基于线性自抗扰的烷氧基化装置温度控制系统
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摘要
烷氧基化装置温度控制系统具有大时滞特性,温度高效控制困难.建立系统数学模型;提出内环为PD控制器,外环为Smith预估器与线性自抗扰控制相结合的控制策略,以解决时滞系统采用自抗扰控制时扩张状态观测器输入信号不同步及Smith预估器抗扰能力差的问题;设计线性自抗扰控制器;从不同点加入扰动进行数值仿真实验,仿真结果证明了所提出方法的有效性.
The temperature control system of alkoxylation device has a characteristic with large time-delay,which brings difficulty to the efficient control of temperature. The mathematical model of the system is established. It is proposed that the inner loop is a PD controller and the outer loop is a combined strategy of Smith predictor and LADRC(Linear Active Disturbance Rejection Control) which can solve the problem of non-synchronization of input signal of ESO(Extended State Observer) by LADRC in time-delay system as well as poor anti-interference performance of Smith predictor. LADRC is designed. Numerical simulation is carried out by adding disturbance from different points and the results of the simulation prove the effectiveness and correctness of the proposed method.
The temperature control system of alkoxylation device has a characteristic with large time-delay,which brings difficulty to the efficient control of temperature. The mathematical model of the system is established. It is proposed that the inner loop is a PD controller and the outer loop is a combined strategy of Smith predictor and LADRC(Linear Active Disturbance Rejection Control) which can solve the problem of non-synchronization of input signal of ESO(Extended State Observer) by LADRC in time-delay system as well as poor anti-interference performance of Smith predictor. LADRC is designed. Numerical simulation is carried out by adding disturbance from different points and the results of the simulation prove the effectiveness and correctness of the proposed method.
引文
[1]王永帅,陈增强,孙明玮,等.一阶惯性大时滞系统Smith预估自抗扰控制[J].智能系统学报,2018,13(4):500-508.
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[9]李杰,齐晓慧,夏元清,等.线性/非线性自抗扰切换控制方法研究[J].自动化学报,2016,42(2):202-212.
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[11]周少祥,胡三高,宋之平.管式换热器分布参数模型的分段线性化方法研究[J].中国电机工程学报,2002,22(6):123-125.
[12]李铁苍.热力过程自动化[M].北京:中国电力出版社,2006.
[13]阮毅.电力拖动自动控制系统[M].北京:机械工业出版社,2010.
[2]王伟,吴敏,曹卫华,等.基于组合灰色预测模型的焦炉火道温度模糊专家控制[J].控制与决策,2010,25(2):185-190.
[3]蒋朝辉,李学明,桂卫华.大时滞系统全参数自适应预测控制策略[J].中南大学学报(自然科学版),2012,43(1):195-201.
[4]张强,冯树兴,岳巍强.基于神经网络的大容积环境温度模拟系统的控制策略[J].控制理论与应用,2006,23(3):429-432.
[5] HAN J Q. From PID to active disturbance rejection control[J]. Transactions on Industrial Electronics,2009,56(3):900-906.
[6]韩京清.时滞对象的自抗扰控制[J].控制工程,2008,15(S1):7-10.
[7]王丽君,李擎,童朝南,等.时滞系统的自抗扰控制综述[J].控制理论与应用,2013,30(12):1521-1533.
[8]唐德翠,高志强,张绪红.浊度大时滞过程的预测自抗扰控制器设计[J].控制理论与应用,2017,34(1):101-108.
[9]李杰,齐晓慧,夏元清,等.线性/非线性自抗扰切换控制方法研究[J].自动化学报,2016,42(2):202-212.
[10]陈增强,程赟,孙明玮,等.线性自抗扰控制理论及工程应用的若干进展[J].信息与控制,2017,46(3):257-266.
[11]周少祥,胡三高,宋之平.管式换热器分布参数模型的分段线性化方法研究[J].中国电机工程学报,2002,22(6):123-125.
[12]李铁苍.热力过程自动化[M].北京:中国电力出版社,2006.
[13]阮毅.电力拖动自动控制系统[M].北京:机械工业出版社,2010.
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