Utilizing polydispersity in three-dimensional random fibrous based sound absorbing materials

• Published in: Materials & Design Vol. 247; p. 113375
• Main Authors: Tran, Quang Vu, Perrot, Camille, Panneton, Raymond, Hoang, Minh Tan, Dejaeger, Ludovic, Marcel, Valérie, Jouve, Mathieu
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 01.11.2024; Elsevier
• Subjects: Engineering Sciences; Fibrous materials; Multiscale model; Optimization; Polydispersity; Sound absorption; Transport properties; Multiscale model; Transport properties; Fibrous materials; Sound absorption; Optimization; Polydispersity
• ISSN: 0264-1275; 0261-3069; 0264-1275
• DOI: 10.1016/j.matdes.2024.113375

The distribution of fiber diameters plays a crucial role in the transport and sound absorbing properties of a three-dimensional random fibrous (3D-RF) medium. Conventionally, volume-weighted averaging of fiber diameters has been utilized as an appropriate microstructural descriptor to predict the static viscous permeability of 3D-RF media. However, the long wavelength acoustical properties of a 3D-RF medium are also sensitive to the smallest fibers, this is particularly true in the high-frequency regime. In our recent research, we demonstrated that an inverse volume-weighted averaging of fiber diameters can effectively serve as a complementary microstructural descriptor to capture the high-frequency behavior of polydisperse fibrous media. In the present work, we reexamine the identification of two representative volume elements (RVEs) which relies on the reconstruction of 3D-RF microstructures having volume-weighted and inverse-volume weighted averaged fiber diameters, respectively in the low-frequency and high frequency regimes. We investigate the implication of such a weighting procedure on the transport and sound absorbing properties of polydisperse fibrous media, highlighting their potential advantages. Furthermore, we discuss the challenges associated with this research field. Finally, we provide a brief perspective of the future directions and opportunities for advancing this area of study. •A strategy to account for the strong variability of fiber diameters is proposed.•This result in a model in which polydispersity of fibers is a key parameter.•Here, we examine if and how polydispersity could be used to enhance sound absorption.•Potential of controlled polydispersity shown in improving sound absorption of fibrous media.