pH control in iron precipitation process based on parameter self-tuning fuzzy controller

doi:10.3969/j.issn.0438-1157.2013.12.043

CIESC Journal ›› 2013, Vol. 64 ›› Issue (12): 4557-4562.DOI: 10.3969/j.issn.0438-1157.2013.12.043

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pH control in iron precipitation process based on parameter self-tuning fuzzy controller

LI Yonggang, YANG Gen, YANG Chunhua

School of Information Science & Engineering, Central South University, Changsha 410083, Hunan, China

Received:2013-08-16 Revised:2013-08-26 Online:2013-12-05 Published:2013-12-05
Supported by:
supported by the National Natural Science Foundation of China (61174133)，the National Key Technology R&D Program of China (2012BAF03B05) and the New Century Excellent Talents in University (NCET-12-0546).

基于参数自整定模糊控制器的沉铁过程pH值稳定控制

李勇刚, 杨根, 阳春华

中南大学信息科学与工程学院, 湖南长沙 410083

通讯作者: 李勇刚
作者简介:李勇刚（1974- ），男，博士，副教授。
基金资助:
国家自然科学基金项目（61174133）；国家支撑计划项目（2012BAF03B05）；新世纪优秀人才支持计划项目（NCET-12-0546）。

Abstract

Abstract: Iron precipitation is the key process for iron removal in zinc hydrometallurgy.In iron precipitation process,it is very important to stabilize the pH value of the solution.However,the pH value fluctuates strongly in practice because of the nonlinearity and coupling in iron precipitation process. At first,the reaction kinetics mechanism of iron precipitation is analyzed.Then,the relationship between the pH value of the solution and the amount of zinc calcine (AZC) added into the solution is researched and the AZC added into the solution is calculated according to the technical requirement of pH value. At last,the parameter self-tuning fuzzy controller is proposed to adjust AZC added into the solution. Simulation results show that the parameter self-tuning fuzzy controller is very effective and it is a feasible method to stabilize pH value in iron precipitation process.

Key words: parameter self-tuning, fuzzy controller, iron precipitation process, pH value

摘要： 针对沉铁过程存在的非线性、强耦合导致溶液pH值难以稳定控制的问题，分析了沉铁过程的工艺及其反应动力学机理。研究了锌焙砂添加量与pH值之间的关系，并根据工艺对pH值的要求，计算沉铁过程所需添加的焙砂量。在此基础上，采用参数自整定模糊控制器对锌焙砂添加量进行补偿调节，从而实现pH值的稳定控制。仿真结果表明：所提出的参数自整定模糊控制器效果良好，为沉铁过程pH值的稳定控制提供了一种切实可行的方法。

关键词: 参数自整定, 模糊控制器, 沉铁过程, pH值

CLC Number:

TP273

LI Yonggang, YANG Gen, YANG Chunhua. pH control in iron precipitation process based on parameter self-tuning fuzzy controller[J]. CIESC Journal, 2013, 64(12): 4557-4562.

李勇刚, 杨根, 阳春华. 基于参数自整定模糊控制器的沉铁过程pH值稳定控制[J]. 化工学报, 2013, 64(12): 4557-4562.

References 20

[1]	Peng Qiurong (彭秋容).Metallurgy of Lead and Zinc (铅锌冶金学)[M].Beijing:Science Press, 2003
[2]	Loan M, Newman O M G, Cooper R M G, Farrow J B, Parkinson G M.Defining the Paragoethite process for iron removal in zinc hydrometallurgy[J].Hydrometallurgy, 2006, 81 (2):104-129
[3]	Claassen J O, Sandenbergh R F.Influence of temperature and pH on the quality of metastable iron phases produced in zine-rich solutions[J].Hydrometallurgy, 2007, 86 (3):178-190
[4]	Yang Zhaohua (杨照华), Yang Zhi (杨智), Wang Huizhong (王慧中).Investigation of two new methods for pH control[J].Journal of Gansu University of Technology (甘肃工业大学学报), 2001, 27 (3):51-54
[5]	Chotteau Vé ronique, Hjalmarsson Hkan.Tuning of dissolved oxygen and pH PID control parameters in large scale bioreactor by lag control//Proceedings of the 21st Annual Meeting of the European Society for Animal Cell Technology[C].Dublin, Ireland, 2009
[6]	He Xianzhong.The pH predictive control during the course of wet zinc metallurgy[J].Electrical Automation, 2009, 31 (1):23-24
[7]	Altinten Ayla.Generalized predictive control applied to a pH neutralization process[J].Computers and Chemical Engineering, 2007, 31 (10):1199-1204
[8]	Li Tao (李涛), Pu Hongchun (蒲鸿春), Feng Yu (冯宇), Qiu Jian (邱剑).An application of fuzzy-Smith control on pH treatment system[J].Instrumentation Analysis Monitoring (仪器仪表与分析监测), 2009 (2):9-11
[9]	Wu Yifeng, Shen Li'e, Zhang Liping.Study on nonlinear pH control strategy based on external recurrent neural network[J].Procedia Engineering, 2011, 15:866-871
[10]	Shahraz A, Boozarjomehry R Bozorgmehry.A fuzzy sliding model control approach for nonlinear chemical process[J].Control Engineering Practice, 2009, 17 (5):541-550
[11]	Chung Chaochin, Chen Hohsien, Ting Chinghua.Grey prediction fuzzy control for pH processes in the food industry[J].Journal of Food Engineering, 2010, 96 (4):575-582
[12]	Dai Rujun (戴如俊).The improvement of fuzzy control based rules[D].Harbin:Harbin Polytechnic University, 2007
[13]	Liu Yijian (刘益剑).The design of fuzzy control and optimization by PSO[D].Hangzhou:Zhejiang University, 2004
[14]	Mei Guanggui (梅光贵), Wang Derun (王德润), Zhou Jingyuan (周敬元), Wang Hui (王辉).Hydrometallurgy of Zinc (湿法炼锌学)[M].Changsha:Central South University Press, 2001
[15]	Xia Zhihua (夏志华), Tang Motang (唐谟堂), Li Shiqing (李仕庆), Luo Yan (罗艳), Tang Chaobo (唐朝波).The study on the kinetics of leaching the residues from the neutral leaching process with high concentration of sulfuric acid at high temperature[J].Mining and Metallurgical Engineering (矿冶工程), 2005, 25 (2):53-57
[16]	Que Shaojuan (阙绍娟), Chen Yanqing (陈燕清), Ma Shaojian (马少健), He Chunlin (何春林).Study on single-state acid leaching of zinc calcine[J].Conservation and Utilization of Mineral Resources (矿产保护与利用), 2011, 2:24-27
[17]	Que Shaojuan (阙绍娟).Experimental investigation on the leaching of high-iron zinc calcine[D].Nanning:Guangxi University, 2010
[18]	Guan Yajun (关亚君).Study on iron leaching and pH value of Fe3+ hydrolysis in zinc hydrometallurgy[J].Chinese Journal of Rare Metals (稀有金属), 2006, 30 (3):419-422
[19]	Yang Ruzhong (杨如中), Wu Jiang (武江), Guo Tianli (郭天立).The improvement of normal method of zinc calcine (A)//The Second National Heavy of Metallurgical New Technology and New Technology Achievements AC Popularization and Application of Proceedings[C].Beijing, 2005:211-216
[20]	Zhu Lianghong (朱良红).The application of fuzzy control in process control[D].Fuzhou:Huaqiao University, 2004

pH control in iron precipitation process based on parameter self-tuning fuzzy controller

基于参数自整定模糊控制器的沉铁过程pH值稳定控制

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