Treatment of Rural Domestic Sewage by Solar Ozonic Ecological Sewage Treatment Plant

Wei Zheng; Yan Ming Yang; Yun Long Li; Jian Qiu Zheng

doi:10.4028/www.scientific.net/AMR.955-959.3393

Paper Titles

Study on Pure Aqueous Extraction Method of PHB/Ectoine Co-Products Based on Osmotic Downshock
p.3377

Effect of Seasonal Variation on Iron Release in Drinking Water Distribution Systems
p.3381

Experimental Test of Dynamic Moving Characteristics for Leak Detecting-Ball in Water Mains
p.3385

Study on Achievement and Temperature Influence of Shortcut Nitrification in Sequencing Biofilm Batch Reactor
p.3389

Treatment of Rural Domestic Sewage by Solar Ozonic Ecological Sewage Treatment Plant
p.3393

Design of a Four-Effect Desalination Demonstration Plant Using Waste Heat from a Diesel Engine
p.3400

Intelligent Irrigation Remote Control System Based on Internet of Things
p.3404

Comparison on Permanganate and Ozone as Pre-Oxidation Agents
p.3408

Effects of Humic Acid on Surface Characteristics and Hydrodynamic Properties of Alum-TiO₂ NPs Flocs
p.3414

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 955-959Treatment of Rural Domestic Sewage by Solar Ozonic...

Treatment of Rural Domestic Sewage by Solar Ozonic Ecological Sewage Treatment Plant

Abstract:

The process technique and design parameters of project of Solar Ozonic Ecological Sewage Treatment Plant (short for SOESTP) which consists of anaerobic reactor, horizontal subsurface flow (HSSF) constructed wetlands(CWs) and the combination of solar power and ozone disinfection are described, the paper further examines the removal efficiency for treating rural domestic sewage, running expense and recycling ability of product water. The results show that the average percentage removal values of CODcr，BOD₅，SS，TN，NH₃-N，TP range from 95.6% to 98.0%, 96.0% to 98.7%, 93.1% to 96.1%, 97.0% to 98.9%, 96.9% to 99.5%, 98.2% to 99.6%, respectively, the reduction of fecal coliform (FC) reaches 99.9%, the effluent quality meets the first level A criteria specified in Discharge Standard of Pollutants for Municipal Wastewater Treatment Plant（GB18918-2002）. The running cost of SOESTP is 0.063yuan/ m³, saves much more than traditional sewage treatment, and the ozone water obtained from the reservoir will be an ideal choice for disinfection .The system has characteristics of easy manipulation, low operating cost, achieving advanced water, energy conservation and environment protection, is thought to be very suitable for use as the promotion of rural small - scale sewage treatment.

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Periodical:

Advanced Materials Research (Volumes 955-959)

Pages:

3393-3399

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.955-959.3393

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Online since:

June 2014

Authors:

Wei Zheng, Yan Ming Yang*, Yun Long Li, Jian Qiu Zheng

Keywords:

Anaerobic Reactor, Constructed Wetland, Ozone Disinfection, Small - Scale Wastewater, Solar Power

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References

[1] Ahmed Ghrabi, Latifa Bousselmi, Fabio Masi, and Martin Regelsberger: Water Science & Technology, VOL. 63(12)( 2011), P. 3006-3012.

DOI: 10.2166/wst.2011.563

Google Scholar

[2] Batty, L.C., Atkin, L., Manning, and D. A. C: Environmental Pollution, VOL. 138(2005), P. 412-419.

Google Scholar

[3] Kadlec R H: Ecological Engineerin. VOL. 33(2) (2008), P. 126-141.

Google Scholar

[4] K. Haarstad, H.J. Bavor , and T. Maehlum: Water Science & Technology, VOL. 65(1) (2012), P. 76-99.

Google Scholar

[5] Dong Liu, Ying Ge, Jie Chang, Changhui Peng, Binhe Gu, Gilbert YS Chan, and Xiaofu Wu : Front Ecological Environment. VOL. 7(5)(2009), P. 261-268.

Google Scholar

[6] Nivala, J., Knowles, P., Dotro, G., Garcia, J., and Wallace, S: Water Resource. VOL. 46 (2012), P. 1625-1640.

Google Scholar

[7] Shubiau,W., Austin, D., Lin Liu，and Dong，R: Ecological Engineering. VOL. 37(2011), P. 948-954.

Google Scholar

[8] Truong, H.D., Quang, L.N., Nguyen, H. C., and Brix, H: Ecological Engibeering. VOL. 37( 2011), P. 711-720.

Google Scholar

[9] Vahid Zahraeifard, and ZhiQiang Deng: Ecological Engineering, VOL. 37(2011), P. 2087-(2091).

Google Scholar

[10] Wallace, S.D., Nivala, and J. A: IWA Specialist Group on the Use of Macrophytes in Water Pollution Control Newslette. VOL. 29 (2)( 2005) ,P. 5-7.

Google Scholar