城市重污染河道治理不同阶段中浮游动物群落的变化

为研究城市重污染河道不同治理阶段中水质变化和浮游动物群落变化特征,于2016—2017年对江苏省宜兴市临溪河进行了工程改善和水生植物恢复两个阶段的治理,并对各阶段治理后河流中的水质及浮游动物进行了调查研究。结果表明,不同阶段水体中高锰酸盐指数、氨氮、TN和TP等基本显著降低。浮游动物的密度和种类、多样性显著提高,轮虫的变化最明显。水生植物恢复后,轮虫优势种由工程治理阶段的角突臂尾轮虫(Brachionus angularis)、壶状臂尾轮虫(Brachionus urceus)等耐污种转变为了寡污的针簇多肢轮虫(Polyarthra trigla),同时出现了腔轮虫(Lecane spp.)和鞍甲轮虫(Lepadella spp.)等清洁水体指示种。根据Margalef指数进行评价,水生植物修复后水体更接近寡污水体,这与水生植物能极大提升水体透明度和DO,为浮游动物提供更多生态位有关。因此,虽然重污染河道治理不同阶段均可显著改善水质,但水生植物恢复对提高浮游动物群落的多样性和稳定性,构建水生生态系统有不可或缺的作用。     

透水坝原位净化山溪性污染河流

针对苕溪流域山溪性河流锦溪水质污染的现状,结合河流水文特征在河道内建设了三级透水坝,考察其对河流水质原位净化的效果。结果表明,透水坝有利于减缓山溪性河流的水速,对水流所携带的悬浮颗粒进行拦截、沉降,对河水浊度的平均去除率约为25%,并可将河水溶解氧(DO)提高1 mg/L以上。透水坝对河流水质的净化效果呈现明显的季节波动,夏季对COD、NH3-N、TN和TP的去除率最高,可维持在20%以上。秋季污染物去除效果有所下降,可能是由于水体中硝化-反硝化菌活性降低、水生植物同化吸收能力有限造成。将来可在透水坝壅水区内优化搭配种植挺水与沉水植物,改善其对氮磷的去除效果。     

生态修复综合技术在杭州虾龙圩河的应用

杭州虾龙圩河由于多年污染，河道水质严重黑臭，自净能力遭到破坏。本研究通过综合利用底泥污染物削减、生物接触氧化水质净化、造流曝气及水生生态系统修复等技术对虾龙圩河进行治理。结果显示，此项综合技术对城市河流污水具有良好的污染物去除性能，COD、NH3-N和TP的去除率分别可达到73．3％、80．1％和81．7％。通过1年的运行与养护，虾龙圩河治理段的水质、生态环境等有了明显改善，没有发生过水华及黑臭现象，河道水体具备了较强的自净能力。     

人工湿地生态修复旅游景区污染水体的研究

提出了采用人工湿地并配合植物操控技术治理旅游景区污染水体,并建立了示范工程.经调试运行,在日处理水量为145 m3条件下,人工湿地对TN、TP、COD和BOD5的去除率分别为63.12%,40.47%,83.07%和73.45%.工程通过2个月的运行,污染水体的水质得到明显改善.该技术为旅游景区和景点的污水治理提供了新途径.     

深圳大工业区初期雨水水质污染特征研究

为研究深圳大工业区初期雨水水质污染特征,分别选择深圳大工业区6个功能区作为监测点监测初期雨水中污染物浓度。结果表明:深圳大工业区居住区和商业区初期雨水COD污染最严重,COD最高分别达到1 467.00、1 333.00mg/L;出口加工区及高科技工业和现代物流业区域的初期雨水TN、TP浓度略低于其他区域。初期雨水中COD、氨氮、TP浓度与SS浓度存在线性相关关系,而TN浓度与SS浓度的线性相关性较差,不同区域随降雨历时变化规律波动各异。深圳大工业区附近河流SS、COD、TN、氨氮、TP浓度受初期雨水影响较大。     

河水受百年一遇大旱后城市降雨径流的污染与治理

2009年入秋至2010年春,中国西南地区发生了百年一遇的特大旱灾。为探讨河水受百年一遇大旱后降雨径流污染的状况,对昆明典型交通干道路面的降雨径流和河水水质进行了监测,分析了大旱后降雨径流污染的严重性和对河水水质的影响,并考察了曝气塘—浮石床水平潜流人工湿地复合系统处理大旱后由城市降雨径流污染导致的重污染河水的效能。结果表明,大旱后的前3场降雨径流污染程度较正常雨季降雨径流污染程度严重,SS、COD、TN及TP浓度平均高出1.3倍。大旱后的前3场降雨径流溢流会对河流造成严重污染。该复合系统在塘调蓄—循环处理运行工况下能有效处理大旱后的重污染河水,对SS、COD、TP、TN和NH4+-N的平均去除率分别为98%、90%、96%、60%和90%,出水均达《城镇污水处理厂污染物排放标准》(GB 18918—2002)一级A标准。     

