An Internal Model Based—Sliding Mode Control for Open-Loop Unstable Chemical Processes with Time Delay

IF 2.8 Q2 ENGINEERING, CHEMICAL ChemEngineering Pub Date : 2023-06-02 DOI:10.3390/chemengineering7030053
C. Camacho, H. Álvarez, Jorge Espín, Oscar Camacho
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引用次数: 1

Abstract

This paper presents a dynamic sliding mode control (DSMC) for open-loop unstable chemical or biochemical processes with a time delay. The controller is based on the sliding mode and internal model control concepts. The proposed DSMC has an internal P/PD controller to provide systems with disturbance rejection. An identification method approximates the open-loop unstable nonlinear process to a first-order delayed unstable process (FODUP). The reduced-order model(FODUP) is used to synthesize the new controller. The performance of the controller is stable and satisfactory despite nonlinearities in the operating conditions due to set-point and process disturbance changes. In addition, the performance analysis of the control schemes was evaluated based on various indices and transient characteristics, including the integral of squared error (ISE), the total variation of control effort (TVu), the maximum overshoot (Mp), and the settling time (ts). Finally, the process output and the control action for all controllers are compared using the nonlinear process as the real plant.
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含时滞开环不稳定化学过程的内模滑模控制
本文提出了一种具有时滞的开环不稳定化学或生化过程的动态滑模控制方法。该控制器是基于滑模和内模控制的概念。所提出的DSMC具有内部P/PD控制器,以提供系统抗干扰性。一种辨识方法将开环不稳定非线性过程近似为一阶延迟不稳定过程。采用降阶模型(FODUP)对新控制器进行综合。尽管由于设定值和过程扰动的变化,控制器在运行条件下存在非线性,但其性能稳定且令人满意。此外,基于平方误差积分(ISE)、控制努力总变化量(TVu)、最大超调量(Mp)和沉降时间(ts)等指标和暂态特性对控制方案进行了性能分析。最后,将非线性过程作为实际对象,比较了各控制器的过程输出和控制动作。
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来源期刊
ChemEngineering
ChemEngineering Engineering-Engineering (all)
CiteScore
4.00
自引率
4.00%
发文量
88
审稿时长
11 weeks
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