On the simulation of a wing with detached end-plates using an actuator line based on an anisotropic Gaussian kernel

IF 0.8 4区工程技术 Q4 ENGINEERING, MECHANICAL

Transactions of The Canadian Society for Mechanical Engineering Pub Date : 2024-01-22 DOI:10.1139/tcsme-2023-0091

M-A. Breault, P. Rochefort, G. Dumas

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引用次数: 0

Abstract

The results of an actuator line method (ALM) using an anisotropic Gaussian kernel for both, velocity sampling and force projection, are compared to the wall-resolved results of a NACA 0015 rectangular wing at an angle of attack of 10°. The rectangular wing is simulated both, with and without, detached end-plates to show that the ALM is capable of accounting for the presence of a narrow gap of 0.01 c between the tip of the wing and the end-plate. The anisotropic kernel shape is varied in the chordwise, thickness-wise, and spanwise directions for different grid sizes and number of actuating points. The body forces are truncated and regularized to enforce proper spacing between the actuating line and the end-plate. ALM and wall-resolved results are compared on the basis of the integrated lift and drag coefficients, the sectional lift and drag coefficients, as well as the tip vortex core size, position, and circulation. Recommendations are made regarding the optimal kernel shape for a given number of actuating points and mesh resolution.

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使用基于各向异性高斯核的推杆线模拟带有分离端板的机翼

使用各向异性高斯核进行速度采样和力投影的致动器线法（ALM）的结果与攻角为 10° 的 NACA 0015 矩形机翼的壁面分辨结果进行了比较。对有无分离端板的矩形机翼进行了模拟，以显示 ALM 能够考虑机翼顶端与端板之间 0.01 c 的窄间隙。各向异性核形状在弦向、厚度向和跨度向都有变化，网格大小和激励点数量各不相同。对体力进行了截断和正则化处理，以确保激励线和端板之间有适当的间距。在综合升力和阻力系数、截面升力和阻力系数以及顶端涡核大小、位置和循环的基础上，对 ALM 和壁面解析结果进行了比较。针对给定的激励点数量和网格分辨率，提出了最佳内核形状的建议。

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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来源期刊

Transactions of The Canadian Society for Mechanical Engineering 工程技术-工程：机械

CiteScore

2.30

自引率

0.00%

发文量

审稿时长

5 months

期刊介绍： Published since 1972, Transactions of the Canadian Society for Mechanical Engineering is a quarterly journal that publishes comprehensive research articles and notes in the broad field of mechanical engineering. New advances in energy systems, biomechanics, engineering analysis and design, environmental engineering, materials technology, advanced manufacturing, mechatronics, MEMS, nanotechnology, thermo-fluids engineering, and transportation systems are featured.