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超声速民机低阻低声爆布局设计与优化方法研究OA

Research on the layout design and optimization method for low drag and low sonic boom supersonic civil aircraft

中文摘要英文摘要

超声速客机是未来民机发展的重要方向之一.针对超声速民机布局快速设计与优化问题,采用欧拉方程加边界层修正的中等精度求解器搭建考虑跨声速与超声速双段巡航的跨速域快速气动优化框架.使用该框架对基准构型进行优化,在双速域 Pareto 解集中选取布局优化结果,并在此基础上对翼身组合体在超声速工况下进行了基于雷诺平均纳维-斯托克斯方程(Reynolds averaged Navier-Stokes,RANS)的高精度低阻伴随优化.优化结果表明,相较于基准构型,在 Ma=0.9 下阻力系数减小 43.4 counts,Ma=1.8 下阻力系数减少了 54.1 counts.为了解决超声速民机在低阻与低声爆性能间的多学科设计权衡问题,采用射线追踪法和基于广义 Burgers 方程的数值预测方法对近场声爆信号进行传播,对地面波形采用 Stevens 发展的 Mark Ⅶ准则计算地面声爆感觉声压级(PLdB),搭建了综合考虑气动性能和不同周向角声爆信号的多学科优化框架,实现了低阻低声爆优化设计.优化结果表明,相较于基准构型,经多学科优化后的外形在阻力性能与声爆特性上均有所改善,其中 Ma=0.9 下阻力系数降低 30.6 counts;Ma=1.8 下阻力系数降低了 50.3 counts,地面声爆感觉声压级平均降低 4.84 PLdB.

Supersonic civil aircraft have become one of the important directions for the future development of civil aviation.For the rapid conceptual design and performance optimization of supersonic civil aircraft layouts,an aerodynamic optimization framework for transonic and supersonic dual-cruise regimes was developed using a medium-fidelity solver based on the Euler equations with boundary layer correction to ensure computational efficiency while capturing key flow features.Using this framework,the baseline configuration was optimized,and the optimization results were selected from the Pareto optimal solution set in the dual-speed domain.Building on this,a high-precision low-drag adjoint optimization based on RANS equation for the wing-body combination was carried out under supersonic conditions,resulting in drag reductions of 43.4 counts at Ma=0.9 and 54.1 counts at Ma=1.8.To further address the multidisciplinary design challenge of simultaneously minimizing both drag and sonic boom intensity,a prediction method combining ray tracing technique and augmented Burgers equation was employed to simulate the propagation of near-field sonic boom signals.The ground waveforms were analyzed using the Mark VII criteria developed by Stevens to calculate the perceived loudness in decibel(PLdB)of the sonic boom.A multidisciplinary optimization framework considering both aerodynamic performance and sonic boom signals at different azimuthal angles was established to achieve a low-drag and low-sonic boom design.The optimization results showed that,compared to the baseline configuration,the final shape achieved comprehensive improvements in both drag and sonic boom performance throughout the entire sonic boom carpet region:The drag coefficient was reduced by 30.6 counts at Ma=0.9 and by 50.3 counts at Ma=1.8,while the average ground-level perceived loudness in decibel was reduced by 4.84 PLdB.

郑钦泽;梁煜;潘翀;王立峰

北京航空航天大学 航空科学与工程学院,北京 100191天目山实验室,杭州 311115||北京航空航天大学 无人系统研究院,北京 100191北京航空航天大学 航空科学与工程学院,北京 100191||天目山实验室,杭州 311115北京航空航天大学 航空科学与工程学院,北京 100191

航空航天

超声速客机低阻低声爆多学科优化跨速域气动优化伴随优化

supersonic civil aircraftlow drag low boommultidisciplinary optimizationcross velocity scope aerodynamic optimizationadjoint optimization

《空气动力学学报》 2026 (5)

88-103,16

天目山实验室"超声速客机关键技术研究及飞行验证"项目(TK-2024-D-004)

10.7638/kqdlxxb-2025.0081

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