Al2O3f+Cf/ZL109混杂复合材料钻削加工性的研究

利用挤压铸造法制备了Al₂O_3f+C_f/ZL109短纤维混杂金属基复合材料,并进行了钻削加工试验研究。考察了Al₂O₃短纤维和C短纤维含量、纤维位向、钻削速度及进给量对钻削力、刀具磨损和钻削精度的影响,并进行了分析。结果表明:以刀具磨损作为衡量标准,该混杂复合材料的钻削加工性次于基体合金。      

多孔Al2O3f/Al2O3复合材料研究进展

作为20世纪90年代兴起的一类连续陶瓷纤维增强陶瓷基复合材料,连续氧化铝纤维增韧氧化铝(Al₂O_3f/Al₂O₃)复合材料已经发展为与C_f/SiC、SiC_f/SiC等非氧化物复合材料并列的陶瓷基复合材料。以多孔基体实现基体裂纹偏转成为Al₂O_3f/Al₂O₃复合材料主要的增韧设计方法,形成的多孔Al₂O_3f/Al₂O₃复合材料具有优异的抗氧化性能和高温力学性能,可在高温富氧、富含水汽的中等载荷工况中长时服役,是未来重要的热结构材料。经过近30年的发展,多孔Al₂O_3f/Al₂O₃复合材料已被应用于航空发动机、燃气轮机等热端部件。本文综述了多孔Al₂O_3f...     

纤维预热温度对连续Al2O3f/Al复合材料力学性能的影响

选用Nextel610型Al₂O₃纤维为增强体、ZL210A连续氧化铝合金为基体,采用真空压力浸渗法制备纤维增强铝基复合材料(Al₂O_3f/Al),纤维的体积分数为40%,预热温度分别为500、530、560和600℃,研究了纤维预热温度对Al₂O_3f/Al复合材料的微观组织、纤维损伤和力学性能的影响。结果表明：随着纤维预热温度的提高复合材料的致密度随之提高,最大达到99.2%,材料的组织缺陷最少,纤维的分布均匀;随着纤维预热温度的提高从复合材料中萃取出来的Al₂O₃纤维的拉伸强度不断降低,纤维预热温度为600℃的复合材料中Al₂O₃纤维的拉伸强度仅为1150 MPa,纤维表面粗糙,有大尺寸附着物。纤维的预热温度对Al₂O_3f/Al复合材料的拉伸强度有显著的影响。预热温度为500、530、560和600℃的复合材料其拉伸强度分别对应于298、465、498和452 MPa。组织缺陷、纤维损伤和界面结合强度,是影响连续Al₂O_3f/Al复合材料强度的主要因素。     

ZA22/Al2O3短纤维复合材料高温拉伸行为的理论分析

采用日本产A G-10TA 型电子万能试验机对挤压铸造ZA 22/Al₂O₃短纤维复合材料的高温抗拉强度进行了测定, 并用Friend 修正的混合律模型对该试验结果进行了理论分析, 结果表明ZA 22/Al₂O₃短纤维复合材料及其基体的强度均随温度升高而下降, 但ZA 22合金基体的强度下降幅度更大。任一纤维体积分数的复合材料, 均存在一临界转变温度T crit; 超过该温度, 复合材料强度大于基体强度。纤维体积分数越大, 所需临界转变温度越低。在本试验中, V f 为15% 和20% 的复合材料的Tcrit分别为123℃和87℃。任一温度下, 复合材料均存在一临界纤维体积分数, 超过该纤维体积分数, 复合材料强度高于基体强度。温度越高, 临界纤维体积分数越低。对ZA 22/Al₂O₃短纤维复合材料来说, Friend 模型中的经验参数C3 的取值随温度升高而降低。      

