夹芯复合材料阻尼性能的研究进展*

doi:10.11896/j.issn.1005-023X.2017.09.023

CLDB

2017, Vol. 31

Issue (9): 165-171 https://doi.org/10.11896/j.issn.1005-023X.2017.09.023

新材料新技术

夹芯复合材料阻尼性能的研究进展^*

邓安仲, 李丰恺

后勤工程学院军事工程管理系,重庆401311;
后勤工程学院化学与材料工程系,重庆401311

Research Progress on Damping Properties of Sandwich Composite

DENG Anzhong, LI Fengkai

Department of Military Engineering Management, Logistics Engineering University, Chongqing 401311;Department of Chemistry and Materials Engineering, Logistics Engineering University, Chongqing 401311

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摘要随着航空航天轻质高速化和精密仪器设备自动化的发展,振动问题日益凸显。夹芯复合材料比强度高、比模量大、减振性能优良,兼具结构和功能一体化的特性,成为航空航天领域研究的热点。从复合材料基体、增强体、界面3个方面阐述了复合材料的减振机理,介绍了目前研究热门的夹芯结构以及芯材、面板、结合界面及其相互作用对阻尼性能的影响规律,概述了夹芯复合材料阻尼改性的研究现状,最后对夹芯复合材料阻尼的研究方向进行了展望。

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	邓安仲
	李丰恺

关键词: 夹芯复合材料阻尼减振

Abstract: With the development of lightweight, high speed and automation of precision instrument and equipment, the vibration problem is increasingly prominent. Sandwich composite has become a hot spot in the field of aeronautics and astronautics due to high strength, high specific modulus, excellent damping performance, the characteristics of structural and functional integration. The damping mechanism from the matrix of composite, reinforcement and interface is elaborated, then the current popular research on the sandwich structures and the influence on damping performance from the core material, panel, bonding interface and interaction between them are introduced. The researches on damping modification of sandwich composite materials are summarized, finally the research direction on sandwich composite damping is prospected.

Key words: sandwich composite damping vibration

出版日期: 2017-05-10 发布日期: 2018-05-03

ZTFLH:

TB332

基金资助: *国家自然科学基金(11372355); 军队后勤重点科研计划(BY215J009)

作者简介: 邓安仲:男,1974年生,博士,教授,主要从事工程管理、复合材料方面的研究;李丰恺:男,1993年生,硕士研究生,主要从事复合材料阻尼方面的研究 E-mail:fengkai9369@163.com

引用本文:

邓安仲, 李丰恺. 夹芯复合材料阻尼性能的研究进展^*[J]. CLDB, 2017, 31(9): 165-171.
DENG Anzhong, LI Fengkai. Research Progress on Damping Properties of Sandwich Composite. Materials Reports, 2017, 31(9): 165-171.

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http://www.mater-rep.com/CN/10.11896/j.issn.1005-023X.2017.09.023 或 http://www.mater-rep.com/CN/Y2017/V31/I9/165

