Paper Titles

Reinforcement of Timber Floors-Transversal Load Distribution on Timber-Concrete Systems
p.657

Lateral Load Bearing Behavior of Timber-Concrete Composite Constructions
p.665

Ultra-Thin Topping Upgrades for Improved Serviceability Performance
p.673

Experimental Characterization of Timber Floors Strengthened by in-Plane Improvement Techniques
p.682

Optimization of Mechanical and Acoustic Performance of Timber Floors
p.690

Seismic Behaviour of Composite Panel Composed of Laminated Wood and Bearing Glass - Experimental Investigation
p.698

Seismic Behaviour and Retrofitting of Timber Frame Walls
p.706

A Development of the Visco-Elastic Damper for Timber Structure and a Suggestion of the Technological Design Assistance System
p.714

Development of Wood-Based Multi-Layer Systems in Existing Building Stock
p.722

HomeAdvanced Materials ResearchAdvanced Materials Research Vol. 778Optimization of Mechanical and Acoustic...

Optimization of Mechanical and Acoustic Performance of Timber Floors

Article Preview

Abstract:

In the paper, the results of an experimental study aimed at evaluating the mutual influence among the intervention techniques normally employed to improve separately the acoustic or the mechanical performance of timber floors are provided. The superimposition of planks having different thickness and arrangement or connections is usually considered to improve the in-plane stiffness of floors, especially in case of interventions on existing buildings in seismic zone, to take into account, if possible, also preservation criteria. On the other hand, the improvement of acoustic comfort is addressed to the use of specific noise-abating materials, like insulating boards (OSB) or sheathings, whose contribution, in terms of mechanical stiffness/strength is often neglected. This work proposes a combined interpretation of the two abovementioned requirements, through the characterization of the main parameters governing the involved physical and mechanical phenomena. The first results obtained on simple unidirectional full-scale specimens of floors are presented; seven combinations among various solution of boards and noise-abating materials are compared, first from a structural and subsequently acoustic point of view. The results allow identifying the solution, which is able to optimize at best both the mechanical and acoustic requirements, to be proposed for the intervention on existing timber floors.

You might also be interested in these eBooks

Structural Health Assessment of Timber Structures

Info:

Periodical:

Advanced Materials Research (Volume 778)

Pages:

690-697

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.778.690

Citation:

Cite this paper

Online since:

September 2013

Authors:

Maria Rosa Valluzzi, Antonino di Bella, Enrico Garbin

Keywords:

Acoustic Performance, In-Plane Mechanical Resistance, Timber Floor

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

© 2013 Trans Tech Publications Ltd. All Rights Reserved

Share:

Citation:

[1] U. Barbisan, F. Laner, I solai in legno, Franco Angeli, Milano, Italy, (1995).

[2] G. Tampone, Il restauro delle strutture di legno, Ed. Hoepli, Milano, Italy, (1996).

[3] C. Modena, M.R. Valluzzi, F. da Porto, F. Casarin, Structural aspects of the conservation of historic masonry constructions in seismic areas: remedial measures and emergency actions, International Journal of Architectural Heritage, 5(4-5) (2011).

DOI: 10.1080/15583058.2011.569632

[4] A. Brignola, S. Pampanin, S. Podestà, Evaluation and control of the in-plane stiffness of timber floors for the performance-based retrofit of URM buildings, Bulletin of the New Zealand Society for Earthquake Engineering, 42(3) (2009), 204-221.

DOI: 10.5459/bnzsee.42.3.204-221

[5] E. Giuriani, A. Marini, Wooden roof box structure for the anti-seismic strengthening of historic buildings, International Journal of Architectural Heritage, 2(3) (2008), 226-246.

DOI: 10.1080/15583050802063733

[6] L. Binda, G. Cardani, A. Saisi, M.R. Valluzzi, Vulnerability analysis of the historical buildings in seismic area by a multilevel approach. Asian Journal of Civil Engineering, 7(4) (2006) 343-357.

[7] M. Corradi, E. Speranzini, A. Borri, A. Vignoli, In-plane shear reinforcement of wood beam floors with FRP, Composites: Part B, 37(4-5) (2006), 310-319.

DOI: 10.1016/j.compositesb.2005.11.003

[8] N. Gattesco, L. Marcorini, High reversibility technique for in-plane stiffening of wooden floors, Proc. Intern. Conf. 6th Structural Analysis of Historical Constructions, Bath, UK, (2008) 1035-1042.

DOI: 10.1201/9781439828229.ch118

[9] R. Tomasi, C. Baldessari, M. Piazza, The refurbishment of existing timber floors: characterization of the In-Plane behaviour, Proc. Prohitech Conference, Rome, Italy, (2009) 255-260.

[10] M.R. Valluzzi, E. Garbin, M. Dalla Benetta, C. Modena, In-plane strengthening of timber floors for the seismic improvement of masonry buildings, Proc. 11th World Conference on Timber Engineering WCTE2010, Riva del Garda, Italy, (2010) (CD-Rom).

DOI: 10.4028/www.scientific.net/amr.778.682

[11] V. Torresan, Analisi sperimentale per l'ottimizzazione delle prestazioni acustiche e meccaniche dei solai in legno, MSc dissertation, University of Padova, Padova, Italy, (2008).

[12] EN ISO 10140-3: 2010, Acoustics - Laboratory measurement of sound insulation of building elements - Part 3: Measurement of impact sound insulation, (2010).

DOI: 10.3403/30087653u

[13] M. Kartous, H.G. Jonasson, A Simplified Method to Determine Impact Sound Improvement on Light-Weight Floors, NT TR 488, (2003) 65 pp.

[14] EN ISO 3741: 2010, Acoustics - Determination of sound power levels and sound energy levels of noise sources using sound pressure - Precision methods for reverberation test rooms, (2010).

DOI: 10.3403/30147252

[15] UNI EN 12512: 2006, Timber structures. Test methods. Cyclic testing of joints made with mechanical fasteners, UNI, Milano, Italy, (2006).

DOI: 10.3403/02536208