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An Improved Prediction Model for the Impact Sound Level of Lightweight Floors: Introducing Decoupled Floor-Ceiling and Beam-Plate Moment. / Mosharrof, Mohammad Sazzad; Brunskog, Jonas; Ljunggren, Fredrik; Ågren, Anders.

In: Acta Acustica united with Acustica, Vol. 97, 2011, p. 254 - 265.

Publication: Research - peer-reviewJournal article – Annual report year: 2011

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Mosharrof, Mohammad Sazzad; Brunskog, Jonas; Ljunggren, Fredrik; Ågren, Anders / An Improved Prediction Model for the Impact Sound Level of Lightweight Floors: Introducing Decoupled Floor-Ceiling and Beam-Plate Moment.

In: Acta Acustica united with Acustica, Vol. 97, 2011, p. 254 - 265.

Publication: Research - peer-reviewJournal article – Annual report year: 2011

Bibtex

@article{2a83ea4d6aaa4041af31e647c68a59a0,
title = "An Improved Prediction Model for the Impact Sound Level of Lightweight Floors: Introducing Decoupled Floor-Ceiling and Beam-Plate Moment",
author = "Mosharrof, {Mohammad Sazzad} and Jonas Brunskog and Fredrik Ljunggren and Anders Ågren",
year = "2011",
doi = "10.3813/AAA.918405",
volume = "97",
pages = "254 -- 265",
journal = "Acustica United with Acta Acustica",
issn = "1610-1928",
publisher = "S./Hirzel Verlag",

}

RIS

TY - JOUR

T1 - An Improved Prediction Model for the Impact Sound Level of Lightweight Floors: Introducing Decoupled Floor-Ceiling and Beam-Plate Moment

AU - Mosharrof,Mohammad Sazzad

AU - Brunskog,Jonas

AU - Ljunggren,Fredrik

AU - Ågren,Anders

PY - 2011

Y1 - 2011

N2 - To better understand the complex acoustic behaviour of lightweight building structures both experimental and theoretical approaches are necessary. Within the theoretical approach developing theoretical models is of great importance. The aim here is to further develop an existing method to predict the impact sound pressure level in a receiving room for a coupled floor structure where floor and ceiling are rigidly connected by beams. A theoretical model for predicting the impact sound level for a decoupled floor structure, which has no rigid mechanical connections between the floor and the ceiling, is developed. An analytical method has been implemented, where a spatial Fourier transform method as well as the Poisson’s sum formula is applied to model transformed plate displacements. Radiated sound power was calculated from these displacements and normalized sound pressure levels were calculated in one-third octave frequency bands. The predicted results from the model are compared with the results from the experiments on the decoupled floor-ceiling construction. The results gave agreements in line with comparisons regarding previous model. The effect of introducing beam-plate moment in the model is studied and is found to be dependent on frequency, showing significant improvement in predicting impact sound level at high frequency region.

AB - To better understand the complex acoustic behaviour of lightweight building structures both experimental and theoretical approaches are necessary. Within the theoretical approach developing theoretical models is of great importance. The aim here is to further develop an existing method to predict the impact sound pressure level in a receiving room for a coupled floor structure where floor and ceiling are rigidly connected by beams. A theoretical model for predicting the impact sound level for a decoupled floor structure, which has no rigid mechanical connections between the floor and the ceiling, is developed. An analytical method has been implemented, where a spatial Fourier transform method as well as the Poisson’s sum formula is applied to model transformed plate displacements. Radiated sound power was calculated from these displacements and normalized sound pressure levels were calculated in one-third octave frequency bands. The predicted results from the model are compared with the results from the experiments on the decoupled floor-ceiling construction. The results gave agreements in line with comparisons regarding previous model. The effect of introducing beam-plate moment in the model is studied and is found to be dependent on frequency, showing significant improvement in predicting impact sound level at high frequency region.

U2 - 10.3813/AAA.918405

DO - 10.3813/AAA.918405

M3 - Journal article

VL - 97

SP - 254

EP - 265

JO - Acustica United with Acta Acustica

T2 - Acustica United with Acta Acustica

JF - Acustica United with Acta Acustica

SN - 1610-1928

ER -