共查询到17条相似文献,搜索用时 62 毫秒
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氧化铝陶瓷增韧技术及机理 总被引:2,自引:1,他引:2
介绍了氧化铝陶瓷增韧技术及其机理(包括相变增韧、晶须和纤维增韧、颗粒弥散增韧、微结构设计增韧、纳米技术增韧、耦合协同增韧),探讨了氧化铝陶瓷材料增韧技术的研究现状和今后的发展方向。 相似文献
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氮化硅陶瓷韧化的研究与进展 总被引:6,自引:0,他引:6
本文阐述了氮化硅陶瓷的增韧补强的研究与进展,对氮化硅的几种常见增韧补强的途径如弥散增韧、纤维增韧、相变增韧、自增韧、层状复合增韧作了评述,指出了目前进行氮化硅陶瓷的增韧的途径与方向。 相似文献
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Al_2O_3/TiO_2纳米复相陶瓷的增韧机理研究 总被引:1,自引:0,他引:1
纳米结构与纳米添加剂对陶瓷体的增韧是多种增韧方式共同存在的.对于1350℃烧结的ATZ陶瓷,其增韧机理为相变增韧和纳米颗粒增韧;对于1450℃的ATZ陶瓷烧结体,增韧机理主要为纳米颗粒增韧、微裂纹增韧.ATZ陶瓷体在1450℃烧结时的增韧效果优于1350℃烧结时的增韧效果. 相似文献
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纳米结构与纳米添加剂对陶瓷体的增韧是多种增韧方式共同存在的.对于1350℃烧结的ATZ陶瓷,其增韧机理为相变增韧和纳米颗粒增韧;对于1 450℃的ATZ陶瓷烧结体,增韧机理主要为纳米颗粒增韧、微裂纹增韧.ATZ陶瓷体在1 450℃烧结时的增韧效果优于1 350℃烧结时的增韧效果. 相似文献
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晶须增韧陶瓷基复合材料是改善陶瓷韧性的有效措施,近年来极受重视,发展迅速。本文简要介绍设计、制备这类复合材料时应考虑的主要问题、这类复合材料的制备技术和达到的强化增韧效果,以及一些有希望的新技术和今后的一些研究课题。 相似文献
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纳米结构与纳米添加剂对陶瓷体的增韧是多种增韧方式共同存在的。对于1350℃烧结的ATZ陶瓷,其增韧机理为相变增韧和纳米颗粒增韧;对于1450℃的ATZ陶瓷烧结体,增韧机理主要为纳米颗粒增韧和微裂纹增韧。而且ATZ陶瓷体在1450℃烧结时的增韧效果优于1350℃烧结时的增韧效果。 相似文献
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Yehong Cheng Ping Hu Shanbao Zhou Xinghong Zhang Wenbo Han 《Journal of the European Ceramic Society》2018,38(11):3752-3758
Graphene is one of the important candidates in ceramic toughening due to its outstanding physical and chemical properties. For the weak interface toughening of large-diameter graphene sheet and alleviation of the interfacial reaction between ceramic precursors and graphene sheets during high-temperature pyrolysis, ZrC–SiC?Graphene composite was synthesized via a facile technology of infiltrating ceramic slurry instead of ceramic precursor into macroporous graphene network and spark plasma sintering. The incorporation of the graphene network improved fracture toughness, critical crack size, and fracture energy of ZrC–SiC ceramic. The multiple length-scale toughening mechanisms of ZrC–SiC?Graphene composite include the macroscopic toughening mechanism of crack deflection and bifurcation and the micro toughening mechanism of graphene bridging, ceramic micro zone tearing, graphene pull-out, graphene and ceramic brick slipping. 相似文献
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《Ceramics International》2022,48(17):24687-24694
The R-curve behavior and toughening mechanisms of graphene nano-platelets (GNPs) reinforced ceramic composites are investigated. A toughening model is developed with the consideration of interface debonding, crack bridging and pull-out of GNPs, which can be used to quantify the contribution of different mechanisms to the improved toughness of ceramic composites. The theoretical results agree well with the experimental data when GNPs homogeneously dispersed in ceramic matrix. All prepared GNPs/ceramic composites exhibit a raising R-curve behavior owing to the toughening mechanisms induced by GNPs, and the curve becomes steeper with increasing GNPs content, indicating that the fracture resistance and flaw tolerance are improved. The dominant toughening mechanism is GNPs pull-out, which is followed by crack bridging and interface debonding. Furthermore, the analytical model suggests that improving GNPs properties, interfacial sheer strength and reducing GNPs thickness can improve the fracture toughness of ceramic composites. 相似文献
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