UFR 2-11 Description: Difference between revisions
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== Introduction == | == Introduction == | ||
The high Reynolds number flow around airfoils at large (beyond stall) | |||
angles of attack is a challenging CFD problem of significant importance | |||
for the aerospace industry. Nonetheless, up to the late 90s of the last | |||
century, the studies providing quantitative data on this type of flow | |||
were, first, exclusively experimental and, second, rather limited. The | |||
lack of CFD studies was caused by the inability of RANS turbulence | |||
models of any level of complexity to represent such massively separated | |||
flows, on one hand, and by an unaffordable computational cost of LES of | |||
such flows, on the other hand. The limited character of the early | |||
experimental studies is explained by the difficulties of measuring | |||
unsteady flow characteristics. For instance, the textbook of Hoerner | |||
[6] provides only the mean lift and drag coefficients. The same is to a | |||
considerable extent true for the later experiments of Sheldahl and | |||
Klimas (1981) [20] and of Raghunathan et al. (1988) [16] (see Table 1). | |||
More systematic studies of the considered UFR, both computational and | |||
experimental, were started towards the end of the last century, when | |||
the growth of the computer power and emergence of appropriate modelling | |||
approaches (e.g., Detached-Eddy Simulation (DES) [24, 26] and Scale- | |||
Adaptive Simulation (SAS) [10, 11]) and measurement techniques capable | |||
of capturing unsteady flow features made this possible. | |||
The key physics of this UFR is predominantly characterised by the | |||
unsteady, three-dimensional, massively-separated wake region. This | |||
takes the form of a nominally periodic shedding of large scale, | |||
coherent vortices in a vortex street pattern, which is overlaid with | |||
finer random turbulent fluctuations at higher frequencies and random | |||
modulation and intermittency at frequencies lower than the vortex | |||
shedding frequency. A visual impression of these features is given in | |||
Figure 1. It has been found that it is necessary to capture these key | |||
physical features in a simulation, not just for the prediction of | |||
unsteady quantities but even in order to reliably predict steady-state | |||
parameters such as the mean force coefficients. | |||
== Review of UFR studies and choice of test case == | == Review of UFR studies and choice of test case == | ||
{{Demo_UFR_Desc_Review}} | {{Demo_UFR_Desc_Review}} | ||
Revision as of 10:27, 5 September 2011
High Reynolds Number Flow around Airfoil in Deep Stall
Flows Around Bodies
Underlying Flow Regime 2-11
Description
Introduction
The high Reynolds number flow around airfoils at large (beyond stall)
angles of attack is a challenging CFD problem of significant importance for the aerospace industry. Nonetheless, up to the late 90s of the last century, the studies providing quantitative data on this type of flow were, first, exclusively experimental and, second, rather limited. The lack of CFD studies was caused by the inability of RANS turbulence models of any level of complexity to represent such massively separated flows, on one hand, and by an unaffordable computational cost of LES of such flows, on the other hand. The limited character of the early experimental studies is explained by the difficulties of measuring unsteady flow characteristics. For instance, the textbook of Hoerner [6] provides only the mean lift and drag coefficients. The same is to a considerable extent true for the later experiments of Sheldahl and Klimas (1981) [20] and of Raghunathan et al. (1988) [16] (see Table 1).
More systematic studies of the considered UFR, both computational and experimental, were started towards the end of the last century, when the growth of the computer power and emergence of appropriate modelling approaches (e.g., Detached-Eddy Simulation (DES) [24, 26] and Scale- Adaptive Simulation (SAS) [10, 11]) and measurement techniques capable of capturing unsteady flow features made this possible.
The key physics of this UFR is predominantly characterised by the unsteady, three-dimensional, massively-separated wake region. This takes the form of a nominally periodic shedding of large scale, coherent vortices in a vortex street pattern, which is overlaid with finer random turbulent fluctuations at higher frequencies and random modulation and intermittency at frequencies lower than the vortex shedding frequency. A visual impression of these features is given in Figure 1. It has been found that it is necessary to capture these key physical features in a simulation, not just for the prediction of unsteady quantities but even in order to reliably predict steady-state parameters such as the mean force coefficients.
Review of UFR studies and choice of test case
Provide a brief review of past studies of this UFR which have included
test case comparisons of experimental measurements with CFD results.
Identify your chosen study (or studies) on which the document will
focus. State the test-case underlying the study and briefly explain how
well this represents the UFR? Give reasons for this choice (e.g a well
constructed test case, a recognised international comparison exercise,
accurate measurements, good quality control, a rich variety of
turbulence or physical models assessed etc.) . If possible, the study
should be taken from established data bases. Indicate whether of not
the experiments have been designed for the purpose of CFD validation
(desirable but not mandatory)?
Contributed by: Charles Mockett; Misha Strelets — CFD Software GmbH and Technische Universitaet Berlin; New Technologies and Services LLC (NTS) and Saint-Petersburg State University
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