Generalized Predictive PID Controller of Differential Pressure in Vertical Roller Mill for Cement-Raw Grinding

NING Yanyan; YUAN Mingzhe; WANG Zhuo

doi:10.3724/SP.J.1219.2012.00378

Volume 41 Issue 3

Jun. 2012

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INFORMATION AND CONTROL > 2012 > (3): 378-383,390. > DOI: 10.3724/SP.J.1219.2012.00378 CSTR: 32166.14.xk.2012.00378

NING Yanyan, YUAN Mingzhe, WANG Zhuo. Generalized Predictive PID Controller of Differential Pressure in Vertical Roller Mill for Cement-Raw Grinding[J]. INFORMATION AND CONTROL, 2012, (3): 378-383,390. DOI: 10.3724/SP.J.1219.2012.00378

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Generalized Predictive PID Controller of Differential Pressure in Vertical Roller Mill for Cement-Raw Grinding

1.
Shenyang Institute of Automation, Chinese Academy of Sciences, Shenyang 110016, China
2.
Graduate of Chinese Academy of Sciences, Beijing 110049, China

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Received Date: April 05, 2011
Revised Date: January 08, 2012
Published Date: June 19, 2012

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Abstract

Abstract

To solve the problems of nonlinearity, large time delay, and slow time-varying in the vertical roll mill grinding process, a generalized predictive proportional-integral-derivative controller (GPC-PID) is proposed, which shares the same structure with the traditional PID controller by constructing the weighted index of control in object function of GPC. The PID parameters are calculated based on the recursive relationship between the GPC and the PID algorithm. The simulation results show that the GPC-PID controller can stabilize the differential pressure well, and has the characteristics of fast response, high anti-interference and robustness.

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[1]	席裕庚．预测控制[M]．北京：国防工业出版社，1993． Xi Y G. Predictive control[M]. Beijing: National Defense Industry Press, 1993.
[2]	孙常保．立式辊磨机原料磨系统工艺的控制[J]．散装水泥，2007(2)：57-59． Sun C B. Process control of vertical roller mill for cement-raw grinding[J]. Bulk Cement, 2007(2): 57-59.
[3]	张松虎．LM立磨的稳定运行和参数控制[J]．新世纪水泥导报，2005(1)：34-35． Zhang S H. Stable operation and parameter control of LM vertical roller mill[J]. Cement Guide for New Epoch, 2005(1): 34-35.
[4]	于加滨．MPS3150 立式磨生产控制与系统优化[J]．四川水泥，2003(4)：25-27． Yu J B. Process control and system optimization of MPS3150 vertical roller mill[J]. Sichuan Cement, 2003(4): 25-27.
[5]	Clarke D W, Mohtadi C, Tuffs P S. Generalized predictive control: Part 1[J]. Automatica, 1987, 23(2): 137-160.
[6]	Zheng D Z, Feng B. Boiler combustion system virtual controller based on predictive control[C]//Proceedings of the 2002 International Conference on Control and Automation. Piscataway, NJ, USA: IEEE, 2002: 247-249.
[7]	王繁珍，陈增强，姚向峰，等．基于频域的PID 广义预测控制器的鲁棒性分析[J]．中国工程科学，2006(10)：66-70． Wang F Z, Chen Z Q, Yao X F, et al. Frequency-domain-based robustness analysis for PID generalized predictive control[J]. Engineering Sciences, 2006(10): 66-70.
[8]	李林欢，苏宏业．一类多输入多输出系统的预测PID 控制算法仿真[J]．系统仿真学报，2004，16(3)：495-498． Li L H, Su H Y. Predictive PID control simulation for a class of MIMO systems[J]. Journal of System Simulation, 2004, 16(3): 495-498.
[9]	Nakano K, Yamamoto T, Hinamoto T. A design of robust selftuning GPC[C]//The 29th Annual Conference of the IEEE Industrial Electronics Society. Piscataway, NJ, USA: IEEE, 2003: 285-290.
[10]	Tan K K, Huang S N, Lee T H. Development of GPC-based PID controller for unstable system with deadtime[J]. ISA Transactions, 2000, 39(1): 57-70.
[11]	Yamamoto T, Yamada T, Fujii T, et al. Design and implementation of a GPC-based auto-tuning PID controller[C]//IEEE International Conference on Industrial Technology. Piscataway, NJ, USA: IEEE, 2006: 1920-1924.
[12]	Kwok K E, Ping M C, Li P. A model-based augmented PID algorithm[ J]. Journal of Process Control, 2000, 10(1): 9-18.

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Generalized Predictive PID Controller of Differential Pressure in Vertical Roller Mill for Cement-Raw Grinding

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