缠绕式变频电磁水处理器电磁频率对抑垢效果的影响

doi:10.11949/j.issn.0438-1157.20141385

化工学报 ›› 2015, Vol. 66 ›› Issue (3): 972-978.DOI: 10.11949/j.issn.0438-1157.20141385

缠绕式变频电磁水处理器电磁频率对抑垢效果的影响

王建国, 李雨通, 邓丽娟

东北电力大学自动化工程学院, 吉林省吉林市 132012

收稿日期:2014-09-16 修回日期:2014-11-28 出版日期:2015-03-05 发布日期:2015-03-05
通讯作者: 李雨通
基金资助:
国家自然科学基金项目(51176028);吉林省重点科技攻关项目(20140204006SF)。

Influence of electromagnetic frequency on scale inhibition for spiral winding variable frequency electromagnetic water processor

WANG Jianguo, LI Yutong, DENG Lijuan

School of Automation Engineering, Northeast Dianli University, Jilin 132012, Jilin, China

Received:2014-09-16 Revised:2014-11-28 Online:2015-03-05 Published:2015-03-05
Supported by:
supported by the National Natural Science Foundation of China (51176028) and the Key Scientific and Technological Project of Jilin Province of China (20140204006SF).

摘要/Abstract

摘要：

针对缠绕式变频电磁水处理系统,利用ANSYS仿真软件对处理腔内水溶液的磁感应强度和感生电流进行分析,探究水体内磁感应强度以及感生电流做功与激励信号频率的内在关系,并利用电磁抑垢效果在线评价实验台,通过改变缠绕式处理腔中电磁场的频率大小分析其对特定硬水循环换热实验管道抑垢效果的影响规律,进而寻求理想的抑垢频率。实验结果表明,电磁频率在分界频率附近时水处理系统能到达较长的污垢诱导期以及较好的抑垢率,抑垢效果最佳。

关键词: 缠绕式处理腔, 频率, 磁感应强度, 感生电流, 抑垢效果, 对流, 传热, 数值分析

Abstract:

For the spiral winding variable frequency electromagnetic water processor, magnetic induction intensity of water in processing cavity and induced current were analyzed with ANSYS simulation software. The inner relationship of magnetic induction intensity and induced current work with excitation signal frequency was studied. Using an online evaluation test bench for electromagnetic scale inhibition, the influence of spiral winding processing cavity frequency on scale inhibition of hard water circulation heat transfer experiment pipe was observed, and the ideal scale inhibition frequency was determined. Under this experimental condition, the frequency near the line frequency had longer scale induction period and stronger scale inhibition effect, and anti-scaling efficiency was the best.

Key words: spiral winding processing cavity, frequency, magnetic induction intensity, induced current, anti-scaling effect, convection, heat transfer, numerical analysis

中图分类号:

TQ085

王建国, 李雨通, 邓丽娟. 缠绕式变频电磁水处理器电磁频率对抑垢效果的影响[J]. 化工学报, 2015, 66(3): 972-978.

WANG Jianguo, LI Yutong, DENG Lijuan. Influence of electromagnetic frequency on scale inhibition for spiral winding variable frequency electromagnetic water processor[J]. CIESC Journal, 2015, 66(3): 972-978.