(Al11La3+Al2O3)/Al复合材料的高温性能及其强化机制

利用Al-La₂O₃的原位反应和粉末冶金工艺制备出(Al₁₁La₃+Al₂O₃)/Al复合材料。结果表明，高能球磨和高温烧结促进了原位反应，使Al与La₂O₃充分反应并制备出致密无缺陷的材料。对其微观组织的分析表明，微米Al₁₁La₃和纳米Al₂O₃颗粒均匀分散于基体之中。这种复合材料的室温抗拉强度为328 MPa、延伸率为10.5%,350℃的高温抗拉强度为119 MPa、延伸率为10.2%。与传统Al-Cu-Mg-Ag和Al-Si-Cu-Mg耐热铝合金相比，本文的制备的(Al₁₁La₃+Al₂O₃)/Al复合材料其高温抗拉强度提高了大约20%。这种材料的室温强化机制源于Al₁₁La₃和Al     

Bi2O3助熔剂对CaO-B2O3-SiO2/Al2O3玻璃陶瓷复合材料性能的影响

以CaO-B₂O₃-SiO₂(CBS)玻璃粉体和Al₂O₃陶瓷粉体为原料,通过在CBS与Al₂O₃的质量比固定为50:50的玻璃-陶瓷复合材料中添加适量的Bi₂O₃作为烧结助熔剂,探讨了Bi₂O₃助熔剂对CBS/Al₂O₃复合材料的烧结性能、介电性能、抗弯强度和热膨胀系数的影响规律.研究表明:Bi₂O₃助熔剂能通过降低CBS玻璃的转变温度和黏度促进CBS/Al₂O₃复合材料的致密化进程,于880 ℃下烧结即能获得结构较致密、气孔较少的CBS/Al₂O₃复合材料.然而,过量添加Bi₂O₃将使玻璃的黏度过低,从而恶化CBS/Al₂O₃复合材料的烧结性能、介电性能及抗弯强度.当Bi₂O₃的添加量为CBS/Al₂O₃复合材料的1.5wt%时,于880 ℃下烧结即能获得最为致密的CBS/Al₂O₃复合材料,密度为2.82 g·cm^-3,这一材料具有良好的介电性能(介电常数为7.21,介电损耗为1.06×10^-3),抗弯强度为190.34 MPa,0~300 ℃的热膨胀系数为3.52×10^-6 K^-1.     

Al2O3@Y3Al5O12纳米短纤维对铝合金基复合材料的增强作用

采用一种具有芯-壳结构的复合纳米纤维增强铝合金复合材料,可以在提高抗拉强度的同时增加塑性。通过真空热压烧结技术制备了Al₂O₃@Y₃Al₅O₁₂复合纳米短纤维增强2024铝合金复合材料。研究了纤维添加质量分数对复合材料致密度、硬度、抗拉强度及延伸率的影响;并探究了芯-壳结构在复合材料增韧中的作用。结果表明:Al₂O₃@Y₃Al₅O₁₂纳米短纤维具有良好的分散性,在超声分散及机械搅拌混粉后均匀吸附在铝合金颗粒表面,无分层及团聚现象;经热压烧结后,Al₂O₃@Y₃Al₅O₁₂纳米短纤维以短纤维形态均匀分散在铝合金基体内,少量添加Al₂O₃@Y₃Al₅O₁₂纳米短纤维起到了桥联和孔洞填充作用,使复合材料致密度和硬度提高;添加质量分数为1wt%时,抗拉强度和延伸率取得最大值,由铝合金的249.3 MPa、2.9%增加到299.1 MPa、4.3%。Al₂O₃@Y₃Al₅O₁₂纳米短纤维的添加可以细化晶粒,阻碍裂纹扩展,且在拔出/断过程中Al₂O₃@Y₃Al₅O₁₂纳米短纤维芯-壳结构的塑性变形起到了增强增韧作用。      

