Research on the Implementation and Analysis of High-Turbidity Raw Water Pre-Treatment with a Barrier Board

Jian Liang Chen; Yi Kuo Chang; Yun Hwei Shen; Kun Liao Chen

doi:10.4028/www.scientific.net/AMR.610-613.1402

Paper Titles

Sulfur Transformations during Supercritical Water Oxidation of Methanthiol and Thiirane
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Study on Removal of Organic Matters in Surface Water by Adsorption Resin SD500
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Simulation of Air Quality and Pollution Control Countermeasures of Chengdu Urban Agglomeration
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Clarification of High-Salinity Mine Water with Plants
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Research on the Implementation and Analysis of High-Turbidity Raw Water Pre-Treatment with a Barrier Board
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Improvement of Inflow Water Quality of Dian Lake Treated by Constructed Wetlands
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Effect of over-Fire Air Velocity on the Aerodynamic Characteristics in a Cold Model of an Arch-Fired Boiler with New over-Fire Air Arrangement
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Study on BOF Gas Dedusting Technology at Contemporary Steel Plant
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Activities of Activated Sludge Affected by Pharmaceutical Wastewater in a Membrane Bioreactor
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Research on the Implementation and Analysis of High-Turbidity Raw Water Pre-Treatment with a Barrier Board

Abstract:

The purpose of this Research is to simulate the water quality of varied High-turbidity Raw Water at different depths under the water’s surface. During the experiment, a Barrier Board was used to extend the flowing route and to change the overflow level for carrying out the pre-treatment of High-turbidity Raw Water through the changes of varied flow rates in order to study the changes and the removal rate of the turbidity for the influent and effluent; with the settled bottom mud surveyed, the operating requirements of the Surface Overflow Rate (SOR). The experimental result indicated that the turbidity of High-turbidity Water can be reduced by means of an inertia restrained flow, extending the flowing route and heightening the overflow level. The results indicated that the turbidity of the effluent was mostly between 380-1,000 NTU in presenting an over 50% removal rate and even up to 93%. When the SOR of the Sedimentation Basin is set at 19.l m/d, a 54-86% turbidity removal rate can be achieved; whereas, a 50-72% removal rate can be achieved when set at 38.3 m/ d. It has indicated that a significant effect could be achieved for turbidity treatment by employing the properties of high-turbidity substances and the convenient physical theory of gravity settling. As such, a visible removal effect could be achieved to exhibit the effect of pre-treatment.