Journal
BUILDING AND ENVIRONMENT
Volume 224, Issue -, Pages -Publisher
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.buildenv.2022.109531
Keywords
Timber construction; Structure -borne sound; Floors; Multi -story; Acoustic metamaterials; Low frequency
Funding
- Forrest and Wood Products Australia (FWPA)
- ARC Training Centre for Advanced Manufacturing of Prefabricated Housing (ARC CAMP -H) [IC150100023]
- Department of Infrastructure Engineering, University of Melbourne
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In recent years, there has been a significant expansion of multi-storey timber construction worldwide, highlighting the need for effective methods to attenuate low frequency structure-borne sound. This review discusses the fundamentals and significance of the problem, analyzes the shortcomings of existing technologies, and explores potential solutions based on metamaterials.
In recent years, advances in timber engineering, combined with an associated evolution in building codes, have led to a significant expansion of multi-storey timber construction worldwide - helping to unlock timber's potential as a sustainable alternative construction material. This expansion has intensified a long-recognised need for more effective methods to attenuate low frequency (20-120 Hz) structure-borne sound. Being lighter and less stiff than steel and concrete, timber structures tend to offer less inertial and elastic resistance to impact forces and existing sound insulation treatments provide inadequate attenuation in the 20-120 Hz range. This leads to high levels of low frequency noise transmission and deleterious effects on occupant comfort. This review lays out the fundamentals of the problem, the significance of its effects on building occupants, and the shortcomings of existing technologies developed to solve it. In this context, potential new metamaterial-based approaches are then considered. In acoustic metamaterials, previously impossible properties, such as infinite or negative mass density, stiffness, or bulk modulus, have been achieved, opening new possibilities for wave attenuation. However, practical issues, relating to structural capacity, imposed additional mass, and the breadth of attenuated frequency ranges, remain challenges to be solved. This article provides a broad overview of the characteristics that make low-frequency structure borne sound attenuation in multi-storey timber buildings so critical for occupant comfort and so difficult to achieve. It analyses the limitations of existing technologies and identifies nonlinear metamaterials that use vibro-impact oscillators to induce energy flow from low to high frequencies as having the best potential for overcoming those limitations.
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