多壁碳纳米管复合材料在26.5～40 GHz频段的电磁性能

采用玻璃布作为分散载体制备多壁碳纳米管/玻璃纤维/环氧树脂复合材料,研究了在26.5～40 GHz频段,多壁碳纳米管的含量对复合材料的电磁参数及电导率的影响,同时测量了复合材料在该波段的电磁波反射率。研究结果表明:随多壁碳纳米管含量的增加,其介电常数实部和虚部随之增加,介电损耗角正切提高了4倍。复合材料的磁导率随多壁碳纳米管含量的提高变化不明显,呈弱磁性。复合材料的电导率随多壁碳纳米管含量的增加,由原来的绝缘体变为半导体。另外,在26.5～40 GHz频段内多壁碳纳米管复合材料对电磁波的隐身效果不好。      

多壁碳纳米管/环氧有机硅树脂吸波涂层的介电和吸波性能研究

研究了不同直径和含量多壁碳纳米管填充环氧有机硅树脂吸波涂层在2~18GHz频率范围内的介电和吸波性能.可以得到吸波涂层的介电常数随着碳纳米管含量的增加而增大.当碳纳米管含量相同时,吸波涂层介电常数随着碳纳米管直径的增加而增大.当碳纳米管含量大于5wt%时,吸波涂层的介电常数在低频急剧增加,且随频率增大而减少,出现频散效应.反射率测试结果表明:当涂层中多壁碳纳米管含量为10wt%、厚度为2mm时,吸波涂层的最大吸收峰随碳纳米管直径的增大向低频移动.多壁碳纳米管填充环氧有机硅树脂吸波涂层的吸波性能在7~14GHz范围内可达到-10dB,具有较好的吸波效果.     

双层结构型吸波复合材料的制备与吸波性能研究

依据传输线理论和阻抗匹配原则,设计并制备了一种以磁性金属微粉为面层、多壁碳纳米管为底层、玻璃纤维布为环氧树脂基体增强体的低频段双层结构型吸波复合材料。采用透射电镜和扫描电镜对多壁碳纳米管和磁性金属微粉的微观形貌进行了表征,采用HP8722ES矢量网络分析仪测量了材料在2～18GHz频率范围内的复介电常数和复磁导率,采用弓形法测试了复合材料在2～8GHz扫频范围内的反射率特性。研究表明,该双层结构型吸波复合材料在低频S波段具有良好的吸波效果,当其匹配厚度为dm=4.0mm时,最大吸收峰在3.08GHz时达到-17dB,反射率小于-10dB的频宽为1.82GHz。     

多壁碳纳米管电磁参数的研究和吸波性能模拟

系统地研究了不同管径类型的多壁碳纳米管在2～18GHz的电磁参数性能,结果表明多壁碳纳米管没有磁性,而且磁损耗也很小;部分碳管的介电常数实部和虚部随管径的增大而增大,而随频率的增加而减小,20～40nm和40～60nm的CNTs在一定频段范围内介电常数的虚部大于实部,使得其损耗角正切大于1,有利于吸波性能的提高.同时对其吸波性能进行了计算机模拟和分析,结果表明,在2～18GHz范围内,当吸波层厚度设为1mm时,20～40nm的碳管复合物在10dB以上频宽可以达到7GHz,最大损耗峰出现在12.4GHz上,对应值为16.52dB,为实现吸波涂层的"宽、薄、轻"具有一定的理论指导意义.     

A型蒙皮复合蜂窝结构设计及其吸波性能

针对引入蒙皮材料导致吸波蜂窝26.5～40 GHz频段吸波性能退化的问题,对蒙皮的结构进行了改进设计,研究了A型蒙皮结构对多层蜂窝吸波性能的影响机制及规律,并得到了最优的蒙皮结构参数。研究结果表明,设计的A型结构,可有效改善蒙皮的高频段透波性能。随着A型蒙皮中透波蜂窝厚度的增加,复合吸波蜂窝在2～18 GHz频段内的吸波性能保持在相当的水平,在26.5～40 GHz波段吸波性能先升高后降低,透波蜂窝的最优厚度为2 mm。基于5种不同电磁特性的吸波蜂窝片材料,设计制备的具有0.3 mm石英布/2 mm透波蜂窝/0.3 mm石英布蒙皮结构的复合蜂窝在2～18 GHz及26.5～40 GHz的超宽频带内具备优异的吸波性能,与仿真优化结果保持一致。     

碳纳米管/三元乙丙橡胶复合材料吸波性能的研究

考察了碳纳米管的介电常数,磁导率以及碳纳米管/三元乙丙橡胶复合材料的电磁吸波性能.研究结果表明,碳纳米管介电常数值远大于磁导率值,且电损耗远大于磁损耗,说明碳纳米管是一种电损耗型吸波介质.通过弓形法测定了碳纳米管/三元乙丙橡胶复合材料在2～18GHz范围内的电磁波吸收性能,结果表明,复合材料在5～18GHz范围内具有较好的微波吸收性能.     

