Carbon Fiber Breakage Mechanism in Aluminum(Al)/Carbon Fibers(CFs) Composite Sheet during Accumulative Roll Bonding(ARB) Process

We put forward a method of fabricating Aluminum(Al)/carbon fibers(CFs) composite sheets by the accumulative roll bonding(ARB) method. The finished Al/CFs composite sheet has CFs and pure Al sheets as sandwich and surface layers. After cross-section observation of the Al/CFs composite sheet, we found that the CFs discretely distributed within the sandwich layer. Besides, the tensile test showed that the contribution of the sandwich CFs layer to tensile strength was less than 11% compared with annealed pure Al sheet. With ex-situ observation of the CFs breakage evolution with-16%,-32%, and-45% rolling reduction during the ARB process, the plastic instability of the Al layer was found to bring shear damages to the CFs. At last, the bridging strengthening mechanism introduced by CFs was sacrificed. We provide new insight into and instruction on Al/CFs composite sheet preparation method and processing parameters.

High-Performance Recyclable Furan-based Epoxy Resin and Its Carbon Fiber Composites with Dense Hydrogen Bonding

The emerging biomass-based epoxy vitrimers hold great potential to fulfill the requirements for sustainable development of society.Since the existence of dynamic chemical bonds in vitrimers often reduces both the thermal and mechanical properties of epoxy resins, it is challenging to produce recyclable epoxy vitrimers with both excellent mechanical properties and good thermal stability. Herein, a monomer 4-(((5-(hydroxymethyl)furan-2-yl)methylene)amino)phenol(FCN) containing furan ring with potential to form high density of hydrogen bonding among repeating units is designed and copolymerized with glycerol triglycidyl ether to yield epoxy resin(FCN-GTE), which intrinsically has dual hydrogen bond networks, dynamic imine structure and resultant high performance. Importantly, as compared to the BPA-GTE, the FCN-GTE exhibits significantly improved mechanical properties owing to the increased density of hydrogen bond network and physical crosslinking interaction. Furthermore, density functional theory(DFT) calculation and in situ FTIR analysis is conducted to decipher the formation mechanism of hydrogen bond network. In addition, the FCN-GTE possesses superior UV shielding, chemical degradation, and recyclability because of the existence of abundant imine bonds. Notably, the FCN-GTE-based carbon fiber composites could be completely recycled in an amine solution.This study provides a facile strategy for synthesizing recyclable biomass-based high-performance epoxy vitrimers and carbon fiber composites.

LLDPE/碳纤维网复合膜的制备及性能

为了提高线型低密度聚乙烯(LLDPE)的拉伸强度和模量,将碳纤维(CF)梳理成均匀的碳纤维网,将其作为增强材料与LLDPE复合制备LLDPE/CF复合膜,综合利用热失重分析(TG)、扫描示差量热分析(DSC)、扫描电子显微镜(SEM)及拉伸测试等手段分析碳纤维网含量对复合膜结构及性能的影响。结果表明:与LLDPE膜相比,LLDPE/CF复合膜的拉伸强度和杨氏模量显著提高并随碳纤维网含量增加而增大,当碳纤维网质量分数仅为1%时,拉伸强度从10.6MPa提高到28.7MPa,提高了171%,杨氏模量由75MPa增大到1119MPa,约提高到原来的15倍;碳纤维网的引入有利于LLDPE/CF复合膜热稳定性能的提高,当碳纤维网含量仅为1%时,LLDPE/CF的初始热分解温度和最大热分解速率温度与LLDPE相比分别提高了21℃和11℃;碳纤维网的引入促进了LLDPE分子链的结晶,使LLDPE/CF复合膜的结晶度增大,有利于拉伸强度和模量提高;SEM结果显示碳纤维网与LLDPE基体间的界面结合较强,有利于力学性能的提高。研究成果可为高性能聚合物/碳纤维复合材料的制备提供实验依据和理论指导价值。