人工河岸湿地对面源污染的处理效果研究

针对城市河道污染治理存在的主要问题,并考虑到华南地区河流水量、水质、水温季节性变化大的特点,构筑了人工河岸湿地试验系统,对该系统约13个月连续性运行进行了观测和研究。结果表明,平均水力负荷为15cm/d工况下,试验系统对高锰酸盐指数、SS、NH3-N、TN和TP的平均去除率分别为50%、60%、50%、35%和45%;系统对高锰酸盐指数、NH3-N和TN的去除效果随季节变化明显,夏季处理效果好于冬季;SS处理效果受季节影响不明显;TP初期处理效果好于末期。该人工河岸湿地既能较好地改善水质,又能改善生态环境、美化城市景观,是一项适合城市河道污染治理的技术。     

基于北京清河流域水质提升的入河排污口排放要求确定策略研究

为探究基于流域水质目标的入河排污口排放标准与排污许可的实施路径,以北京清河为例,通过入河排污口实地摸排,确定了22个入河排污口和5个河道断面,并于2019年3—10月对27个采样点进行12次水样采集,对水样COD、氨氮、TN和TP进行检测。基于研究河段实测数据,应用MIKE11模型构建流域水动力水质模型,分析3种情景组合的截污纳管方案(方案1)、截污减排方案(方案2)对河段水质的改善效果,以及减排方案在雨期、非雨期对河段水质的污染影响。结果表明:(1)与方案1相比,方案2下研究河段水质状况明显改善,下游出水断面(Q5断面)的COD、氨氮、TN和TP模拟值分别降低49.08%、61.27%、65.80%、63.86%;COD、氨氮、TN和TP排放总量分别削减了541.95、46.13、216.79、8.30t/a。(2)雨期雨水汇入河段后,各污染物达标情况反而恶化,因此应做好入河排污口的污染管控,科学控制入河排污口雨期污染。     

水生生态系统构建技术在改善景观水质中的应用

通过对广东惠州西湖水质的改善及构建水生生态系统的示范工程研究，即将水位调控、湖底底质处理、水生生物的种植养殖工程、系统优化维护管理等技术进行集成、总结，形成水生生态系统，构建和改善景观水水质的稳定技术。研究结果表明：示范区与对照区比较，浊度下降最高值为80．6mg／L；透明度提高3-6倍；CODcr最大去除率为42．6％；系统对水体上下层溶解氧含量的影响表现出明显的差异：示范区与对照区上层溶解氧含量最大相差值为1．2mg／L，下层为3．4mg／L；叶绿素a去除率达到80％以上；比较TN、TP的动态变化结果显示，系统对TP的影响更加明显，最高去除率为68．1％，对TN的最高去除率为19．8％。     

复合植物床式人工湿地研究

本实验研究针对应用于面源污染控制的人工湿地中水生植物的选择和布置问题进行研究，通过对人工湿地动态运行实验和研究考察，发现床体中COD、TN降解规律，通过人工湿地栽种不同水生植物的各床体的COD去除效果比较实验和不同水生植物复氧性能比较实验，得出复氧性能最好的水生植物为芦苇，然后综合这三个实验，在传统的植物床系统基础上，提出更加有利于提高系统污水处理效率的改进形式；复合植物床式人工湿地。     

漂浮植物塘处理农村分散生活污水的应用

通过现场实验评价了漂浮植物塘配合化粪池处理农村分散生活污水的效果。实验结果表明,漂浮植物有效地抑制了污染水体中藻类的生长;在平均水力停留时间为36 d,COD、TN、TP平均污染负荷分别为3.1、0.86和0.056 g/(m2.d)的条件下,大薸塘对COD、TN、TP的平均去除率分别为68.5%、89.9%和85.2%,出水COD、TN和TP平均浓度分别为47、4.15和0.40 mg/L,达到GB18918-2002中的一级A标准。在水乡地区利用漂浮植物与农村宅河构造漂浮植物处理系统,是一种深度处理化粪池出水、控制农村生活污水对河道造成污染的有效措施。     

