Processing and microstructure of Al2O3/YAG eutectic ceramic by laser rapid remelting
-
摘要: 采用激光快速熔凝技术制备Al2O3/YAG共晶自生复合陶瓷, 研究Al2O3/YAG共晶陶瓷在高能激光束作用下,不同扫描速率(0.01~2.0mm/s)、超高温度梯度下的凝固组织特征及其生长机制,探索激光熔凝过程控制参数与凝固组织的关系.研究结果表明:激光熔凝Al2O3/YAG共晶陶瓷由无规则连续分布的Al2O3相和YAG相两相组成,没有晶界和其他相,Al2O3相的体积分数为(45.0±2.0)%,两相耦合生长,交错分布,是典型的快速凝固层片状非规则共晶组织;共晶层间距细密, 并随激光扫描速度的增大而减小,扫描速度为0.02mm/s 时,共晶间距约为1~2μm,扫描速度为2.0mm/s时,共晶间距仅为0.5μm左右;综合热分析表明,Al2O3/YAG共晶熔点为2096K,与相图吻合.Abstract: Laser rapid remelting experiments were conducted on the preparation of Al2O3/YAG eutectic ceramic in-situ composite to investigate the microstructure characteristic and growth behavior under an ultra-high temperature gradient and different laser scanning rates of 0.01~2.0mm/s, and to explore the relationship between the laser processing parameters and the microstructure. The results show that the laser remelted Al2O3/YAG eutectic is composed of irregularly and continuously distributed Al2O3 and YAG phases without grain boundary and any other phase. The volume fraction of Al2O3 is (45.0±2.0)%. The two phases couple each other and complexly interweave, in which the microstructure belongs to the typical lamellar structure of rapidly solidified anomalous eutectic. The eutectic spacing is very small and decreases from about 1~2μm to 0.5μm as the laser scanning rate increases from 0.02~2.0mm/s. The synthetical themal analysis(STA) shows that the eutectic temperature of Al2O3/YAG is 2096K, matching the phase diagram of Al2O3-Y2O3 system.
-
[1] Waku Y, Nakagawa N, Wakamoto T, et al. A ductile ceramic eutectic composite with high strength at 1873K [J]. Nature, 1997, 389:49-52 [2] Sayir A. Directional solidification of eutectic ceramics [M]. Oxford:Oxford University Press, 1999:1-7 [3] Pastor J Y, Llorca J, Salazar A, et al. Mechanical properties of melt-grown alumina-yttrium aluminum garnet eutectics up to 1900K [J]. J Am Ceram Soc, 2005, 88(6):1488-1495 [4] 王华明,张凌云,李安,等. 金属材料快速凝固激光加工成形[J]. 北京航空航天大学学报,2004,30(10):962-967 Wang Huaming, Zhang Lingyun, Li An, et al. Rapid solidification laser processing and forming of advaced aeronautical metallic materials[J]. Journal of Beijing University of Aeronautics and Astronautics, 2004,30(10):962-967(in Chinese) [5] 张军, 苏海军, 刘林. Al2O3/YAG共晶自生复合陶瓷的激光熔凝实验研究[J]. 航空材料研究学报,2003,23:171-174 Zhang Jun, Su Haijun, Liu Lin. Experiment research on Al2O3/YAG eutectic ceramic in-situ composite with laser remelting [J]. J Aeronautical Mater, 2003, 23:171-174(in Chinese) [6] Jackson K A, Hunt J D. Lamellar and rod eutectic growth [J]. Trans AIEE, 1966, 236:1129-1142 [7] Matson L E, Hecht N. Microstructural stability and mechanical properties of directionally solidified alumina/YAG [J]. J Eur Ceram Soc, 1999, 19:2487-2501 [8] 杨森,黄卫东,林鑫,等. 激光快速凝固条件下Al-5.6wt%Mn合金的组织选择规律研究[J]. 应用激光,1999,19(5):243-246 Yang Sen, Huang Weidong, Lin Xin, et al. Study on microstructure selection of Al-5.6wt%Mn alloy under laser rapid solidification condition [J]. Applied Laser, 1999, 19(5):243-246(in Chinese) [9] Francisco I D, Merino R I, Orera V M, et al. Growth of Al2O3/ZrO2 (Y2O3) eutectic rods by the laser floating zone technique:effect of the rotation [J]. J Eur Ceram Soc, 2005, 25(8):1341-1350 [10] Yasuda H, Ohnaka I, Sugiyama A, et al. Undercooled melt shaping of Al2O3-YAG eutectic composite by melting the Al2O3-YAP eutectic structure [J]. Mater Sci Forum, 2005(475-479):2709-2712 [11] Caslavsky J L, Viechnicki D J. Melting behavior of metastability of yttrium aluminum garnet (YAG) and YAlO3 determined by optical difference thermal analysis [J]. J Mater Sci, 1980, 15(7):1709-1718 [12] Mizutani Y, Yasuda H, Ohnaka I, et al. Phase selection of the Al2O3-Y2O3 system controlled by nucleation [J]. Mater Trans, 2000, 42(2):238-244
点击查看大图
计量
- 文章访问数: 3057
- HTML全文浏览量: 55
- PDF下载量: 2102
- 被引次数: 0