Low-Boom Design for Supersonic Transport with Canard and Forward-Swept Wings Using Equivalent Area Design Method

IF 0.1 4区工程技术 Q4 ENGINEERING, AEROSPACE

Aerospace America Pub Date : 2023-08-16 DOI:10.3390/aerospace10080717

Yuki Kishi, Risato Yashiro, Masahiro Kanazaki

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引用次数: 1

Abstract

Forward-swept wings can be expected to be lower-boom planforms with similar amount of drag as backward-swept wings because of their good lift distributions. In this study, the equivalent area distribution of a ten-seater supersonic forward-swept wing aircraft with a canard was designed to obtain design knowledge for leading boom reduction. The equivalent area distribution of the aircraft was calculated by solving the compressible Euler equation. A feasible target equivalent area distribution was generated based on Darden’s method and compared with the equivalent area distribution. To achieve a closer match in terms of lift and geometry with the target, the main wing planform and the position of the main wing along the body and vertical axes were modified. The low-boom performances were evaluated using the extended Burgers equation. The design results indicated that the forward-swept wing configuration with a canard could divide the single peak of the leading boom into two peaks. Thus, the sonic boom strength of the canard configuration was 2.5 PLdB lower than that of the configuration without the canard wing.

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基于等效面积设计方法的鸭翼前掠翼超声速低爆设计

由于前掠翼具有良好的升力分布，因此可以预期后掠翼具有与后掠翼相似的阻力量。本文对十座舱前掠翼鸭翼飞机的等效面积分布进行了设计，以获得前置减振设计知识。通过求解可压缩欧拉方程，计算了飞机的等效面积分布。基于Darden方法生成了可行的目标等效面积分布，并与等效面积分布进行了比较。为了在升力和几何形状方面与目标更接近，对主翼平台和主翼沿机体和垂直轴的位置进行了修改。利用扩展的Burgers方程对低爆性能进行了评价。设计结果表明，鸭翼前掠翼结构可以将前导臂的单峰划分为双峰。因此，鸭翼构型的音爆强度比无鸭翼构型低2.5 PLdB。

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

Aerospace America 工程技术-工程：宇航

自引率

0.00%

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审稿时长

4-8 weeks