Finite Element Simulation of Edge Absorbers for Room Acoustic Applications

Florian Kraxberger; Eric Kurz; Leon Merkel; Manfred Kaltenbacher; Stefan Schoder

Finite Element Simulation of Edge Absorbers for Room Acoustic Applications

Florian Kraxberger^*, Eric Kurz, Leon Merkel, Manfred Kaltenbacher, Stefan Schoder

^*Corresponding author for this work

Research output: Chapter in Book/Report/Conference proceeding › Conference paper

Abstract

To perform acoustic treatments in rooms for the low frequency range, porous absorbent material is often placed in or close to the edge of the room. This work presents a simulation procedure based on the Helmholtz equation which is solved using the Finite Element (FE) method. Thereby, the complex density and bulk modulus of the used porous material is obtained by fitting the Johnson-Champoux-Allard-Lafarge model to measurements in an impedance tube using the four-microphone method. The simulated room is modeled with sound-hard boundary conditions and has the same dimensions as the echoic chamber at the Building Physics Laboratory at Graz University of Technology. From the FE simulations, transfer functions are computed, which allow for a comparison to decay curve measurements following ISO 354 obtained in the echoic chamber. Therewith it can be shown that the simulation results are in good agreement to the measurements. The FE simulation results allow for a prediction of the sound field in the room, additionally the simulated sound field in the absorber can be visualized.

Original language	English
Title of host publication	Fortschritte der Akustik - DAGA 2023
Editors	Otto von Estorff, Stephan Lippert
Publisher	Deutsche Gesellschaft für Akustik e.V.
Pages	1292-1295
Number of pages	4
ISBN (Electronic)	978-3-939296-21-8
Publication status	Published - Mar 2023
Event	DAGA 2023 - 49. Jahrestagung für Akustik - Hamburg, Germany Duration: 6 Mar 2023 → 9 Mar 2023

Conference

Conference	DAGA 2023 - 49. Jahrestagung für Akustik
Abbreviated title	DAGA 2023
Country/Territory	Germany
City	Hamburg
Period	6/03/23 → 9/03/23

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

https://pub.dega-akustik.de/DAGA_2023/data/articles/000419.pdf

1 Conference or symposium (Participation in/Organisation of)
1 Talk at conference or symposium

Finite Element Simulation of Edge Absorbers for Room Acoustic Applications
Florian Kraxberger (Speaker), Eric Kurz (Contributor), Leon Merkel (Contributor), Manfred Kaltenbacher (Contributor) & Stefan Schoder (Contributor)
8 Mar 2023
Activity: Talk or presentation › Talk at conference or symposium › Science to science
DAGA 2023 - 49. Jahrestagung für Akustik
Florian Kraxberger (Participant)
6 Mar 2023 → 9 Mar 2023
Activity: Participation in or organisation of › Conference or symposium (Participation in/Organisation of)

Cite this

Kraxberger, F , Kurz, E , Merkel, L , Kaltenbacher, M & Schoder, S 2023, Finite Element Simulation of Edge Absorbers for Room Acoustic Applications. in O von Estorff & S Lippert (eds), Fortschritte der Akustik - DAGA 2023. Deutsche Gesellschaft für Akustik e.V., pp. 1292-1295, DAGA 2023 - 49. Jahrestagung für Akustik, Hamburg, Germany, 6/03/23. <https://pub.dega-akustik.de/DAGA_2023/data/articles/000419.pdf>