极地低温下CFRP筋与混凝土黏结性能数值分析

为进一步了解极地低温下碳纤维增强复合材料(CFRP)筋与混凝土的黏结性能,在现有试验的基础上,采用ABAQUS软件建立考虑CFRP筋表面特征的数值模型,分析64种工况,研究低温下CFRP筋直径、肋高、肋宽与混凝土保护层厚度等参数对黏结性能的影响。结果表明:考虑CFRP筋表面特征的数值模型可以较好地表征CFRP筋与混凝土之间的应力传递,能够反映低温下CFRP筋与混凝土的损伤情况与黏结破坏机制;低温可显著提高CFRP筋-混凝土的黏结强度;在低温下,随着CFRP筋直径的增加,CFRP筋与混凝土的黏结强度降低,同时弱化了低温对黏结强度的增强效应;随着CFRP筋肋高的增加,CFRP筋-混凝土的低温黏结强度呈现先提高后降低的趋势,肋高为筋材直径8%时黏结强度达到最大值;CFRP筋肋宽的变化主要影响黏结滑移曲线的形状;相比常温试件,在低温下试件发生拔出破坏时的混凝土保护层厚度更大。

高低温对碳纤维/环氧树脂复合材料高压气瓶的性能影响

为了获得T1000碳纤维/环氧树脂复合材料高压气瓶环境适应能力,有效地掌握气瓶高低温适应性固有规律,以容积50 L、工作压力30 MPa的复合材料气瓶(钛为内衬、碳纤维/环氧树脂为复合层)为研究对象,首先介绍了高低温循环下带压气瓶(在-40~80℃范围内成功通过热真空、热循环验证,具备高压承载能力)的热真空、热循环试验数据,然后采用与气瓶相同复合材料的拉伸试样(缠绕角分别为0°和90°),通过高低温极限摸底试验获得了复合材料经历不同梯度高低温后的拉伸性能数据,通过数据比对分析获得了高低温影响拉伸强度衰减的规律。同时,提出了一种高低温极限摸底试验的可靠性评估方法。结果表明,在-50~100℃范围内,试样拉伸强度及断裂伸长率变化较小;当温度高于100℃时,纤维和树脂的性能发生衰减,导致拉伸强度明显降低;当温度低于-50℃时,树脂的性能发生衰减,纤维受到的影响较小。试样高低温极限摸底试验的可靠度大于0.999,表明采用拉伸试样高低温拉伸强度数据的替代方式具有较高的等效性。

聚吡咯共轭结构对碳纤维增强树脂基复合材料热循环稳定性能的影响

为解决碳纤维增强树脂基复合材料(CFRPs)存在的碳纤维与基体间界面黏结性较弱和在热循环过程中因热膨胀系数不匹配而产生界面破坏的问题,通过低温聚合得到含有较多共轭结构的聚吡咯(PPy)对预处理后碳纤维(CF)进行表面改性,分别在0、30、60℃下制得碳纤维/聚吡咯复合纤维(PPy/CF),并研究了不同聚合温度下制备的CFRPs的界面结合性能、热膨胀性能和热循环稳定性能。结果表明:PPy/CF-0纤维的表面粗糙度与CF相比增加了2.09倍,这有利于树脂锚定在碳纤维表面,从而提高界面结合性能;并且PPy/CF-0纤维表面的聚吡咯层具有较完善的共轭结构,整体表现为负热膨胀系数,使得复合材料的层间剪切强度和界面剪切强度分别达到了CF的1.56倍和1.70倍;此外还使得CFRPs的热循环稳定性有了较明显的提升,经100次热循环实验后,其剪切强度仍能保持在初始数值的70%以上。

树脂黏度对碳纤维与环氧树脂浸润性及界面结合性能的影响

碳纤维与环氧树脂基体形成良好的界面结合是发挥复合材料基本性能的保障,考察3种国产T700级碳纤维,研究树脂黏度对碳纤维浸润性以及界面结合性能的影响。结果表明:由室温升到60℃,树脂体系黏度从1401.9mPa·s降低到102.77mPa·s,碳纤维与树脂的接触角减小,浸润能力增强,从而提高复合材料的界面结合强度,在60℃下制备的复合材料层间剪切强度提高了17.44%。同时纤维表面的沟槽结构能够加强物理机械互锁作用,加强复合材料的界面结合强度。

