先驱体浸渍-裂解SiC界面改性涂层对气相渗硅3D-C_f/SiC复合材料力学性能的影响

界面改性涂层对调节复合材料的力学性能起到重要作用。特别是在气相渗硅(GSI)制备C_f/SiC复合材料时,合适的界面改性涂层一方面保护C纤维不受Si反应侵蚀,另一方面调节C纤维和SiC基体的界面结合状况。通过在3D-C纤维预制件中制备先驱体浸渍-裂解(PIP)SiC涂层来进行界面改性,研究了PIP-SiC涂层对GSI C_f/SiC复合材料力学性能的影响。结果表明:无涂层改性的GSI C_f/SiC复合材料力学性能较差,呈现脆性断裂特征,其弯曲强度、弯曲模量和断裂韧性分别为87.6 MPa、56.9GPa和2.1 MPa·m~(1/2)。具有PIP-SiC界面改性涂层的C_f/SiC复合材料力学性能得到改善,PIP-SiC涂层改性后,GSI C_f/SiC复合材料的弯曲强度、弯曲模量和断裂韧性随着PIP-SiC周期数的增加而降低,PIP-SiC为1个周期制备的GSI C_f/SiC复合材料的力学性能最高,其弯曲强度、弯曲模量、断裂韧性分别为185.2 MPa、91.1GPa和5.5 MPa·m~(1/2)。PIP-SiC界面改性涂层的作用机制主要体现在载荷传递和"阻挡"Si的侵蚀2个方面。     

化学气相反应法制备SiC涂层对C/C复合材料力学性能影响

采用化学气相反应法在C/C复合材料表面制备了SiC涂层,利用X射线衍射仪、扫描电镜及能谱等分析手段研究了涂层的形貌和结构,并采用三点弯曲试验研究了材料的力学性能,讨论了SiC涂层及制备工艺对复合材料断裂行为的影响.结果表明:涂层后材料的弯曲强度和最大断裂位移明显增大.未涂层C/C复合材料的平均弯曲强度为172.4MPa,而涂层后C/C复合材料的平均弯曲强度为239.8MPa,弯曲强度提高了39.1%.涂层试样强度的提高主要与制备过程中部分蒸气扩散渗透反应引起的界面强化及SiC颗粒的增强作用有关.此外,涂层后材料的断裂模式未发生明显转变,断裂过程中试样表现出一定的假塑性和韧性断裂特征.     

界面涂层对液相硅浸渗制备C/SiC复合材料力学性能的影响

采用化学气相沉积工艺对短切碳纤维毡体进行界面涂层改性处理后树脂浸渍裂解得到了多孔C/C预制体,再将预制体液相硅浸渗制备了C/SiC复合材料.对比了纤维有无界面涂层对C/SiC复合材料力学性能的影响,并分析了其断裂机制.结果表明,与无界面涂层改性相比,碳毡经化学气相沉积SiC涂层改性处理后制备的C/SiC复合材料的力学性能更好,强度和模量分别提高了192％和36％.界面涂层增强了纤维的抗硅化效果是C/SiC复合材料力学性能提高的主要原因,但同时复合材料也呈现出脆性断裂模式.     

纤维表面涂层对SiC(f)/SiC复相陶瓷力学性能和界面结构的影响

报道了化学气相浸渍（CVI）工艺制备的SiC（f）/SiC复相陶瓷中纤维表面涂层对复合材料力学性能和显微结构的影响。SEM观察表明：C或B N表面涂层改变了SiC（f）/SiC复相陶瓷中纤维与基体间的强界面结合,使断裂过程中的界面解离和纤维拔出大大增加,与此同时材料的断裂韧性和断裂功明显提高。说明C或BN纤维表面涂层能够大大地改善SiC（f）/SiC复相陶瓷的脆性断裂行为模式。高分辨电镜的观察证实在CVI过程初期,纤维表面首先发生石墨界面相的沉积,该界面相具有明显的层状晶格条纹,而纤维表面C涂层为无定型态。     

