Shape factor for the relay feedback autotuning

IF 0.9 Q4 ENGINEERING, CHEMICAL

Indian Chemical Engineer Pub Date : 2020-12-01 DOI:10.1080/00194506.2020.1846630

Friedrich Y. Lee, M. Baldea, T. Edgar, Jietae Lee

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Abstract

ABSTRACT Relay in the feedback loop produces a stable oscillation whose cyclic steady state response contains process information of ultimate gain and ultimate period. By measuring these process data and Ziegler-Nichols type tuning rules, PID controllers can be designed. Due to its simplicity and performances, this earlier relay feedback method becomes one of the standard methods for autotuning of PID controllers. Later the first-order plus time delay (FOPTD) models are used for the relay feedback method with additional process data such as the process steady-state gain, improving autotuning performances. Like other FOPTD model-based methods, this FOPTD model-based relay feedback method is very popular in the field. However, for some high-order processes, the FOPTD model-based method shows oscillatory closed-loop responses that are not acceptable. For such processes, the critically damped second-order plus time delay (C2PTD) identifiable with the same three process information of steady state gain, ultimate gain and ultimate period can be used. Unfortunately, the C2PTD model-based relay feedback method cannot cover the whole range of processes. One solution is the selective use of FOPTD and C2PTD models. For this purpose of selection, a shape factor that uses the process measurement of average residence time is proposed here. GRAPHICAL ABSTRACT

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继电器反馈自动调谐的形状因子

反馈回路中的继电器产生稳定振荡，其循环稳态响应包含了最终增益和最终周期的过程信息。通过测量这些过程数据和Ziegler-Nichols型整定规则，可以设计PID控制器。由于其简单和性能，这种早期的继电器反馈方法成为PID控制器自整定的标准方法之一。随后将一阶加时滞(FOPTD)模型用于继电器反馈方法，增加过程稳态增益等过程数据，提高了自整定性能。与其他基于FOPTD模型的方法一样，这种基于FOPTD模型的继电器反馈方法在该领域非常受欢迎。然而，对于一些高阶过程，基于FOPTD模型的方法显示出不可接受的振荡闭环响应。对于这类过程，可以使用具有相同稳态增益、最终增益和最终周期三个过程信息的临界阻尼二阶加时滞(C2PTD)。遗憾的是，基于C2PTD模型的继电器反馈方法不能覆盖整个过程。一种解决方案是选择性地使用FOPTD和C2PTD模型。为了这种选择的目的，在这里提出了一种形状因子，它使用平均停留时间的过程测量。图形抽象

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来源期刊

Indian Chemical Engineer ENGINEERING, CHEMICAL-

CiteScore

3.00

自引率

6.70%

发文量