基于新型有机多孔复合基质的生物系统去除污染水体中的氮磷

针对太湖入湖河道污染水体中的氮磷超标问题,以海绵铁、沸石、砾石和土壤为基质,采用动态吸附+生物法,对氮磷开展基于新型有机多孔复合填料的去除效果研究,结果表明,生物系统中的新型有机多孔复合基质在空间上形成了好氧-缺氧微环境,获得了较好的同步硝化-反硝化效果;通过正交实验确定流量0.00075 L/s,曝气时间24 h,pH值7,曝气量20 L/min为去除氮磷的最优条件;相对一级动力学方程、双常数方程而言,Elovich方程对3种填料的吸附动力学特征拟合最好,决定系数R2在0.81～0.92之间。通过平均去除效果较优分析,好氧条件下,NH3-N平均去除70.6%,TP平均去除81.2%;厌氧条件下,TN平均去除62.4%,COD平均去除42.6%;NH3-N、TP、TN和COD的最低浓度分别为0.75、0.095、1.1和18.3 mg/L,综合考虑主要污染物的去除效果和经济效益,本项新型有机多孔复合填料结合生物系统适宜去除河原平网地区污染水体中的氮磷。     

曝气充氧和人工造流技术修复河道污染水体

基于模拟河道反应器，考察了曝气充氧及人工造流技术对污染水体的修复效果。结果表明，河道本身具有一定的自净能力，自然运行条件下对COD、TP、NH₃-N和TN的去除率分别为7.44%、4.88%、5.70%和10.60%。通过对模拟河道进行曝气充氧，最佳气水比条件下对COD、TP、NH₃-N和TN的去除率分别为15.33%、10.45%、6.78%和21.18%。在曝气基础上通过设置人工阻流板，对COD、TP、NH₃-N和TN的去除率分别为26.82%、16.07%、9.51%和23.80%。结果初步显示，通过曝气充氧和人工造流技术的集成应用研究，对污染水体具有明显有效的修复作用。     

Establishment of reference conditions for nutrients in an intensive agricultural watershed,Eastern China

Nutrient enrichment from nonpoint source pollution is one of the main causes of poor water quality and biotic impairment in many streams and rivers worldwide. The establishment of reference nutrient conditions in a river system is an essential but difficult task for water quality control. In the present study, the reference concentrations of total nitrogen (TN) and total phosphorus (TP) were estimated in an intensive agricultural watershed, the Cao-E River system of Eastern China. Based on a 3-year water quality monitoring data in the river system, three approaches were adopted to establish the reference concentrations of TN and TP, those are the 75th percentile of frequency distribution of nutrient concentrations in reference streams, the 25th percentile of frequency distribution of nutrient concentration in general streams (including reference and non-reference streams) and regression modeling. Results showed that the nutrient reference concentrations were slightly different from different approaches. By the three approaches, the average reference concentrations for TN and TP in the study system were 1.73?±?0.13 mg l^?1 and 55.23?±?4.77 μg l^?1 with CV of 7.39 % and 8.63 %, respectively. Accordingly, the reference concentrations for TN and TP were recommended to be 1.70 mg l^?1 and 55 μg l^?1, respectively. In the mountainous and intensive agricultural watershed, the major anthropogenic impacts to river water quality were the urban area percentage cover, cropland area with slopes 0–8°, and livestock and poultry waste loads density. These variables could account for 89.7 % and 80.3 % of the total variations for TN and TP concentration, respectively.     

Support vector machine―an alternative to artificial neuron network for water quality forecasting in an agricultural nonpoint source polluted river?

Water quality forecasting in agricultural drainage river basins is difficult because of the complicated nonpoint source (NPS) pollution transport processes and river self-purification processes involved in highly nonlinear problems. Artificial neural network (ANN) and support vector model (SVM) were developed to predict total nitrogen (TN) and total phosphorus (TP) concentrations for any location of the river polluted by agricultural NPS pollution in eastern China. River flow, water temperature, flow travel time, rainfall, dissolved oxygen, and upstream TN or TP concentrations were selected as initial inputs of the two models. Monthly, bimonthly, and trimonthly datasets were selected to train the two models, respectively, and the same monthly dataset which had not been used for training was chosen to test the models in order to compare their generalization performance. Trial and error analysis and genetic algorisms (GA) were employed to optimize the parameters of ANN and SVM models, respectively. The results indicated that the proposed SVM models performed better generalization ability due to avoiding the occurrence of overtraining and optimizing fewer parameters based on structural risk minimization (SRM) principle. Furthermore, both TN and TP SVM models trained by trimonthly datasets achieved greater forecasting accuracy than corresponding ANN models. Thus, SVM models will be a powerful alternative method because it is an efficient and economic tool to accurately predict water quality with low risk. The sensitivity analyses of two models indicated that decreasing upstream input concentrations during the dry season and NPS emission along the reach during average or flood season should be an effective way to improve Changle River water quality. If the necessary water quality and hydrology data and even trimonthly data are available, the SVM methodology developed here can easily be applied to other NPS-polluted rivers.     

