Aerodynamic design of laminar flow wings for jet aircraft: Review

被引:0
|
作者
Yang T. [1 ]
Bai J. [1 ]
Duan Z. [2 ]
Shi Y. [3 ]
Deng Y. [2 ]
Zhou Z. [4 ]
机构
[1] School of Aeronautics, Northwestern Polytechnical University, Xi'an
[2] AVIC First Aircraft Design and Researoh Institute, Xi'an
[3] School of Aerospace Engineering, Xi'an Jiaotong University, Xi'an
[4] China Aerodynamic Research and Development Center, Mianyang
来源
Hangkong Xuebao/Acta Aeronautica et Astronautica Sinica | 2022年 / 43卷 / 11期
基金
中国国家自然科学基金;
关键词
computational fluid dynamic; drag reduction; hybrid laminar flow; natural laminar flow; optimization design;
D O I
10.7527/S1000-6893.2022.27016
中图分类号
学科分类号
摘要
The laminar flow technology is the core technology for the future development of "green aviation", and its huge drag reduction potential makes it a research hotspot in the aviation field. This article starts from the physical characteristics of flow and the nature of transition phenomena of jet airliners, and expounds the realization principle and application scope of the NLF and HLFC technology. The global research status and development trend of the NLF/HLFC technology are reviewed. Focusing on the cutting-edge issues of the CFD-based laminar flow wing design technology, we systematically discuss the laminar flow from multiple levels of engineering application-oriented transition prediction methods, gradient-free/gradient-based optimization methods, uncertainty analysis and the robust optimization method. Meanwhile, the similarities and differences between the laminar flow wing aerodynamic design and full turbulent aerodynamic design are discussed, and the aerodynamic design theories of the NLF and HLFC wing are then sorted out. Finally, based on the development trend of the jet airliner technology, the problems faced by the laminar flow design technology are summarized, and the future development direction and suggestions for the aerodynamic optimization design technology of laminar flow wings are presented. © 2022 AAAS Press of Chinese Society of Aeronautics and Astronautics. All rights reserved.
引用
收藏
相关论文
共 165 条
  • [91] CODER J G, MAUGHMER M D., Computational fluid dynamics compatible transition modeling using an amplification factor transport equation, AIAA Journal, 52, 11, pp. 2506-2512, (2014)
  • [92] OBERKAMPF W L, TRUCANO T G., Verification and validation in computational fluid dynamics[J], Progress in Aerospace Sciences, 38, 3, pp. 209-272, (2002)
  • [93] XU J K, BAI J Q., Amplification factor transport model based on boundary layer similarity solution[J], Acta Aeronautica et Astronautica Sinica, 37, 4, pp. 1103-1113, (2016)
  • [94] SHI Y Y, BAI J Q, HUA J, Et al., Transition prediction based on amplification factor and Spalart-Allmaras turbulence model[J], Journal of Aerospace Power, 30, 7, pp. 1670-1677, (2015)
  • [95] XU J K, QIAO L, BAI J Q., Improved local amplification factor transport equation for stationary crossflow instability in subsonic and transonic flows[J], Chinese Journal of Aeronautics, 33, 12, pp. 3073-3081, (2020)
  • [96] WALTERS D K, LEYLEK J H., A new model for boundary layer transition using a single-point RANS approach, Journal of Turbomachinery, 126, 1, pp. 193-202, (2004)
  • [97] WANG L, XIAO L H, FU S., A modular RANS approach for modeling hypersonic flow transition on a scramjet-forebody configuration, Aerospace Science and Technology, 56, pp. 112-124, (2016)
  • [98] XU J L, ZHOU Y, QIAO L, Et al., One-equation transition model based on turbulent kinetic energy transport, Journal of Propulsion Technology, 40, 4, pp. 741-749, (2019)
  • [99] QIU Y S, BAI J Q, LIU N, Et al., Global aerodynamic design optimization based on data dimensionality reduction[J], Chinese Journal of Aeronautics, 31, 4, pp. 643-659, (2018)
  • [100] WILKE G., Variable-fidelity methodology for the aerodynamic optimization of helicopter rotors, AIAA Journal, 57, 8, pp. 3145-3158, (2019)
567891011121314