特高压气体绝缘金属封闭开关设备用Al2O3/环氧树脂复合材料的非等温固化动力学及蠕变性能

针对特高压气体绝缘金属封闭开关设备（GIS）用Al₂O₃/环氧树脂（EP）复合材料,采用非等温差示扫描量热（DSC）法研究了Al₂O₃/EP复合材料的固化行为,对其DSC曲线进行分峰处理,利用等转化率方法求得不同反应阶段的表观活化能。根据Málek判据得到Al₂O₃/EP复合材料的固化行为符合的模型类型,并求得不同反应阶段的各个动力学参数及固化动力学方程。利用SEM观察Al₂O₃/EP复合材料的微观形貌,通过动态热力学分析仪（DMA）分析其动态热力学性能和高温蠕变性能,利用时温等效预测了Al₂O₃/EP复合材料的长时蠕变行为。结果表明,DSC热流曲线表现为双峰分布;Al₂O₃/EP复合材料的两个反应阶段的表观活化能分别为35.3 kJ/mol及48.1 kJ/mol,Sestak-Berggren自催化模型能够很好地描述Al₂O₃/EP复合材料体系在不同固化阶段的固化行为。Al₂O₃颗粒均匀分散于树脂基体中,填料的加入使裂纹发生偏转。Al₂O₃/EP复合材料的储能模量（E'）随温度的升高而降低,损耗因子（tanδ）峰值对应的玻璃化转变温度（T_g）为120.03℃。Al₂O₃/EP复合材料的抗蠕变性能随着拉伸应力和温度的增加而减弱,随着时间的延长,其蠕变速率减小。      

Cf-ZrW2O8/9621复合材料制备及碳纤维和ZrW2O8含量对其热膨胀的影响

热膨胀是影响复合材料性能和使用寿命的主要因素之一。为研究具有低/负热膨胀的复合材料,本文以碳纤维粉、ZrW₂O₈颗粒和环氧树脂为原料,采用模压法制备了C_f-ZrW₂O₈/9621环氧树脂基复合材料,研究了碳纤维粉和ZrW₂O₈颗粒含量对复合材料热膨胀行为的影响规律,并分析了不同温度区间内C_f-ZrW₂O₈/9621环氧树脂基复合材料热膨胀的变化规律。研究结果表明：在30～200℃范围内,当ZrW₂O₈颗粒含量不变时,随着碳纤维粉含量的增加复合材料的平均热膨胀系数逐渐降低,其中碳纤维粉含量增加到12%时,复合材料的平均热膨胀系数最低,为29.9×10^-6/℃,降低了约60%;当碳纤维粉含量不变时,ZrW₂O₈颗粒含量逐渐增加到12%时,复合材料的平均热膨胀系数呈现...     

原位自生纳米Al2O3/Al-Zn-Cu复合材料的力学性能

将纳米ZnO粉末和Al粉球磨后冷压成Al-ZnO预制块,然后将其加到Al-Zn-Cu熔体中进行Al-ZnO原位反应,制备出纳米Al₂O₃颗粒增强Al-Zn-Cu基复合材料。能谱面扫描分析和透射电镜观察结果表明,复合材料由纳米Al₂O₃颗粒和Al₂Cu析出相两种颗粒/析出相组成。纳米Al₂O₃颗粒通过异质形核和晶界钉扎,细化了Al-Zn-Cu合金晶粒组织和Al₂Cu析出相。原位纳米Al₂O₃颗粒的生成提高了基体合金的拉伸性能,轧制+热处理使Al₂O₃/Al-Zn-Cu复合材料的拉伸强度比相同处理的基体合金提高约100%,总伸长率提高约98%。     

Hybrid effects on tensile properties of hybrid short-glass-fiber-and short-carbon-fiber-reinforced polypropylene composites

Hybrid composites of polypropylene reinforced with short glass fibers and short carbon fibers were prepared using extrusion compounding and injection molding techniques. The tensile properties of these composites were investigated taking into account the effect of the hybridization by these two types of short fibers. It was noted that the tensile strength and modulus of the hybrid composites increase while the failure strain of the hybrid composites decreases with increasing the relative carbon fiber volume fraction in the mixture. The hybrid effects for the tensile strength and modulus were studied by the rule of hybrid mixtures (RoHM) using the tensile strength and modulus of single-fiber composites, respectively. It was observed that the strength shows a positive deviation from that predicted by the RoHM and hence exhibits a positive hybrid effect. However, the values of the tensile modulus are close to those predicted by the RoHM and thus the modulus shows no existence of a hybrid effect. Moreover, the failure strains of the hybrid composites were found to be higher than the failure strain of the single carbon fiber-reinforced composite, indicating that a positive hybrid effect exists. Explanations for the hybrid effects on the tensile strength and failure strain were finally presented.     

