Abstract

The U-duct turbulent flow is a known benchmark problem with the computational challenges of high Reynolds number, high curvature and strong flow dependence on the inflow profile. We use this benchmark problem to test and evaluate the Space–Time Variational Multiscale (ST-VMS) method with ST isogeometric discretization. A fully-developed flow field in a straight duct with periodicity condition is used as the inflow profile. The ST-VMS serves as the core method. The ST framework provides higher-order accuracy in general, and the VMS feature of the ST-VMS addresses the computational challenges associated with the multiscale nature of the unsteady flow. The ST isogeometric discretization enables more accurate representation of the duct geometry and increased accuracy in the flow solution. In the straight-duct computations to obtain the inflow velocity, the periodicity condition is enforced with the ST Slip Interface method. All computations are carried out with quadratic NURBS meshes, which represent the circular arc of the duct exactly in the U-duct computations. We investigate how the results vary with the time-averaging range used in reporting the results, mesh refinement, and the Courant number. The results are compared to experimental data, showing that the ST-VMS with ST isogeometric discretization provides good accuracy in this class of flow problems.

Highlights

  • In the benchmarking context of the U-duct turbulent flow, which has a number of computational challenges, we conduct test and evaluation of the Space–Time Variational Multiscale (ST-VMS) method [1,2,3] with ST isogeometric discretization [1,4,5,6]

  • The results are compared to experimental data [188] to show how the ST-VMS with ST isogeometric discretization performs in this class of flow problems

  • We have conducted test and evaluation of the ST-VMS with ST isogeometric discretization in the benchmarking context of the U-duct turbulent flow, which has a number of computational challenges, and there is a good amount of experimental and computational data associated with this benchmark problem

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Summary

Introduction

In the benchmarking context of the U-duct turbulent flow, which has a number of computational challenges, we conduct test and evaluation of the Space–Time Variational Multiscale (ST-VMS) method [1,2,3] with ST isogeometric discretization [1,4,5,6]. Turbulent-flow test and evaluation studies were conducted earlier for the ST-VMS (see [5,7,8]), but the computations in [7,8] were with finite element discretization, and the computation in [5] was with a significantly milder

Stabilized and VMS ST computational methods
ST Slip Interface method
ST Isogeometric Analysis
Stabilization parameters and element lengths
U-duct turbulent flow
Outline of the remaining sections
Nondimensionalization
Problem setup
Boundary conditions
Computational conditions
Results
Sequence of computations
Effect of the time-averaging range
Effect of the Courant number
Concluding remarks
ST-VMS
Δ pd P 2

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