抗静电LLDPE/CNT复合材料的制备及其性能研究

目的制备特种产品用抗静电包装材料。方法采用碳纳米管(CNT)对线性低密度聚乙烯(LLDPE)进行熔融复合改性,研究CNT含量对LLDPE电学性能、力学性能、结晶行为及热稳定性的影响,并对确定的最优体系进行应用性能考核。结果CNT具有较大的长径比,直径为10~20 nm,纯度较高。LLDPE/CNT复合材料表面电阻率变化呈现明显的“渝渗”现象,当CNT质量分数从3%增加至5%时,其表面电阻率由1013Ω骤降至105Ω。随着CNT含量增加,LLDPE/CNT复合材料的拉伸强度增加,断裂伸长率和冲击强度有所降低。CNT没有改变LLDPE的熔融行为,但其结晶度和熔点随着CNT含量增加而略有降低。LLDPE/CNT复合材料起始降解温度和最大降解速率处温度随着CNT含量增加而增加。CNT质量分数为4%的LLDPE/CNT复合材料综合性能最优,热氧老化后其表面电阻率几乎无变化,相比纯LLDPE,其熔融指数有所下降,氧化诱导时间大幅提升。结论通过CNT对LLDPE树脂进行改性,制备了综合性能优良的抗静电LLDPE/CNT复合材料,在特种产品包装领域具有良好的应用前景。

碳纤维/酚醛复合材料射线检测高密度影像分析

碳纤维/酚醛复合材料是固体火箭发动机喷管耐高温部件的重要材料,从影像形貌、黑度分布规律方面入手,对某产品射线检测中发现的异常高密度影像,进行了总结、分类,并结合产品制备工艺和射线检测方法特点,对部分实物进行了解剖观察和理化分析,确定了异常影像的产生原因为碳纤维团聚、高硅氧纤维掺杂、石块混入等,归纳了影像评判的方法和要素,以为同类产品的缺陷影像识别提供参考。

轴向荷载作用下碳纤维布约束损伤混凝土能量耗散试验研究

本文对碳纤维布约束损伤混凝土在轴向荷载作用下的力学性能开展试验研究。设计了混凝土损伤度、碳纤维布层数及碳纤维布缠绕角度三种变量,通过试验结果分析了三种变量对碳纤维布约束混凝土应力-应变曲线、峰值应力、耗能效果及机械损伤度的影响规律。试验结果表明:相较于未损伤试件,0.4σm(σm为未损伤混凝土试件单轴抗压强度)、0.5σm、0.6σm、0.7σm应力幅值损伤下素混凝土损伤度均值分别为7.24%、14.86%、25.31%、36.66%,损伤度与损伤应力幅值间指数函数呈现良好的正相关。碳纤维布的约束作用增强试件峰值应力及延性,0.4σm损伤应力作用后,相较于未粘贴碳纤维布试件,粘贴1,2,3层碳纤维布试件峰值应力增幅分别为34.99%、55.16%、64.42%,碳纤维布粘贴层数与峰值应力间指数函数呈负相关,过量的纤维布使试件应力增幅不再明显。碳纤维布缠绕角度的增大使试件单位体积耗散能线性降低,缠绕角度的增大降低了荷载作用下试件的承载效果。应力损伤幅值的增大使试件机械损伤度降低,碳纤维布层数的增加使试件机械损伤度增加,纤维布的约束保护作用极大提升了试件的耗能效果。

高模量碳纤维复合材料管件高低温交变环境结构稳定性研究

针对高模量碳纤维复合材料管件高低温交变环境下截面变形、分层问题,基于纤维混杂思路,在其大角度差铺层之间增设单层超薄(0.02 mm)无碱玻璃纤维平纹布,仿真分析表明,该玻璃纤维平纹布的加入,有效缓解了碳纤维大角度铺层之间的热膨胀失配,降低了层间应力。高低温交变试验结果印证了仿真分析的正确性,经过液氮温度(-196℃)至+150℃共六个高低温交变循环后,层间设置玻璃纤维平纹布的管件试件截面结构保持完整,几何尺寸未发生变化。单向板弯曲对比试验表明,超薄玻璃纤维平纹布的加入不仅起到了层间增韧效果,且对结构的弯曲性能无明显影响,这得益于超薄玻璃纤维平纹布的低模量与极小的厚度占比(1.6%)。