混杂比对碳/芳纶纤维混杂纬编双轴向多层衬纱织物增强复合材料力学性能的影响

利用层内混杂的方式制备碳/芳纶纤维混杂纬编双轴向多层衬纱织物,通过对材料进行拉伸、三点弯曲等实验研究该织物增强复合材料的力学性能及混杂比对其力学性能的影响。结果表明,按照一定的混杂比加入芳纶纤维后复合材料的拉伸性能提高,表现出积极的混杂效应。由于延伸性好的芳纶纤维的加入,使复合材料的拉伸断裂伸长率明显提高,材料破坏模式出现了完全脆性断裂模式(C12材料破坏形式)和“扫帚”形纤维断裂模式(C8A4,C6A6材料破坏形式)。此外,按照一定的混杂比加入芳纶纤维也有效改善了碳纤维增强复合材料的破坏韧性,碳/芳纶纤维混杂MBWK织物增强复合材料的弯曲强度和弯曲模量随混杂比的提高而呈下降趋势,当复合材料中芳纶含量从42%(体积分数,下同)(C6A6)到59.2%(C4A8)的变化过程中,弯曲强度和弯曲模量的降低率较高。0°试样在混杂比为59.2%(C4A8)时,弯曲挠度最大,达到7.49 mm,远高于纯芳纶纤维或纯碳纤维增强的复合材料。所有90°混杂复合材料试样的弯曲挠度均高于纯芳纶纤维或纯碳纤维增强的复合材料,表现出积极的混杂效应。     

短切纤维增强复合材料拉伸强度的预测

在分析单向连续纤维增强复合材料纵向拉伸时细观受力与变形的基础上,对连续纤维的长度和方向进行尺寸和方向性修正,给出了短切纤维增强复合材料的拉伸强度预测公式.使用这个预测公式计算短切碳纤维增强PTFE复合材料的拉伸强度,预测值与实验值吻合得较好.     

Analytical modeling of strength in randomly oriented PP and PPTA short fiber reinforced gypsum composites

Fiber reinforced gypsum are prevalent building materials in which short fibers with high tensile strength are embedded into a gypsum matrix to produce supplemental strong and lightweight construction materials. Due to confrontation to a rising risk of death and economic disaster in earthquake-prone areas, quake-resistant materials and structures should be employed for building constructions. Gypsum based composites as a unique candidate for this purpose reduce the risks and produce much confident construction materials for residential buildings. In this work tensile strength of gypsum composites with different volume fraction of polypropylene (PP) and poly-paraphenylene terephthalamide (PPTA) fibers up to 15% were studied. Stress transfer ability from matrix to fibers were analyzed using theoretical shear lag analyses, scanning electron microscope, and pull out tests. The interfacial characteristics were also studied by scanning electron microscope (SEM). The ability of the composites to withstand against longitudinal tensile load was also studied by tensile tests of dog-bone shaped, random oriented fiber reinforced gypsum. Tensile strength of randomly oriented short fiber reinforced gypsum was evaluated by a mathematical model. The obtained results from the model and experimental results have been compared and discussed.     

r—Al2O3,莫来石纤维增强Al—Si复合材料拉伸过程原位SEM研究

用扫描电镜观察了莫来石、ｒ－Ａｌ２Ｏ３两种短纤维增强Ａｌ－１２％Ｓｉ复合材料的拉伸变形和断裂过程，结果表明：对莫来石纤维增强Ａｌ－１２％Ｓｉ复合材料，与外加载荷方向成小角度的纤维是裂纹优先萌生的地方；ｒ－Ａｌ２Ｏ３纤维增强Ａｌ－１２％Ｓｉ事材料抵抗断裂能力小于晨来石纤维增强Ａｌ－１２％Ｓｉ复合材料；提出了莫来石纤维增强Ａｌ－１２％Ｓｉ复合材料的断裂模式。     

