Acta Aeronautica et Astronautica Sinica ›› 2023, Vol. 44 ›› Issue (15): 528964-528964.doi: 10.7527/S1000-6893.2023.28964
• Fluid Mechanics and Vehicle Conceptual Design • Previous Articles
Lin BI1, Sen ZOU1,2, Zhigong TANG1(
), Xianxu YUAN1, Chao WU1,3
CJA
Received:2023-05-05
Revised:2023-05-30
Accepted:2023-06-08
Online:2023-06-12
Published:2023-06-09
Contact:
Zhigong TANG
E-mail:tangzhigong@126.com
Supported by:CLC Number:
Lin BI, Sen ZOU, Zhigong TANG, Xianxu YUAN, Chao WU. Linear stability of microchannel flow considering rarefaction effects[J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(15): 528964-528964.
Fig.1
Schematic diagrams of plane Couette flow, plane Poiseuille flow, and Rayleigh-Bénard flow
Fig.2
Streamwise velocity profiles of Poiseuille flow at different Kn (ax =5×10-5)
Fig.3
Streamwise velocity profiles of Poiseuille flow at different χ (ax =5×10-5, Kn=0.02)
Fig.4
Streamwise velocity profiles of Poiseuille flow at different ax (Kn=0.01)
Fig.5
Streamwise velocity profiles of Couette flow (The upper and lower plates move in the opposite direction at a speed of Ma=0.1) at different Kn
Fig. 6
Streamwise velocity profiles of Couette flow (The upper and lower plates move in the opposite direction at a speed of Ma=0.1) at different χ (Kn=0.02)
Fig.7
Streamwise velocity profiles of Couette flow at different plate moving speeds (Kn=0.02)
Fig.8
Density and temperature profiles of Rayleigh-Bénard flow corresponding to HS and VHS models (Kn=0.01)
Table 1
Eigenvalues of the least stable mode of Poiseuille flow (Ma=5×10-4, Re=2 000.0, α=1.0)
| N | 高斯积分点: 5×5 | 高斯积分点: 8×8 | ||
|---|---|---|---|---|
| 相速度 | 增长率 | 相速度 | 增长率 | |
| 33 | 0.312 117 65 | -0.019 972 51 | 0.312 118 05 | -0.019 974 29 |
| 49 | 0.312 099 84 | -0.019 828 63 | 0.312 100 80 | -0.019 829 83 |
| 65 | 0.312 100 02 | -0.019 809 90 | 0.312 100 26 | -0.019 811 27 |
| 81 | 0.312 100 07 | -0.019 804 71 | 0.312 099 98 | -0.019 806 09 |
| 97 | 0.312 099 70 | -0.019 803 42 | 0.312 100 42 | -0.019 804 57 |
Table 2
Eigenvalues of the least stable mode of Couette flow (Ma=5×10-4, Re=800.0, α=1.0)
| N | 高斯积分点: 5×5 | 高斯积分点: 8×8 | ||
|---|---|---|---|---|
| 相速度 | 增长率 | 相速度 | 增长率 | |
| 33 | ±0.576 433 81 | -0.129 635 06 | ±0.576 433 07 | -0.129 634 90 |
| 49 | ±0.576 468 64 | -0.129 539 31 | ±0.576 468 40 | -0.129 537 87 |
| 65 | ±0.576 472 79 | -0.129 527 99 | ±0.576 472 73 | -0.129 527 10 |
| 81 | ±0.576 474 26 | -0.129 525 29 | ±0.576 473 96 | -0.129 525 64 |
| 97 | ±0.576 474 64 | -0.129 524 27 | ±0.576 474 27 | -0.129 524 42 |
Fig.9
Phase velocity spectra
Table 3
Eigenvalues of the least stable mode of Couette flow (Ma=0.1, Kn=0.04, α=3.0)
| N | Navier-Stokes方程(无滑移边界条件) | Navier-Stokes方程(滑移边界条件) | ||||
|---|---|---|---|---|---|---|
| 相速度 | 增长率 | 相速度 | 增长率 | |||
| 40 | 1.483 883 1×10-14 | -1.197 056 4 | -5.828 452 1×10-14 | -1.168 249 8 | ||
| 80 | -1.905 262 5×10-14 | -1.197 055 2 | -1.815 787 0×10-13 | -1.168 252 7 | ||
| 120 | -4.825 780 4×10-11 | -1.197 055 1 | -5.743 615 3×10-13 | -1.168 253 0 | ||
| N | BGK方程(高斯积分点: 12×12) | BGK方程(高斯积分点: 16×16) | ||||
| 相速度 | 增长率 | 相速度 | 增长率 | |||
| 40 | 1.394 621 1×10-14 | -1.154 724 7 | -3.161 691 4×10-14 | -1.154 627 8 | ||
