Morphing of Reversible Axial Fan Blade: A FSI-FEM Study

Volume 1: Aircraft Engine; Fans and Blowers; Marine; Wind Energy; Scholar Lecture Pub Date : 2021-06-07 DOI:10.1115/gt2021-59554

V. F. Barnabei, A. Castorrini, A. Corsini, F. Rispoli

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引用次数: 2

Abstract

Reversible axial fans are widely used in industrial and tunnel ventilation systems, and a lot of research effort is spent in the design process of the blades shape and blades profile. The target is to achieve reasonable performances in both flow directions, but those are still below the levels of the corresponding non-reversible geometries. In this paper, an alternative design solution for reversible axial fan is presented by adopting flexible blades instead of the rigid ones. Such design, inspired by the boat sails, could allow the blade to change its shape by passively adapting to the flow field, from a symmetrical blade profile to a not symmetric one, and thus adapting the curvature to the flow condition. In the paper, a series of alternative materials and material distributions are analysed and compared. The analysis is conducted by performing Fluid-Structure Interaction simulations using stabilized Finite Elements formulations for both the fluid and the structure dynamics. Simulations are performed using the in-house built software FEMpar, which implements the Residual Based Variational MultiScale to model the Navier-Stokes equation, the Total Lagrangian formulation for the non-linear elastic solid and the Solid Extension Moving Mesh Technique to move the fluid mesh.

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可逆轴流风机叶片变形的FSI-FEM研究

可逆轴流风机广泛应用于工业通风和隧道通风系统中，在叶片形状和叶片型线的设计过程中花费了大量的研究精力。目标是在两个流动方向上都达到合理的性能，但这些性能仍然低于相应的非可逆几何形状的水平。本文提出了一种采用柔性叶片代替刚性叶片的可逆轴流风机设计方案。这种设计受到船帆的启发，可以让叶片通过被动地适应流场来改变其形状，从对称的叶片轮廓到不对称的叶片轮廓，从而使曲率适应流动条件。本文对一系列替代材料和材料分布进行了分析和比较。分析是通过使用稳定的有限元公式对流体和结构动力学进行流固耦合模拟来进行的。仿真使用内部软件FEMpar进行，该软件实现了基于残差的变分多尺度模型来模拟Navier-Stokes方程，非线性弹性固体的总拉格朗日公式和固体扩展移动网格技术来移动流体网格。

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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Volume 1: Aircraft Engine; Fans and Blowers; Marine; Wind Energy; Scholar Lecture

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