Intermittency and local Reynolds number in Navier-Stokes turbulence: A cross-over scale in the Caffarelli-Kohn-Nirenberg integral

We consider the Navier-Stokes system in a periodic porous medium Ωε where ε is the characteristic pore size. The viscosity is of order εβ with 0≤β<3/2, sufficiently close to the critical exponent β=3/2. An asymptotic expansion for the velocity and the pressure, in terms of the local Reynolds number Reε=ε3−2βis set and a second-order error estimate is proved.

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Force Production by Wing Flapping: The Role of Stroke Angle of Attack and Local Reynolds Number

33rd AIAA Applied Aerodynamics Conference ◽

10.2514/6.2015-2415 ◽

2015 ◽

Author(s):

Alok A. Rege ◽

Brian Dennis ◽

Kamesh Subbarao

Keyword(s):

Reynolds Number ◽

Angle Of Attack ◽

Force Production ◽

Local Reynolds Number

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Numerical analysis of high-lift configurations with oscillating flaps

CEAS Aeronautical Journal ◽

10.1007/s13272-021-00498-7 ◽

2021 ◽

Author(s):

Johannes Ruhland ◽

Christian Breitsamter

Keyword(s):

Reynolds Number ◽

Flow Separation ◽

Separated Flow ◽

Navier Stokes ◽

Rotational Axis ◽

High Lift ◽

Hinge Point ◽

Reduced Frequency ◽

Flap Deflection ◽

The Impact

AbstractThis study presents two-dimensional aerodynamic investigations of various high-lift configuration settings concerning the deflection angles of droop nose, spoiler and flap in the context of enhancing the high-lift performance by dynamic flap movement. The investigations highlight the impact of a periodically oscillating trailing edge flap on lift, drag and flow separation of the high-lift configuration by numerical simulations. The computations are conducted with regard to the variation of the parameters reduced frequency and the position of the rotational axis. The numerical flow simulations are conducted on a block-structured grid using Reynolds Averaged Navier Stokes simulations employing the shear stress transport $$k-\omega $$ k - ω turbulence model. The feature Dynamic Mesh Motion implements the motion of the oscillating flap. Regarding low-speed wind tunnel testing for a Reynolds number of $$0.5 \times 10^{6}$$ 0.5 × 10 6 the flap movement around a dropped hinge point, which is located outside the flap, offers benefits with regard to additional lift and delayed flow separation at the flap compared to a flap movement around a hinge point, which is located at 15 % of the flap chord length. Flow separation can be suppressed beyond the maximum static flap deflection angle. By means of an oscillating flap around the dropped hinge point, it is possible to reattach a separated flow at the flap and to keep it attached further on. For a Reynolds number of $$20 \times 10^6$$ 20 × 10 6 , reflecting full scale flight conditions, additional lift is generated for both rotational axis positions.

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Simulating flow separation from continuous surfaces: routes to overcoming the Reynolds number barrier

Philosophical Transactions of The Royal Society A Mathematical Physical and Engineering Sciences ◽

10.1098/rsta.2009.0002 ◽

2009 ◽

Vol 367 (1899) ◽

pp. 2885-2903 ◽

Cited By ~ 18

Author(s):

Michael Leschziner ◽

Ning Li ◽

Fabrizio Tessicini

Keyword(s):

Reynolds Number ◽

Turbulent Flows ◽

Major Elements ◽

Wall Layer ◽

Navier Stokes ◽

Eddy Simulation ◽

Large Eddy ◽

Rans Models ◽

High Reynolds ◽

Near Wall

This paper provides a discussion of several aspects of the construction of approaches that combine statistical (Reynolds-averaged Navier–Stokes, RANS) models with large eddy simulation (LES), with the objective of making LES an economically viable method for predicting complex, high Reynolds number turbulent flows. The first part provides a review of alternative approaches, highlighting their rationale and major elements. Next, two particular methods are introduced in greater detail: one based on coupling near-wall RANS models to the outer LES domain on a single contiguous mesh, and the other involving the application of the RANS and LES procedures on separate zones, the former confined to a thin near-wall layer. Examples for their performance are included for channel flow and, in the case of the zonal strategy, for three separated flows. Finally, a discussion of prospects is given, as viewed from the writer's perspective.

