小型混合翼身气动设计与分析新方法

Journal of Aeronautics and Aerospace Engineering Pub Date : 2018-01-31 DOI:10.4172/2168-9792.1000206

Baig Az, T. A. Cheema, Z. Aslam, Khan Ym, H. SajidDar, Khaliq Sb

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引用次数: 7

摘要

混合翼身(BWB)概念是一个相对较新的飞机概念。机翼和机身融合成一个整体结构，大大减少了阻力，增加了升力，使其成为一种高效的设计。这项研究的目的是设计一种无线电控制的小型BWB飞机，用于远距离低空飞行，以便运送有效载荷。BWB分为中机身和外机翼。在XFLR5中分析了HS522、LA2573A、NACA 25111和MH78四种翼型。考虑到其升力和力矩特性，中机身和机翼分别选用了NACA 25111和MH78。失速速度和机翼载荷是决定飞机面积和尺寸的主要因素，这使得飞机的翼展达到了5英尺。重心被放置在气动中心之前，以提供俯仰的静态和动态稳定性。加入扭转、二面体和横扫以增加稳定性和可控性。最后的设计在XFLR5中进行了稳定性测试，并在商业计算流体动力学代码ANSYS-Fluent中进行了比较。这些模拟结果与缩小20%原型的风洞测试结果进行了比较。在XFLR5中发现3D面板方法的结果与风洞结果非常接近，但在10°攻角后的CFD结果与风洞结果不一致。因此，对于设计这种尺寸的飞机，CFD被认为是不必要的。最终，用聚苯乙烯泡沫制成了一个更大的测试原型，并成功实现了飞行。

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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A New Methodology for Aerodynamic Design and Analysis of a Small Scale Blended Wing Body

The blended wing body (BWB) concept is a relatively new concept of an aircraft. The wings and the fuselage blend into one integral structure greatly reduce drag and increases lift thus making it a highly efficient design. The aim of the research was to design a radio controlled small scale BWB aircraft for use over long ranges at low altitudes in order to deliver payloads. The BWB was divided into the center body and the outer wing. Four airfoils, HS522, LA2573A, NACA 25111 and MH78 were analyzed in XFLR5. In consideration of their lift and moment characteristics, NACA 25111 and MH78 were selected for the center body and the wing respectively. The stall speed and wing loading were the primary factors used in determining the area and size of the aircraft which converged to a design having a five feet wingspan. Center of gravity was placed ahead of aerodynamic center to provide static and dynamic stability in pitch. Twist, dihedral and sweep were given to increase stability and controllability. The final design was tested in XFLR5 for stability and in commercial computational fluid dynamic code ANSYS-Fluent for comparison. These simulation results were compared to wind tunnel tests of a 20% scaled down prototype. 3D Panel Method results in XFLR5 were found to be very close to wind tunnel results but CFD results were seen to be not conforming to the wind tunnel results after 10° angle of attack. Thus, CFD was deemed to be unnecessary for designing a plane of this size. Ultimately, a larger test prototype was made out of polystyrene foam and a successful flight was achieved.

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Journal of Aeronautics and Aerospace Engineering

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