@inproceedings{2a58295d76844cda89050563e83e0130,

title = "Finite Element Simulation of Edge Absorbers for Room Acoustic Applications",

abstract = "To perform acoustic treatments in rooms for the low frequency range, porous absorbent material is often placed in or close to the edge of the room. This work presents a simulation procedure based on the Helmholtz equation which is solved using the Finite Element (FE) method. Thereby, the complex density and bulk modulus of the used porous material is obtained by fitting the Johnson-Champoux-Allard-Lafarge model to measurements in an impedance tube using the four-microphone method. The simulated room is modeled with sound-hard boundary conditions and has the same dimensions as the echoic chamber at the Building Physics Laboratory at Graz University of Technology. From the FE simulations, transfer functions are computed, which allow for a comparison to decay curve measurements following ISO 354 obtained in the echoic chamber. Therewith it can be shown that the simulation results are in good agreement to the measurements. The FE simulation results allow for a prediction of the sound field in the room, additionally the simulated sound field in the absorber can be visualized.",

author = "Florian Kraxberger and Eric Kurz and Leon Merkel and Manfred Kaltenbacher and Stefan Schoder",

year = "2023",

month = mar,

language = "English",

pages = "1292--1295",

editor = "{von Estorff}, Otto and Stephan Lippert",

booktitle = "Fortschritte der Akustik - DAGA 2023",

publisher = "Deutsche Gesellschaft f{\"u}r Akustik e.V.",

address = "Germany",

note = "DAGA 2023 - 49. Jahrestagung f{\"u}r Akustik, DAGA 2023 ; Conference date: 06-03-2023 Through 09-03-2023",

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TY - GEN

T1 - Finite Element Simulation of Edge Absorbers for Room Acoustic Applications

AU - Kraxberger, Florian

AU - Kurz, Eric

AU - Merkel, Leon

AU - Kaltenbacher, Manfred

AU - Schoder, Stefan

PY - 2023/3

Y1 - 2023/3

N2 - To perform acoustic treatments in rooms for the low frequency range, porous absorbent material is often placed in or close to the edge of the room. This work presents a simulation procedure based on the Helmholtz equation which is solved using the Finite Element (FE) method. Thereby, the complex density and bulk modulus of the used porous material is obtained by fitting the Johnson-Champoux-Allard-Lafarge model to measurements in an impedance tube using the four-microphone method. The simulated room is modeled with sound-hard boundary conditions and has the same dimensions as the echoic chamber at the Building Physics Laboratory at Graz University of Technology. From the FE simulations, transfer functions are computed, which allow for a comparison to decay curve measurements following ISO 354 obtained in the echoic chamber. Therewith it can be shown that the simulation results are in good agreement to the measurements. The FE simulation results allow for a prediction of the sound field in the room, additionally the simulated sound field in the absorber can be visualized.

AB - To perform acoustic treatments in rooms for the low frequency range, porous absorbent material is often placed in or close to the edge of the room. This work presents a simulation procedure based on the Helmholtz equation which is solved using the Finite Element (FE) method. Thereby, the complex density and bulk modulus of the used porous material is obtained by fitting the Johnson-Champoux-Allard-Lafarge model to measurements in an impedance tube using the four-microphone method. The simulated room is modeled with sound-hard boundary conditions and has the same dimensions as the echoic chamber at the Building Physics Laboratory at Graz University of Technology. From the FE simulations, transfer functions are computed, which allow for a comparison to decay curve measurements following ISO 354 obtained in the echoic chamber. Therewith it can be shown that the simulation results are in good agreement to the measurements. The FE simulation results allow for a prediction of the sound field in the room, additionally the simulated sound field in the absorber can be visualized.

M3 - Conference paper

SP - 1292

EP - 1295

BT - Fortschritte der Akustik - DAGA 2023

A2 - von Estorff, Otto

A2 - Lippert, Stephan

PB - Deutsche Gesellschaft für Akustik e.V.

T2 - DAGA 2023 - 49. Jahrestagung für Akustik

Y2 - 6 March 2023 through 9 March 2023

ER -

Finite Element Simulation of Edge Absorbers for Room Acoustic Applications

Abstract

Conference

UN SDGs

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Activities

Finite Element Simulation of Edge Absorbers for Room Acoustic Applications

DAGA 2023 - 49. Jahrestagung für Akustik

Cite this