航空复合材料及其基体树脂的太赫兹光谱特性研究

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英文篇名：Terahertz Time-Domain Spectroscopic Study of Aircraft Composite and Matrix Resins 作者：王强 ; 李欣屹 ; 常天英 ; 胡秋平 ; 白金鹏 英文作者：WANG Qiang;LI Xin-yi;CHANG Tian-ying;HU Qiu-ping;BAI Jin-peng;Airforce Engineering University;College of Instrumentation and Electrical Engineering,Jilin University;Institute of Automation,Shandong Academy of Sciences;AVIC Composite Corporation Ltd.; 关键词：太赫兹时域光谱 ; 航空玻璃纤维复合材料 ; 基体树脂 ; 介电常数 ; 光谱特性 英文关键词：Terahertz time-domain spectroscopy;;Aircraft glass fiber composites;;Matrix resin;;Dielectric constant;;Spectral characteristic 中文刊名：GUAN 英文刊名：Spectroscopy and Spectral Analysis 机构：空军工程大学;吉林大学仪器科学与电气工程学院;山东省科学院自动化研究所;中航工业复合材料有限责任公司; 出版日期：2018-09-15 出版单位：光谱学与光谱分析 年：2018 期：v.38 基金：国家自然科学基金项目(71701210)资助 语种：中文; 页：GUAN201809010 页数：7 CN：09 ISSN：11-2200/O4 分类号：56-62

摘要

现如今各类航空复合材料大量应用在航空飞机制造领域,而不同基体树脂的复合材料具有不同的性能优势,其物理性能关系到复合材料的设计、使用与检测。为研究不同种类的航空玻璃纤维复合材料及其基体树脂在太赫兹频段的光谱特性与介电性能,利用太赫兹时域光谱技术(THz-TDS)在0.2~1.0THz频段内研究了3类不同航空玻璃纤维复合材料及其基体树脂:环氧树脂3238A/玻璃纤维EW180A,氰酸酯树脂9915/玻璃纤维QW120A,双马来酰亚胺树脂QY8911/玻璃纤维ZW100A的光谱吸收和介电色散特性,计算得到了不同航空复合材料及其基体树脂的折射率n、吸收系数α、介电常数实部ε′和介电常数虚部ε″,并结合改性添加剂进行了基体树脂的对比分析,以及结合增强体玻璃纤维进行了复合材料的对比分析,在此基础上,使用Debye模型对树脂体系中偶极子的弛豫过程进行了理论计算,并对实验结果进行了拟合分析。研究表明,对于ε″和α,均以QW120A/9915ZW100A/QY8911>EW180A/3238A和9915>QY8911>3238A;在聚合物树脂内部,偶极子的极化行为由于弛豫运动而受阻尼影响,滞后于交变电场的周期性变化,导致取向极化的程度相对减弱,ε′和n呈现反常的色散现象,即ε′和n随频率的增大而降低,而对于复合材料,玻璃纤维作为无机非金属材料弱化了聚合物树脂中极化行为的影响,均未出现反常色散现象;由于混合型树脂体系中不同极性的基团发生极化响应的机制不同,导致实际介电耗损高于拟合结果,而ε′和n并不受影响,因而在使用Debye方程进行拟合时,ε″和α的拟合结果稍有误差。首次报道了不同航空复合材料及其基体树脂在太赫兹频段的介电性能差异、光谱特性及其规律,给出了环氧、氰酸酯和双马来酰亚胺三种不同航空树脂及其玻璃纤维复合材料在太赫兹频段的基础参数,为太赫兹频段下固体电介质材料透波性能的研究补充了新的内容,为航空复合材料的太赫兹无损检测提供了重要参考,并且对航空复合材料性能改进、吸波复合材料、光电半导体材料、太赫兹超材料和高性能雷达罩等研究具有重要意义。
        Nowadays,many kinds of advanced composite have been applied in manufacture of aircraft.And composites with different matrix resin have different performance superiorities,its physical properties influence the design,employment and detection of composites.The purpose of this study was to investigate the spectral characteristics and dielectric properties of aircraft glass fiber composites and matrix resins in the terahertz(THz)frequency range.Terahertz time-domain spectroscopy was employed to examine the spectral absorption and dielectric dispersion characteristics of three major types,namely,epoxy resins3238 A/glass fiber EW180 A,cyanate ester(CE)resin 9915/glass fiber QW120 A,and bismaleimide(BMI)resins QY8911/glass fiber ZW100 A,in the 0.2~1.0 THz frequency range.The refractive index n,the absorption coefficientαand the real partε′and imaginary partε″of the dielectric constant of each composite and resin were calculated.Additionally,the influence of added modifying groups in resins was analyzed and the property of composites with glass fiber was compared.On this basis,the relaxation process of the dipoles in each resin system was theoretically calculated and fitting analyzed using the Debye model.The results showed the following points.The sequence ofε″andαis QW120 A/9915ZW100 A/QY8911>EW180 A/3238 Aand 9915>QY8911>3238 A.In polymers,due to their relaxation motions,the polarization behavior of the dipoles was affected by damping,resulting in a relative decrease in the extent of orientation polarization.ε′and neach exhibited an abnormal dispersion,i.e.,ε′and ndecreased with increasing frequency.However,the influence of polarization behavior is weakened by the glass fiber of composites,which don't exhibit an abnormal dispersion.Due to the difference in the mechanism of polarization response between groups differing in polarity in the mixed resin systems,the fitting of the data ofε′and nusing the Debye equation had good results,whereas there was an error between the fitted and measured values ofε″andα.This study reports,for the first time,the difference in dielectric properties between various types of composites and matrix resins,and their spectral characteristics and patterns in the THz frequency range.Additionally,it gives the basic parameters of five aircraft glass fiber composites with epoxy,CE and BMI resins in the THz frequency range,adds new content to the research on solid dielectric materials in the THz frequency range,and provides an important reference for THz nondestructive testing of aeronautical composites and improving the performance of aeronautical composites and matrix resins as well as technologies currently in rapid development,such as THz and wave-absorbing materials,opto-semiconductors and high-performance radomes.

引文

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