| ZTA—SiCw—TiC复相陶瓷材料强韧化机理研究 |
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| 引用本文: | 程晋荣,许煜汾.ZTA—SiCw—TiC复相陶瓷材料强韧化机理研究[J].上海大学学报(自然科学版),1997,3(1):49-54. |
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| 作者姓名: | 程晋荣 许煜汾 |
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| 作者单位: | [1]上海大学 [2]合肥工业大学 |
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| 摘 要: | 四方氧化锆相变增韧、碳化硅晶须补强、碳化钛粒子弥散强化,同时引入一个新的陶瓷基复合材料系统中产生了叠加的强韧化效果。热压ZTA-SiCw-TiC复相陶瓷材料与Al2O3-SiCw-TiC相比具有更高的综合机械性能。碳化钛在基体中形成连续的骨架阻碍晶粒的长大,随着碳化钛含量的增加,基体的硬度明显增加。主要强韧化机理有相变增韧、晶须拔出、载荷转移、裂纹偏转等。基体的主要断裂方式为穿晶解理断裂。
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| 关 键 词: | 碳化硅晶须 碳化钛 复相陶瓷 强韧化 ZTA |
Studies on ZTA SiC w TiC Multiphase Composite Ceramics |
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| Cheng Jinrong.Studies on ZTA SiC w TiC Multiphase Composite Ceramics[J].Journal of Shanghai University(Natural Science),1997,3(1):49-54. |
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| Authors: | Cheng Jinrong |
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| Abstract: | The ZrO 2( t ) phase transformation, SiC w whisker and TiC particle dispersion were all introduced into a new ceramic composite system, leading to accumulated strengthening and toughening effects. Compared with Al 2O 3 SiC w TiC, hot pressed ZTA SiC w TiC multiphase ceramics has better comprehensive mechanical properties. TiC forms a continuous skeleton structure, preventing the growth of crystallites in the matrix. The hardness of the matrix increases with the increase of TiC content in it. Main strengthening and toughening mechanism could be explained by phase transformation, whisker pullout, load transfer, crack deflection, etc. The major fracture mode of matrix is transgranular cleavage. |
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| Keywords: | phase transformation toughening whisker reinforcement dispersion strengthening zirconia toughened alumina(ZTA) SiC whisker TiC |
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