For Libraries For Publication Open Access Downloads About Us Contact Us
Paper Titles
Effect of Aqueous Extracts of Cultured Cordyceps militaris on Bombyx mori Ovary Cell Lines
p.271
Microwave Synthesis of Nanosilver Colloidal Suspension for Anti-Bacterial Coating
p.277
Photosynthetic Responses of Energy Plant Maize under Cadmium Contamination Stress
p.283
Cadmium Tolerance and Accumulation in Vitex negundo var. heterophylla in Pot Experiment
p.287
Ultrasound Enhanced Coagulation to Remove Organic Matter in Low Temperature and Low Turbidity Studies
p.291
Adsorption of 4-Chlorophenol onto Hypercrosslinked Resins
p.298
Influence of pH and Nitrate on Perchlorate Biological Reduction
p.303
Kinetic Studies for the Inhibition Effect of Pentachlorophenol on Alkaline Phosphatase Activity In Vitro
p.309
Study on the Photocatalytic Degradation of Wastewater under the Optimal Preparation of the Activated Carbon Supported TiO2 Thin Film
p.313

Ultrasound Enhanced Coagulation to Remove Organic Matter in Low Temperature and Low Turbidity Studies

Article Preview

Abstract:

In the experiment that the disposal of low temperature and low turbidity water, we observed the influence of some factors ,such as the acting time of ultrasound, ultrasonic power, amount of coagulant and the PH value of system, in disposing the organic matters of low temperature and low turbidity water. The experimental results show that the water samples which were disposed by ultrasound acting firstly and then by coagulation precipitate processing are best. When ultrasonic acting is 9 min, ultrasonic power transferred to 25 W, the amount of coagulant polyferric sulphate is 12 mg/L and the system pH is 7, the maximum of COD removal rate will up to 87.2%.

You might also be interested in these eBooks
Progress in Environmental Science and Engineering (ICEESD) View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 356-360)

Pages:

291-297

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.356-360.291

Citation:

Cite this paper

Online since:

October 2011

Authors:

Jun Wen Li, Xin Li, Xiao Hui Xu, Dong Bing Wang

Keywords:

Enhanced Coagulation, Low Temperature and Low Turbidity, Ultrasonic

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2012 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

References

[1] Haiying Li. Shallow talk low temperature and low turbidity water treatment technology [J]. Environmental Science Tribune,2009,28 (Supplement) :84~86.(In Chinese)

Google Scholar

[2] S Kempeneers, Vanmf, Gillel. Adecade of large scale experience in dissolved air flotation [J]. Wat. Sci. Tech,2001,43 (8):27~34.

Google Scholar

[3] Peng Rao. Low temperature and low turbidity water treatment [J]. Technology for Development, 2009, 09: 55.(In Chinese)

Google Scholar

[4] T. Schfield. Dissolved air flotation in drinking water production[J].Wat. Sci. Tech,2001,43 (8):9~18.

Google Scholar

[5] K. Ebie, Y. Azuma. Reducing turbidity and coagulant residue intreated water through optimization of rapid mix conditions [J].Water Science & Technology: Water Supply,2002,2(5-6):103~110.

DOI: 10.2166/ws.2002.0157

Google Scholar

[6] Guoying Li, Youjie He, Bi Shi. Ultrasonic technology strengthen treatment tannery wastewater treatment of organic matter [J]. Environmental Science, 2001, 22 (5): 102~104.(In Chinese)

Google Scholar

[7] Chunxi Li, Hui Wei. Ultrasound technology in wastewater treatment applications and research [J]. The environmental pollution control technology and equipment,2001,2 (2): 64~69.(In Chinese)

Google Scholar

[8] Jianhua Ma, Jianfu Zhao, Xuenong Yi. Ultrasonic technology research progress in water treatment [J]. Shanghai Environmental Science,2002,21 (5):298~301.(In Chinese)

Google Scholar

[9] Guoqing Nie, Yaoguo Wu, Xiang Li,Qiuhua Wang. Ultrasonic technology in water treatment in the research progress of the main influence factors [J]. Water treatment technology,2008,34 (3) : 11~14.(In Chinese)

Google Scholar

[10] Jie Chen, Bo Wang, Guangming Zhang. Ultrasound enhanced coagulation remove algae experiment research [J]. Environment engineering journal,2007,1 (3):66~71.(In Chinese)

Google Scholar

[11] Huchun Tao, Qi Zhang, Shaofeng Li. Acidification-Fenton-coagulation treatment process printed circuit board imaging wastewater [J]. Industrial Water Treatment,2009,11:18~20.(In Chinese)

Google Scholar

[12] T. J .Lee, K .Nakano, M .Matsumara. Ultrasonic irradiation for blue-green algae bloom control Environ. Technol,2001,22 (4): 383~390.

DOI: 10.1080/09593332208618270

Google Scholar

[13] Shaogang Liu. Ultrasonic strengthen treatment acid bright red. GR wastewater [J]. Nanjing university of technology,2004.(In Chinese)

Google Scholar

[14] J .M . Ko, S .H .Yo. Koda. .Effects of sample volume and frequeney on ultrasonic power in solution sonication,Japanese Journal of Applied Physies,Part1:Regular Papers & Short Notes &Review Papers,1998,37 (SB):2992~2995.

Google Scholar

[15] Xuemei Qi, Yongchang Liu. The enhanced coagulation technology to remove the water research progress of organic matter [J]. Shanghai electric power of journals,2007,23(4):354~358.(In Chinese)

Google Scholar

[16] T Maria,M Sylwia,W Antoni. Removal of organic matter by coagulation enhanced with adsorption on PAC [J]. Desalination, 2004, 16: 179~187.

Google Scholar

[17] Xiaodong Jiang. Water treatment technology enhanced coagulation technology research and application [J]. Chongqing industry higher school journal,2005,20 (1):39~42.(In Chinese)

Google Scholar

© 2025 Trans Tech Publications Ltd. All rights are reserved, including those for text and data mining, AI training, and similar technologies. For open access content, terms of the Creative Commons licensing CC-BY are applied.
Scientific.Net is a registered trademark of Trans Tech Publications Ltd.