轨道交通用碳纤维复合材料技术现状与发展趋势

碳纤维增强复合材料具有高比强度、高比模量、抗疲劳性能优异、性能可设计、易于大面积成型等突出优点,是促进轨道交通装备轻量化发展,提升运行速度、运载能力、安全性与舒适性的理想材料。文中总结了现阶段碳纤维复合材料在轨道交通领域的成功应用案例;在此基础上,从基础原材料、结构设计、成型制造的3个维度详细分析了轨道交通用碳纤维复合材料技术现状;针对高质量、低成本轨道交通用复合材料需求,结合航空航天领域相关技术最新进展,对未来轨道交通领域碳纤维复合材料的发展趋势进行了展望。

碳纤维复合材料高效低碳加工综合实验设计

以碳纤维增强基复合材料(CFRP)为加工对象,设计了一种高效低碳钻削加工的综合实验项目。基于响应曲面法研究了机床主轴转速、进给速度和CFRP板材铺层顺序对CFRP构件加工质量的影响,建立了预测回归方程,最终得出最优孔口质量和最低功耗的工艺参数:最佳铺层顺序为[0°,90°,0°,90°],主轴转速在2000 r/min左右,进给速度设置在50 mm/min左右时功率最低;主轴转速在10000 r/min左右,进给速度设置在20 mm/min左右时分层因子最低。实验涉及新型材料加工、绿色加工和节能降碳等多个学科领域,能够增强学生的科研兴趣,提高实践动手能力和创新意识。

一种考虑应变率的复合材料动态压缩响应预测模型

本文提出一种考虑应变率效应的复合材料动态压缩响应预测模型,该模型基于人工神经网络,根据材料的弹性模量等属性参数即可预测其不同应变率下的动态压缩响应。建立了T300/QY8911预浸料制备的碳纤维增强复合材料高应变率压缩响应预测模型,预测了该材料应变率为517 s^(-1)、721 s^(-1)和1070 s^(-1)时的动态压缩响应,并开展试验,对预测结果进行了验证。结果表明,预测结果与试验结果吻合度较高,应力最大误差仅为-1.5856%,应变最大误差仅为1.7037%。

吸湿及烘干对复合材料共胶接断裂韧性的影响

已固化的复合材料层板在存放过程中会吸收环境中的水分,继而对复合材料的胶接性能造成影响。通过I型断裂韧性表征共胶接性能,针对两种T800级碳纤维增强环氧树脂基复合材料待胶接层板进行吸湿及烘干处理,接着采用两种胶膜材料(M型及E型)制备共胶接试验件,开展I型断裂韧性测试,得到待胶接层板的吸湿曲线,待胶接层板吸湿后的胶接性能变化规律,以及烘干后胶接性能的恢复情况。试验结果表明:随着吸湿时间的延长,待胶接层板的吸湿率增加,层板1的最大吸湿率和吸湿速率都明显高于层板2;同时随着吸湿率增加,共胶接层板的断裂韧性降低,且M型胶膜的胶接性能始终强于E型胶膜的胶接性能;通过将待胶接层板进行烘干处理可以较大程度恢复复合材料的胶接性能,因此可选择合适的烘干工艺以解决吸湿后胶接性能下降的问题,但烘干处理无法使吸湿后的层板1与E胶膜胶接的试验件胶接性能恢复。

青岛海洋环境碳纤维复合材料与低合金钢电偶腐蚀研究

目的 探究碳纤维复合材料在舰船应用时与金属材料的电偶腐蚀问题。方法 针对一种典型舰船用碳纤维增强乙烯基树脂复合材料,在青岛海洋大气环境下开展0.5、1、1.5、2 a期的自然曝晒试验,进而采用电化学分析手段考察其与低合金钢的电偶腐蚀效应,结合老化机制探究碳纤维复合材料的老化行为对其与钢电偶腐蚀的影响。结果及结论 在青岛大气环境曝晒不同周期的复合材料试样,开路电位与低合金钢相差较大,存在较高的电偶腐蚀倾向。随曝晒时间的延长,复合材料表面微裂纹不断产生、扩展,导致电化学反应活性点增多,两者电偶电流密度随之增大。在青岛海洋大气环境下暴露2 a后,碳纤维增强乙烯基树脂复合材料与低合金钢的电偶电流为0.356 9μA/cm^(2),两者的电偶腐蚀敏感性达到B级。