不同界面SiC/SiC复合材料的断裂行为研究

碳化硅纤维增强碳化硅复合材料(SiC/SiC)是极具前景的高温结构材料。通过先驱体浸渍裂解(PIP)工艺分别制备了PyC界面和CNTs界面SiC/SiC复合材料, 对两种SiC/SiC复合材料的整体力学性能以及界面剪切强度等进行了测试表征, 并对材料中裂纹的产生与扩展进行了原位观测。结果表明, 两种界面SiC/SiC复合材料弯曲强度相近, 但PyC界面SiC/SiC复合材料的断裂韧性约为CNTs界面SiC/SiC复合材料的两倍。在PyC界面SiC/SiC复合材料中, 裂纹沿纤维-基体界面扩展, PyC涂层能够偏转或阻止裂纹, 材料呈现伪塑性断裂特征; 而在CNTs界面SiC/SiC复合材料中, 裂纹在扩展路径上遇到界面并不偏转, 初始裂纹最终发展为主裂纹, 材料呈现脆性断裂模式。     

SiCf/SiC复合材料的显微结构和抗氧化性能

采用热梯度强制流动化学气相渗积(FCVI)工艺制备了连续SiC纤维增强SiC陶瓷基复合材料.渗积分两步进行,第一步先等温渗积裂解碳用为界面层.第二步热梯度强制流动渗积SiC.利用X射线衍射分析、电镜等手段研究了复合材料的显微结构,结果表明:FCVI制备的SiC基体为β-SiC,具有亚向微米级的晶粒结构,结晶度良好.测定了复合材料的强度和断裂韧性,研究了复合材料的抗氧化性能.结构表明:裂断碳界面层的氧化物是复合材料力学性能恶化循环化的主要原因.试样表面涂覆SiC涂层可以避免复合材料力学性能恶化.     

界面相对3D-SiC/SiC复合材料静态力学性能及内耗特征的影响

采用先驱体浸渍裂解工艺制备无界面、SiC、PyC和PyC/SiC等界面相SiC/SiC复合材料, 研究了SiC/SiC复合材料的微观结构及静态力学性能, 并通过强迫振动法系统分析了界面相对复合材料内耗行为的影响。研究结果表明, 引入界面相有效改善了复合材料的微观结构及力学性能, 并降低了复合材料的内耗。其中, PyC/SiC复相界面中亚层SiC限制了PyC界面相与纤维的结合及塑性形变, 提高了复合材料的力学性能; 同时, 界面相对SiC/SiC复合材料内耗行为有显著影响, 材料内耗水平与界面剪切强度成反比。对比50和350 ℃时的材料内耗变化率发现, 随界面剪切强度增大, 材料内耗呈降低的趋势, 且含有PyC的PyC/SiC界面复合材料具有较低的内耗变化率, 说明PyC/SiC复相界面的SiC/SiC复合材料更适于高温振动环境。     

“CVI+压力PIP”混合工艺制备低成本 C/SiC复合材料

以低成本填料改性有机硅浸渍剂作为先驱体,采用"化学气相渗透法+压力先驱体浸渍裂解法"(CVI+P-PIP)混合工艺制备了低成本C/SiC陶瓷复合材料.研究了浸渍剂裂解机理,探讨了界面涂层对复合材料性能的影响.结果表明,填料改性有机硅浸渍剂裂解产物结构致密、陶瓷产率高;压力可提高填料改性有机硅浸渍剂的致密效率.混合工艺充分利用沉积SiC基体和裂解SiC基体的致密化特点,有效缩短了制备周期.C/SiC/C三层界面不仅可降低纤维/基体之间结合强度界面,提高了复合材料韧性;而且减缓了氧化性气体扩散到碳纤维表面的速度,改善了复合材料的抗氧化性能.复合材料的抗弯强度达到455MPa,断裂韧性达到15.7MPa·m-1/2.在1300℃空气中氧化3h,复合材料失重仅8.5%.     

