Aluminization has been employed on alloys to form dense and adhesive Al2O3 surface layers to prolong their service life at high temperature. A cobalt-base superalloy AMS 5608 was used to deposit a cobalt aluminide layer at 950 -C for 9 h by a pack cementation process. The cyclic oxidation tests on aluminized alloys and the untreated substrate were conducted at 1100 -C for 196 h. It is found that the cobalt aluminide phase (around 60 Am in thickness) is achieved. A continuous Cr–W rich intermetallic layer is formed in the interdiffusion zone. After cyclic oxidation test, a dense and protective Al2O3 surface layer is produced on the aluminized alloy and phase transformation reactions occur in the aluminide layer and interdiffusion zone. It is observed that the aluminizing process has greatly enhanced the cyclic oxidation resistance of the Co-base superalloy at 1100 -C. However, the inward diffusion of Al and formation of cracks and pores in the interdiffusion zone cause detrimental effects on the cyclic oxidation resistance of the superalloy for long-term exposure.
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机译:已经在合金中使用铝化以形成致密和粘合剂Al2O3表面层,以延长其在高温下的使用寿命。使用钴基超合金AMS 5608在950-C℃下通过包装胶结过程沉积钴铝化层。铝化合金的环状氧化试验和未处理的基材在1100 -C中进行196小时。发现钴铝化相(厚度约为60μm)。在相互线区中形成连续的CR-W富含金属间层。在循环氧化试验后,在铝化合金中产生致密和保护性Al 2 O 3表面层,并在铝化层和相互扩散区中发生相变反应。观察到,铝化工艺大大提高了1100-C1的基础超合金的环状氧化抗性。然而,Al的向内扩散和相互扩散区中的裂缝和孔的形成会对高温合金的循环氧化抗性作用进行有害影响,以便长期暴露。
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