参考文献 26

[1]	Lipusa L C, A?ko B, Hamlerb A. Electromagnets for high-flow water processing [J]. Chemical Engineering and Processing, 2011, 50 (9): 952-958
[2]	Wang Jianguo (王建国), He Fang (何芳), Di Hao (邸昊). Correlation analysis of magnetic field and conductivity, pH value in electromagnetic restraint of scale formation [J]. CIESC Journal (化工学报), 2012, 63 (5): 1468-1473
[3]	Shelver W L, Kamp L M, Church J L. Measurement of triclosan in water using a magnetic particle enzyme immunoassay [J]. Journal of Agricultural and Food Chemistry, 2007, 55 (10): 3758-3763
[4]	Xiao Zengli (肖曾利), Pu Chunsheng (蒲春生). Review of technology and application on magnetized water treatment for anti-scaling [J]. Fault-Block Oil & Gas Field (断块油气田), 2010, 17 (1): 121-125
[5]	Chen Bowu (陈博武). Status and trends of the fouling monitoring technology of cooling water [J]. Industrial Water Treatment (工业水处理), 2006, 26 (5): 4-8
[6]	He Jun (何俊), Zhao Zongze (赵宗泽), Li Yuehua (李跃华). Research status and progress in scale inhibition and removal by physical technology [J]. Industrial Water Treatment (工业水处理), 2010, 30 (9): 5-9
[7]	Cheolho Bai. Effect of electronic anti-fouling treatment on fouling mitigation with circulating cooling-tower water [J]. Int. Comm. Heat Mass Transfer, 2001, 28 (5): 671-680
[8]	Chang M C, Tai C Y. Effect of the magnetic field on the growth rate of aragonite and the precipitation of CaCO3 [J]. Chemical Engineering Journal, 2010, 164 (1): 1-9
[9]	Zhang Xuefeng (张雪峰), Niu Yonghong (牛永红). Research progress on application of magnetic treatment industrial water technology [J]. Chemical Industry and Engineering Progress (化工进展), 2011, 30: 831-833
[10]	Alimi Fathi, Tlili Mohamed, Gabrielli Claude. Effect of a magnetic water treatment on homogeneous and heterogeneous precipitation of calcium carbonate [J]. Water Research, 2006, 40: 1941-1950
[11]	Botello-Zubiate M E, Alvarez A, Martinez-Villafane A. Influence of magnetic water treatment on the calcium carbonate phase formation and the electrochemical corrosion behavior of carbon steel [J]. Journal of Alloys and Compounds, 2004, 369 (1/2): 256-259
[12]	Song Liu. A study of fouling in a heat exchanger with an application of an electronic anti-fouling technology[D]. Michigan USA: Drexel University, 1999
[13]	Jiang Dening (姜德宁), Zhou Kun (周昆). Experimental study on anti-scale of pipes based on alternating magnetic field [J]. Journal of Tianjin University of Technology and Education (天津工程师范学院学报), 2008, 18 (1): 21-25
[14]	Jin Zhenhua (金贞花), Chen Yongchang (陈永昌), Xing Xiaokai (邢晓凯). Investigation on the high voltage electrostatic anti-fouling technology for heat transfer enhancement [J]. Journal of Engineering Thermophysics (工程热物理学报), 2006, 27 (6): 1035-1037
[15]	Chen Can (陈璨), Liu Runhua (刘润华). The impact of electromagnetic frequency on CaCO3 solubility quantitative research [J]. Science Technology and Engineering (科学技术与工程), 2009, 9 (15): 4567-4570
[16]	Xing Xiaokai (邢晓凯), Ma Chongfang (马重芳), Chen Yongchang (陈永昌). Experimental study of electromagnetic anti-fouling technology to enhanced heat transfer [J]. Journal of University of Petroleum (石油大学学报), 2005, 29 (1): 79-83
[17]	Fei Jiyou (费继友), Li Yuquan (李玉泉), Bai Xin (白鑫). The electromagnetic frequency conversion water anti-scale technology and experimental research [J]. Chemical Automation and Instrument (化工自动化及仪表), 2010, 38 (2): 157-161
[18]	Chen Xiaozhuan (陈小砖), Liu Jianhua (柳建华), Ma Chongfang (马重芳). Experimental research on mechanism of electromagnetic anti-fouling technology on cooling water flowing through absorber [J]. Fluid Machinery (流体机械), 2011, 11 (39): 67-70
[19]	Sung H Lee. A study of physical water treatment technology to mitigate the mineral fouling in a heat exchanger[D]. USA: Thesis of Drexel University, 2002
[20]	Ding Jie (丁洁),Dong Lingyun (董凌云). Magnetic treatment water anti-scale and the influence in the anti-scaling induction period//9th National Chemical Engineering Science and Technology[C]. Qingdao, China, 1998: 216-220
[21]	Xie Qifen (谢绮芬). The anti-scale mechanism and design of magnetic water device [J]. Water Treatment Technology (水处理技术), 1985, 11 (2): 49-52
[22]	Donsldson J D, Grimes S. Lifting the scales from our pipes [J]. New Scientist, 1988, 117 (18): 43-46
[23]	Han Yong (韩勇), Zhao Yongping (赵永平), Chai Xin (柴鑫). Analytical modeling of induced current for DC pulse water processor system and optimizing of excitation coil [J]. Electric Machines and Control (电机与控制学报), 2011, 9 (15): 31-38
[24]	Yan Zhaowen (阎照文). ANSYS10.0 Electromagnetic Analysis Technology and Engineering Example Explanation (ANSYS10.0电磁分析技术及实例详解) [M]. Beijing: China Water Power Press, 2006
[25]	Yang Shanrang (杨善让), Xu Zhiming (徐志明), Sun Lingfang (孙灵芳). Heat Exchanger Fouling and Countermeasures (换热设备污垢与对策) [M]. 2nd ed. Beijing: Science Press, 2004: 1-5
[26]	HG/T 2160—1991: Cooling water dynamic simulation test method[S]. Beijing: Chemical Industry Press, 1996

缠绕式变频电磁水处理器电磁频率对抑垢效果的影响

Influence of electromagnetic frequency on scale inhibition for spiral winding variable frequency electromagnetic water processor

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