C/C多孔体的高温热处理对C/SiC复合材料结构及力学性能的影响

以三维针刺碳毡作为预制体,先采用树脂单向加压浸渍-热解工艺制备出C/C多孔体,再通过反应熔体浸渗法获得C/SiC复合材料。重点研究了C/C多孔体的高温热处理对C/SiC复合材料结构和力学性能的影响。结果表明,C/C多孔体的高温热处理不会改变C/SiC复合材料的相组成,但可使复合材料中的SiC含量提高,C含量降低;高温热处理有利于熔融Si浸渗,使复合材料致密度增大,孔隙率降低,从而使其弯曲断裂强度提高约28%;高温热处理还可使纤维-基体界面结合强度降低,改善复合材料的断裂韧性。     

纤维涂层法制备SiCf/Cu复合材料及其性能分析

为研究纤维涂层法制备SiCf/Cu复合材料的性能特点,通过磁控溅射法先后将Ti6Al4V界面改性层和基体Cu涂层涂覆到SiC纤维表面,并通过真空热压法将被涂覆的纤维制备成SiCf/Cu复合材料.对Ti6Al4V涂层、Cu涂层以及复合材料进行了微观分析,并测试了复合材料的拉伸强度.研究表明,复合材料的Cu基体由致密而细小的晶粒组成;Ti6Al4V提高了纤维/基体界面结合强度,复合材料轴向抗拉强度高达500 MPa,界面脱粘主要发生在纤维表面的碳涂层与纤维之间.     

Mechanical properties of 3D KD-I SiCf/SiC composites with engineered fibre-matrix interfaces

Three-dimensional (3D) silicon carbide (SiC) matrix composites reinforced with KD-I SiC fibres were fabricated by precursor impregnation and pyrolysis (PIP) process. The fibre-matrix interfaces were tailored by pre-coating the as-received KD-I SiC fibres with PyC layers of different thicknesses or a layer of SiC. Interfacial characteristics and their effects on the composite mechanical properties were evaluated. The results indicate that the composite reinforced with as-received fibre possessed an interfacial shear strength of 72.1 MPa while the composite reinforced with SiC layer coated fibres had a much higher interfacial shear strength of 135.2 MPa. However, both composites showed inferior flexural strength and fracture toughness. With optimised PyC coating thickness, the interface coating led to much improved mechanical properties, i.e. a flexural strength of 420.6 MPa was achieved when the interlayer thickness is 0.1 μm, and a fracture toughness of 23.1 MPa m^1/2 was obtained for the interlayer thickness of 0.53 μm. In addition, the composites prepared by the PIP process exhibited superior mechanical properties over the composites prepared by the chemical vapour infiltration and vapour silicon infiltration (CVI-VSI) process.     

纤维涂层对复合材料力学性能的影响

对于ＳｉＣ纤维／ＭＡＳ微晶玻璃复合系统，发现在烧结温度下，纤维和基体之间有较严重的化学反应发生，界面结合强，力学性能较差．通过对ＮｉｃａｌｏｎＳｉＣ纤维加涂层，发现Ｎｂ２Ｏ５和ｃ涂层对复合材料的界面结合改善不大，而ＬＣＡＳ晶玻璃涂层能使纤维和基体间的界面结合明显减弱，力学性能大幅度提高，室温抗折强度和断裂韧性分别达３２７ＭＰａ和１３．９ＭＰａ·ｍ１／２．     

Design,Fabrication, Characterization and Simulation of PIP-SiC/SiC Composites

Continuous SiC fiber reinforced SiC matrix composites (SiC/SiC) have been studied and developed for high temperature and fusion applications. Polymer impregnation and pyrolysis (PIP) is a conventional technique for fabricating SiC/SiC composites. In this research, KD-1 SiC fibers were employed as reinforcements, a series of coatings such as pyrocarbon (PyC), SiC and carbon nanotubes (CNTs) were synthesized as interphases, PCS and LPVCS were used as precursors and SiC/SiC composites were prepared via the PIP method. The mechanical properties of the SiC/SiC composites were characterized. Relationship between the interphase shear strength and the fracture toughness of the composites was established. X-ray tomographic scans of the SiC/SiC composites were performed and the closed porosities of the composites were calculated. The compatibility of the SiC/SiC composites with liquid LiPb at 800 °C and 1000 °C was investigated. High-resolution synchrotron X-ray tomography was applied to the SiC/SiC composite and digital volume correlation was employed for Hertzian indentation testing of the SiC/SiC composite. A Cellular Automata integrated with Finite Elements (CAFE) method was developed to account for the effect of microstructure on the fracture behavior of the SiC/SiC composite.     

