跨声速中程飞机混合层流控制机翼及吸力系统设计

IF 1.5 3区工程技术 Q2 ENGINEERING, AEROSPACE

Journal of Aircraft Pub Date : 2023-10-18 DOI:10.2514/1.c037398

Adarsh Prasannakumar, Anand Sudhi, Arne Seitz, Camli Badrya

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引用次数: 0

摘要

混合层流控制(HLFC)在飞机的粘滞减阻方面具有重要的应用前景。然而，在商业应用中使用HLFC需要进一步简化。本研究为跨声速高通量燃料电池机翼和吸力系统的概念设计提供了工具。在研究的第一部分中，机翼翼型部分使用多目标遗传算法在六个展向位置优化最小总阻力。利用涡点阵法求解了机翼的诱导阻力。在研究的第二部分，吸气系统的设计是使用ASPeCT进行的，这是HLFC系统设计的内部求解器。提出了一种简化的吸气系统内部结构，使其易于集成到机翼结构中。提出了一种总阻力惩罚方法，在匹配目标吸力分布和吸力系统复杂性之间建立平衡。最后，分析了设计升力系数变化对吸力系统附加重量和非设计性能的影响。考虑到额外增加的重量和发动机的输出功率，HLFC系统最多可以减少7%的燃油消耗。

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Design of Hybrid-Laminar-Flow-Control Wing and Suction System for Transonic Midrange Aircraft

Hybrid laminar flow control (HLFC) has shown significant promise in the viscous drag reduction of aircraft. However, the use of HLFC for commercial applications requires further simplification. The current study proposes tools for the conceptual design of transonic HLFC wing and suction system. In the first part of the study, airfoil sections for the wing are optimized for minimum total drag using a multi-objective genetic algorithm approach at six spanwise locations. The induced drag of the wing is estimated using a vortex lattice method solver. In the second part of the study, suction system design is performed using ASPeCT, an in-house solver for HLFC system design. A simplified inner structure for the suction system is proposed, which can be integrated easily within the wing structure. A total drag penalty approach is proposed to establish a tradeoff between matching the target suction distribution and the complexity of the suction system. Finally, the additional weight and off-design performance of the suction system are analyzed for a [Formula: see text] change in the design lift coefficient. A maximum fuel reduction of 7% can be expected with the HLFC system taking into account the additional weight added and power off-take from the engine.

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来源期刊

Journal of Aircraft 工程技术-工程：宇航

CiteScore

4.50

自引率

31.80%

发文量

141

审稿时长

6 months

期刊介绍： This Journal is devoted to the advancement of the applied science and technology of airborne flight through the dissemination of original archival papers describing significant advances in aircraft, the operation of aircraft, and applications of aircraft technology to other fields. The Journal publishes qualified papers on aircraft systems, air transportation, air traffic management, and multidisciplinary design optimization of aircraft, flight mechanics, flight and ground testing, applied computational fluid dynamics, flight safety, weather and noise hazards, human factors, airport design, airline operations, application of computers to aircraft including artificial intelligence/expert systems, production methods, engineering economic analyses, affordability, reliability, maintainability, and logistics support, integration of propulsion and control systems into aircraft design and operations, aircraft aerodynamics (including unsteady aerodynamics), structural design/dynamics , aeroelasticity, and aeroacoustics. It publishes papers on general aviation, military and civilian aircraft, UAV, STOL and V/STOL, subsonic, supersonic, transonic, and hypersonic aircraft. Papers are sought which comprehensively survey results of recent technical work with emphasis on aircraft technology application.