[1]	Zhang Y,Ma N, Li X, et al.Study on damping capacity of aluminum composite reinforced with in situ TiAl3 rod[J]. Mater Des,2008,29(5):1057.
[2]	Hu J, Liu G, Tang S W.Damping behavior in Al18B4O33W/Al composite containing an interfacial layer with lowmelting point metal particles[J].J Alloys Compd, 2012,5(13):61.
[3]	Asmatilu R,Claus R O,Mecham J B.Improving the damping properties of composite using ferroelectric inclusion[J].J Intelligent Mater Systems Struct, 2005,16(5):463.
[4]	Treviso A, Van B Genechten, Mundo D.Damping in composite materials: Properties models[J].Composites Part B, 2015, 78:144.
[5]	Zhang Zhongming,Liu Hongzhao.Damping of material and progress in the damping materials[J].J Funct Mater,2001,32(3):227(in Chinese).张忠明,刘宏钊.材料阻尼及阻尼材料的研究进展[J].功能材料,2001,32(3):227.
[6]	James J Sargianis, Hyung-Ick Kim, Erik Andres.Sound and vibration damping characteristics in natural material based sandwich composites[J].Compos Struct,2013,96:538.
[7]	Tan Lianghong.Development and application of damping materials and sound insulation materials[D].Changsha:Central South University, 2013(in Chinese).谭亮红. 阻尼材料和隔声材料的开发及应用研究[D].长沙:中南大学,2013.
[8]	Zhu Xi,Shi Yong,Mei Zhiyuan.Study on the application of sandwich composite materials in the acoustic stealth structure and its related technologies[J]. Chin J Ship Res,2007,2(3):34(in Chinese).朱锡,石勇,梅志远.夹芯复合材料在艇声隐身结构中的应用及其相关技术研究[J].中国舰船研究,2007, 2(3):34.
[9]	Wu Linzhi,Pan Shidong.Survey of design and manufacturing of sandwich structures[J].Mater China, 2009,28(4):40(in Chinese).吴林志,泮世东.夹芯结构的设计及制备现状[J].中国材料进展,2009,28(4):40.
[10]	Tian Nong,Xue Zhongmin,Chen Chun.Research on continuous basalt fiber and its reinforced composite material[J].Glass Fiber Reinforced Plastics/Composites,2009(1):85(in Chinese).田农,薛忠民,陈淳.纤维增强聚合物基复合材料阻尼性能的研究进展[J].玻璃钢/复合材料,2009(1):85.
[11]	Liang Jizhao.Storage modulus and its characterization of inorganic particulate-filled polymer composites[J]. J South China University of Technology:Nat Sci Ed,2008,36(11):143(in Chinese).梁基照. 无机粒子填充聚合物复合材料的储能模量及其表征[J].华南理工大学学报:自然科学版,2008,36(11):143.
[12]	Ni Nannan,Wen Yuefang.Process on the research of structure-dam-ping composites[J].J Mater Eng,2015,43(6):90(in Chinese).倪楠楠,温月芳.结构-阻尼复合材料研究进展[J].材料工程,2015,43(6):90.
[13]	Zhang Xiaonong,Wu Renjie.Damping mechanism and mapacity of metal matrix composites[J].Mater Mech Eng,1996,20(6):1(in Chinese).张小农,吴人洁.金属基复合材料的阻尼机制与性能[J].机械工程学报,1996,20(6):1.
[14]	Wang Shuibing, Li Chunhong, et al.Influence of interfacial features on Youngs modulus and interfacial damping of particle-reinforced metal matrix composite[J]. J Southwest University:Nat Sci Ed,2008,30(7):172(in Chinese).王水兵.李春红,等.界面特征对颗粒增强金属基复合材料弹性模量和界面阻尼的影响[J].西南大学学报:自然科学版,2008,30(7):172.
[15]	Wei J N, Zhong J S.Interface damping mechanism of macroscopic graphite particulate reinforced commercially pure aluminum metal matrix composites[J].J Hefei University of Technology,2010,33(10):1481(in Chinese).魏健宁,钟健松.宏观石墨颗粒增强工业纯铝金属基复合材料界面阻尼机制[J].合肥工业大学学报:自然科学版,2010,33(10):1481.
[16]	Zhang Xiaonong.Study on interface damping of metal matrix compo-sites[J].Science China(Series E),2002,32(1):14(in Chinese).张小农. 金属基复合材料界面阻尼功能研究[J].中国科学,2002,32(1):14.
