The Effect of Applied Magnetic Field on the Mine Water Coagulation

Zhe Guo; Jian Guo Cui; Gang Wei

doi:10.4028/www.scientific.net/AMM.522-524.1021

Paper Titles

Research on Water Saving Irrigation and Optimal Allocation of Water Resources
p.1000

Driving Force and Influence of Habitat Conditions on Tubifex tubifex (Oligochaeta, Tubificidae) Drift in Source Water
p.1005

Hydraulic Regime Analysis of On-Off Valve Regulation
p.1009

Analysis of Difference of Water Use Efficiency in China
p.1015

The Effect of Applied Magnetic Field on the Mine Water Coagulation
p.1021

Establishment and Application of a Comprehensive Evaluation Model for Management of Water-Saving Irrigation Developing Level Based on Set Pair Analysis - Si Chuan Province as Example
p.1027

Optimization of Multi-Objective Crop Pattern Based on Water and Fertilizer Resources Allocation
p.1034

Influences and Countermeasures of the Shale Gas Exploitation on Water Environment
p.1039

Development of Plant Genetic Diversity by Biotechnology and Genomics
p.1047

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 522-524The Effect of Applied Magnetic Field on the Mine...

The Effect of Applied Magnetic Field on the Mine Water Coagulation

Abstract:

It is significant to use different techniques to improve the overall efficiency of mine water treatment, because the utilization rate of treated mine water is low and the treating cost is high. According to the characteristics of water quality of coal mine water, the influence of the magnetic field on mine water treatment was studied in this paper in order to provide a reference for mine water treatment. It was found that magnetic field has effect on surface tension and electrical conductivity of mine water. When the magnetic field strength is less than 0.3T, the surface tension of the mine water decreases with the increase of magnetic field intensity, while the magnetic field strength is more than 0.3T, the surface tension of the mine water increases with the increase of magnetic field intensity. In the range of 0.0T ~ 0.5T, the mine water conductivity increases with the increase of magnetic field intensity and, as high as 14.8 ms/cm, then along with the increase of magnetic field intensity, the conductivity remains same. The influence of magnetic field intensity, amount of coagulant and magnetization time on coagulation were studied in this paper, and their effect were also investigated by Orthogonal test. The results show that when the magnetic field intensity is 0.35 T, magnetization time is 4 min and the amount of coagulant is 3 ml/L, the coagulation effect is the best. Under the condition, the mine water turbidity fell to 0.85 NTU from 200 NTU.

You might also be interested in these eBooks

Environmental Protection and Sustainable Development

View Preview

Info:

Periodical:

Applied Mechanics and Materials (Volumes 522-524)

Pages:

1021-1026

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.522-524.1021

Citation:

Cite this paper

Online since:

February 2014

Authors:

Zhe Guo, Jian Guo Cui, Gang Wei

Keywords:

Coagulation, Magnetization, Mine Water, Orthogonal Experiment

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

References

[1] Yantao Li, Yongjin Xue: Industrial Water Treatment, Vol. 27 (2007), 11-13(In Chinese).

Google Scholar

[2] Jinsheng Tan, Changfeng Huang, Xibo Xu et al: Coal and Chemical Industry, Vol. 36 (2013), 54- 56(In Chinese).

Google Scholar

[3] Rulu Zhou, Liang Gao, et al: Coal Mine Environmental Protection, Vol. 14 (2000), 10-12(In Chinese).

Google Scholar

[4] Liang Gao, Rulu Zhou et al: Energy Environmental Protection, Vol. 18 (2004), 46-48(In Chinese).

Google Scholar

[5] Kewu Pi, Yatian Lou: Environmental Technology, Vol. 1 (2003), 26-28(In Chinese).

Google Scholar

[6] Dejian Dou, Kehong Wu: Industrial Water & Wastiewater, Vol. 32 (2001) (In Chinese).

Google Scholar

[7] Liping Wang, Youqing He, et al: Environmental Engineering, Vol. 25 (2007), 12-14(In Chinese).

Google Scholar

[8] Haiming Du, Fayu Zhang, et al: Technology of Water treatment, Vol. 35 (2009), 86-90(In Chinese).

Google Scholar

[9] J. Skvarla, K. F. Zele: Int J Miner Process, Vol. 68 (2003), 17-36.

Google Scholar

[10] Jing Yang, Fuqin Li: Journal of Liaoning Technical University (Natural Science), Vol. 27 (2008), 458-460(In Chinese).

Google Scholar

[11] Yuhang Ren, Zhuan Xu, et al: Journal of Zhejiang University (Natural Science), Vol. 3 (1997) (In Chinese).

Google Scholar

[12] Juan Du, Ruiyu Feng, et al: Hebei Chemical Industry, Vol. 29 (2006), 21-24(In Chinese).

Google Scholar

[13] Wei Ma, Jin Xiao, et al: Journal of Dalian Railway Institute, Vol. 19 (1998), 5-7(In Chinese).

Google Scholar