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Airborne acoustic properties of composite structural insulated panels CSIPs composed of fibre- magnesium-cement facesheets and expanded polystyrene core were studied. The sound reduction ratings were measured experimentally in an acoustic test laboratory composed of two reverberation chambers. The numerical finite element (FEM) model of an acoustic laboratory available in ABAQUS was used and verified with experimental results. Steady-state and transient FE analyses were performed. The 2D and 3D modelling FE results were compared. Different panel core modifications were numerically tested in order to improve the airborne sound insulation of CSIPs.
Wydawca
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Rocznik
Tom
Strony
351--364
Opis fizyczny
Bibliogr. 31 poz., tab., wykr.
Twórcy
autor
- Faculty of Civil and Environmental Engineering, Gdansk University of Technology Narutowicza 11/12, 80-233 Gdansk, Poland
autor
- Faculty of Civil and Environmental Engineering, Gdansk University of Technology Narutowicza 11/12, 80-233 Gdansk, Poland
autor
- Faculty of Civil and Environmental Engineering, Gdansk University of Technology Narutowicza 11/12, 80-233 Gdansk, Poland
Bibliografia
- 1. ABAQUS (2010a), Theory Manual, Ver. 6.10.
- 2. ABAQUS (2010b), Analysis User’s Manual, Ver. 6.10.
- 3. AMICHI K., ATALLA N., RUOKOLAINEN R. (2010), A new 3D finite element sandwich plate for predicting the vibroacoustic response of laminated, steel panels, Finite Elements in Analysis and Design, 46, 1131-1145.
- 4. DEL COZ DIAZ J.J., RABANAL P.J.A., NIETO P.J.G., LOPEZ M.A.S. (2010a), Sound transmission loss analysis through a multilayer lightweight concrete hollow brick wall by FEM and experimental validation, Building and Environment, 45, 2373-2386.
- 5. DEL COZ DIAZ J.J., NIETO F.P.G., RABANAL F.P., SIERRA J.L.S. (2010b), Optimization of an acoustic test chamber involving the fluid-structure interaction by FEM and experimental validation, Meccanica, 45, 704-722.
- 6. CREMER L., HECKL M. (1988), Structure-borne sound, Springer Verlag, Berlin.
- 7. HOKMARK B. (2007), Acoustic analysis of loudspeakers cavity including viscothermal effects, Master’s Dissertation, Lund University.
- 8. ISO 140-1 (1997), Acoustics - Measurement of sound insulation in buildings and of building elements - Part 1: Requirements for laboratory test facilities with suppressed flanking transmission.
- 9. ISO 140-3 (1995), Acoustic - Measurement of sound insulation in buildings and of building elements - Part 3: Laboratory measurements of airborne sound insulation of building elements.
- 10. ISO 140-4 (1998). Acoustics - Measurement of sound insulation in buildings and of building elements - Part 4: Field measurements of airborne sound insulation between rooms.
- 11. ISO 717-1 (1996), Acoustics - Rating of sound insulation in buildings and of building elements - Part 1: Airborne sound insulation.
- 12. KRAKERS L.A. (2009), Parametric fuselage design - Integration of mechanics and acoustic & thermal insulation, PhD Thesis, Delft University.
- 13. LANG M.A., DYM C.L. (1975), Optimal acoustic design of sandwich panels, Journal of Acoustical Society of America, 57, 1481-1487.
- 14. MAKRIS S.E., DYM C.L., MACGREGOR SMITH J. (1986), Transmission loss optimization in acoustic sandwich panels, Journal of Acoustical Society of America, 79, 1833-1843.
- 15. MALUSKI S., GIBBS B.M. (2004), The effect of construction material, contents and room geometry on the sound field in dwellings at low frequencies, Applied Acoustics, 65, 31-44.
- 16. NAIFY CH. J., HUANG CH., SNEDDON M., NUTT S. (2011), Transmission loss of honeycomb sandwich structures with attached gas layers, Applied Acoustics, 72, 71-77.
- 17. NAOKI K., TAKAYASU U. (2007), Improvements to the Johnson-Allard model for rigid-framed fibrous materials, Applied Acoustics, 68, 1468-1484.
- 18. OKUZONO T., OTSURU T., TOMIKU R., OKAMOTO N. (2010), Fundamental accuracy of time domain finite element method for sound-field analysis of rooms, Applied Acoustics, 71, 940-946.
- 19. PAPADOPOULOS C.I. (2002), Development of an optimised, standard compliant procedure to calculate sound transmission loss: design of transmission rooms, Applied Acoustics, 63, 1003-1029.
- 20. PAPADOPOULOS C.I. (2003), Development of an optimized, standard compliant procedure to calculate sound transmission loss: numerical measurements, Applied Acoustics, 64, 1069-1085.
- 21. PETERS S.T. (1998), Handbook of composites, Chapman & Hall, London.
- 22. PN-B-02151-3 (1999), Building Acoustics - Noise protection in buildings - Sound insulation of buildings and building elements - Requirements [in Polish].
- 23. SHENGCHUN W., ZHAOXIANG D., WEIDONG D.S. (2010), Sound transmission loss characteristics of unbounded orthotropic sandwich panels in bending vibration considering transverse shear deformation, Composite Structures, 92, 12, 2885-2889.
- 24. SMAKOSZ L., WAWRZYNOWICZ A., KRZACZEK M., TEJCHMAN J. (2012), Experimental and numerical evaluation of composite structural insulated wall panels, Proc. 15th European Conference on Composite Materials ECCM 15, Venice, Italy.
- 25. SMAKOSZ L., TEJCHMAN J. (2014), Evaluation of strength, deformability and failure mode of composite structural insulated panels, Materials and Design, 54C, 1068-1082.
- 26. SZUDROWICZ B., ZUCHOWICZ-WODNIKOWSKA I., TOMCZYK P. (2002), Sound insulation properties of building barriers and their components [in Polish], Building Research Institute (ITB), Warszawa.
- 27. TARNOW V. (2005), Dynamic measurements of the elastic constants of glass wool, J. Acoust. Soc. Am., 118, 6, 3672-3678.
- 28. WANG T., LI S., NUTT S.R. (2009), Optimal design of acoustical sandwich panels with a genetic algorithm, Applied Acoustics, 70, 3, 416-425.
- 29. WEN-CHAO H., CHUNG-FAI N. (1998), Sound insulation improvement using honeycomb sandwich panels, Applied Acoustics, 53, 1-3, 163-177.
- 30. VIGRAN T.E. (2008), Building Acoustics, Taylor & Francis, London and New York.
- 31. XENAKI V.K. (2005), Experimental investigation of the mechanical behaviour of EPS geofoam under static and, dynamic/cyclic loading, PhD Thesis, University of Patras.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-d1b9991a-9961-4c76-9149-dcfceb180cb8