Microstructure and mechanical properties of carbon fiber reinforced multilayered (PyC–SiC)n matrix composites

Carbon fiber reinforced multilayered (PyC–SiC)_n matrix (C/(PyC–SiC)_n) composites were prepared by isothermal chemical vapor infiltration. The phase compositions, microstructures and mechanical properties of the composites were investigated. The results show that the multilayered matrix consists of alternate layers of PyC and β-SiC deposited on carbon fibers. The flexural strength and toughness of C/(PyC–SiC)_n composites with a density of 1.43 g/cm³ are 204.4 MPa and 3028 kJ/m³ respectively, which are 63.4% and 133.3% higher than those of carbon/carbon composites with a density of 1.75 g/cm³. The enhanced mechanical properties of C/(PyC–SiC)_n composites are attributed to the presence of multilayered (PyC–SiC)_n matrix. Cracks deflect and propagate at both fiber/matrix and PyC–SiC interfaces resulting in a step-like fracture mode, which is conducive to fracture energy dissipation. These results demonstrate that the C/(PyC–SiC)_n composite is a promising structural material with low density and high flexural strength and toughness.     

CVI-iC/TaC改性C/C复合材料的力学性能及其断裂行为

以针刺碳纤维整体毡为预制体,采用化学气相渗透工艺对预制体纤维进行PyC/SiC/TaC的多层复合模式的涂层改性, 然后采用化学气相渗透和热固性树脂浸渍-化进行增密,制备出新型C/C复合材料。对复合材料的微观结构和力学性能进行了研究。结果表明:包覆在碳纤维表面的PyC/SiC/TaC多层结构均匀致密、无裂纹,在C/C复合材料中形成空间管状网络结构;改性后C/C复合材料的抗弯强度和韧性均大大提高, 平均抗弯强度达到522 MPa,断裂位移达到1.19mm;复合材料弯曲断裂形式表现为脆性断裂,经过2000℃高温热处理以后,复合材料的抗弯强度下降,但最大断裂位移增大,弯曲断裂形式由脆性断裂转变为良好的假塑性断裂。      

Effects of trace amount of nanometric SiC additives with wire or particle shapes on the mechanical and thermal properties of alumina matrix composites

SiC nanowires (SiCNWs) are suitable candidates used as additives to improve the thermal conductivity of alumina, since they exhibit superior properties such as high chemical and thermal stability. In this study, alumina matrix composites reinforced with very small amount of β-SiC/SiO₂ core–shell nanowires were fabricated by hot-pressing. They were first characterized and compared with alumina matrix specimens containing SiC nanopowder. It was found out that with 0.2 wt% SiC additives, the grain sizes of the alumina specimens were reduced by 20 % of that of the monolithic one, regardless of the shape of the SiC additives. Vickers hardness of specimen containing both SiCNWs and SiC nanopowders slightly increased, while fracture toughness decreased more than that of the monolithic alumina. Thermal conductivity of the specimens increased with increased amount of SiCNWs and was better than those of the specimens containing SiC nanopowders. The alumina composite containing 0.2 wt% SiCNWs had higher thermal conductivity than that of the monolithic alumina by as much as 45 %. From these results, it is clear that only small amount of nanosized SiC as an additive material, particularly SiCNWs, has a significant effect on the properties of alumina matrix composites.     

