ACTA AERONAUTICAET ASTRONAUTICA SINICA ›› 2023, Vol. 44 ›› Issue (1): 627211-627211.doi: 10.7527/S1000-6893.2022.27211
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Binbin ZHAO1,2, Heng ZHANG3(
), Jie LI1
CJA
Received:2022-03-29
Revised:2022-04-18
Accepted:2022-06-13
Online:2023-01-15
Published:2022-06-27
Contact:
Heng ZHANG
E-mail:qwedc0919@163.com
Supported by:CLC Number:
Binbin ZHAO, Heng ZHANG, Jie LI. Review of numerical simulation on complex separated flow of iced airfoil[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2023, 44(1): 627211-627211.
Fig.1
Schematic diagram of transient flow field structure behind horn ice [3]
Fig.2
Two-dimensional structured grid near glaze ice shape[14]
Fig.3
Comparison of computed results of lift coefficients for airfoil[14]
Fig.4
Comparison of streamwise velocity contours of airfoil with glaze ice(α=6°,top: result of S-A model;bottom: result of test)[15]
Fig.5
Comparison of pressure coefficient Cp distributions (left: S-A model; right: SST model)[17]
Fig.6
Unstructured mesh near three-dimensional ice shape[18]
Fig.7
Comparison of midspan pressure distributions of model at α=0°[18]
Fig.8
Unstructured surface mesh of three-dimensional ice shape[28]
Fig.9
Iso-surface of Q-criterion of instantaneous flow structure of different angles of attack[28]
Fig.10
Comparison of lift characteristic curves [28]
Fig.11
Vortex structures of shear layer of NLF0414 iced airfoil[32]
Fig.12
Multi-block structured grid near simplified ice shape[41]
Fig.13
Comparison of predicted pressure distributions(α=5°)[41]
Fig.14
Contours of spanwise vorticity of instantaneous flow field[41]
Fig.15
Hybrid mesh near ice shape[42]
Fig.16
Comparison of predicted pressure distributions(α=6°)[42]
Fig.17
Comparison of time-averaged streamwise velocity distributions(α=6°)[42]
Fig.18
Comparison of root-mean-square of fluctuations in streamwise velocity component (α=6°)[42]
Fig.19
Comparison of time-averaged pressure distributions (α=8°)[44]
Fig.20
Comparison of time-averaged pressure distributions [45]
Fig.21
Comparison of iso-surface of Q-criterion of instantaneous flow field[45]
Fig.22
Muti-scale vortices structure captured by IDDES-SLA[61]
Fig.23
Generation and evolution of shear layer vortex structure described by IDDES-SLA[61]
Fig.24
Characteristics of spatial pressure fluctuations captured by different subgrid models[61]
Fig.25
Muti-block structured grid near ice ridge[64]
Fig.26
Comparison of time-averaged streamwise velocity contours(top: result of PIV; bottom: result of ZDES) [64]
Fig.27
Power spectral densities of velocity fluctuations behind ice ridge[64]
Fig.28
Iso-surface of Q-criterion of instantaneous flow field behind ice ridge [64]
Fig.29
Instantaneous wake flow field of ZDES
Fig.30
Comparison of mean streamwise velocity profiles near wall[48]
Fig.31
Comparison of root-mean-square of fluctuations in streamwise velocity component near wall[48]
Fig.32
Iso-surface of instantaneous streamwise velocity[48]
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