Compressible flows on moving domains: Stabilized methods, weakly enforced essential boundary conditions, sliding interfaces, and application to gas-turbine modeling

Fei Xu; George Moutsanidis; David Kamensky; Ming Chen Hsu; Muthuvel Murugan; Anindya Ghoshal; Yuri Bazilevs

doi:10.1016/j.compfluid.2017.02.006

Compressible flows on moving domains: Stabilized methods, weakly enforced essential boundary conditions, sliding interfaces, and application to gas-turbine modeling

Fei Xu
, George Moutsanidis
, David Kamensky
, Ming Chen Hsu
, Muthuvel Murugan
, Anindya Ghoshal
, Yuri Bazilevs

Civil Engineering

Iowa State University
University of California at San Diego
U.S. Army Research Laboratory

Research output: Contribution to journal › Article › peer-review

101 Scopus citations

Abstract

A novel stabilized formulation for 3D compressible viscous flows on moving domains is developed. New weak imposition of essential boundary conditions and sliding-interface formulations are also proposed in the context of moving-domain compressible flows. The new formulation is successfully tested on a set of examples spanning a wide range of Reynolds and Mach numbers showing its superior robustness. Experimental validation of the new formulation is also carried out with good success. In addition, the formulation is applied to simulate flow inside a gas turbine stage, illustrating its potential to support design of real engineering systems through high-fidelity aerodynamic analysis.

Original language	English
Pages (from-to)	201-220
Number of pages	20
Journal	Computers and Fluids
Volume	158
DOIs	https://doi.org/10.1016/j.compfluid.2017.02.006
State	Published - Nov 24 2017

Keywords

Compressible flow
Discontinuity capturing
Gas turbine
Sliding-interface formulation
Stabilized methods
Weak essential boundary conditions

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10.1016/j.compfluid.2017.02.006

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title = "Compressible flows on moving domains: Stabilized methods, weakly enforced essential boundary conditions, sliding interfaces, and application to gas-turbine modeling",

abstract = "A novel stabilized formulation for 3D compressible viscous flows on moving domains is developed. New weak imposition of essential boundary conditions and sliding-interface formulations are also proposed in the context of moving-domain compressible flows. The new formulation is successfully tested on a set of examples spanning a wide range of Reynolds and Mach numbers showing its superior robustness. Experimental validation of the new formulation is also carried out with good success. In addition, the formulation is applied to simulate flow inside a gas turbine stage, illustrating its potential to support design of real engineering systems through high-fidelity aerodynamic analysis.",

keywords = "Compressible flow, Discontinuity capturing, Gas turbine, Sliding-interface formulation, Stabilized methods, Weak essential boundary conditions",

author = "Fei Xu and George Moutsanidis and David Kamensky and Hsu, \{Ming Chen\} and Muthuvel Murugan and Anindya Ghoshal and Yuri Bazilevs",

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T1 - Compressible flows on moving domains

T2 - Stabilized methods, weakly enforced essential boundary conditions, sliding interfaces, and application to gas-turbine modeling

AU - Xu, Fei

AU - Moutsanidis, George

AU - Kamensky, David

AU - Hsu, Ming Chen

AU - Murugan, Muthuvel

AU - Ghoshal, Anindya

AU - Bazilevs, Yuri

PY - 2017/11/24

Y1 - 2017/11/24

N2 - A novel stabilized formulation for 3D compressible viscous flows on moving domains is developed. New weak imposition of essential boundary conditions and sliding-interface formulations are also proposed in the context of moving-domain compressible flows. The new formulation is successfully tested on a set of examples spanning a wide range of Reynolds and Mach numbers showing its superior robustness. Experimental validation of the new formulation is also carried out with good success. In addition, the formulation is applied to simulate flow inside a gas turbine stage, illustrating its potential to support design of real engineering systems through high-fidelity aerodynamic analysis.

AB - A novel stabilized formulation for 3D compressible viscous flows on moving domains is developed. New weak imposition of essential boundary conditions and sliding-interface formulations are also proposed in the context of moving-domain compressible flows. The new formulation is successfully tested on a set of examples spanning a wide range of Reynolds and Mach numbers showing its superior robustness. Experimental validation of the new formulation is also carried out with good success. In addition, the formulation is applied to simulate flow inside a gas turbine stage, illustrating its potential to support design of real engineering systems through high-fidelity aerodynamic analysis.

KW - Compressible flow

KW - Discontinuity capturing

KW - Gas turbine

KW - Sliding-interface formulation

KW - Stabilized methods

KW - Weak essential boundary conditions

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DO - 10.1016/j.compfluid.2017.02.006

M3 - Article

AN - SCOPUS:85015626389

SN - 0045-7930

VL - 158

SP - 201

EP - 220

JO - Computers and Fluids

JF - Computers and Fluids

ER -

Compressible flows on moving domains: Stabilized methods, weakly enforced essential boundary conditions, sliding interfaces, and application to gas-turbine modeling

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Keywords

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