Comparison of inclusions in A286 precipitation hardening stainless steel with different smelting processes
WEI Liangliang1, SUN Yongqing*2, GUAN Yulong3, WANG Changjun2, LIU Zhenbao2
1. Aerospace Precision Products Inc., China Aerospace Science & Industry Corp., Tianjin 300308, China; 2. Special Steel Institute, Central Iron & Steel Research Institute Co., Ltd., Beijing 100081, China; 3. Technical Center, Fushun Special Steel Co., Ltd., Fushun 113000, China
Abstract:A286 austenitic precipitation hardening stainless steel (also known as GH2132 superalloy in China) is a widely used high-temperature fastener material with service temperature below 650 ℃. In the actual production and use of this material, two smelting production processes, including electric arc furnace + ladle furnace + electro slag remelting (EAF+LF+ESR) and vacuum induction melting + vacuum arc remelting (VIM+VAR), have been used. So far, no systematic comparative studies on A286 stainless steel produced by these two processes have been carried out in China. The A286 test steel samples produced by the above two smelting processes were taken as the research object. The differences and characteristics of the two test steels in terms of structure, type, composition, particle size, distribution and morphology of non-metallic inclusions were compared and studied using Aspex inclusion analyzer, scanning electron microscope (SEM) and other test tools. The results showed that the amount and area of inclusions in EAF + LF + ESR steel were more than 3 times of those in VIM + VAR steel. The inclusions in both test steels were composed of TiC, TiN, Ti (C, N), etc. The inclusions in the former sample were mainly in the form of TiN inclusions, and most of them were large-size chain like with large aspect ratio and complex shape, which were unfavorable to the mechanical properties and corrosion resistance of the material at room temperature. The inclusions in the latter sample were mainly in the form of TiC with small size and simple shape. By controlling the N mass fraction in A286 test steel below 0.001%, the amount and size of Ti containing inclusions could be controlled at a low level. Due to the characteristics of EAF + LF + ESR process, the content of P in the test steel was high, which was about 10 times of that in VIM+VAR test steel. According to the data, it may be beneficial to the high temperature creep property of A286 stainless steel. The results of the study could provide technical reference for the use of A286 stainless steel in different environments and service requirements.
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