Biomimetic Linkage Mechanism Robust Control for Variable Stator Vanes in Aero-Engine.

IF 3.4 3区医学 Q1 ENGINEERING, MULTIDISCIPLINARY Biomimetics Pub Date : 2024-12-21 DOI:10.3390/biomimetics9120778

Qinqin Sun, Zhangyang Lu, Xingyu Gui, Ye-Hwa Chen

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Abstract

This work addresses the position tracking control design of the stator vane driven by electro-hydrostatic actuators facing uncertain aerodynamic disturbances. Rapidly changing aerodynamic conditions impose complex disturbance torques on the guide vanes. Consequently, a challenging task is to enhance control precision in complex uncertain environments. Inspired by the principles of mammalian muscle movement, a novel robust control strategy based on the backstepping method has been proposed. Using backstepping, virtual rotational speed and virtual pressure difference force are designed, which decompose the high-order position closed-loop control problem into three lower-order parts, eliminating the need for matching conditions. Subsequently, robust controllers were designed, and stability proofs and performance analyses of the controllers were provided. This control strategy was tested through numerical hydraulic simulation. The results show that compared to other control methods, this approach significantly improves tracking accuracy and robustness. Therefore, it is believed that this method has the potential to become a new generation solution for such problems.

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航空发动机可变定子叶片仿生连杆机构鲁棒控制。

本文研究了在不确定气动干扰下，由电静液作动器驱动的静叶位置跟踪控制设计。快速变化的气动条件对导叶施加了复杂的扰动力矩。因此，如何提高复杂不确定环境下的控制精度是一项具有挑战性的任务。受哺乳动物肌肉运动原理的启发，提出了一种基于反推法的鲁棒控制策略。采用反推法设计了虚拟转速和虚拟压差力，将高阶位置闭环控制问题分解为三个低阶部分，消除了匹配条件的需要。随后，设计了鲁棒控制器，并给出了控制器的稳定性证明和性能分析。通过数值液压仿真对该控制策略进行了验证。结果表明，与其他控制方法相比，该方法显著提高了跟踪精度和鲁棒性。因此，相信该方法有可能成为解决此类问题的新一代解决方案。

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