Research progress in preparation and acoustic properties of polymer composites with high noise reduction

doi:10.19491/j.issn.1001-9278.2023.11.019

Abstract

Abstract:

In this paper， the action mechanisms of porous sound absorbing materials， multi⁃layered sound absorbing materials， composite porous sound absorbing materials， single⁃layered sound insulating materials and multi⁃layered sound insulating materials were briefly introduced from the aspects of polymeric sound absorbing materials and sound insulating materials. Based on the limitations of the performance of existing materials， the preparation methods of polymeric composite soundproofing materials and the ways to improve their soundproofing performance were reviewed in detail. Moreover， through combining with the literature， the preparation methods and acoustic properties of layered composite noise⁃reducing materials， environmentally friendly composite noise⁃reducing materials， and acoustic metamaterials were introduced to provide a direction for the future improvement of noise⁃reducing polymeric materials. Finally， a brief outlook on the development prospects of high⁃noise composite materials was presented.

Key words: polymer, sound absorption, sound insulation, layered structure, environmental protection

CLC Number:

TQ320.7

LYU Chong, ZHU Wenwen, SHI Zhengxue, JIA Yingzi, JIANG Xueliang, YOU Feng, HUANG Ligang, YAO Chu, LIU Fangjun. Research progress in preparation and acoustic properties of polymer composites with high noise reduction[J]. China Plastics, 2023, 37(11): 170-177.

Figures/Tables 7

Fig.1. Simulation structure of periodic cell

Fig.2. Schematic diagram of chirped multi⁃storey structure

Fig.3. Morphology of CCS and the CCS/Mt aerogel

Fig.4. Schematic diagram of sound absorption mechanism of directionally antagonistic graphene sound absorber