碳纳米管/镍铁氧体涂层的吸波性能及吸波机理

采用柠檬酸络合物形成的溶胶凝胶制备了镍铁氧体,并将所得镍铁氧体与碳纳米管混合均匀,得到不同碳纳米管质量分数的复合材料。采用微波矢量网络分析仪测量了复合材料的电磁参数,根据电磁参数研究了1mm厚涂层在2~18GHz频段的微波反射率。结果表明:复合材料的吸波性能明显优于单纯的镍铁氧体材料,而且复合材料中碳纳米管含量对吸波性能有明显的影响。对于厚度为1mm的薄涂层,当碳纳米管的质量分数为20%时,涂层具有最优的吸波性能,最大吸收峰值达-14.02dB,小于-10dB的有效带宽达3GHz;然后通过电损耗功率密度分析了复合材料的微波吸收机理,并给出了厚度为1mm的薄涂层,当其中的碳纳米管含量为20%时,吸波效果最佳的理论解释。     

多壁碳纳米管/环氧树脂复合材料的吸波性能

本文将高温碱处理多壁碳纳米管分散到环氧树脂中制成多壁碳纳米管/环氧树脂吸波复合材料,并研究了该复合材料的微波吸收性能。改变碳纳米管高温碱处理的浓度可以使复合材料的最大吸收峰向高频方向移动,与此同时,吸收峰强度和吸波频宽也有所提高,这对于调整雷达吸波材料的吸波频段、吸波强度和吸波频宽有着十分重要的意义。测试结果还表明,这种新型吸波复合材料的体积电阻率在106~107Ω.cm数量级,具有良好的抗静电的能力。     

CIPs@Mn0.8Zn0.2Fe2O4-CNTs复合材料低频吸波性能研究

随着5G无线通信与低频雷达侦察技术的飞速发展,低频电磁波辐射已成为当代的严重问题。目前,中高频段吸波材料的研究已趋于成熟,而设计低频段吸波材料仍面临巨大的挑战,亟待研究者们解决。基于四分之一波长相消机制,本研究设计了0.5～3 GHz低频段复合吸波材料。采用简单的一步水热法,诱导铁氧体在羰基铁粉与碳纳米管表面生长,制备出CIPs@Mn_0.8Zn_0.2Fe₂O₄-CNTs三元复合材料,对比研究了碳纳米管含量对材料吸收峰频率的影响。实验结果表明,引入碳纳米管,一方面为材料带来了界面极化、偶极极化等额外的损耗机制,增加了材料的衰减系数;另一方面基于四分之一波长相消机制,高介电与高磁导率的耦合,使材料在低频段获得良好的阻抗匹配。最终,在4 mm厚度下,样品分别在2.11与1.75 GHz处,获得了–40.8与–32.1 dB的反射损耗,–10 dB带宽分别为1.70～2.70 GHz和1.40～2.20 GHz。该复合材料制备工艺简单,低频吸收性能良好,具有很大的应用潜力,为开发更有效的低频吸波材料提供了新...     

镀镍碳纳米管／PPESK复合材料的制备及微波吸收性能

采用化学镀工艺在多壁碳纳米管表面包覆镍-磷合金,并将其与杂萘联苯聚醚砜酮(PPESK)混合制备吸波复合材料。通过扫描电镜、能量散射光谱对镀镍碳管的形貌和成分进行分析,反射率测试系统对复合材料在8 GHz~18 GHz频段的微波吸收特性进行表征。结果表明,在镀镍过程中使用超声振荡有利于得到均匀的镀层。当吸波样品平均厚度为0.97 mm,碳管含量为5 phr时,镀镍碳管/PPESK复合材料的最大吸收峰在10.9 GHz(RL=-27.5 dB),RL<-10 dB的频宽为4.0 GHz。随着填料含量增加,吸收峰往低频方向移动。     

