朱广生1, 姚世勇2, 段毅2(
)
CJA
收稿日期:2023-05-23
修回日期:2023-05-26
接受日期:2023-06-06
出版日期:2023-06-07
发布日期:2023-06-06
通讯作者:
段毅
E-mail:duanyeebj@163.com
基金资助:
Guangsheng ZHU1, Shiyong YAO2, Yi DUAN2()
Received:2023-05-23
Revised:2023-05-26
Accepted:2023-06-06
Online:2023-06-07
Published:2023-06-06
Contact:
Yi DUAN
E-mail:duanyeebj@163.com
Supported by:摘要:
减阻和降热是高速飞行器设计面临的2个核心问题。减阻可提高升阻比,减少飞行器燃料消耗;降热可减轻热防护系统重量,提升飞行器有效载荷。减阻降热是提高飞行器精细化设计,增强飞行器性能的关键技术。从高速飞行器减阻降热的工程需求出发,重点对激波、边界层的减阻降热流动控制技术的研究现状进行了回顾,并指出了其在工程应用中存在的问题与后续应重点关注的方向,以期实现飞行器主动流动控制的工程化应用,提升飞行器性能。
中图分类号:
朱广生, 姚世勇, 段毅. 高速飞行器减阻降热流动控制技术研究进展及工程应用[J]. 航空学报, 2023, 44(15): 529049-529049.
Guangsheng ZHU, Shiyong YAO, Yi DUAN. Research progress and engineering application of flow control technology for drag and heat reduction of high-speed vehicles[J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(15): 529049-529049.
图 1
气动杆诱导的流场特性
图2
马赫数8时带有12 mm空腔导弹模型流场的纹影照片[10]
图3
不同总压比条件下的逆向喷流纹影图像[28]
图4
激光放电与球体相互作用的纹影图像[40]
图5
气动杆有/无侧向喷流下的纹影图像[47]
图6
不同射流条件与策略下的马赫云图与流线分布[53]
图7
引射区域的流动结构分布[66]
图8
基于多孔介质的二氧化碳引射延迟转捩[76]
图9
沙丘形斜坡的近孔流场[98]
图10
多孔介质发汗冷却示意图[102]
图11
SHEFEX II飞行器的发汗冷却实验[107]
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