Fig.5. Damping of sound wave pathway and possible mechanism of dissipation

Fig.6. SEM images of multilayer composites with different orientation

Fig.7. Comparison of experimental and simulation results

References 44

1	Gwon Jae Gyoung， Kim Seok Kyeong， Kim Jung Hyeun. Sound absorption behavior of flexible polyurethane foams with distinct cellular structures［J］. Materials & Design， 2016， 89： 448⁃454.
2	Kim Seok Kyeong， Giwook Sung， Gwon Jae Gyoung， et al. Controlled phase separation in flexible polyurethane foams with diethanolamine cross⁃linker for improved sound absorption efficiency［J］. International Journal of Precision Engineering and Manufacturing⁃Green Technology， 2016， 3（4）： 367⁃373.
3	Lu Bing， Lv Lingxiao， Yang Hongsheng， et al. High performance broadband acoustic absorption and sound sensing of a bubbled graphene monolith［J］. Journal of Materials Chemistry A， 2019， 7（18）： 11 423⁃11 429.
4	Jiang Xueliang， Wang Zhijie， Yang Zhen， et al. Structural design and sound absorption properties of nitrile butadiene rubber⁃polyurethane foam composites with stratified structure［J］. Polymers，2018， 10（9）：946.
5	Carolina Simón⁃Herrero， Nieves Peco， Amaya Romero， et al. PVA/nanoclay/graphene oxide aerogels with enhanced sound absorption properties［J］. Applied Acoustics，2019， 156： 40⁃45.
6	Kim Ji Mun， Kim Do Hoon， Kim Jiwan， et al. Effect of graphene on the sound damping properties of flexible polyurethane foams［J］. Macromolecular Research，2017， 25（2）： 190⁃196.
7	Van Hai Trinh， Vincent Langlois， Johann Guilleminot， et al. Tuning membrane content of sound absorbing cellular foams： Fabrication， experimental evidence and multiscale numerical simulations［J］. Materials & Design，2019， 162： 345⁃361.
8	Iwan Prasetiyo， Eki Muqowi， Azma Putra， et al. Modelling sound absorption of tunable double layer woven fabrics［J］. Applied Acoustics，2020， 157： 107008.
9	Katarzyna Kobiela⁃Mendrek， Marcin Bączek， Jan Broda， et al. Acoustic performance of sound absorbing materials produced from wool of local mountain sheep［J］. Materials，2022， 15（9）： 3139.
10	Jan Broda， Marcin Bączek. Acoustic properties of multi⁃layer wool nonwoven structures［J］. Journal of Natural Fibers，2020， 17（11）： 1 567⁃1 581.
11	徐稳，王知杰，朱雯雯，等. 微穿孔板⁃聚合物层状结构材料的制备和吸声性能［J］. 材料研究学报，2021， 35（7）： 535⁃542.
	XU W， WANG Z J， ZHU W W，et al. Preparation and sound absorption properties of MPP⁃polymers layered structure materials［J］. Chinese Journal of Materials Research，2021， 35（7）： 535⁃542.
12	Wang Zonghui， Huang Yixing， Zhang Xiaowei， et al. Broadband underwater sound absorbing structure with gradient cavity shaped polyurethane composite array supported by carbon fiber honeycomb［J］. Journal of Sound and Vibration，2020， 479： 115375.
13	Qi Lize， Zhi Chao， Meng Jiaguang， et al. Highly efficient acoustic absorber designed by backing cavity⁃like and filled⁃microperforated plate⁃like structure［J］. Materials & Design，2023， 225： 111484.
14	Jimenez N， Romero⁃Garcia V， Cebrecos A， et al. Broadband quasi perfect absorption using chirped multi⁃layer porous materials［J］. AIP Advaneces， 2016， 6（12）：121605.
15	Cao Leitao， Si Yang， Wu Yuanyuan， et al. Ultralight， superelastic and bendable lashing⁃structured nanofibrous aerogels for effective sound absorption［J］. Nanoscale， 2019， 11（5）： 2 289⁃2 298.
16	Cao Leitao， Shan Haoru， Zong Dingding， et al. Fire⁃resistant and hierarchically structured elastic ceramic nanofibrous aerogels for efficient low⁃frequency noise reduction［J］. Nano Letters， 2022， 22（4）： 1 609⁃1 617.
17	Satoru Takeshita， Amin Sadeghpour， Deeptanshu Sivaraman， et al. Solvents， CO₂ and biopolymers： structure formation in chitosan aerogel［J］. Carbohydrate Polymers， 2020， 247： 2 289⁃2 298.
18	Li Zengling， Chen Nan， Qu Liangti. Directly freeze⁃drying porous graphene aerogel as acoustic⁃absorbing material［J］. Journal of Physics： Conference Series， 2021， 2009： 012059.
19	Jiang Xueliang， Zhang Jun， You Feng， et al. Chitosan/clay aerogel： microstructural evolution， flame resistance and sound absorption［J］. Applied Clay Science， 2022， 228： 106624.
20	Shen Junshi， Hu Ruofei， Jiang Xueliang， et al. Enhanced toughness and sound absorption performance of bio⁃aerogel via incorporation of elastomer［J］. Polymers， 2022， 14（7）： 1344.
21	Jung⁃Hwan Oh， Kim Jieun， Lee Hyeongrae， et al. Directionally antagonistic graphene oxide⁃polyurethane hybrid aerogel as a sound absorber［J］. ACS Applied Materials & Interfaces，2018， 10（26）： 22 650⁃22 660.
22	Nine Md Julker， Md Ayub， Zander Anthony C， et al. Graphene oxide⁃based lamella network for enhanced sound absorption［J］. Advanced Functional Materials，2017， 27（46）： 1703820.