Study on the electrical behavior of MWCNTs in GF/Epoxy composites

The multi-wall nanotubes (MWCNTs) were divisionalized equably by the fabric of glass in composites. Then the electrical properties such as permittivity, conductance and electromagnetic interference (EMI) shielding effectiveness (SE) of MWCNTs in GF/EP composite were studied. The effect of the content and dispersion of MWCNTs were researched in this work. Firstly the permittivity of MWCNTs/GF/EP composites were studied respectively by keeping layers of glass fabric and increasing content of MWCNTs or keeping content of MWCNTs and changing layers of glass fabric in electromagnetic wave band (5.85-18 GHz). Then the conductance of MWCNTs/GF/EP composites with different MWCNTs contents was tested. Furthermore, the EMI SE of composites with different MWCNTs contents in electromagnetic wave band (5.85-18 GHz) were studied. In addition, the morphologies of MWCNTs/GF/EP composites with the different MWCNTs weight percent were observed. The results show that the real part of permittivity of composites can be improved highest up to 75 and the imaginary part increase maximum up to 80. However there is no disciplinarian about effect of layers of glass fabric on dielectric property. The MWCNTs/GF/EP composite can be changed from the insulator to the semiconductor along with increasing the weight percent of MWCNTs. In electromagnetic wave band 5.85-18 GHz, the values of SE are increasing with increasing content of the MWCNTs.     

A study of the electromagnetic properties of Cobalt-multiwalled carbon nanotubes (Co-MWCNTs) composites

Electroless plating was utilized to deposit Cobalt (Co) on the surface of multi-walled carbon nanotubes (MWCNTs), and the technological parameters of electroless plating were optimized. To obtain optimized processing parameters, field-emission scanning electron microscope (FESEM) as well as energy dispersive spectroscopy (EDS) results were presented to show the morphology, components of as-prepared Co-MWCNTs. Based on the optimized processing parameters, Co-MWCNTs were prepared and filled into the epoxy resin to fabricate Co-MWCNTs composites. The electromagnetic properties of pure MWCNTs composites and Co-MWCNTs composites were studied. To sum up, the pure MWCNTs composites with a filler concentration of 2 wt% had an intense absorbing peak at 15.20 GHz, where the highest reflection loss (R) reached −21.41 dB. Compared to the pure MWCNTs composite at the same concentration, the Co-MWCNTs composites showed a higher impedance which implies a better potential absorbing property and makes Co-MWCNTs probable to be utilized in electromagnetic absorbing field.     

CIP/GF/CF/EP吸波复合材料的制备及力学性能

为制备兼具力学性能和电磁吸收性能的结构型吸波材料,采用真空辅助成型工艺设计制备一种以羰基铁粉(CIP)为吸收剂,玻璃纤维(GF)为透波层,碳纤维(CF)为反射层,环氧树脂(EP)为基体的吸波复合材料。研究了不同质量比CIP/EP对吸波复合材料力学性能和微波吸收性能的影响。通过FTIR和DSC分析可知CIP未与EP发生化学反应。SEM结果表明CIP能够在EP树脂基体中均匀分散,不趋向于纤维表面。力学测试分析结果显示:当CIP/EP质量比达到30%时,CIP/GF/CF/EP复合材料的力学性能最佳,拉伸强度为347.56MPa,拉伸模量为25.99GPa,较纯GF/CF/EP复合材料提升了4.3%和5.7%;弯曲强度为339.6MPa,弯曲模量为23.7GPa,较纯GF/CF/EP复合材料提升了18.2%和71.2%。矢量网络分析可知复合吸波板的吸波性能随CIP含量的增加而增加,且吸波损耗反射峰值朝低频段移动。     

复合材料中碳纤维的铺设方式对吸波性能的影响

实验采用东华大学自制的碳纤维作为吸波剂，在基体环氧树脂中平行排列，制备出了吸波复合材料。采用矢量网络分析仪在2~18GHz波段，对复合材料的吸波性能进行测试。结果表明：复合材料的吸波性能不仅与碳纤维含量有关，还与碳纤维在基体中的排列方式有关，当碳纤维含量为3．2％（质量分数）时，吸波复合材料最大反射衰减为-18．64dB，反射率〈-10dB的频率带宽为2．6GHz，同时采用电磁理论对材料的吸收机理进行了探讨。     

Effects of Multi-walled Carbon Nanotubes on the Electromagnetic Absorbing Characteristics of Composites Filled with Carbonyl Iron Particles

The electromagnetic(EM) wave absorbing property of silicone rubber filled with carbonyl iron particles(CIPs) and multi-walled carbon nanotubes(MWCNTs) was examined.Absorbents including MWCNTs and spherical/flaky CIPs were added to silicone rubber using a two-roll mixer.The complex permittivity and complex permeability were measured over the frequency range of 1-18 GHz.The two EM parameters were verified and the uniform dispersion of MWCNTs and CIPs was confirmed by comparing the measured reflection loss(RL) with the calculated one.As the MWCNT weight percent increased,the RL of the spherical CIPs/silicone rubber composites changed insignificantly.It was attributed to the random distribution of spherical CIPs and less content of MWCNTs.On the contrary,for composites filled with flaky CIPs the absorption bandwidth increased at thickness 0.5 mm(RL value lower than-5 dB in 8-18 GHz) and the absorption ratio increased at lower frequency(minimum-35 dB at 3.5 GHz).This effect was attributed to the oriented distribution of flaky CIPs caused by interactions between the two absorbents.Therefore,mixing MWCNTs and flaky CIPs could achieve wider-band and higher-absorption ratio absorbing materials.     

