Your search keyword '"turbulent boundary layer"' showing total 3 results

1. URANOS: A GPU accelerated Navier-Stokes solver for compressible wall-bounded flows.

Author

De Vanna, Francesco, Avanzi, Filippo, Cogo, Michele, Sandrin, Simone, Bettencourt, Matt, Picano, Francesco, and Benini, Ernesto

Subjects

*COMPRESSIBLE flow, *TURBULENT boundary layer, *MACH number, *REYNOLDS number, *NAVIER-Stokes equations, *GRAPHICS processing units, *INTERNET domain naming system

Abstract

URANOS, a massively parallel GPU-accelerated compressible flow solver for high-fidelity modeling of compressible wall flows, is presented. URANOS is based on modern high-fidelity and high-resolution discretization strategies for time-accurate compressible flow predictions. The solver provides six different convective scheme implementations, a cutting-edge method for viscous terms treatment, and three different frameworks for turbulence modeling (DNS, LES, and innovative WMLES), while utilizing a high-order finite-difference approach, ranging from second to sixth order spatial accuracy. This paper details all of these numerical models and implementation issues. Computationally, URANOS combines multiple three-dimensional MPI parallelization strategies with the open standard, OpenACC, for machine wide, on node, and on GPU parallelism, tailoring the software to match the state-of-the-art HPC computing facilities. Special attention is given to the GPU porting and data management, detailing the solver scaling properties and performance for multi-node/-GPU systems on three distinct architectures. In these experiments the different MPI strategies are compared for both GPU-aware MPI/GPU (Host-based MPI) and results are provided proving, consistently, that the GPU-aware MPI outperforms the GPU (Host-based MPI) approach. Furthermore, the GPU version is compared to the CPU only demonstrating over three times speed-up for a node-to-node comparison, even at large scales, with an efficiency of about 80% while using 1024 GPUs. Finally, the manuscript presents several validation benchmarks, from simple academic comparisons to turbulent channel and boundary layer configurations. URANOS is compared with the best DNS data available in the literature across various Mach numbers, ranging from almost incompressible conditions to hypersonic regimes, illustrating the solver's capability in treating a wide range of complex wall-flows problems using DNS, wall-resolved, and wall-modeled LES approaches. Thus, using OpenACC as a paradigm, URANOS provides a straightforward and efficient platform that can efficiently exploit the most modern GPU-accelerated computing architectures in a totally open-source and non-vendor-specific way. The solver represents a framework where the CFD community can explore the limits of modeling, test new models/methods all across a broad range of Mach and Reynolds numbers flows. The solver is released under a BSD license. Program title: Unsteady Robust All-around Navier-StOkes Solver (URANOS) CPC Library link to program files: https://doi.org/10.17632/pw5hshn9k6.1 Developer's repository link: https://gitlab.com/fralusa/uranos%5fgpu Licensing provisions: BSD License 2.0 Programming language: Fortran 90, OpenACC, MPI Nature of problem: Solving the compressible Navier-Stokes system of equations in a three-dimensional Cartesian framework from low to high Mach and Reynolds numbers conditions. Solution method: Convective terms are treated with several high-order high-resolution shock-capturing schemes (WENO/TENO) in hybrid and non-hybrid versions. The system dynamics is advanced in time with a three-stage, third-order total variation diminishing Runge-Kutta method. Three-dimensional MPI parallelization is implemented in several optimized arrangements and coupling OpenACC directives in a genuinely multi-GPU logic. [ABSTRACT FROM AUTHOR]

Published

2023

2. Turbulent Fluid Flow, by Bernard P. S., John Wiley & Sons Ltd, 2019; ISBN: 978-1-119-10624-1.

Author

Icha, Andrzej

Subjects

FLUID flow, TURBULENCE, REYNOLDS stress, TURBULENT boundary layer, DIFFUSION, EDDY viscosity

Abstract

Then, the notion of the Reynolds number is recalled briefly and the classical statistical machinery is introduced, including Reynolds' averaging technique, one-and two-point correlations functions and the Fourier analysis of velocity field. Next, a set of model equations for the calculation of turbulent homogeneous shear flows is presented, and the vorticity flux correlation is analysed in the context of transport in the channel flow. Then, the hybrid strategies that merge LES and RANS approaches are described including Detached Eddy Simulation (DES), blending methods, Flow Simulation Methodology (FSM), zonal RANS/LES formulations, Partially Averaged Navier-Stokes (PANS), and the Scale Adaptive Simulation (SAS), which is an alternative to standard DES. [Extracted from the article]

Published

2020

3. Review of Turbulence in Coastal and Civil Engineering by Mutlu Sumer and David Fuhrman.

Author

Constantinescu, George

Subjects

*COASTAL engineering, *TURBULENCE, *CIVIL engineering, *HYDRAULIC engineering, *WAVE mechanics, *INTERNAL waves, *TURBULENT boundary layer

Abstract

Though some of the topics covered are primarily relevant to coastal processes (wave boundary layers, breaking waves), most of the book content addresses a much wider audience, which includes hydraulic engineers. Moreover, topics like oscillatory turbulent boundary layers and combined oscillatory and current flows are also relevant for hydraulics and river engineering applications. The authors are to be particularly commended for their effort to emphasize fundamental turbulent processes and the role of coherent structures in explaining more advanced topics related to unsteady boundary layers developing over a loose boundary. [Extracted from the article]

Published

2020