Improving the Sound Absorption Properties of Flexible Polyurethane (PU) Foam using Nanofibers and Nanoparticles

Hajizadeh, Roohalah; Khavanin, Ali; Barmar, Mohammad; Jafari, Ahmad Jonidi; Dehghan, Somayeh Farhang

doi:10.32604/sv.2019.06523

Cited by 5 publications

(7 citation statements)

References 23 publications

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“…Hajizadeh et al have found that the use of a combination of nanoclay particles, polyacrylonitrile nanofibers (NFs), and PVDF NFs could synergistically improve the SAC of flexible PU foam by more than twice in the middle frequency region. [97] They have ascribed the phenomenon to the large specific surface characteristics of fillers. Tiuc et al have mixed synthetic textile fibers (including nylon, polyacril, and modal) with PU foam.…”

Section: Physical Blending Modificationmentioning

confidence: 99%

Recent Advances in Preparation and Structure of Polyurethane Porous Materials for Sound Absorbing Application

Dong,

Duan,

Chen

et al. 2024

Macromol. Rapid Commun.

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Various acoustic materials have been developed to resolve noise pollution problem in many industries. Especially, materials with porous structure have been broadly used to absorb sound energy in civil construction and transportation area. Polyurethane (PU) porous materials possess excellent damping properties, good toughness and well‐developed pore structures, which have a broad application prospect in sound absorption field. This work aimed to summarize the recent progress of fabrication and structure for PU porous materials in sound absorption application. The sound absorption mechanisms of porous materials were introduced. Different kinds of structure for typical PU porous materials in sound absorption application were covered and highlighted, which included PU foam, modified PU porous materials, aerogel, templated PU and special PU porous materials. Finally, the development direction and existing problems of PU material in sound absorption application were briefly prospected. It can be expected that porous PU with high sound absorption coefficient can be obtained by using some facile methods. The design and accurate regulation of porous structures or construction of multilayer sound absorption structure will be favorably recommended to fulfill the high demand of industrial and commercial applications in the future work.This article is protected by copyright. All rights reserved

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Section: Physical Blending Modificationmentioning

confidence: 99%

Recent Advances in Preparation and Structure of Polyurethane Porous Materials for Sound Absorbing Application

Dong,

Duan,

Chen

et al. 2024

Macromol. Rapid Commun.

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“…The outer topography of the foams is almost open cell as the gases on the outer surface will have an atmospheric effect [20]. Few SEM analysis reports have shown that rigid foams are a combination of both open and closed cells in cell structure [21].…”

Section: Figure 1 Process and Formation Of Polyurethane Foammentioning

confidence: 99%

Experimental and numerical study of rigid polyurethane foams for mechanical characteristics using finite element analysis

Jeyanthi,

Nivedhitha,

Jeyamani

et al. 2023

J. Phys.: Conf. Ser.

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Over the past three decades, the global market has attracted polyurethane (PU) foams. It has been estimated that three-quarters of global consumption of polyurethane products are mainly foams. Based on hardness and density, foams can be classified into flexible and rigid. Features like flexibility, durability, stiffness, lightweight, less cost, and low density make foams more suitable for a wide range of automotive, industrial and agricultural industries. In this aspect, rigid foams are largely used as base materials for insulating purposes, seals, gaskets, tires, bedding, and seating of trucks. Generally, these PU foams are synthesized by mixing two chemicals: polyol and isocyanates. But unfortunately, the utilisation of Petro-based polyols makes PU foam restricted due to the rapid depletion of fossil fuels. Hence, this study attempts to replace Petro-based polyols with castor oil-based polyols. Other mechanical properties, such as compression strength, were tested to evaluate its ductile and flow behaviour. Finally, the developed Kelvin foam models were used for Finite Elemental Analysis (FEM) using ANSYS software to validate experimental results. Based on the results shows that both experimental and numerical analysis of castor oil PU foams resulted in greater compressive strength when compared to Petro-based PU foams.

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“…After the sound wave entered composite samples, due to the porous structure of IBPIF, the sound wave would continue to reflect and propagate inside, resulting in the vibration of the air inside the sample, causing friction between air molecules and friction between air molecules and the cell wall to convert a part of sound energy into heat energy. [30,[36][37][38] In addition, because IBPIF was filled in the separated core of ARHC, IBPIF was surrounded by honeycomb walls of pure aramid. Therefore, during the sound wave propagation, the honeycomb wall also played a certain role in reflection and increased the propagation path of the sound wave inside the sample, and finally achieved the absorption for the sound wave.…”

Section: Sound Absorption Performance Of Composite Materialsmentioning

confidence: 99%

Research on Acoustic Absorption Properties of Aramid Honeycomb Composite Material Reinforced by Polyimide Foam

Sun

Zhang

et al. 2022

Adv Eng Mater

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To endue sound absorption behavior for aramid honeycomb core (ARHC), isocyanate-based polyimide foam (IBPIF) with excellent thermal insulation and acoustic properties produced by a new formulation of foaming slurry is filled into ARHC by the free foaming route. As a core factor to adjust the cellular structure of IBPIF, the effect of water dosage on the acoustic behavior of IBPIF and IBPIF filled ARHC (IBPIF/ARHC) is studied, and the optimal formula to produce IBPIF/ARHC is filtered out. Results suggest that water dosage effectively regulates the cellular structure of IBPIF. When water dosage is 7.2 g, IBPIF has a large windows opening rate, which plays a positive role in sound absorption performance. IBPIF/ARHC-3 has the best sound absorption property, which possesses a maximum sound absorption coefficient (α) of 0.9 at 1500 Hz. Its average α increases to 0.78 and shows an increase of 680% compared to ARHC. Meanwhile, the density of IBPIF/ARHC is only about 59 kg m À3 . In 300-600 Hz range, IBPIF-3 and ARHC show obvious synergy effects in sound absorption behavior. The average α of IBPIF-3 and ARHC is only 0.3 and 0.06, respectively, and that of IBPIF/ARHC-3 reaches up to 0.42. The thermal insulation performance of ARHC is also improved, and thermal conductivity decreases from 0.067 to 0.047-0.049 W (m K) À1 .

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Improving the Sound Absorption Properties of Flexible Polyurethane (PU) Foam using Nanofibers and Nanoparticles

Cited by 5 publications

References 23 publications

Recent Advances in Preparation and Structure of Polyurethane Porous Materials for Sound Absorbing Application

Recent Advances in Preparation and Structure of Polyurethane Porous Materials for Sound Absorbing Application

Experimental and numerical study of rigid polyurethane foams for mechanical characteristics using finite element analysis

Research on Acoustic Absorption Properties of Aramid Honeycomb Composite Material Reinforced by Polyimide Foam

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