[17]	Wang Wei.Study on damping properties of C/SiC composites[D].Xi'an:Northwestern Polytechnical University,2005(in Chinese).王玮. C/SiC复合材料阻尼性能研究[D].西安:西北工业大学,2005.
[18]	Kwak G H, Inoue K, Tominaga Y, et al.Characterization of the vibrational damping loss factor and viscoelastic properties of ethylene-propylene rubbers reinforced with micro-scale fillers[J]. Appl Polym Sci,2001,82:3058.
[19]	胡保全,牛晋川.先进复合材料[M].第2版.北京:国防工业出版社,20B.
[20]	郭创奇,朱其仁,郑震,等. 聚氨酯/纳米氧化锌复合材料的动态力学性能[C]∥2005年全国高分子学术论文报告会.北京,2005: 487.
[21]	Gou Chuanping,Chen Erfan,Ma Chi.Research progress in effect of inorganic fillers on properties of polyur ethane damping materials[J].Liaoning Chem Ind,2012,41(5):81(in Chinese).苟川平,陈尔凡,马驰.无机填料对聚氨酯阻尼材料性能影响的研究进展[J].辽宁化工,2012,41(5):81.
[22]	Wang Tingmei, Chen Shoubing, Wang Qihua.Damping analysis of polyurethane/epoxy graft interpenetrating polymer network compo-sites filled with short carbon fiber and micro hollow glass bead[J].Mater Des,2010,3(1):3810.
[23]	Wang Zhengxing,Weng Wei.Damping properties of aluminium matrix cenosphere composite[J].Mater Heat Treatment,2009,38(10):128(in Chinese).汪正兴,翁巍.铝基空心微珠复合材料的阻尼性能[J].材料热处理技术,2009,38(10):128.
[24]	Rakesh Chandra, Singh S P.A study of damping in composites[J].J Sound Vibration,2003,26(2): 475.
[25]	Gu Jinhai, Zhang Xiaonong, Gu Mingyuan.Effect of fiber coating on the longitudinal damping capacity of fiber-reinforced metal matrix composites[J].Mater Lett,2005,59:180.
[26]	Gu Jinhai, Zhang Xiaonong, Gu Mingyuan.Effect of interphase on the damping capacity of particulate-reinforced metal matrix composite[J].J Alloys Compd,2004,381:182.
[27]	Chalivendra V B, Shukla A, Bose A, et al.Processing and mechanical characterization of lightweight polyurethane composites[J]. J Mater Sci,2003,38(8):1631.
[28]	Kim H S, Plubrai P.Manufacturing and failure mechanisms of syntactic foam under compression[J]. Composites Part A,2004, 35(9):1009.
[29]	Hu Cong.Structural design and properties study of poly urethane materials[D].Beijing: Beijing University of Chemical Technology,2011(in Chinese).胡聪. 聚氨酯阻尼材料的结构设计和性能研究[D].北京:北京化工大学,2011.
[30]	Song Yuanjun,Li Na.Study on property of polyurethane foam materials[J].Chem Adhesion,2010,32(2):19(in Chinese).宋元军,李娜.聚氨酯泡沫材料的性能研究[J].化学与粘合,2010,32(2):19.
[31]	Boucher M A, Smith C W.Effective topologies for vibration dam-ping inserts in honeycomb structures[J].Compos Struct,2013,10:1.
[32]	Yang Jinshui, Ma Li, Rüdiger Schmidt.Hybrid lightweight compo-site pyramidal truss sandwich panels with high damping and stiffness efficiency[J].Compos Struct, 2016, 14(8):85.
[33]	Yang Jinshui.Research on damping characteristic of composite lattice sandwich structures[D]. Harbin:Harbin Institute of Technology,2012(in Chinese).杨金水. 复合材料点阵夹芯结构阻尼特性的研究[D].哈尔冰:哈尔滨工业大学,2012.
[34]	Updike D P.On the large deformation of a rigid plastic spherical shell compressed by a rigid plate[J].J Manuf Sci Eng,1972,94(3): 949.
[35]	Updike D P,kalnins A.Axisymmetric behavior of an elastic spherical shell compressed between rigid plates[J].J Appl Mech, 1970,37(3):635.
[36]	Gupta N K, Sheriff N M, Velmurugan R.Experimental and theore-tical studies on buckling of thin spherical shell under axial loads[J]. Int J Mech Sci, 2008, 50(3):422.