| 80 | 1.394 571 8×10-14 | -1.154 704 3 | -2.821 082 6×10-14 | -1.154 603 4 | ||
| 120 | 1.329 705 9×10-14 | -1.154 703 4 | -3.080 486 8×10-14 | -1.154 602 4 | ||
Table 4
Eigenvalues of the least stable mode of Poiseuille flow (ax =0.002, Kn=0.01, α=3.0)
| N | Navier-Stokes方程(无滑移边界条件) | Navier-Stokes方程(滑移边界条件) | ||||
|---|---|---|---|---|---|---|
| 相速度 | 增长率 | 相速度 | 增长率 | |||
| 40 | 0.770 874 7 | -0.171 362 3 | 0.779 954 1 | -0.169 712 0 | ||
| 80 | 0.770 874 7 | -0.171 362 3 | 0.775 290 6 | -0.168 697 1 | ||
| 120 | 0.770 874 7 | -0.171 362 3 | 0.774 452 8 | -0.168 514 8 | ||
| 160 | 0.770 874 7 | -0.171 362 3 | 0.774 162 5 | -0.168 451 6 | ||
| N | BGK(高斯积分点: 12×12) | BGK(高斯积分点: 16×16) | ||||
| 相速度 | 增长率 | 相速度 | 增长率 | |||
| 40 | 0.779 661 4 | -0.169 730 4 | 0.779 671 8 | -0.169 717 9 | ||
| 80 | 0.774 972 5 | -0.168 717 9 | 0.774 982 1 | -0.168 706 1 | ||
| 120 | 0.774 132 3 | -0.168 535 5 | 0.774 141 7 | -0.168 523 8 | ||
| 160 | 0.773 850 8 | -0.168 460 6 | 0.773 841 4 | -0.168 472 2 | ||
Fig.10
Neutral curves in (Fr, Kn) plane for HS monatomic gas (Kn=0.01)
Fig.11
Phase velocity and growth rate of the least stable mode of Poiseuille flow driven by ax =5×10-5 versus α at different Kn
Fig.12
Phase velocity and growth rate of the least stable mode of Poiseuille flow driven by ax =5×10-5 versus Knudsen number at different wave numbers
Fig.13
Phase velocity and growth rate of the least stable mode of Poiseuille flow versus α at different χ (Kn=0.03, ax =5×10-5)
Fig.14
Phase velocity and growth rate of the least stable mode of Poiseuille flow versus α at different ax (Kn=0.01)
Fig.15
Phase velocity and growth rate of the least stable mode of Couette flow versus α at different Kn (Ma=0.01)
Fig.16
Phase velocity and growth rate of the least stable mode of Couette flow versus Kn at different α (Ma=0.01)
Fig.17
Phase velocity and growth rate of the least stable mode of Couette flow versus α at different χ (Kn=0.03, Ma=0.1)
Fig.18
Phase velocity and growth rate of the least stable mode of the Couette flow versus α at different Ma (χ=1.0, Kn=0.02)
Fig.19
The neutral curves of monoatomic and diatomic gases for different molecular models (α=π)
Fig.20
Growth rate of the most unstable mode varying with Fr and Kn for different molecular models (α=π)
Fig.21
Growth rates of the most unstable modes corresponding to diatomic gases under different molecular models varying with α (Fr=3.0, Kn=0.01)
Fig.22
Phase velocity spectra at different Kn (Fr=3.0, α=π)
Fig.23
Variation of growth rate of the most unstable mode with α for different Kn (Fr=3.0)
Table 5
Grid convergence analysis of growth rate corresponding to the least stable mode of Rayleigh-Bénard flow
| α | N | 增长率 | ||
|---|---|---|---|---|
| Kn = 0.01 | Kn = 0.02 | Kn = 0.03 | ||
| 0.04 | 100 | -0.015 210 | -0.005 804 | -0.004 004 |
| 200 | -0.015 762 | -0.005 904 | -0.004 056 | |
| 300 | -0.015 816 | -0.005 914 | -0.004 061 | |
| 400 | -0.015 829 | -0.005 916 | -0.004 062 | |
| 0.06 | 100 | -0.022 570 | -0.014 783 | -0.009 484 |
| 200 | -0.022 716 | -0.014 899 | -0.009 538 | |
| 300 | -0.022 730 | -0.014 910 | -0.009 543 | |
| 400 | -0.022 733 | -0.014 913 | -0.009 545 | |
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