23	Fei Yanpei， Fang Wei， Zhong Mingqiang， et al. Morphological structure， rheological behavior， mechanical properties and sound insulation performance of thermoplastic rubber composites reinforced by different inorganic fillers［J］. Polymers， 2018， 10（3）： 276.
24	夏立超，吴宏，郭少云. 低密度聚乙烯/蒙脱土复合材料的制备及隔声性能［J］. 高分子材料科学与工程［J］. 2016， 32（5）： 119⁃123.
	XIA L C， WU H， GUO S Y. Preparation and sound insulation property of LDPE / OMMT composites［J］. Polymer Materials Science & Engineering［J］. 2016， 32（5）： 119⁃123.
25	Sabet Seyed Mohammad， Reza Keshavarz， Abdolreza Ohadi. Sound isolation properties of polycarbonate/clay and polycarbonate/silica nanocomposites［J］. Iranian Polymer Journal， 2018， 27（1）： 57⁃66.
26	Kar Goutam Prasanna， Sourav Biswas， Suryasarathi Bose. Tailoring the interface of an immiscible polymer blend by a mutually miscible homopolymer grafted onto graphene oxide： outstanding mechanical properties［J］. Physical Chemistry Chemical Physics， 2015， 17（3）： 1 811⁃1 821.
27	Yang Yong， Li Binbin， Chen Zhaofeng， et al. Sound insulation of multi⁃layer glass⁃fiber felts： Role of morphology［J］. Textile Research Journal， 2017， 87（3）： 261⁃269.
28	Zhang Fengshun， Guo Molin， Xu Kangming， et al. Multilayered damping composites with damping layer/constraining layer prepared by a novel method［J］. Composites Science and Technology， 2014， 101： 167⁃172.
29	Xia Lichao， Wu Hong， Guo Shaoyun， et al. Enhanced sound insulation and mechanical properties of LDPE/mica composites through multilayered distribution and orientation of the mica［J］. Composites Part A： Applied Science and Manufacturing， 2016， 81： 225⁃233.
30	Fan Li， Chen Zhe， Zhang Shu⁃yi， et al. An acoustic metamaterial composed of multi⁃layer membrane⁃coated perforated plates for low⁃frequency sound insulation［J］. Applied Physics Letters，2015， 106（15）：151908.
31	Xue Bai， Xie Lan， Bao Yue， et al. Multilayered epoxy/glass fiber felt composites with excellently acoustical and thermal insulation properties［J］. Journal of Applied Polymer Science， 2019， 136（3）： 46935.
32	Lihua Lyu， Lu Jing， Guo Jing， et al. Sound absorption properties of multi⁃layer structural composite materials based on waste corn husk fibers［J］. Journal of Engineered Fibers and Fabrics， 2020， 15：1⁃8.
33	Jin Yeqing， Zhu Xuekang， Pang Fuzhen， et al. Application study on noise reduction of multi⁃storey composite structure cabin［C］//Proceedings of the 2018 IEEE 8th International Conference on Underwater System Technology： Theory and Applications， Wuhan， China： IEEE，2018：1⁃5.
34	霍又嘉，朱雯雯，潘博坤，等.软硬层状聚氯乙烯复合结构材料的制备和声学性能［J］. 高分子材料科学与工程，2021， 37（3）： 123⁃128，134.
	HUO Y J， ZHU W W， PAN B K，et al. Preparation and acoustic properties of poly（vinyl chloride）soft⁃hard layered structural composites［J］. Polymer Materials Science & Engineering，2021， 37（3）： 123⁃128，134.
35	Marco Caniato， Luca Cozzarini， Chiara Schmid， et al. Acoustic and thermal characterization of a novel sustainable material incorporating recycled microplastic waste［J］. Sustainable Materials and Technologies， 2021， 28： e00274.
36	Domenico Curto， Andrea Guercio， Vincenzo Franzitta. Investigation on a bio⁃composite material as acoustic absorber and thermal insulation［J］. Energies，2020， 13（14）： 3699.
37	Rubén Maderuelo⁃Sanz， García⁃Cobos Francisco José， Sánchez⁃Delgado Francisco José， et al. Mechanical， thermal and acoustical evaluation of biocomposites made of agricultural waste for ceiling tiles［J］. Applied Acoustics，2022， 191： 108689.
38	Ali M， Almuzaiqer R， Al⁃Salem K， et al. New novel thermal insulation and sound⁃absorbing materials from discarded facemasks of COVID-19 pandemic［J］. Scientific Reports， 2021， 11（1）： 23240.
39	Zhai Shi⁃Long， Wang Yuan⁃Bo， Zhao Xiao⁃Peng. A kind of tunable acoustic metamaterial for low frequency absorption［J］. Wuli Xuebao/Acta Physica Sinica， 2019， 68（3）：108586.
40	Man Xianfeng， Luo Zhen， Liu Jian， et al. Hilbert fractal acoustic metamaterials with negative mass density and bulk modulus on subwavelength scale［J］. Materials & Design， 2019， 180： 107911.
41	Ma Fuyin， Wang Chang， Du Yang， et al. Enhancing of broadband sound absorption through soft matter［J］. Materials Horizons， 2022， 9（2）： 653⁃662.
42	Yin Xiaokai， Xu Yongchao， Cui Hongyu. Research on low frequency sound insulation properties of membrane⁃type acoustic metamaterials［J］. IOP Conference Series： Materials Science and Engineering， 2021， 1 210（1）： 012001.
43	Jun⁃Young Jang， Choon⁃Su Park， Song Kyungjun. Lightweight soundproofing membrane acoustic metamaterial for broadband sound insulation［J］. Mechanical Systems and Signal Processing，2022， 178： 109270.
44	Xie Suchao， Li Zhen， Yan Hongyu， et al. Ultra⁃broadband sound absorption performance of a multi⁃cavity composite structure filled with polyurethane［J］. Applied Acoustics， 2022， 189： 108612.

