Consistent Non-Reflecting Boundary Conditions for Both Steady and Unsteady Flow Simulations in Turbomachinery Applications

Schlüß, Daniel; Frey, Christian; Ashcroft, Graham

doi:10.7712/100016.2342.5411

Cited by 19 publications

(12 citation statements)

References 27 publications

(37 reference statements)

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“…The solution proposed in [7] to deal with this is to reformulate the nonreflecting condition in terms of a condition on the 1D characteristic variables. This approach has been used successfully by other authors employing a pseudo time iteration solver [1,14,21] and will therefore likely be investigated further in future work. In addition to this, the interface will be extended to become conservative by employing a different treatment of the mean flow similar to what has been done previously by e.g.…”

Section: Discussionmentioning

confidence: 99%

Implementation of a Quasi-Three-Dimensional Nonreflecting Blade Row Interface for Steady and Unsteady Analysis of Axial Turbomachines

Lindblad

Wukie

Villar

et al. 2018

2018 AIAA/CEAS Aeroacoustics Conference

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Higher order nonreflecting blade row interfaces are today widely used for performing both steady and unsteady simulations of the flow withing axial turbomachines. In this paper, a quasithree-dimensional nonreflecting interface based on the exact, two-dimensional nonreflecting boundary condition for a single frequency and azimuthal wave number developed by Giles is presented. The formulation has been implemented to work for both steady simulations as well as unsteady simulations employing the nonlinear Harmonic Balance method. The theory behind the construction of the nonreflecting interface is presented and details on the numerical implementation is also provided. The implementation is verified for two dimensional wave propagation along a straight cascade. It is shown that the interface correctly absorbs incoming waves, but also found that the chosen implementation strategy may be ill-posed. A simple solution to stabilize the implementation is therefore implemented, but future work should seek a more generic solution to this problem.

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Section: Discussionmentioning

confidence: 99%

Implementation of a Quasi-Three-Dimensional Nonreflecting Blade Row Interface for Steady and Unsteady Analysis of Axial Turbomachines

Lindblad

Wukie

Villar

et al. 2018

2018 AIAA/CEAS Aeroacoustics Conference

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“…It should be emphasised that this formulation is also consistent with the steady flow boundary conditions. More precisely, it is guaranteed that the time mean of a converged periodic flow satisfies the steady NRBCs [21].…”

Section: Methodsmentioning

confidence: 99%

Flutter Analysis of a Transonic Steam Turbine Blade with Frequency and Time-Domain Solvers

Frey

Ashcroft

Kersken

et al. 2019

IJTPP

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The aim of this study was to assess the capabilities of different simulation approaches to predict the flutter stability of a steam turbine rotor. The focus here was on linear and nonlinear frequency domain solvers in combination with the energy method, which is widely used for the prediction of flutter onset. Whereas a GMRES solver was used for the linear problem, the nonlinear methods employed a time-marching procedure. The solvers were applied to the flutter analysis of the first rotor bending mode of the open Durham Steam Turbine test case. This test case is representative of the last stage of modern industrial steam turbines. We compared our results to those published by other researchers in terms of aerodynamic damping and local work per cycle coefficients. Time-domain, harmonic balance, and time-linearised methods were compared to each other in terms of CPU efficiency and accuracy.

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“…A one-dimensional non-reflecting boundary condition, which drives the time and surface averaged boundary state towards prescribed values (stagnation pressure, Fig. 1 Overview of the computational domain, boundary conditions, instrumentation for time series in front of turbulent structures visualized by spanwise vorticity for better orientation stagnation temperature and flow angles at inflow, static pressure at outflow) by means of incoming characteristics, is used for both inflow and outflow [38].…”

Section: Les Of the T106c Low-pressure Turbine Cascadementioning

confidence: 99%

Statistical Error Estimation Methods for Engineering-Relevant Quantities From Scale-Resolving Simulations

Bergmann

Morsbach

Ashcroft

et al. 2021

Journal of Turbomachinery

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Scale-resolving simulations, such as large eddy simulations, have become affordable tools to investigate the flow in turbomachinery components. The resulting time-resolved flow field is typically analyzed using first- and second-order statistical moments. However, two sources of uncertainty are present when recording statistical moments from scale-resolving simulations: the influence of initial transients and statistical errors due to the finite number of samples. In this paper, both are systematically analyzed for several quantities of engineering interest using time series from a long-time large eddy simulation of the low-pressure turbine cascade T106C. A set of statistical tools to either remove or quantify these sources of uncertainty is assessed. First, the Marginal Standard Error Rule is used to detect the end of the initial transient. The method is validated for integral and local quantities and guidelines on how to handle spatially varying initial transients are formulated. With the initial transient reliably removed, the statistical error is estimated based on standard error relations considering correlations in the time series. The resulting confidence intervals are carefully verified for quantities of engineering interest utilizing cumulative and simple moving averages. Furthermore, the influence of periodic content from large scale vortex shedding on the error estimation is studied. Based on the confidence intervals, the required averaging interval to reduce the statistical uncertainty to a specific level is indicated for each considered quantity.

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Consistent Non-Reflecting Boundary Conditions for Both Steady and Unsteady Flow Simulations in Turbomachinery Applications

Cited by 19 publications

References 27 publications

Implementation of a Quasi-Three-Dimensional Nonreflecting Blade Row Interface for Steady and Unsteady Analysis of Axial Turbomachines

Implementation of a Quasi-Three-Dimensional Nonreflecting Blade Row Interface for Steady and Unsteady Analysis of Axial Turbomachines

Flutter Analysis of a Transonic Steam Turbine Blade with Frequency and Time-Domain Solvers

Statistical Error Estimation Methods for Engineering-Relevant Quantities From Scale-Resolving Simulations

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