[37]	Gupta N K, Venkatesh. Experimental and numerical studies of dynamic axial compression of thin walled spherical shells[J]. Int J Impact Eng,2004, 30(8):1225.
[38]	Shariati M, Allahbakhsh H R.Numerical and experimental investigations on the buckling of steel semi-spherical shells under various loadings[J]. Steel Constr,2010,48(8):620.
[39]	Diao Fengchao.Dynamics analysis and experiment of thin walled rotating paraboloidal shell with fixed boundary [D]. Harbin: Harbin Institute of Technology,2009(in Chinese).刁凤超. 固定边界薄壁抛物回转壳体动力学分析与实验[D].哈尔滨:哈尔滨工业大学,2009.
[40]	Mohamed Menaa, Aouni A Lakis.Dynamic analysis of spherical shell partially filled with fluid[J].Comput Fluids,2015,108:67.
[41]	Yang Kun.Research on crashworthiness and dynamic characteristics of automobile frame with foam filling structure[D].Fuxin: Liaoning Technical University,2013(in Chinese).杨昆. 泡沫招填充结构汽车车架耐撞性及动态特性研究[D]. 阜新:辽宁工程技术大学,2013.
[42]	Banhart J, Baurneister J, Weber M.Damping properties of alumi-nium foams[J].Mater Sci Eng,1996,20(5):221.
[43]	Wei Jianning.Study on the influence of macroscopic pores on the damping properties of metal materials and damping mechanisms[J].Mater Rev:Res,2015,29(5):31(in Chinese).魏健宁. 李根梅宏观孔对金属材料阻尼行为的影响及其阻尼机制研究[J].材料导报:研究篇,2015,29(5):31.
[44]	Ren Runtao,Guo Wantao.Studies on damping performance of matrix adhesive for resin matrix composite[J].Noise Vibration Control,2003,3(2):20(in Chinese).任润桃,郭万涛.结构型树脂基阻尼复合材料基体胶液阻尼性能研究[J].噪声与振动控制,2003,3(2):20.
[45]	Dutra R C L, Soares B G, Campos E A.Composite materials constituted by a modified polypropylene fiber and epoxy resin[J].J Appl Polym Sci,1999,73(1):69.
[46]	Fan Yongzhong, Sun Kang.Study on damping property of epoxy re-sin matrix composites and its application in noise reduction[J].Mater Eng,2003(3):29(in Chinese).范永忠,孙康.环氧树脂基复合材料的阻尼性能及在降噪上的应用研究[J].材料工程,2000(3):29.
[47]	El-Tantawy F, Yong K S.A novel ultrasonic transducer backing from porous epoxy resin-titanium-silane coupling agent and plasticizer composites[J].Mater Lett, 2004, 58(1-2):154.
[48]	Gu Jian,Wu Gaohui.Study on preparation and properties of high damping hollow bead/poxy composites[J].J Funct Mater, 2007,38(5):763(in Chinese).顾健,武高辉.高阻尼空心微珠/环氧复合材料的制备及性能研究[J].功能材料,2007,38(5):763.
[49]	Cui Qichao.Studu on damping property of continuouscarbon fiber reinforce epoxy composites filled with carbon nanotube[D].Harbin: Harbin Institute of Technology,2011(in Chinese).崔启超. 碳纳米管改性连续碳纤维/环氧树脂复合材料的阻尼性能研究[D].哈尔滨:哈尔滨工业大学,2011.
[50]	He Bailing,Zhao Guiping, Lu Tianjian.Analysis of vibration and energy-absorption characteristics of sandwich plates with metallic foam cores and composite facesheets[J].Acta Armamentarii,2014,35(2):228(in Chinese).何柏灵,赵桂平,卢天健.复合材料面层-泡沫金属夹芯板的振动及吸能特性分析[J].兵工学报,2014,35(2):228.
[51]	Gision R F.The use of strain energy-based finite element techniques in the analysis of various aspects of composite materials and structures[J].J Compos Mater,1992,26(17):2585.
[52]	Wu Haipeng,Hou Diyang,Sun Lina.Damping analysis of glass and carbon fiber composites[J].Chin J Appl Mech,2011,29(1):65(in Chinese).武海鹏,侯涤洋,孙立娜.玻璃纤维、碳纤维复合材料的阻尼性能分析[J].应用力学学报,2011,29(1):65.

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