In this study, the process optimization of sprayed powders and deposition performance for amorphous Al2O3–Y3Al5O12 (YAG) coatings was investigated. The solid-state reaction mechanism of the nano-sized Al2O3 and Y2O3 powders with eutectic molar ratio was studied by multiple step-by-step heating cycle calcination processes. The calcination process could be adjusted according the dominant control factors like chemical reaction rate or ion diffusion rate. Finally, the actual deposition performance of the calcined powders (Al2O3/YAG) was examined by atmospheric plasma spraying (APS). XRD, SEM and DTA were used to characterize the powders and the as-sprayed coatings. The results showed that the reaction of Al2O3–Y2O3 system is a high temperature solid reaction dominated by Al3 diffusion, the initial reaction process was usually belong to chemical kinetic range, then the reaction will be transformed from chemical kinetic range to diffusion dynamic range with the temperature increasing. The process optimization of powders was very effective, and the deposition effect of coating was effective.
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机译:在该研究中,研究了喷涂粉末和无定形Al2O3-y3Al5O12(YAG)涂层的喷涂粉末和沉积性能的过程优化。通过多级逐步加热循环煅烧方法研究了具有共晶摩尔比的纳米型Al2O3和Y2O3粉末的固态反应机理。可以根据化学反应速率或离子扩散速率等主导控制因子来调节煅烧过程。最后,通过大气等离子体喷涂检查煅烧粉末(Al 2 O 3 / YAG)的实际沉积性能(APS)。 XRD,SEM和DTA用于表征粉末和喷涂涂层。结果表明,Al 2 O 3-Y 2 O 3系统的反应是由Al3扩散为主的高温固体反应,初始反应过程通常属于化学动力学范围,然后将反应从化学动力学范围转化为扩散动态范围温度升高。粉末的过程优化非常有效,涂层的沉积效果有效。
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