纳米材料增强复合钎料的研究进展

综合评述了纳米材料增强复合钎料的研究与应用现状。首先介绍了纳米材料增强复合钎料的制备方法,讨论了机械混合法与原位合成法的工艺及特点,然后分别从金属颗粒、氧化物或其他化合物及碳纳米材料3个方面来介绍纳米材料对复合钎料微观组织及性能的影响。重点指出了具有优异性能的碳纳米管与石墨烯材料增强复合钎料的研究进展,并对其发展趋势进行分析和展望。

石墨烯包覆泡沫铜复合中间层钎焊碳/碳复合材料与铌的工艺与性能

针对石墨烯增强相在焊缝中难以分散均匀、结构完整性差、易团聚等问题.采用等离子增强化学气相沉积(PECVD)方法在泡沫铜表面原位制备高质量石墨烯,得到石墨烯增强泡沫铜复合中间层.使用该复合中间层钎焊碳/碳(C/C)复合材料与铌(Nb).采用Raman, SEM, HRTEM方法表征石墨烯以及钎焊接头的微观组织结构.结果表明,泡沫铜独特的多孔网络结构使其表面原位生长的高质量石墨烯在焊缝中均匀分布.同时,石墨烯优异的化学惰性保证了泡沫铜骨架的完整性,并协同石墨烯自身的低线膨胀系数充分发挥了缓解残余应力的作用,有效提高了接头的抗剪强度.

SiO_(2f)/SiO_2复合材料表面碳活化辅助钎料润湿机理

针对SiO_(2f)/SiO_2复合材料钎焊中存在表面钎料润湿性差、难以获得有效接头的难题,提出一种表面碳活化辅助钎料润湿的方法.利用PECVD方法低温原位在复合材料表面制备极薄的碳活化层,以辅助活性钎料在其表面铺展润湿.研究表明采用该方法在400℃/15 min条件下即可在SiO_(2f)/SiO_2表面制备出碳活化层,且复合材料表面形貌无变化.润湿结果表明碳活化层的引入显著改善了Ag-Cu-Ti钎料在复合材料表面的润湿性,860℃/10 min下润湿角从131°降至27°.碳活化层主要借助碳与活性元素良好的亲和力活化了复合材料表面状态,进而促进活性钎料在其表面铺展润湿.

Graphene-coated copper foam interlayer for brazing carbon/carbon composite and niobium

Problems such as poor structural integrity,inhomogeneous dispersion,and agglomeration of graphene in the brazing seam are typically encountered for graphene additives in a brazed joint interface.To resolve these problems,a plasma-enhanced chemical vapor deposition process was employed for in-situ preparation of a high-quality graphene-coated copper(Cu)foam composite interlayer prior to be applied for brazing carbon/carbon composite and niobium.The prepared graphene and the brazed joints were characterized via Raman spectroscopy,scanning electron microscopy,and high-resolution transmission electron microscopy.The results revealed that graphene was evenly distributed in the brazing seam with the help of the Cu foam,which was characterized by interconnected porosity.Simultaneously,the excellent chemical inertia of graphene inhibited the collapse of the Cu foam,based on which the thermal residual stress in the joint was effectively mitigated due to the synergistic reinforcement effect of the Cu foam(with good plastic deformation capacity)and graphene(with extremely low coefficient of linear expansion).This effect led to significant improvement in the average shear strength of the joint.

表面金属热渗辅助钎焊C/SiC-Nb接头界面增强机制

针对碳纤维增强碳化硅复合材料(C/SiC)与Nb金属钎焊接头存在残余应力高导致连接强度下降的难题,借助反应扩散机制对C/SiC复合材料表面进行改性,成功制备了纤维增强热渗区,降低了钎焊接头的残余应力,实现了界面结构强化,获得了高质量钎焊连接接头.本研究选用的热渗金属Ni-Cr-Si合金可在C/SiC复合材料表面充分润湿,为扩散的快速充分进行奠定了基础;之后探究了热渗工艺对热渗深度及界面结构的影响规律,实现了任意深度热渗区的可控制备.用AgCuTi钎料对热渗处理后的C/SiC复合材料与Nb进行了钎焊连接,钎焊接头的典型界面结构可表示为:C/SiC/Cf+Ni_(2)Si+Cr_(3)Ni_(2)Si+Cr_(23)C_(6)/Ag(s,s)+(Cu,Ni)/Nb.本研究从残余应力的调控与界面结构改善所引导的第二相强化等方面,详细阐述了热渗工艺对接头的界面强化机制.热渗区热膨胀系数介于复合材料与钎料之间,形成属性梯度过渡,有效缓解了接头高残余应力.热渗区钎料的连接由Cu、Ni互扩散实现,替代原位脆性化合物反应层;碳纤维与弥散分布碳化物起到的第二相增强作用,有效提高区域断裂强度,裂纹断裂路径也随之延长,接头强度获得进一步提升.在热渗深度为77μm时,接头平均抗剪切强度可提升至115.2 MPa,相比未热渗接头提高了36%.