[1]	QIN Sen, HE Hezhi, ZHANG Tao, HUANG Zhaoxia, QU Jinping. Study on volume⁃pulsation injection⁃molding technology for plastics [J]. China Plastics, 2023, 37(9): 96-101.
[2]	REN Guozhen, WANG Mengmeng, HUANG Jianjian, JIN Gang. Study on preparation and properties of PEEK/TLCP blends under volume elongation flow field [J]. China Plastics, 2023, 37(8): 1-7.
[3]	YANG Xiying, CHEN Meng, ZHANG Wencai, PEI Qiang. Study on thermal stability of asphalt modified with styrene butadiene styrene/nano calcium carbonate composite [J]. China Plastics, 2023, 37(8): 45-54.
[4]	HAO Chunbo, XIAO Dajun, LIU Quanzhong, ZHENG Shusong, WANG Chun, LI Chunhui, YAO Xiuchao. Preparation and performance of high⁃flowing and high⁃impact polystyrene [J]. China Plastics, 2023, 37(2): 1-6.
[5]	JIN Qingping, LIU Yundie. Research progress in durability of fiber⁃reinforced⁃polymer⁃confined concrete columns [J]. China Plastics, 2023, 37(2): 121-128.
[6]	GU Hainan, YING Jie, QIU Qihao, CHEN Meng, WANG Chenye, TONG Qifeng. Development for applications of bio⁃based polycarbonate [J]. China Plastics, 2023, 37(10): 34-39.
[7]	SUN Jing, XIONG Faqiang, DENG Ruhui, TAO Yaxian, CHEN Xinggang. Research progress in intelligent polymeric materials for medical monitoring [J]. China Plastics, 2023, 37(10): 40-49.
[8]	WANG Jie, ZHANG Weimeng, HU Jing. Effect of poly（lactic acid）⁃co⁃hydroxyacetic acid copolymer coating on performance of poly（lactic acid） 3D printed scaffolds [J]. China Plastics, 2023, 37(1): 1-7.
[9]	ZHANG Weicheng, HU Xiang, LUO Hongxing, JIN Hui, YOU Feng, JIANG Xueliang, YAO Chu. Study on sound absorption and dynamic mechanical properties of polyurethane foaming materials filled with hollow glass beads [J]. China Plastics, 2023, 37(1): 38-45.
[10]	GAO Yonghong, PENG Mengmi, JIN Qingping. Temperature effect on bond performance between glass fiber reinforcement polymer bars and concrete [J]. China Plastics, 2022, 36(9): 16-23.
[11]	SONG Dejian, YU Peng, PENG Jinsong, XU Miaojun. Preparation of flame retardant EVA hot melt adhesive and its application in repairing cables [J]. China Plastics, 2022, 36(9): 53-56.
[12]	YANG Chaoyong, GUO Jinqiang, WANG Fuyu, ZHNAG Yuxia. Research progress in preparation and modification methods of high-performance plastic films [J]. China Plastics, 2022, 36(9): 167-179.
[13]	JIAO Zhiwei, WANG Kechen, ZHANG Yang, YANG Weimin. Performance of PVC/ABS composites filled with carbon black and talc powders based on carbon nano coating deposition [J]. China Plastics, 2022, 36(8): 10-15.
[14]	ZHANG Bing. Study on test of oxidation induction time for random copolymer polypropylene pipe [J]. China Plastics, 2022, 36(8): 107-109.
[15]	YANG Yan, WANG Jie, LI Zongyu, WANG Yiming, WANG Yunnan, LI Shuijuan, LEI Liangcai, LI Haiying. A review for synthetic methods of hyperbranched ionic liquid polymers [J]. China Plastics, 2022, 36(8): 159-165.