碳纤维增强尼龙1010的力学性能及其对摩擦磨损的影响

用碳纤维填充尼龙1010制备了碳纤维增强尼龙复合材料,并对碳纤维增强尼龙复合材料的力学性能和摩擦学性能进行了实验研究。力学实验结果表明:碳纤维增强使尼龙复合材料的拉伸强度、表面硬度增大,碳纤维增强尼龙材料的拉伸强度在20%碳纤维含量时达到最大值;碳纤维表面处理对尼龙复合材料的拉伸强度有很大影响,碳纤维表面氧化处理提高了碳纤维增强尼龙复合材料的拉伸强度。摩擦磨损实验表明:碳纤维增强尼龙复合材料的摩擦系数和磨损率与其拉伸强度和硬度有密切关系。随着拉伸强度和硬度的提高,尼龙复合材料摩擦系数和磨损率降低;摩擦系数和磨损率与拉伸强度具有反比关系,与材料硬度具有二次方程关系,与碳纤维填充量之间存在负指数变化规律。      

Strain rate and temperature dependence of tensile strength for carbon/glass fibre hybrid composites

The tensile strength of epoxy resin reinforced with a random planar orientation of short carbon and glass fibres increased as the strain rate increased, and the increase in tensile strength became slightly remarkable with increasing temperature. The strain rate-temperature superposition was held for each composite. The strain rate and temperature dependence of tensile strength of composites could be estimated based on the dependence of the mechanical properties of the matrix resin, the interfacial yield shear strength and the critical fibre length. The strain rate and temperature dependence of the tensile strength of the hybrid composite could be estimated by the additive rule of hybrid mixtures, using the strain rate and temperature dependence of the tensile strength of both composites. The experimental values at a higher rate were lower than the calculated values. It was hypothesized that this may have been caused by the ineffective fibres formed during preparation of the specimen.     

Asymmetric hybrid composite: A design concept to improve flexural properties of Kevlar Aramid composites

Asymmetric hybridization is proposed as a mechnanism for improvement of flexural properties of composites reinforced with Kevlar¹ aramid fiber, where the compressive strength of the fiber is a limiting factor. A calculation based on a bi-material beam model is presented, which determines the placement and arrangement of fibers in a composite such that the stress developed on the tensile side of the composite equals the ultimate tensile strength of Kevlar. An experimental investigation was conducted with asymmetric hybrid composites of J-polymer reinforced with Kevlar and carbon fibers. In the best cases, the observed ultimate flexural and shear strengths were improved by 40% and 25% by comparison with values typically seen for composites of J-polymer and Kevlar.     

Effects of fibre length on tensile strength of carbon/glass fibre hybrid composites

The tensile strength of epoxy resin reinforced with random-planar orientation of short carbon and glass fibres increased as the length of the reinforcing fibres increased, and the increase in tensile strength remained almost unchanged after the fibre length reached a certain level. The tensile strength of composites at any fibre length could be estimated by taking the strain rate and temperature dependence of both the yield shear strength at the fibre-matrix interphase and the mean critical fibre length into consideration. The tensile strength of the hybrid composite could be estimated by the additive rule of hybrid mixtures, using the tensile strength of both composites.     

Hybrid carbon nanotube–carbon fiber composites with improved in-plane mechanical properties

In this study carbon nanotubes (CNTs) were grown on carbon fibers to enhance the in-plane and out-of-plane properties of fiber reinforced polymer composites (FRPs). A relatively low temperature synthesis technique was utilized to directly grow CNTs over the carbon fibers. Several composites based on carbon fibers with different surface treatments (e.g. growing CNTs with different lengths and distribution patterns and coating the fibers with a thermal barrier coating (TBC) layer) were fabricated and characterized via on- and off-axis tensile tests. The on-axis tensile strength and ductility of the hybrid FRPs were improved by 11% and 35%, respectively, due to the presence of the TBC and the surface grown CNTs. This configuration also exhibited 16% improvement on the off-axis stiffness. Results suggest that certain CNT growth patterns and lengths are more pertinent than the other surface treatments to achieve superior mechanical properties.