| 妫水河湿地植物作用及调水水质响应模拟 |
| 摘要点击 1183 全文点击 555 投稿时间:2020-02-10 修订日期:2020-03-27 |
| 查看HTML全文
查看全文 查看/发表评论 下载PDF阅读器 |
| 中文关键词 表流湿地 MIKE 21-EcoLab 水质模拟 植物净化作用 妫水河 |
| 英文关键词 surface wetland MIKE 21-EcoLab water quality simulation purification function of vegetation Guishui River |
|
| 中文摘要 |
| 本文基于湿地植物在河流湖泊中的物理、生化反应机制,应用MIKE21中EcoLab的编辑功能,建立湿地植物的水质模块,将植物的阻流、产氧、耗氧及微生物和植物吸收营养盐过程参与计算中,耦合湿地水动力实现水质模拟.在对妫水河表流湿地调研及监测基础上,建立妫水河下游与三里河的模型,考虑湿地植物类型、分布及水量变化下的植物有效面积等作用,定量研究工程尺度上河流湿地水动力及水质净化效果.计算中采用实测数据率定湿地植物对水质作用的关键参数,并对模拟结果进行验证.通过模拟,无循环系统对支流三里河及上游调水时,岸带湿地建设后相比建设前,下游出口处氨氮、磷酸盐和总氮的浓度下降了14.29%、33.33%和20.00%;循环系统运行后,三里河和妫水河上游流量分别增加0.4 m3 ·s-1,使得部分河段水位抬升,断面平均流速略有增加,三里河和妫水河的有效湿地覆盖率分别增加了144.44%和13.16%,出水口处水质与工程前相比,氨氮、磷酸盐和总氮分别下降了35.71%、50.00%和46.67%,循环体系的建设加强了湿地净化功能.模型有机地将湿地植物分布融合进模型水质计算中,为河湖湿地生态修复、方案设计和水利调控等综合措施下的水质响应研究提供了模型方法和技术支撑. |
| 英文摘要 |
| A two-dimensional model MIKE21 coupled with a modified EcoLab module was applied to model the water quality of surface flow wetlands. In the model, vegetation effects, oxygen production, nutrient consumption by microorganisms and vegetation were set in the solutions of hydrodynamic, chemical, and biological processes. Based on the field investigation and measurements in the Guishui River wetland, the model was established for the downstream reaches of the Guishui River and the Sanli River. The model calculated the hydrodynamics and water quality changes by vegetation type and distribution. The model parameters were calibrated and results were validated using the measurements. The concentrations of ammonia nitrogen, phosphate, and total nitrogen at outflow decreased by 14.29%, 33.33%, and 20.00% in the presence of wetland vegetation compared to no wetland vegetation. During water circulation, the flow rate increased by 0.4 m3 ·s-1 at the inlet of Guishui and Sanli rivers, increasing the water level and velocity in some parts of the rivers. The water areas with vegetation in Sanli and Guishui rivers increased by 144.44% and 13.16%, respectively. The concentrations of ammonia nitrogen, phosphate, and total nitrogen at outflow decreased by 35.71%, 50.00%, and 46.67% compared to no wetlands and no circulation. The circulation strengthened the wetland purification function. The wetland vegetation distribution was organically integrated into the model for water quality calculation, which provides the technical support for the water quality response research under comprehensive measures such as river and lake wetland ecological restoration and water conservancy regulation. |
|
|
|
