Tools and methodologies for box-wing aircraft conceptual aerodynamic design and aeromechanic analysis

IF 1.2 4区工程技术 Q3 ENGINEERING, MECHANICAL

Mechanics & Industry Pub Date : 2021-01-01 DOI:10.1051/meca/2021037

K. Abu Salem, Palaia Giuseppe, Cipolla Vittorio, Binante Vincenzo, Zanetti Davide, Chiarelli Mario

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引用次数: 15

Abstract

A way to face the challenge of moving towards a new greener aviation is to exploit disruptive aircraft architectures; one of the most promising concept is the PrandtlPlane, a box-wing aircraft based on the Prandtl's studies on multiplane lifting systems. A box-wing designed accordingly the Prandtl “best wing system” minimizes the induced drag for given lift and span, and thus it has the potential to reduce fuel consumption and noxious emissions. For disruptive aerodynamic concepts, physic-based aerodynamic design is needed from the very early stages of the design process, because of the lack of available statistical data; this paper describes two different in-house developed aerodynamic design tools for the PrandtlPlane conceptual aerodynamic design: AEROSTATE, for the design of the box-wing lifting system in cruise condition, and THeLMA, aiming to define the layout of control surfaces and high lift devices. These two tools have been extensively used to explore the feasible space for the aerodynamic design of the box-wing architecture, aiming to define preliminary correlations between performance and design variables, and guidelines to properly initialize the design process. As a result, relevant correlations have been identified between the rear-front wing loading ratio and the performance in cruise condition, and for the rear-front flap deflections and the aeromechanic characteristics in low speed condition.

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箱翼飞机概念气动设计和气动力学分析的工具和方法

面对迈向新的绿色航空挑战的一种方法是利用颠覆性的飞机架构;最有前途的概念之一是PrandtlPlane，这是一种基于Prandtl对多平面升降系统研究的箱翼飞机。根据普朗特“最佳机翼系统”设计的箱形机翼，在给定升力和跨度的情况下，最大限度地减少了诱导阻力，因此它有可能减少燃料消耗和有害气体排放。对于破坏性的空气动力学概念，由于缺乏可用的统计数据，从设计过程的早期阶段就需要基于物理的空气动力学设计;本文介绍了普兰特飞机概念气动设计的两种不同的内部开发气动设计工具:AEROSTATE，用于设计巡航状态下的箱翼升力系统，THeLMA，旨在定义控制面和高升力装置的布局。这两种工具已被广泛用于探索箱翼结构气动设计的可行空间，旨在确定性能与设计变量之间的初步相关性，并为适当初始化设计过程提供指导。研究结果表明，巡航状态下后前翼载荷比与性能、低速状态下后前翼偏转与气动力学特性之间存在相关性。

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

Mechanics & Industry ENGINEERING, MECHANICAL-MECHANICS

CiteScore

2.80

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： An International Journal on Mechanical Sciences and Engineering Applications With papers from industry, Research and Development departments and academic institutions, this journal acts as an interface between research and industry, coordinating and disseminating scientific and technical mechanical research in relation to industrial activities. Targeted readers are technicians, engineers, executives, researchers, and teachers who are working in industrial companies as managers or in Research and Development departments, technical centres, laboratories, universities, technical and engineering schools. The journal is an AFM (Association Française de Mécanique) publication.