Smart skin for control of wall-bounded turbulent flows

用于控制壁面湍流的智能蒙皮

• 批准号: RGPIN-2020-07231
• 负责人: Ghaemi, Sina
• 金额: $ 3.35万
• 依托单位: University of Alberta
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2022
• 资助国家: 加拿大
• 起止时间: 2022-01-01 至 2023-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=760178
• 关键词: Smart; skin; control; wall; bounded

A boundary layer is a thin layer of fluid in the immediate vicinity of a solid surface where fluid velocity transitions from the velocity of the solid surface to the bulk fluid velocity. The shear stress in the fluid generates this velocity gradient, and projects as `skin-friction' on the surface. In most industrial situations, for example, the flow over an aircraft or inside a pipeline, the motions of fluid elements in the boundary layer are chaotic. Such a fluid layer is known as a turbulent boundary layer (TBL), and has a larger velocity gradient that generates greater skin-friction. In addition, when an increasing pressure gradient is imposed on a TBL, like in a diffuser or on an aircraft wing, the TBL may separate from the surface. This generates `pressure drag' and strong fluid-structure interactions. As a result, the TBL is the chief source of high fuel consumption, pollution, and structural vibration in aircrafts, submersibles, ships, and pipelines. Due to this integral effect, any progress in the control of TBLs will have a profound impact on our socio-economic and environmental protection needs. The subject of this research program is the control of attached and separated TBLs using a novel `smart skin'. To achieve this goal, we will first experimentally characterize the surface pressure of large-scale motions in attached and separated TBLs to develop a predictive model for turbulence control. In parallel, we will develop deformable surfaces that can generate on-demand local surface depression or protrusion. Linear actuators, with a frequency and displacement that matches the pressure footprint, will be integrated under a deformable skin. We will implement an array of active deformable panels and surface pressure sensors into a `smart skin'. Finally, the performance of the `smart skin' will be evaluated in a closed-loop system for active control of attached and separated TBLs. In the long-term, the proposed program will increase our fundamental knowledge of coherent motions in TBLs and provide guidelines on how to control TBLs. The developed `smart skin' will make it possible to manipulate a variety of turbulent flows including TBLs. The smart skin will also become a test-bench for the application of advanced control algorithms, artificial intelligence, and machine learning. Such an approach can ultimately modernize how we handle turbulence. It can make a breakthrough by bringing turbulence control to a variety of industrial sectors to increase efficiency and reduce environmental footprints. In addition, the multidisciplinary nature of this research program will train highly qualified personnel who are trained in a variety of disciplines.

边界层是紧邻固体表面的一薄层流体，其中流体速度从固体表面的速度转变为整体流体速度。流体中的剪切应力产生这种速度梯度，并以“表面摩擦”的形式投射到表面上。在大多数工业情况下，例如飞机上或管道内的流动，边界层中流体单元的运动是混乱的。这种流体层被称为湍流边界层（TBL），并且具有较大的速度梯度，会产生更大的表面摩擦力。此外，当对 TBL 施加不断增加的压力梯度时，例如在扩散器或飞机机翼上，TBL 可能会与表面分离。这会产生“压力阻力”和强烈的流体-结构相互作用。因此，TBL 是飞机、潜水器、船舶和管道中高燃油消耗、污染和结构振动的主要来源。由于这种整体效应，TBL控制方面的任何进展都将对我们的社会经济和环境保护需求产生深远的影响。 该研究项目的主题是使用新型“智能皮肤”来控制附着和分离的 TBL。为了实现这一目标，我们将首先通过实验表征附着式和分离式 TBL 中大规模运动的表面压力，以开发湍流控制的预测模型。与此同时，我们将开发可变形表面，可以按需产生局部表面凹陷或突出。频率和位移与压力足迹相匹配的线性致动器将集成在可变形蒙皮下。我们将在“智能皮肤”中实现一系列主动变形面板和表面压力传感器。最后，“智能皮肤”的性能将在闭环系统中进行评估，以主动控制连接和分离的 TBL。从长远来看，拟议的计划将增加我们对 TBL 相干运动的基础知识，并为如何控制 TBL 提供指导。开发的“智能皮肤”将使操纵包括 TBL 在内的各种湍流成为可能。智能皮肤也将成为先进控制算法、人工智能和机器学习应用的测试平台。这种方法最终可以使我们处理动荡的方式现代化。它可以通过为各种工业部门带来湍流控制来提高效率并减少环境足迹来取得突破。此外，该研究项目的多学科性质将培养受过多种学科培训的高素质人才。