一种低成本铁镍基高温合金的显微组织演变及蠕变断裂行为

IF 2.9 4区材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Technology Pub Date : 2023-10-23 DOI:10.1080/10667857.2023.2270865

L.L. Wei, B.K. Pan, Y.G. Wang, B. Li, X.S. Jia

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引用次数: 0

摘要

追求具有优异蠕变性能的低成本高温合金对实际工程应用具有重要意义。研究了一种低成本铁镍基高温合金在750℃/130 MPa和700℃/200 MPa条件下的蠕变性能、微观组织演变及变形机理。在上述条件下，蠕变断裂寿命分别达到14,715 h和12,716 h。长期蠕变后，球状碳化物和γ′粒子(Ni3(Al,Ti))因奥斯特瓦尔德成熟而逐渐长大。在晶界迁移、应力和扩散的协同作用下，晶界处出现异常的粗针状γ′相，并沿择优取向生长。讨论了无析出区、碳化物和重合点阵边界对蠕变性能的影响。fe - ni基高温合金的蠕变机制以位错滑移为主。位错绕过γ′相移动，在析出相周围形成位错弓。

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Microstructure evolution and creep-rupture behaviour of a low-cost Fe-Ni-based superalloy

The pursuit of low-cost superalloys with excellent creep property is of great importance for practical engineering application. In this study, the creep performance, microstructure evolution and deformation mechanism of a low-cost Fe-Ni-based superalloy under the condition of 750°C/130 MPa and 700°C/200 MPa were investigated. The creep rupture life reached 14,715 h and 12,716 h, respectively, under the aforementioned conditions. After long-term creep, carbides and γ′ particles (Ni3(Al,Ti)) with spherical shape grew gradually due to the Ostwald ripening. Abnormal coarse needle-like γ′ phase presented at grain boundaries and grew along preferred orientation under the synergy effect of grain boundary migration, stress, and diffusion. Influence of precipitate-free zones, carbides, and coincidence site lattice (CSL) boundary on the creep properties were discussed. The creep deformation mechanism of the Fe-Ni-based superalloy were dominated by dislocations slip. Dislocations moved via by-passing the γ′ phase and formed dislocation bows around the precipitates.

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来源期刊

Materials Technology 工程技术-材料科学：综合

CiteScore

6.00

自引率

9.70%

发文量

105

审稿时长

8.7 months

期刊介绍： Materials Technology: Advanced Performance Materials provides an international medium for the communication of progress in the field of functional materials (advanced materials in which composition, structure and surface are functionalised to confer specific, applications-oriented properties). The focus is on materials for biomedical, electronic, photonic and energy applications. Contributions should address the physical, chemical, or engineering sciences that underpin the design and application of these materials. The scientific and engineering aspects may include processing and structural characterisation from the micro- to nanoscale to achieve specific functionality.