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引用次数: 0
摘要
本文采用直接数值模拟(DNS)方法研究了光滑板和水平周期边界条件下二维湍流rayleigh - b纳德(RB)对流中羽流喷射和冲击区的热输运和温度分布。对顶板和底板在瑞利数为、滑移长度b为0 (NS)到∞(FS)的参数范围内进行了数值研究。根据b可以看到两种不同的流动模式,即对流滚转状态和纬向流动,它们影响努塞尔数和雷诺数。我们表明,当归一化滑移长度(其中为无滑移(NS)板的热边界层厚度)时,纬向流动发生。且随增大而增大,在纬向流产生前达到最优。观察到对流滚转状态和纬向流动的有效标度指数。对流滚转状态下,随着滑差长度的变化,局部热通量的幂律标度分别出现在羽流喷射区和羽流冲击区。不同滑板对羽流喷射和冲击区域的DNS数据与Huang et al. (J Fluid Mech. 2022;943:A2)预测的温度剖面吻合较好。
Effect of slip length on flow dynamics and heat transport in two-dimensional Rayleigh–Bénard convection
We report a direct numerical simulation (DNS) study of the heat transport and temperature profiles of the plume ejecting and impacting regions in the two-dimensional turbulent Rayleigh–Bénard (RB) convection with slippery plates and horizontally periodic boundary conditions. The numerical study is conducted in the parameter range of Rayleigh number from to and the slip length b from 0 (NS) to ∞ (FS) for the top and bottom plates. Two distinct flow patterns can be seen depending on b, namely convection roll state and zonal flow, which affect the Nusselt number and the Reynolds number . We show that the zonal flow occurs when the normalised slip length , where is the thermal boundary layer thickness for the no-slip (NS) plates. and increase with increasing , and can reach the optimum before the generation of the zonal flow. It is observed that with the effective scaling exponent for the convection roll state, and for the zonal flow. Furthermore, for the convection roll state, the power-law scaling of the local heat flux is in the plume ejecting region, while in the plume impacting region, for varying slip length . The DNS data with different slippery plates for both plume ejecting and impacting regions agree well with the predicted temperature profiles by Huang et al. (J Fluid Mech. 2022;943:A2).
期刊介绍:
Turbulence is a physical phenomenon occurring in most fluid flows, and is a major research topic at the cutting edge of science and technology. Journal of Turbulence ( JoT) is a digital forum for disseminating new theoretical, numerical and experimental knowledge aimed at understanding, predicting and controlling fluid turbulence.
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