材料科学
复合材料
复合数
脆性
陶瓷
化学气相沉积
陶瓷基复合材料
接头(建筑物)
图层(电子)
钎焊
沉积(地质)
化学气相渗透
纤维
管(容器)
焊接
物理气相沉积
碳化硅
纤维增强复合材料
作者
Benjamin W. Lamm,Joseph Pegna,Ercan Cakmak,Weicheng Zhong,Takaaki Koyanagi
标识
DOI:10.1002/adem.202501581
摘要
The joining of ceramic monoliths or composites to date has primarily been limited to the formation of brittle monolithic joints using heterogeneous (dissimilar) materials, similar to brazing in metals. The development of a damage‐tolerant joint layer by SiC fiber reinforcements is demonstrated here. Tube workpieces made of SiC fiber‐SiC matrix composite are joined using a nonwoven SiC fiber mat densified by embedded wire chemical vapor deposition (EWCVD), creating a fiber‐reinforced weld‐like joint by homogeneous joining. EWCVD uses a localized heating method to target deposition and growth to the joint region specifically, while minimizing thermal damage to the surrounding composite tube material. X‐ray computed tomography (XCT) is used to nondestructively characterize as‐made joints for relative density, adhesion, and composition. In situ XCT analysis during mechanical testing revealed crack deflections in the bonding layer, which indicates a toughening mechanism typical of ceramic matrix composite phase. Gas permeation testing of these proof‐of‐concept composite joints identified relatively high leak rates in comparison to fully coated SiC/SiC composite tube workpieces. The novelty of the composite joining method and current technology challenges, including gas permeability, are discussed in comparison with traditional ceramic joints and materials.
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