预估型氨法脱硫控制系统研究

doi:10.16180/j.cnki.issn1007-7820.2022.05.010

摘要/Abstract

摘要：

燃煤发电系统中氨法脱硫控制系统具有时变、大延时、大惯性的特点。针对典型的大延迟系统,文中提出基于Smith预估器的脱硫控制系统,通过抵消系统被控对象中的纯滞后环节来提高系统的实时性。Smith预估器依赖准确的PID模型,系统中PID参数整定仍存在不确定性。利用SOA算法对PID参数进行整定,将绝对误差积分ITAE作为适应度函数,通过对适应度值的不断寻优,找到最佳的比例积分微分系数组合。仿真结果表明,相较于Smith预估器控制下的脱硫系统,基于SOA的Smith预估PID控制系统跟随性好且反应迅速,调节时间缩小为原来的9%,峰值时间缩小为原来的5%,具有较小的超调量,系统的实时性和稳定性得到保证。上述结果证明该算法对工程控制系统有效,并具有良好的应用前景。

关键词: 氨法脱硫, Smith预估器, PID参数整定, SOA, 优化, 实时跟踪, 大延时系统, 过程控制

Abstract:

The ammonia desulfurization control system in the coal-fired power generation system has the characteristics of time-varying, large delay and large inertia. Aiming at the typical large delay system, a desulfurization control system based on Smith predictor is proposed to improve the real-time performance of the system by offsetting the pure delay link in the controlled object. The Smith predictor relies on an accurate PID model, and there are still uncertainties in the PID parameter tuning in the system. The SOA algorithm is used to adjust the PID parameters, and the absolute error integral ITAE is used as the fitness function. Through the continuous optimization of the fitness value, the best combination of the proportional integral differential coefficient is found. The simulation results show that compared to the desulfurization system under the control of Smith predictor, the new system has good follow ability and rapid response, the adjustment time is reduced to 9% of the original, and the peak time is reduced to 5% of the original, and has a very small overshoot. The real-time and stability of the system are guaranteed. These results indicate that the algorithm is effective for engineering control systems and has a good prospect of popularization and application.

Key words: ammonia desulfurization, Smith predictor, PID parameter tuning, SOA, optimization, real-time tracking, large delay system, process control

中图分类号:

TP273

李猛,马立新. 预估型氨法脱硫控制系统研究[J]. 电子科技, 2022, 35(5): 60-65.

LI Meng,MA Lixin. Research on Predictive Ammonia Desulfurization Control System[J]. Electronic Science and Technology, 2022, 35(5): 60-65.

