Strengthening of Mullite by Dispersion of Carbide Ceramics Particles

JSME international journal. Series A, mechanics and material engineering Pub Date : 1996-04-15 DOI:10.1299/JSMEA1993.39.2_259

M. Chu, Shigemi Sato, Y. Kobayashi, K. Ando

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引用次数: 14

Abstract

Both mullite/SiC (0.27 μm and 1.20 μm) and mullite/TiC composite ceramics were prepared by hotpressing at 1650°C under 35 MPa for 4h. Room-temperature bending fracture stress, Young's modulus, Vicker's hardness and fracture toughness were investigated as functions of SiC and TiC volume fraction (0-20%). Grain growth of mullite was prevented by the existence of dispersed particles (SiC, TiC) in the matrix. As a result, bending fracture stress of both mullite/SiC and mullite/TiC composite ceramics was improved. In the case of the mullite/SiC system, bending fracture stress inceased with increasing SiC content and showed a maximum value of 604 MPa at 20 vol%, which was about 80% higher than that of monolithic mullite. On the other hand, fracture toughness of mullite/TiC ceramic composite was observed to incease from 2.65 to 3.9 MPa√m with the addition of 20 vol% TiC. Correspondingly, the bending-fracture stress increased from 330 to 410 MPa. The strengthening mechanism of thermal treatment in air was also investigated for mullite/SiC composite ceramics and it was concluded to be useful for increasing bending fracture stress. Detailed reseach on the microstructure showed that the Hall-Petch relationship was satisfied for grain size and bending fracture stress.

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碳化物陶瓷颗粒分散对莫来石的强化作用

以莫来石/SiC (0.27 μm和1.20 μm)和莫来石/TiC复合陶瓷为材料，在1650℃、35 MPa下热压4h制备。研究了室温弯曲断裂应力、杨氏模量、维氏硬度和断裂韧性随SiC和TiC体积分数(0 ~ 20%)的变化规律。基体中分散颗粒(SiC, TiC)的存在阻碍了莫来石晶粒的生长。结果表明，莫来石/SiC复合陶瓷和莫来石/TiC复合陶瓷的弯曲断裂应力均得到改善。莫来石/SiC体系的弯曲断裂应力随SiC含量的增加而增大，在20 vol%时达到最大值604 MPa，比整体莫来石高约80%。另一方面，当TiC含量为20 vol%时，莫来石/TiC陶瓷复合材料的断裂韧性由2.65 MPa / m提高到3.9 MPa / m。相应的，弯曲断裂应力从330 MPa增加到410 MPa。研究了莫来石/碳化硅复合陶瓷在空气中热处理的强化机理，得出莫来石/碳化硅复合陶瓷在空气中热处理有利于提高弯曲断裂应力的结论。显微组织研究表明，在晶粒尺寸和弯曲断裂应力方面满足Hall-Petch关系。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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JSME international journal. Series A, mechanics and material engineering

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