~24.50.503.720.3~4.53.6 TP0.68~2.20mg·L-1,1.10mg·L-1,4,TP0.5mg·L-1,54.9%(4).、,[30].265mg·m-2·d-1,,96kg,10%.191510 : 4 Fig.4ConcentrationandremovalrateofTPinYaonigouconstructedwetland.4 ,ICP.,FeAl10%~20%,CaMg,,Ca、Mg、FeAl.(Ca2+、Mg2+、Fe3+、Al3+),[3,13,15,17,21].,,,,;,,,[7,29].90%,.,,97%99%.,[11,20,23].[22],,、.,,、、、.,,、、,N、P[24,30].10%,.,,13%18%.P,,、,,P,;,、,,[22,27].,,.,,.,,10℃,.1 BraskerudBC.2002.Factorsaffectingnitrogenretentioninsmallconstructedwetlandstreatingagriculturalnon-pointsourcepollu-tion.EcolEng,18:351~3702 CarstenS.2003.Treatmentofrainbowtroutfarmeffluentsincon-structedwetlandwithemergentplantsandsubsurfacehorizontalwaterflow.Aquaculture,217:207~2213 ChescheirGM,SkaggsRW,GilliamJW.1992.Evaluationofwet-landbufferareasfortreatmentofpumpedagriculturaldrainagewa-ter.TransAmerSocAgricEng,35:175~1824 ChenG-Z(),MaM-J(),LanC-Y(),etal.1990.InvestigationonecologysystemofpondpurifiedbyCattail.ChinJEcol(),9(4):11~15(inChinese)5 CuiL-H(),ZhuX-Z(),LuoS-M(),etal.2003.Purificationefficiencyofvertical-flowwetlandsystemcon-structedbycinderandturfsubstrateonmunicipalwastewater.ChinJApplEcol(),14(4):597~60