Study on the Design of Wetland Based on Hydrodynamic Condition - A Case of Candle Lake Wetland at Qingxiu Mountain Scenic Spot in Nanning City

Qiu Lin Liao; Gen Li; Shou Yun Shen

doi:10.4028/www.scientific.net/AMM.723.150

Paper Titles

Experimental Investigation of Solid Attitude Control System Using Proportional Pintle Thrusters
p.131

Initial-Boundary Value Problem on Unsteady Flows in a Canal
p.136

Numerical Simulation of Flow Field in the Tundish with Two Outlets
p.140

Numerical Simulations and Experiments on Changes in Erythrocyte Morphology under Continue Flow Ventricular Assisted Devices
p.145

Study on the Design of Wetland Based on Hydrodynamic Condition - A Case of Candle Lake Wetland at Qingxiu Mountain Scenic Spot in Nanning City
p.150

The Influence of Characterization of Metallic Gasket Rough Surface on Gas Sealing Performance in Seal Structure
p.162

The Kinematic Analysis of Double Water Jets Ship
p.167

3D Numerical Simulation and Experimental Analysis of Spillway Tunnel
p.171

Dynamics Simulation of Particles of a Smoke Generator Based on SPH Method
p.176

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 723Study on the Design of Wetland Based on...

Study on the Design of Wetland Based on Hydrodynamic Condition - A Case of Candle Lake Wetland at Qingxiu Mountain Scenic Spot in Nanning City

Abstract:

Candle Lake wetland at Qingxiu Mountain scenic spot is one of the most important parts of the 'China Water Town' program in Nanning city. In order to figure out the scientific rationality of the situation and design of wetland system, five pilot programs are set up based on flow velocity of three inlets, quantity and position of five outlets and the shape of center island to simulate the flow field and velocity of Candle Lake wetland by using two-dimensional numeral simulation. The results indicated that as follows: 1. The flow field and velocity of Candle Lake wetland can't be improved by increasing the velocity of inlets in the wetland system, so that the problem of large standing water can’t be solved. 2. The flow field and velocity of Candle Lake wetland are influenced by the position and quantity of outlets, especially the outlet 2, outlet 4 and outlet 5, which can improve the flow field and velocity effectively. 3. The flow field and velocity of Candle Lake wetland are also influenced by the shape of shoreline. Optimizing shoreline of Chengxiang Island can improve the flow field and velocity of Candle Lake wetland near the island very well. The flow field and slow velocity of Candle Lake wetland can be improved effectively by the optimizing shape of the Chengxiang Island and the position of outlet 4 and outlet 5, and the problems of large standing water and circulation can be solved very well.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volume 723)

Pages:

150-161

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.723.150

Citation:

Cite this paper

Online since:

January 2015

Authors:

Qiu Lin Liao, Gen Li, Shou Yun Shen*

Keywords:

Candle Lake, Hydrodynamic, Landscape Wetland, Numeral Simulation, Wetland Engineering

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] Tong qingyuan, Zhao dongquan, Hu jie. Design for Simulation &Maintenance System of Water Quality in Beijing Olympic Forest Park [J]. Chinese Landscape Architecture, 2006, (8): 22-26.

Google Scholar

[2] Dang dongyu. The Practice of Water Purification and Landscape Construction in Wu River Wetland [J]. Chinese Landscape Architecture, 2012, (9): 83-86.

Google Scholar

[3] Sun lin, Shen shouyun, Xiong qiming. Effects of four aquatic plants on water quality [J]. Journal of Central South University of Forestry & Technology，2011，31(1): 91-97.

Google Scholar

[4] Chen yonghua, Wu xiaofu, Hao jun. Selection and Purification Constructed Wetlands in Potential Evaluation of Woody Plant in Vertical Flow the Subtropical Area[J]. Environmental Science, 2014, 35(2): 585-591.

Google Scholar

[5] Chen yonghua, Wu xiaofu, Hao jun . The adaptability and decontamination effect of four kinds of woody plants inconstructed wetland environment．Ecological Sinica, 2014, 34( 4) : 916-924.

DOI: 10.5846/stxb201305191110

Google Scholar

[6] Wang Hui. The two-dimensional numerical simulations for the flow field of Furong Lake base on CFD.

Google Scholar

[7] Huang Li, Peng Shujuan. Research on water quality simulation and prediction of small scenic water body.

Google Scholar

[8] Luo Bijun, Fan Zaiyi, Chen Lina. Study on Circulation Mode and Flow Field 0ptimization of Landscape Water Using Fluent Software[J]. China Water & Wastewater, 2009, 25(19): 95-97.

Google Scholar

[9] Liao ping'an, Hu Xiulin. Experimental study on the effect of flow velocity on algal growth [J]. Beijing Water Resources, 2005, (2): 12-15.

Google Scholar

[10] Wang Hua, Pang Yong. Numerical Simulation on Hydrodynamic Character for Algae Growth.

Google Scholar

[11] Zhang Yimin, Zhang Yngchun, Zhang Longjiang. The influence of lake hydrodynamics on blue algal growth. [J]. China Environmental Science, 2007, 27(5): 707-711.

Google Scholar

[12] Wang Lili. Research on the Relevant Factors of the Algal Growth in Hydrodynamic Condition [D]Chong Qin University, 2006: 98-112.

Google Scholar

[13] Jiao Shijun. The effects of velocity of glow to the growth of algae low current area of the Three Gorges.

Google Scholar

[14] B. Foddy. Translated by Luo Di an. Algology [M]. Shanghai science and Technology Press, 1980: 392-394.

Google Scholar

[15] Yuan wenlin, Zhang Weijia, Huang Yong. Research on Manual Hydraulic Circulation for Improving Water Quality in Irregular Ponds in Garden [J]. China Water & Wastewater, 2008, 24(3): 17-20.

Google Scholar