Re = 10,000时Taylor-Couette-Poiseuille流动的数值模拟

IF 1.8 Q3 MECHANICS Fluids Pub Date : 2023-10-19 DOI:10.3390/fluids8100280

Andrey Gavrilov, Yaroslav Ignatenko

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引用次数: 0

摘要

通过大涡模拟，研究了Re = 10000, ri/ro=0.5，内旋圆柱在速度范围N=Uω/Ub=0÷4内充分发展的同心环空湍流。同时，通过稳态、非稳态RANS k-ω SST (URANS)和椭圆混合模型(EBM)进行了仿真比较。本研究的主要重点是高旋转对平均流量、湍流统计和涡结构的影响。切向速度和雷诺应力张量的分布在N>0.5 ~ 1时改变了它们的行为。随着旋转的增加，切向波动的产生比轴向波动的产生更占优势，湍流动能的最大位置向壁面移向缓冲区。URANS和EBM方法在平均流量、湍流统计和积分参数方面与LES方法一致。LES和URANS在压力损失预测上的差异不超过20%，但平均差值在11%左右。EBM方法将压力损失低估了9%，平均不超过5%。URANS很好地描述了涡旋结构。

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Numerical Simulation of Taylor—Couette—Poiseuille Flow at Re = 10,000

A fully developed turbulent flow in a concentric annulus, Re =10,000, ri/ro=0.5, with an inner rotating cylinder in the velocity range N=Uω/Ub=0÷4, is studied via a large-eddy simulation. Also, for comparison, simulations by steady-state, unstatiounary RANS k-ω SST (URANS), and Elliptic Blending Model (EBM) were made. The main focus of this study is on the effect of high rotation on the mean flow, turbulence statistics, and vortex structure. Distribution of the tangential velocity and the Reynolds stress tensor change their behaviour at N>0.5∼1. With rotation increases, the production of tangential fluctuation becomes dominant over axial ones and the position of turbulent kinetic energy maximum shifts towards the wall into the buffer zone. URANS and EBM approaches show good agreement with LES in mean flow, turbulent statistics, and integral parameters. The difference in pressure loss prediction between LES and URANS does not exceed 20%, but the average difference is about 11%. The EBM approach underestimates pressure losses up to 9% and on average not more than 5%. Vortex structures are described well by URANS.

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