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Chebyshev谱方法研究非稳态Maxwell流体在轴向余弦振荡圆柱上的斜驻点流动

白羽 唐巧丽 张艳

白羽, 唐巧丽, 张艳. Chebyshev谱方法研究非稳态Maxwell流体在轴向余弦振荡圆柱上的斜驻点流动[J]. 应用数学和力学, 2023, 44(10): 1226-1235. doi: 10.21656/1000-0887.430361
引用本文: 白羽, 唐巧丽, 张艳. Chebyshev谱方法研究非稳态Maxwell流体在轴向余弦振荡圆柱上的斜驻点流动[J]. 应用数学和力学, 2023, 44(10): 1226-1235. doi: 10.21656/1000-0887.430361
BAI Yu, TANG Qiaoli, ZHANG Yan. A Chebyshev Spectral Method for the Unsteady Maxwell Oblique Stationary Point Flow on an Axially Cosine Oscillating Cylinder[J]. Applied Mathematics and Mechanics, 2023, 44(10): 1226-1235. doi: 10.21656/1000-0887.430361
Citation: BAI Yu, TANG Qiaoli, ZHANG Yan. A Chebyshev Spectral Method for the Unsteady Maxwell Oblique Stationary Point Flow on an Axially Cosine Oscillating Cylinder[J]. Applied Mathematics and Mechanics, 2023, 44(10): 1226-1235. doi: 10.21656/1000-0887.430361

Chebyshev谱方法研究非稳态Maxwell流体在轴向余弦振荡圆柱上的斜驻点流动

doi: 10.21656/1000-0887.430361
基金项目: 

国家自然科学基金项目 21878018

北京市自然科学基金和北京市教育委员会联合项目 KZ201810016018

详细信息
    作者简介:

    唐巧丽(1997—), 女, 硕士生(E-mail: tqli1934168623@163.com)

    张艳(1972—), 女, 教授, 博士, 硕士生导师(E-mail: zhangyan1@bucea.edu.cn)

    通讯作者:

    白羽(1979—), 女, 教授, 博士, 硕士生导师(通讯作者. E-mail: baiyu@bucea.edu.cn)

  • 中图分类号: O357

A Chebyshev Spectral Method for the Unsteady Maxwell Oblique Stationary Point Flow on an Axially Cosine Oscillating Cylinder

  • 摘要: 研究了非稳态Maxwell流体斜撞击轴向余弦振荡圆柱的斜驻点流动. 首先,基于斜驻点流动特性,在柱面坐标系下求得关于压力的二阶常微分方程,对压强进行修正,建立了非稳态Maxwell流体在振荡圆柱上斜驻点流动的边界层模型. 接着,合理的相似变换将模型转化,使用Chebyshev谱方法求得模型的数值解. 结果表明,在贴近圆柱表面的流体随着圆柱体做周期性运动;圆柱的曲率越大越会使在同一时刻同一位置处的流体质点的速度越大;相反,非稳态参数及流体的记忆特性也会在更靠近圆柱壁面处阻碍流体流动.
  • 图  1  斜驻点流动模型

    Figure  1.  The oblique stagnation point flow model diagram

    图  2  不同振荡参数ω下的速度三维图

      为了解释图中的颜色,读者可以参考本文的电子网页版本,后同.

    Figure  2.  3D plots of velocities u for different values of oscillation parameter ω

    图  3  不同非稳态参数α下的速度u

    Figure  3.  Velocities u for different values of unsteady parameter α

    图  4  不同圆柱曲率参数β下的速度u

    Figure  4.  Velocities u for different values of curvature parameter β

    图  5  不同速度比参数s1下的速度u

    Figure  5.  Velocities u for different values of velocity ratio parameter s1

    图  6  不同Deborah拉数De下的速度u

    Figure  6.  Velocities u for different values of Deborah number De

    图  7  流线(剪切参数s2=10)

    Figure  7.  Streamlines (shear parameter s2=10)

    图  8  流线(剪切参数s2=-10)

    Figure  8.  Streamlines (shear parameter s2=-10)

    表  1  现有f″(0)的数据与文献[33-34]中f″(0)的数据对比结果

    Table  1.   Comparison results between the present data and the data in ref. [33-34]

    s1 β=0,De=0,N=120,L=6
    ref. [33] ref. [34] present
    0.15(a/c=0.3) -0.849 4 - -0.849 4
    0.25(a/c=0.5) - -0.667 3 -0.667 3
    0.4(a/c=0.8) -0.299 4 - -0.299 4
    1(a/c=2) 2.017 5 2.017 5 2.017 5
    1.5(a/c=3) 4.729 2 4.729 3 4.729 3
    2(a/c=4) 8.000 4 - 8.000 4
    下载: 导出CSV

    表  2  选取不同长度Lf″(0)的数据对比结果

    Table  2.   Data comparison results of f″(0) with different values of length L

    s1 β=0,De=0,N=120
    L=6 L=7 L=8 L=9
    0.15(a/c=0.3) -0.849 420 808 3 -0.849 420 047 2 -0.849 420 014 1 -0.849 420 022 6
    0.25(a/c=0.5) -0.667 263 677 5 -0.667 263 660 4 -0.667 263 666 5 -0.667 263 681 3
    0.4(a/c=0.8) -0.299 388 804 7 -0.299 388 802 1 -0.299 388 810 2 -0.299 388 830 4
    1(a/c=2) 2.017 502 833 5 2.017 502 837 70 2.017 502 821 3 2.017 502 787 82
    1.5(a/c=3) 4.729 282 401 84 4.729 282 403 29 4.729 282 384 3 4.729 282 346 45
    2(a/c=4) 8.000 429 507 31 8.000 429 504 18 8.000 429 481 5 8.000 429 443 28
    下载: 导出CSV
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  • 收稿日期:  2022-11-09
  • 修回日期:  2023-03-15
  • 刊出日期:  2023-10-31

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