Case study on rehabilitation of a polluted urban water body in Yangtze River Basin

In the past three decades, the fast development of economy and urbanization has caused increasingly severe pollutions of urban water bodies in China. Consequently, eutrophication and deterioration of aquatic ecosystem, which is especially significant for aquatic vegetation, inevitably became a pervasive problem across the Yangtze River Basin. To rehabilitate the degraded urban water bodies, vegetation replanting is an important issue to improve water quality and to rehabilitate ecosystem. As a case study, a representative polluted urban river, Nanfeihe River, in Hefei City, Anhui Province, was chosen to be a rehabilitation target. In October 2009 and May 2010, 13 species of indigenous and prevalent macrophytes, including seven species emergent, one species floating leaved, and five species submersed macrophytes, were planted along the bank slopes and in the river. Through 1.5 years’ replanting practice, the water quality and biodiversity of the river had been improved. The concentrations of total nitrogen (TN), total phosphorus (TP), and ammonia nitrogen (NH₄ ⁺–N) declined by 46.0, 39.5, and 60.4 %, respectively. The species of macrophytes increased from 14 to 60, and the biodiversity of phytoplankton rose significantly in the river (p?<?0.05). The biomasses of zooplankton and benthos were also improved after the vegetation replanting. The study confirmed that vegetation replanting could alleviate the increasing water pollution and rehabilitate the degraded aquatic ecosystem. The case study would be an example for polluted urban waters restoration in the middle–downstream area of Yangtze River Base.     

可渗透反应墙技术的水质净化特性

通过中试研究考察了可渗透反应墙(PRB)技术的动态水质净化特性。结果表明:(1)在动态条件下,PRB中试系统中COD、NH4+-N、NO3--N、TN、TP去除率随水力停留时间(HRT)的延长而增加。当HRT为7.00h时,COD、NH4+-N、TN、TP去除率分别为59.4%、26.9%、76.6%、62.2%、82.0%。HRT的延长使难生物降解的有机物也得到部分降解,PRB中试系统中铁屑及新生态的[H]、铁离子的氧化还原作用可以大幅度提高水的可生化性。(2)PRB技术对COD、NH4+-N、TN、TP的去除主要发生在反应区前半段,而且PRB中试系统中COD、NH4+-N、TN、TP沿程的变化情况可用指数方程来描述,动态模型预测曲线拟合较好。同时,对于实际PRB技术工程,PRB技术选择适当的反应介质及介质配比是关键环节。     

复合人工湿地对城市受污染河水的净化效果

采用2种复合人工湿地系统处理昆明市城市河流污水,为期1年的运行结果表明:2种复合人工湿地系统对城市河流污水具有良好的污染物去除性能,TN、TP、COD和SS的月平均去除率分别达到50%、85%、85%和80%以上;2种复合人工湿地系统具有良好的耐冲击性,季节变化对出水水质不存在显著影响。其中,垂直上行流复合人工湿地系统性能更优于垂直上行流与水平流复合人工湿地系统;强降雨会对复合人工湿地出水水质造成一定的影响。     

潜流人工湿地-生物接触氧化处理低温低浓度生活污水

在低温低浓度生活污水的实验研究中，回流比和气水比是影响潜流人工湿地一生物接触氧化组合工艺污染物去除效果的重要因素，推荐回流比R=1．0，气水比为4：1，在该工况下，进水COD浓度在170．8～221．3mg／L时，平均去除率可达90％；进水NH3-N浓度在17．3～25．9mg／L，平均去除率45％～65％；进水TN浓度在25．1～38．49mg／L时，平均去除率45％～65％；进水TP浓度在2．2～3．1mg／L时，平均去除率65％～80％。污染物沿程浓度分析结果表明，该组合工艺可以在低温季节通过曝气促进氨氮硝化，大幅提高NH3-N和TN去除率，同时可以充分发挥复合潜流湿地功能。