玻纤/碳纤三维编织一体成型多异质界面复合材料电磁屏蔽性能

为减少电磁波在碳纤维复合材料表面反射,减少二次污染,采用玻纤作为阻抗匹配层,为增强复合材料对电磁波的吸收,构造玻纤-碳纤多异质界面,通过多次反射延伸传播路径消耗电磁波;采用三维混杂编织工艺设计并制备3种玻纤/碳纤一体成型多异质界面预制件,再通过真空辅助树脂传递模塑成型技术固化得到复合材料H-G/C、H-G/C/G和H-G/C/G/C,研究分析3种复合材料的电磁屏蔽性能和轴向静态压缩性能。结果表明,3层结构的H-G/C/G复合材料在频率为12.34GHz时屏蔽效能高达71.14dB,X波段内平均吸收功率系数为0.77,屏蔽机制以吸收为主,抗压缩强度为254.59MPa,复合材料表现出低反射、高屏蔽效能和高抗压缩强度特性。

Effect of fiber angle on LYP steel shear walls behavior

Steel shear wall(SSW) was properly determined using numerical and experimental approaches.The properties of SSW and LYP(low yield point) steel shear wall(LSSW) were measured.It is revealed that LSSW exhibits higher properties compared to SSW in both elastic and inelastic zones.It is also concluded that the addition of CFRP(carbon fiber reinforced polymers) enhances the seismic parameters of LSSW(stiffness,energy absorption,shear capacity,over strength values).Also,stress values applied to boundary frames are lower due to post buckling forces.The effect of fiber angle was also studied and presented as a mathematical equation.

Experimental research on blast power of fiber reinforced anti-hard target warhead

Fiber reinforced anti-hard-target warhead is a new-type sample munition, which is only designed based on theoretical analysis and numerical simulation in laboratory. This warhead consists of carbon composite casings and high explosive, which can greatly reduce the damage to objects outside the damage range. In order to evaluate its blasting damage effect on concrete target, the three types of charges were researched by means of experiment, which are bare charge, charge with carbon composite material shell and charge with steel shell. Experimental results show that the peak overpressure of charge with carbon fiber composite shell is higher than that of charge with steel shell, but is lower than that of bare charge in the case of the same TNT equivalence. No fragments and fragment effect exist for distant target under the condition of charge with carbon fiber composite shell. However, the experimental result of the charge with steel shell is completely contrary. According to the blast effect in the concrete target, the charge with carbon composite material shell is optimal in matched impedance and detonation propagation.Also, the effective energy produced by the detonation of explosive with carbon composite material shell is the largest.

The effect of carbon nanotubes and polypropylene fibers on bond of reinforcing bars in strain resilient cementitious composites

Stress transfer between reinforcing bars and concrete is engaged through rib translation relative to concrete, and comprises longitudinal bond stresses and radial pressure. The radial pressure is equilibrated by hoop tension undertaken by the concrete cover. Owing to concrete＇s poor tensile properties in terms of strength and deformability, the equilibrium is instantly released upon radial cracking of the cover along the anchorage with commensurate abrupt loss of the bond strength. Any improvement of the matrix tensile properties is expected to favorably affect bond in terms of strength, resilience to pullout slip, residual resistance and controlled slippage.The aim of this paper is to investigate the local bond of steel bars developed in adverse tensile stress conditions in the concrete cover. In the tests, the matrix comprises a novel, strain resilient cementitious composite （SRCC） reinforced with polypropylene fibers （PP） with the synergistic action of carbon nano-tubes （CNT）. Local bond is developed over a short anchorage length occurring in the constant moment region of a four-point bending short beam. Parameters of investigation were the material structure （comprising a basic control mix, reinforced with CNTs and/or PP fibers） and the age of testing. Accompanying tests used to characterize the cementitious material were also conducted. The test results illustrate that all the benefits gained due to the synergy between PP fibers and CNTs in the matrix, namely the maintenance of the multi-cracking effect with time, the increased strength and deformability as well as the highly increased material toughness, were imparted in the recorded bond response. The local bond response curves thus obtained were marked by a resilient appearance exhibiting sustained strength up to large levels of controlled bar-slip; the elasto-plastic bond response envelope was a result of the confining synergistic effect of CNTs and the PP fibers, and it occurred even without bar yielding.