区间法基于LMI的有界不确定性压水堆鲁棒PID控制器设计

2019 7th International Conference on Control, Mechatronics and Automation (ICCMA) Pub Date : 2019-11-01 DOI:10.1109/ICCMA46720.2019.8988755

S. Banerjee, Jiamei Deng, Vineet Vajpayee, V. Becerra, N. Bausch, S. Shimjith, A. Arul

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引用次数: 2

摘要

压水堆由于其自调节和自稳定的特点而在核电工业中很受欢迎，这反过来又有助于它们执行负载跟随运行。然而，由于反应堆固有的非线性特性，快速动力机动是一项具有挑战性的任务。它会导致随着反应堆功率的变化而变化的行为。此外，热量从燃料传递到冷却剂，由于燃料和冷却剂温度的变化，反应性发生了变化，这给系统带来了不确定性。因此，为负载跟踪操作设计一个鲁棒控制器是必要的。本文除了考虑功率传感器模型和执行器模型外，还考虑了压水堆的点动力学模型与Mann热-水力模型的耦合。该模型已被确定为具有测量参数(燃料和冷却剂)有界不确定性的区间系统。然后，通过改变加权矩阵，制定了一种使用线性矩阵不等式设计单个鲁棒PID控制器的方法。结果已通过MATLAB仿真验证，并在结果部分谨慎举例说明。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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LMI Based Robust PID Controller Design for PWR with Bounded Uncertainty using Interval Approach

Pressurized Water Reactors are popular in the nuclear power generation industry due to their self-regulating and self-stabilizing features which in turn help them to perform load-following operation. However, fast power maneuvering is a challenging task due to inherent nonlinearity in a reactor. It leads to changes in the behavior with variation in reactor power. Further, the heat transfers from fuel to coolant and the reactivity changes due to variation in fuel and coolant temperatures introduces uncertainty in the system. Thus, it is essential to design a robust controller for load-following operation. In this paper, the point kinetics model of PWR coupled with the Mann’s thermal-hydraulic model has been considered in addition to power sensor model and actuator model. This model has been identified as an interval system with bounded parametric uncertainties in measurements (fuel and coolant). The work then formulates a methodology to design a single robust PID controller using linear matrix inequalities by varying the weighting matrices. The outcomes have been validated using MATLAB simulations and discreetly exemplified in the result section.

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2019 7th International Conference on Control, Mechatronics and Automation (ICCMA)

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