为改善β型Ti-Nb-Zr合金的生物活性,添加20wt%的焦磷酸钙(CPP)生物陶瓷,利用放电等离子烧结技术制备20CPP/Ti-35Nb-7Zr生物复合材料.借助XRD、SEM及力学测试方法等研究不同烧结温度(1000~1200℃)下复合材料的微观组织及力学性能,揭示其组织演变对力学性能的影响机制.结果表明: 20CPP/Ti-35Nb-7Zr复合材料主要由β-Ti相基体、少量残留α-Ti相及金属-陶瓷相(CaTiO3、Ti2O、CaO、CaZrO3和TixPy)组成;随着烧结温度升高,复合材料中β-Ti相和金属-陶瓷相逐渐增多;金属与陶瓷之间的剧烈反应导致金属-陶瓷相的形态结构发生变化,复合材料中金属-陶瓷相从颗粒状析出物演变成连续网状组织,起到割裂基体的作用.20CPP/Ti-35Nb-7Zr复合材料的压缩弹性模量和抗压强度随着烧结温度的升高而增大,其中压缩弹性模量从64.0 Gpa增加至71.4 Gpa,金属-陶瓷相形态结构变化起主导作用.因此,控制20CPP/Ti-Nb-Zr复合材料中金属-陶瓷相的形态结构将有利于改善其力学性能.
To improve the bioactivity of β-type Ti-Nb-Zr alloy,20 wt% CPP (calcium pyrophosphate) was added as bio-ceramic,and then the 20CPP/Ti-35Nb-7Zr composites were fabricated by spark plasma sintering (SPS) technology.The study was focus on microstructure and mechanical properties of the composites sintered at different temperatures (1 000-1 200℃).The influence mechanism of microstructure evolution on the mechanical properties was revealed.Results show that the composites are consisted of β-Ti phase matrix,a little residual α-Ti phase and metal-ceramic phases (CaO,Ti2O,CaTiO3,CaZrO3 and TixPy).With increasing sintering temperature,the β-Ti phase and metal-ceramic phase increase gradually.The changes of metal-ceramic phases from particle-like precipitate to a continuous network structure are caused by the fierce reaction between metal and ceramic,which separates the matrix.Compressive elastic moduli and compressive strength of 20CPP/Ti-35Nb-7Zr composites present substantial increases (64.0 to 71.4 GPa) with increase of sintering temperature due to the morphological changes of metal-ceramic phases.Therefore,it will be beneficial to improving mechanical properties by controlling the morphological structure of metal-ceramic phases in 20CPP/Ti-Nb-Zr composite.
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