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Plunging Airfoil: Reynolds Number and Angle of Attack Effects

Aerospace ◽

10.3390/aerospace8080216 ◽

2021 ◽

Vol 8 (8) ◽

pp. 216

Author(s):

Emanuel A. R. Camacho ◽

Fernando M. S. P. Neves ◽

André R. R. Silva ◽

Jorge M. M. Barata

Keyword(s):

Reynolds Number ◽

High Performance ◽

Angle Of Attack ◽

Systems Design ◽

Reynolds Numbers ◽

Navier Stokes ◽

Low Reynolds Numbers ◽

Operational Conditions ◽

Naca0012 Airfoil ◽

The Mean

Natural flight has consistently been the wellspring of many creative minds, yet recreating the propulsive systems of natural flyers is quite hard and challenging. Regarding propulsive systems design, biomimetics offers a wide variety of solutions that can be applied at low Reynolds numbers, achieving high performance and maneuverability systems. The main goal of the current work is to computationally investigate the thrust-power intricacies while operating at different Reynolds numbers, reduced frequencies, nondimensional amplitudes, and mean angles of attack of the oscillatory motion of a NACA0012 airfoil. Simulations are performed utilizing a RANS (Reynolds Averaged Navier-Stokes) approach for a Reynolds number between 8.5×103 and 3.4×104, reduced frequencies within 1 and 5, and Strouhal numbers from 0.1 to 0.4. The influence of the mean angle-of-attack is also studied in the range of 0∘ to 10∘. The outcomes show ideal operational conditions for the diverse Reynolds numbers, and results regarding thrust-power correlations and the influence of the mean angle-of-attack on the aerodynamic coefficients and the propulsive efficiency are widely explored.

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A note on the solution of the Navier-Stokes equations for a spherically symmetric expansion into a very low pressure

Journal of Fluid Mechanics ◽

10.1017/s0022112073001606 ◽

1973 ◽

Vol 59 (2) ◽

pp. 391-396 ◽

Cited By ~ 2

Author(s):

N. C. Freeman ◽

S. Kumar

Keyword(s):

Shock Wave ◽

Reynolds Number ◽

Stokes Equation ◽

Stokes Equations ◽

Low Pressure ◽

Navier Stokes ◽

Spherically Symmetric ◽

Navier Stokes Equation ◽

Navier Stokes Equations ◽

Type Flow

It is shown that, for a spherically symmetric expansion of a gas into a low pressure, the shock wave with area change region discussed earlier (Freeman & Kumar 1972) can be further divided into two parts. For the Navier–Stokes equation, these are a region in which the asymptotic zero-pressure behaviour predicted by Ladyzhenskii is achieved followed further downstream by a transition to subsonic-type flow. The distance of this final region downstream is of order (pressure)−2/3 × (Reynolds number)−1/3.

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Numerical Simulation of Turbine Blade Boundary Layer and Heat Transfer and Assessment of Turbulence Models

Journal of Turbomachinery ◽

10.1115/1.2841190 ◽

1997 ◽

Vol 119 (4) ◽

pp. 794-801 ◽

Cited By ~ 7

Author(s):

J. Luo ◽

B. Lakshminarayana

Keyword(s):

Heat Transfer ◽

Boundary Layer ◽

Reynolds Number ◽

Low Reynolds Number ◽

Turbulence Models ◽

Navier Stokes ◽

Bypass Transition ◽

Boundary Layer Development ◽

Low Reynolds ◽

Layer Development

The boundary layer development and convective heat transfer on transonic turbine nozzle vanes are investigated using a compressible Navier–Stokes code with three low-Reynolds-number k–ε models. The mean-flow and turbulence transport equations are integrated by a four-stage Runge–Kutta scheme. Numerical predictions are compared with the experimental data acquired at Allison Engine Company. An assessment of the performance of various turbulence models is carried out. The two modes of transition, bypass transition and separation-induced transition, are studied comparatively. Effects of blade surface pressure gradients, free-stream turbulence level, and Reynolds number on the blade boundary layer development, particularly transition onset, are examined. Predictions from a parabolic boundary layer code are included for comparison with those from the elliptic Navier–Stokes code. The present study indicates that the turbine external heat transfer, under real engine conditions, can be predicted well by the Navier–Stokes procedure with the low-Reynolds-number k–ε models employed.

