Flexible Discretization for Computational Aeroacoustics

Manfred Kaltenbacher; Johannes Heinz; Klaus Roppert; Stefan Schoder

doi:10.23967/wccm-eccomas.2020.148

Flexible Discretization for Computational Aeroacoustics

Manfred Kaltenbacher, Johannes Heinz, Klaus Roppert, Stefan Schoder

Institute of Fundamentals and Theory in Electrical Engineering (4370)

Research output: Contribution to conference › Paper

Abstract

This contribution discusses the capabilities of non-conforming grid techniques to allow an optimal discretization for each subdomain. In doing so, we derive the Nitsche-type mortaring formulation for the acoustic wave equation, which incorporates the physical transmission condition of continuity of acoustic pressure and its flux being the normal component of the acoustic particle velocity. The Nitschetype mortaring handles the coupling by symmetrizing the bilinear form and adding an appropriate jump term. The simulation of the edge tone demonstrates the applicability and superiority of non-conforming grids for computational aeroacoustics at low Mach numbers compared to conforming finite element methods

Original language	English
Number of pages	11
DOIs	https://doi.org/10.23967/wccm-eccomas.2020.148
Publication status	Published - 2021
Event	14th World Congress on Computational Mechanics: WCCM-ECCOMAS 2020 - Virtuell, France Duration: 11 Jan 2021 → 15 Jan 2021

Conference

Conference	14th World Congress on Computational Mechanics
Abbreviated title	WCCM-ECCOMAS 2020
Country/Territory	France
City	Virtuell
Period	11/01/21 → 15/01/21

Access to Document

10.23967/wccm-eccomas.2020.148Licence: CC BY-NC-SA 4.0

Cite this

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title = "Flexible Discretization for Computational Aeroacoustics",

abstract = "This contribution discusses the capabilities of non-conforming grid techniques to allow an optimal discretization for each subdomain. In doing so, we derive the Nitsche-type mortaring formulation for the acoustic wave equation, which incorporates the physical transmission condition of continuity of acoustic pressure and its flux being the normal component of the acoustic particle velocity. The Nitschetype mortaring handles the coupling by symmetrizing the bilinear form and adding an appropriate jump term. The simulation of the edge tone demonstrates the applicability and superiority of non-conforming grids for computational aeroacoustics at low Mach numbers compared to conforming finite element methods",

author = "Manfred Kaltenbacher and Johannes Heinz and Klaus Roppert and Stefan Schoder",

year = "2021",

doi = "10.23967/wccm-eccomas.2020.148",

language = "English",

note = "14th World Congress on Computational Mechanics : WCCM-ECCOMAS 2020, WCCM-ECCOMAS 2020 ; Conference date: 11-01-2021 Through 15-01-2021",

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T1 - Flexible Discretization for Computational Aeroacoustics

AU - Kaltenbacher, Manfred

AU - Heinz, Johannes

AU - Roppert, Klaus

AU - Schoder, Stefan

PY - 2021

Y1 - 2021

N2 - This contribution discusses the capabilities of non-conforming grid techniques to allow an optimal discretization for each subdomain. In doing so, we derive the Nitsche-type mortaring formulation for the acoustic wave equation, which incorporates the physical transmission condition of continuity of acoustic pressure and its flux being the normal component of the acoustic particle velocity. The Nitschetype mortaring handles the coupling by symmetrizing the bilinear form and adding an appropriate jump term. The simulation of the edge tone demonstrates the applicability and superiority of non-conforming grids for computational aeroacoustics at low Mach numbers compared to conforming finite element methods

AB - This contribution discusses the capabilities of non-conforming grid techniques to allow an optimal discretization for each subdomain. In doing so, we derive the Nitsche-type mortaring formulation for the acoustic wave equation, which incorporates the physical transmission condition of continuity of acoustic pressure and its flux being the normal component of the acoustic particle velocity. The Nitschetype mortaring handles the coupling by symmetrizing the bilinear form and adding an appropriate jump term. The simulation of the edge tone demonstrates the applicability and superiority of non-conforming grids for computational aeroacoustics at low Mach numbers compared to conforming finite element methods

U2 - 10.23967/wccm-eccomas.2020.148

DO - 10.23967/wccm-eccomas.2020.148

M3 - Paper

T2 - 14th World Congress on Computational Mechanics

Y2 - 11 January 2021 through 15 January 2021

ER -