化学气相浸渗2D Cf/(SiC-C)复合材料的微观结构与强韧性

采用等温等压化学气相浸渗法(ICVI)制备了二维碳纤维增韧碳化硅碳二元基复合材料(2D C_f/(SiC-C)).利用扫描电镜(SEM)和背散射电子成像(BSE)研究了其基体的微观结构, 并与二维碳纤维增韧碳化硅陶瓷基复合材料(2D C_f/SiC)比较了室温力学性能和断口形貌.结果表明：2D C_f/(SiC-C)复合材料的基体是由SiC与热解碳(PyC)组成的多层结构, PyC基体层分布均匀而连续, 且与SiC基体层结合紧密.纤维束内部PyC基体层较厚的2D C_f/(SiC-C)复合材料具有较高的强韧性, 其拉伸强度、断裂应变、断裂韧性和断裂功分别比2D C_f/SiC复合材料的提高了3%、142%、22%和58%.SiC与PyC组成的多层基体使2D C_f/(SiC-C)复合材料的纤维在拔出过程中发生了两次集中拔出, 且第一次集中拔出的纤维对复合材料的强韧性起主要作用.     

Enhancing both strength and toughness of carbon/carbon composites by heat-treated interface modification

A simple method to increase both strength and toughness of carbon/carbon (C/C) composites is presented. This method is based on the heat treatment of the pre-deposited thin carbon coating, leading to the formation of more orderly pyrolytic carbon (PyC) as a functional interlayer between fiber and matrix that could optimize the interfacial sliding strength in C/C composites. Effects of such a heat-treated PyC layers on the microstructure, tensile strength and fracture behavior of unidirectional C/C composites were investigated. Results showed that although the in-situ fiber strength was deteriorated after the introduction of interfacial layer, tensile strength of the specimen was greatly improved by 38.5% compared with pure C/C composites without any treatment. The interfacial sliding stress sharply decreased, which was interpreted from finite element analysis and verified by Raman spectra. Therefore, the fracture behavior was changed from brittle fracture to multiple-matrix cracking induced non-linear mechanical behavior. Finally, the ultimate strength can be predicted by different models according to the interfacial sliding stress. Our research would provide a meaningful way to improve both strength and toughness of C/C composites.     

界面过渡层对SiC/Al双连续相复合材料性能的影响

研究了界面过渡层对SiC/Al双连续相复合材料性能的影响.结果表明,界面过渡层降低了复合材料中的残余应力,改善了界面的结合,提高了复合材料的压缩性能.当界面过渡层中SiC的体积分数接近50%时,复合材料的压缩强度最高,塑性最好,但弹性模量较低.界面过渡层的存在改变了复合材料的弯曲断裂机制.SiC原始泡沫增强的复合材料在断裂时,增强体SiC泡沫先断裂,基体后破坏,断裂表面凹凸不平;含界面过渡层的复合材料断裂时,过渡层的外侧界面先被撕开,内侧界面结合良好,基体与增强体同时断裂,断口平整.     

不同物相电沉积CNTs对C/SiC复合材料力学性能的影响

采用电沉积法与化学气相渗透(CVI)法将碳纳米管(CNTs)分别引入到碳纤维表面和SiC基体中,制得了不同物相电沉积CNTs的C/SiC复合材料(CNTs-C)/SiC和C/(CNTs-SiC)。研究了CNTs沉积物相对C/SiC复合材料力学性能的影响,分析了不同CNTs沉积物相的C/SiC复合材料的拉伸强度及断裂机制。结果表明:相较于未加CNTs的C/SiC复合材料,CNTs沉积到碳纤维表面的(CNTs-C)/SiC复合材料的拉伸强度提高了67.3%,断裂功提高了107.2%;而将CNTs引入到SiC基体中的C/(CNTs-SiC)复合材料的断裂功有所降低,拉伸强度也仅提高了6.9%,CNTs没有表现出明显的增强增韧效果;C/(CNTs-SiC)复合材料与传统的C/SiC复合材料有相似的断裂形貌特征,断裂拔出机制类似,主要为纤维增强增韧,CNTs的作用不明显。