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Finite-amplitude steady waves in plane viscous shear flows

Journal of Fluid Mechanics ◽

10.1017/s0022112085003482 ◽

1985 ◽

Vol 160 ◽

pp. 281-295 ◽

Cited By ~ 34

Author(s):

F. A. Milinazzo ◽

P. G. Saffman

Keyword(s):

Boundary Layer ◽

Reynolds Number ◽

Stokes Equations ◽

Reynolds Numbers ◽

Finite Amplitude ◽

Linear Instability ◽

Navier Stokes ◽

Unidirectional Flow ◽

Viscous Shear ◽

Finite Amplitude Waves

Computations of two-dimensional solutions of the Navier–Stokes equations are carried out for finite-amplitude waves on steady unidirectional flow. Several cases are considered. The numerical method employs pseudospectral techniques in the streamwise direction and finite differences on a stretched grid in the transverse direction, with matching to asymptotic solutions when unbounded. Earlier results for Poiseuille flow in a channel are re-obtained, except that attention is drawn to the dependence of the minimum Reynolds number on the physical constraint of constant flux or constant pressure gradient. Attempts to calculate waves in Couette flow by continuation in the velocity of a channel wall fail. The asymptotic suction boundary layer is shown to possess finite-amplitude waves at Reynolds numbers orders of magnitude less than the critical Reynolds number for linear instability. Waves in the Blasius boundary layer and unsteady Rayleigh profile are calculated by employing the artifice of adding a body force to cancel the spatial or temporal growth. The results are verified by comparison with perturbation analysis in the vicinity of the linear-instability critical Reynolds numbers.

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Parameter Extension Simulation of Turbulent Flows in a Compressor Cascade With a High Reynolds Number

Volume 2C: Turbomachinery ◽

10.1115/gt2020-14809 ◽

2020 ◽

Author(s):

Yan Jin

Keyword(s):

Reynolds Number ◽

Turbulent Flow ◽

Turbulent Flows ◽

Stokes Equations ◽

Simulation Method ◽

Potential Method ◽

Navier Stokes ◽

Reference Solution ◽

Compressor Cascade ◽

High Reynolds

Abstract The turbulent flow in a compressor cascade is calculated by using a new simulation method, i.e., parameter extension simulation (PES). It is defined as the calculation of a turbulent flow with the help of a reference solution. A special large-eddy simulation (LES) method is developed to calculate the reference solution for PES. Then, the reference solution is extended to approximate the exact solution for the Navier-Stokes equations. The Richardson extrapolation is used to estimate the model error. The compressor cascade is made of NACA0065-009 airfoils. The Reynolds number 3.82 × 105 and the attack angles −2° to 7° are accounted for in the study. The effects of the end-walls, attack angle, and tripping bands on the flow are analyzed. The PES results are compared with the experimental data as well as the LES results using the Smagorinsky, k-equation and WALE subgrid models. The numerical results show that the PES requires a lower mesh resolution than the other LES methods. The details of the flow field including the laminar-turbulence transition can be directly captured from the PES results without introducing any additional model. These characteristics make the PES a potential method for simulating flows in turbomachinery with high Reynolds numbers.

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Investigating Gas Turbine Internal Cooling Using Supercritical CO2 at High Reynolds Numbers for Direct Fired Cycle Applications

10.1115/gt2021-59630 ◽

2021 ◽

Author(s):

Matthew Searle ◽

Arnab Roy ◽

James Black ◽

Doug Straub ◽

Sridharan Ramesh

Keyword(s):

Heat Transfer ◽

Reynolds Number ◽

Nusselt Number ◽

Gas Turbines ◽

Cfd Simulation ◽

Reynolds Numbers ◽

Navier Stokes ◽

Process Conditions ◽

Internal Cooling ◽

Air Breathing

Abstract In this paper, experimental and numerical investigations of three variants of internal cooling configurations — dimples only, ribs only and ribs with dimples have been explored at process conditions (96°C and 207bar) with sCO2 as the coolant. The designs were chosen based on a review of advanced internal cooling features typically used for air-breathing gas turbines. The experimental study described in this paper utilizes additively manufactured square channels with the cooling features over a range of Reynolds number from 80,000 to 250,000. Nusselt number is calculated in the experiments utilizing the Wilson Plot method and three heat transfer characteristics — augmentation in Nusselt number, friction factor and overall Thermal Performance Factor (TPF) are reported. To explore the effect of surface roughness introduced due to additive manufacturing, two baseline channel flow cases are considered — a conventional smooth tube and an additively manufactured square tube. A companion computational fluid dynamics (CFD) simulation is also performed for the corresponding cooling configurations reported in the experiments using the Reynolds Averaged Navier Stokes (RANS) based turbulence model. Both experimental and computational results show increasing Nusselt number augmentation as higher Reynolds numbers are approached, whereas prior work on internal cooling of air-breathing gas turbines predict a decay in the heat transfer enhancement as Reynolds number increases. Comparing cooling features, it is observed that the “ribs only” and “ribs with dimples” configurations exhibit higher Nusselt number augmentation at all Reynolds numbers compared to the “dimples only” and the “no features” configurations. However, the frictional losses are almost an order of magnitude higher in presence of ribs.

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