Microstructural stability and mechanical properties of a boron modified Ni–Fe based superalloy for steam boiler applications

Ni–Fe based superalloys are being considered as boiler materials in 700°C advanced ultra-supercritical (A-USC) coal fired power plants due to their excellent oxidation and hot corrosion resistance, outstanding workability and low cost. In this paper, the microstructural stability and mechanical prop...

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Published inMaterials science & engineering. A, Structural materials : properties, microstructure and processing Vol. 639; pp. 380 - 388
Main Authors Wang, Changshuai, Guo, YongAn, Guo, Jianting, Zhou, Lanzhang
Format Journal Article
LanguageEnglish
Published Elsevier B.V 01.07.2015
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Summary:Ni–Fe based superalloys are being considered as boiler materials in 700°C advanced ultra-supercritical (A-USC) coal fired power plants due to their excellent oxidation and hot corrosion resistance, outstanding workability and low cost. In this paper, the microstructural stability and mechanical properties of a boron (B) modified Ni–Fe based superalloy designed for 700°C A-USC during thermal exposure at 650–750°C for up to 5000h were investigated. The results show that adding boron has no apparent influence on the major precipitates, including spherical γ′ and blocky MC. However, the amount of M23C6 decreases markedly after standard heat treatment. During long-term thermal exposure, the addition of boron has no influence on γ′ coarsening, η phase precipitation and primary MC degeneration, but decreases the growth rate of M23C6 along grain boundary. The stress rupture life and ductility are obviously improved after the addition of B. Meanwhile, the yield strength of B-doped alloy almost keeps the same level as that without boron addition. The fracture surface characterization exhibits that the dimples increase significantly after adding boron. During long-term thermal exposure, the elongation of the alloy with B addition increases slightly, but, for the alloy without B addition, the elongation obviously increases. The improvement of the stress rupture life and ductility can be attributed to the increase of grain boundary strength and the optimization of M23C6 carbide distribution at grain boundary.
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ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2015.05.026