Fabrication of radar absorbing structure (RAS) using GFR-nano composite and spring-back compensation of hybrid composite RAS shells

The fiber-reinforced composite materials have been advanced to provide excellent mechanical and electromagnetic properties. The radar absorbing structure (RAS) is such an example that satisfies both radar absorbing property and structural characteristics. The absorbing efficiency of RAS can be obtained from selected materials having special absorptive properties and structural characteristics such as multi-layer and stacking sequence.

In this research, to develop a RAS, three-phase composites consisted of {glass fiber}/{epoxy}/{nano size carbon materials} were fabricated, and their radar absorbing efficiency was measured on the X-band frequency range (8–12 GHz). Although some of GFR (Glass Fiber–Reinforced)-nano composites showed outstanding absorbing efficiency, during their manufacturing process, undesired thermal deformation (so called spring-back) was produced. The main cause of spring-back is thought to be temperature drop from the cure temperature to the room temperature. In order to reduce spring-back, two types of hybrid composite shells were fabricated with {carbon/epoxy} and {glass/epoxy} composites. Their spring-back was measured by experiment and predicted by finite element analysis (ANSYS). To fabricate desired final geometry, a spring-back compensated mold was designed and manufactured. Using the mold, hybrid composite shells with good dimensional tolerance were fabricated.     

石墨烯/酞菁铁复合材料的制备与吸波性能

采用酞菁铁（FePc）粉体和石墨烯（G）共研磨热压法制备了G/FePc复合材料,研究了G对FePc耐热性能和吸波性能的影响。采用SEM和XPS表征了G/FePc复合材料的表面形貌和G与FePc之间的相互作用,结果发现,FePc均匀地吸附于G片层表面,且固化后形成了层状结构,从而改善了G/FePc复合材料的耐热性能和吸波性能。进一步通过TGA和矢量网络分析方法研究了不同G添加量对G/FePc复合材料的耐热性能和电磁性能的影响,并对G/FePc复合材料不同厚度的吸波性能进行了模拟分析。结果表明,G/FePc复合材料的耐热性能和吸波性能均随着G含量的增加而提高,当G添加量为5%（质量比）时,G/FePc复合材料在1 000℃热解残留率达到62.2%,在3.5 mm厚度下最大反射损耗达到-30.50 dB,反射损耗小于-10 dB的带宽为1.38 GHz,具有优良的耐热性能和吸波性能。      

高能量超声波改性MWCNTs/环氧树脂特性分析

采用高能量超声波与低能量超声波对一种多壁碳纳米管(MWCNTs)/环氧树脂体系进行改性处理,结合流变仪、DSC、FTIR、XPS、XRD、TEM等测试手段,分析了不同超声波处理条件下MWCNTs物理化学特性的变化及其对MWCNTs在环氧树脂中的分散性和相容性的影响,并进一步考察了MWCNTs/环氧树脂体系的耐热性和弯曲性能。实验结果表明:超声波能量不同,MWCNTs的改性效果不同,高能量超声波对MWCNTs有更好的分散效果和分散效率,并能使MWCNTs表面活性增强,而低能量超声波则不明显;添加少量高能量超声波改性的MWCNTs,可以提高环氧树脂的弯曲模量和玻璃化转变温度,表明MWCNTs与基体之间形成了较强的结合界面。     

Characterization of electromagnetic properties of polymeric composite materials with free space method

The introduction of microwave radars during the second World War altered the air defense scenario significantly, and this led to the development of the “stealth” techniques. By reducing the detectability of aircrafts or warships, of which the radar cross section (RCS) is a measure, they could evade radar detection, which affected not only the mission success rate but also survival of them in the hostile territory. In the very early stage of the research on stealth techniques, many researches were mainly concentrated on the reduction of RCS and development of radar absorbing materials (RAM), but nowadays studies on investigating the radar absorbing structures (RAS) using fiber reinforced polymeric composite materials are becoming popular research field.

In this study, electromagnetic characteristics of unidirectional E-glass fiber reinforced epoxy composites were tested with free space methods, which can overcome drawbacks of conventional cavity and waveguide methods. Complex relative permittivities of low-loss composite were measured with respect to the angle between the fiber orientation and the electric field vector of EM wave in X-band frequency range. From the experimental data, empirical relation between the dielectric properties of composites and test variable was suggested and verified.