图/表 6

图1

图2

图3

图4

图5

表1

参考文献 19

[1]	王博华.粒子群算法的改进及其在PID参数整定中的应用[D].长沙:湖南大学,2017.
	Wang Bohua.Improvement of particle swarm optimization and its application in PID parameters tuning[D].Changsha:Hunan University,2017.
[2]	尹玉.基于BP神经网络的脱硫系统PH值预测[D].北京:华北电力大学,2013.
	Yin Yu.The prediction of PH value in desuIfurization system based on BP neural network[D].Beijing:North China Electric Power University,2013.
[3]	马立新,吕梦圆.氨法脱硫自适应实时跟踪控制系统[J].系统仿真学报,2018,30(5):1838-1843.
	Ma Lixin,Lü Mengyuan.Adaptive real-time tracking control system for ammonia desulphurization[J].Journal of System Simulation,2018,30(5):1838-1843.
[4]	邓若辰,钟文琪,孙立.基于粒子群算法的脱硫系统PH值分数阶PID优化控制[J].工业控制计算机,2020,33(12):87-90.
	Deng Ruochen,Zhong Wenqi,Sun Li.Fractional PID optimal control of PH value of desulfurization system based on particle swarm optimization[J].Industrial Control Computer,2020,33(12):87-90.
[5]	刘长良,马曾辉.过热汽温系统的Smith预估器参数多目标优化控制[J].模式识别与人工智能,2015,28(3):282-288.
	Liu Changliang,Ma Zenghui.Multi-objective optimization control of Smith-predictor parameters in superheated steam temperature system[J].Pattern Recognition and Artificial Intelligence,2015,28(3):282-288.
[6]	陈尚巧,王明春,张宇飞,等.基于PSO-SOA融合算法的PID参数优化[J].工业控制计算机,2019,32(10):22-27.
	Cheng Shangqiao,Wang Mingchun,Zhang Yufei,et al.PID parameter optimization based on PSO-SOA fusion algorithm[J].Industrial Control Computer,2019,32(10):22-27.
[7]	张连强,王东风.基于改进人群搜索算法的PID参数优化[J].计算机工程与设计,2016,37(12):3390-3393.
	Zhang Lianqiang,Wang Dongfeng.Optimization of PID parameters based on improved seeker optimization[J].Computer Engineering and Design,2016,37(12):3390-3393.
[8]	杜美君,张伟,谢亚莲.基于粒子群算法的PID控制器参数优化[J].电子科技,2019,32(6):7-11.
	Du Meijun,Zhang Wei,Xie Yalian.Particle swarm optimization based PID controller parameter optimization.[J],Electronic Science and Technology,2019,32(6):7-11.
[9]	葛育晓,赵荣珍.基于改进SOA算法自整定PID系统优化研究[J].仪表技术与传感器,2020(10):108-116.
	Ge Yuxiao,Zhao Rongzhen.Research on self-tuning PID system optimization based on improved seeker optimization algorithm[J].Instrument Technique and Sensor,2020(10):108-116.
[10]	申奥勇,詹跃东.基于二次型性能指标的燃料电池过氧比径向基函数比例积分微分控制[J].信息与控制,2020,21(11):4-8.
	Shen Aoyong,Zhan Yuedong.RBF-PID control of fuel cell oxygen excess radio based on secondary performance index[J].Information and Control,2020,21(11):4-8.
[11]	高礼科,倪福生,蒋爽.基于模糊PID控制器的旋流泵调速控制[J].仪表与自动化装置,2020,35(12):72-76.
	Gao Like,Ni Fusheng,Jiang Shuang.Speed control of cyclone rump based on fuzzy PID controller[J].Automation & Instrumentation,2020,35(12):72-76.
[12]	张皓,高瑜翔.前馈反馈Smith预估模糊PID组合温度控制算法[J].中国测试,2020,46(11):132-138.
	Zhang Hao,Gao Yuxiang,Temperature control algorithm combined the feedforward feedback with Smith predictor and fuzzy PID[J].China Measurement & Test,2020,46(11):132-138.
[13]	吴延凯,张伟,马盈满,等.基于GA-PSO融合算法的二自由度PID参数优化[J].电子科技,2019,32(10):54-59.
	Wu Yankai,Zhang Wei,Ma Yingman,et al.Two degree of freedom PID parameter optimization based on GA-PSO fusion algorithm[J].Electronic Science and Technology,2019,32(10):54-59.
[14]	Kim K H.Model reference adaptive control-based adaptive corrent control scheme of a PM synchronous motor with an improved servo performance[J].IET Electric Power Applications,2009,3(1):8-18. doi: 10.1049/iet-epa:20080030
[15]	Rajinikanth V,Latha K.Setpoint weight PID controller tuning for unstable system using heuristic algorithm[J].Archives of Control Sciences,2012,22(4):481-505. doi: 10.2478/v10170-011-0037-8
[16]	Hashemi M,Askari J,Ghaisari J,et al.Robust adaptivr actuator failure compensation for a class of uncertain nonlinear systems[J].International Journal of Automation and Computing,2017,14(6):719-728. doi: 10.1007/s11633-016-1016-0
[17]	Giraldo S A C,Flesch R C C,Normey-Rico J E.Multivariable greenhouse control using the filtered smith predictor[J].Journal of Control, Automation and Electrical Systems,2017,27(4):349-358. doi: 10.1007/s40313-016-0250-6
[18]	Tuba M,Bacanin N.Improved seeker optimization algorithm hybridized with firefly algorithm for constrained optimization problems[J].Neurocomputing,2014,143(1):197-207. doi: 10.1016/j.neucom.2014.06.006
[19]	张春燕.湿法烟气脱硫控制系统方案研究[J].电子设计工程,2012,20(6):118-120.
	Zhang Chunyan.Study on the scheme of the flue gas desulfurization control system[J].Electronic Design Engineering,2012,20(6):118-120.

参数	PID控制	Smith预估	SOA控制
峰值时间/s	270.00	78.00	0.36
超调量/%	5.600	0.690	0.038
调节时间/s	360.0	130.0	1.2
负荷平均跟踪用时/s	280.00	36.60	3.65