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高太元, 崔凯, 胡守超, 王秀平. 高超声速飞行器上壁面多目标优化及性能分析[J]. 力学学报, 2013, 45(2): 193-201. DOI:10.6052/0459-1879-12-227
引用本文: 高太元, 崔凯, 胡守超, 王秀平. 高超声速飞行器上壁面多目标优化及性能分析[J]. 力学学报, 2013, 45(2): 193-201.DOI:10.6052/0459-1879-12-227
Gao Taiyuan, Cui Kai, Hu Shouchao, Wang Xiuping. MULTI-OBJECTIVE OPTIMIZATION AND AERODYNAMIC PERFORMANCE ANALYSIS OF THE UPPER SURFACE FOR HYPERSONIC VEHICLES[J]. Chinese Journal of Theoretical and Applied Mechanics, 2013, 45(2): 193-201. DOI:10.6052/0459-1879-12-227
Citation: Gao Taiyuan, Cui Kai, Hu Shouchao, Wang Xiuping. MULTI-OBJECTIVE OPTIMIZATION AND AERODYNAMIC PERFORMANCE ANALYSIS OF THE UPPER SURFACE FOR HYPERSONIC VEHICLES[J].Chinese Journal of Theoretical and Applied Mechanics, 2013, 45(2): 193-201.DOI:10.6052/0459-1879-12-227

高超声速飞行器上壁面多目标优化及性能分析

MULTI-OBJECTIVE OPTIMIZATION AND AERODYNAMIC PERFORMANCE ANALYSIS OF THE UPPER SURFACE FOR HYPERSONIC VEHICLES

  • 摘要:为分析小攻角巡航条件下吸气式高超声速飞行器上壁面的变化对其气动性能和容积的影响, 以参数化后的飞行器上壁面对称面型线为设计变量, 在飞行马赫数6.5, 飞行高度27 km, 飞行攻角为4°的条件下, 采用计算流体力学为性能分析工具, Pareto多目标遗传算法为优化设计方法, 开展了二维条件下的升阻比/容积双目标优化设计. 在此基础上, 选择典型的二维优化结果, 重构生成对应的三维构型并进行数值分析, 获得了飞行器气动性能和容积间的相互关系. 结果表明在巡航条件下, 尽管二维/三维条件下飞行器的气动参数数值有较大差别, 但在这2种条件下, 飞行器的升阻比和容积间的关系均近似呈线性反比例关系. 同时, 对于三维构型而言, 在给定容积不变的条件下, 通过改变上壁面对称面型线的形状仅能使升阻比获得较小的增量(约0.36%). 相比之下, 当给定升阻比基本不变的条件下, 飞行器容积可调空间相对较大, 约为1.93%. 此外, 计算结果还表明, 在飞行器的容积基本不变情况下, 通过调节上壁面对称面型线, 可使飞行器的俯仰力矩获得5%左右的调节空间, 且其升阻比基本不变.

    Abstract:To aim at analyzing the variation of the aerodynamic performance as well as the volume of hypersonic vehicles caused by the modification of the upper surface, a two-dimensional multi-objective optimization study is carried out by considering the design condition of flight Mach number 6.5, flight altitude 27 km, and 4? flight angle of attack. The CFD-embedded pareto genetic algorithm is used as the optimization driver. On the basis of 2D optimization results, several typical 3D configurations are generated, and a primary relationship between the aerodynamic performance and the volume is obtained by numerical simulation. The results show that the lift-to-drag ratio is approximately linear inverse proportion to the volume for both two-dimensional and three-dimensional configurations, though there are significant di erences between the 2D and 3D aerodynamic coe cient values. Moreover, the lift-to-drag ratio can only gain a little increment (about 0.36%) by adjusting the symmetrical profile shape of the upper surface when the volume is a constant, while the volume has a relatively large adjustable range (about 1.93%) under the condition of fixing the lift-to-drag ratio. Besides, the numerical results also demonstrate that the adjustment range of the pitch moment of the vehicle is about 5% by modifying the shape of the upper surface when the lift-to-drag ratio and the volume are all fixed simultaneously.

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