Goldobin Denis S
Institute of Continuous Media Mechanics, UB RAS, 614013, Perm, Russia.
Department of Theoretical Physics, Perm State University, 614990, Perm, Russia.
Eur Phys J E Soft Matter. 2017 Nov 24;40(11):103. doi: 10.1140/epje/i2017-11594-4.
In the dynamics of a viscous fluid, the case of vanishing kinematic viscosity is actually equivalent to the Reynolds number tending to infinity. Hence, in the limit of vanishing viscosity the fluid flow is essentially turbulent. On the other hand, the Euler equation, which is conventionally adopted for the description of the flow of an inviscid fluid, does not possess proper turbulent behaviour. This raises the question of the existence of the passage to the limit of an inviscid fluid for real low-viscosity fluids. To address this question, one should employ the theory of turbulent boundary layer near an inflexible boundary (e.g., rigid wall). On the basis of this theory, one can see how the solutions to the Euler equation become relevant for the description of the flow of low-viscosity fluids, and obtain the small parameter quantifying accuracy of this description for real fluids.
在粘性流体动力学中,运动粘度消失的情况实际上等同于雷诺数趋于无穷大。因此,在粘度消失的极限情况下,流体流动本质上是湍流。另一方面,传统上用于描述无粘性流体流动的欧拉方程并不具备适当的湍流特性。这就引出了对于实际低粘度流体而言,是否存在向无粘性流体极限过渡的问题。为了解决这个问题,应该采用刚性边界(如刚性壁)附近的湍流边界层理论。基于该理论,可以看出欧拉方程的解如何与低粘度流体流动的描述相关,并获得量化实际流体这种描述精度的小参数。