EFFECT OF HORIZONTAL MAGNETIC FIELD ON THE MICROSTRUCTURE OF DIRECTIONALLY SOLIDIFIED Ni-BASED SUPERALLOY

Acta Metall Sin

2010, Vol. 46

Issue (1): 71-76 DOI:

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EFFECT OF HORIZONTAL MAGNETIC FIELD ON THE MICROSTRUCTURE OF DIRECTIONALLY SOLIDIFIED Ni-BASED SUPERALLOY

DONG Jianwen; REN Zhongming; REN Weili; LI Xi; LI Xu

Shanghai Key Laboratory of Modern Metallurgy $\&$ Materials Processing; Shanghai University; Shanghai 200072

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DONG Jianwen REN Zhongming REN Weili LI Xi LI Xu. EFFECT OF HORIZONTAL MAGNETIC FIELD ON THE MICROSTRUCTURE OF DIRECTIONALLY SOLIDIFIED Ni-BASED SUPERALLOY. Acta Metall Sin, 2010, 46(1): 71-76.

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Abstract

Some problems still exist in the directionally solidified superalloy, such as coarse dendritic structure, thick second phase and composition segregation. Many efforts have been made to enhance the overall performance of superalloy by improving the components and processes. However, the higher alloying degree not only increases the solidification segregation, but also increases the tendency of precipitating σ-phases, Laves-phases, μ-phases and other harmful phases. Therefore, it is crucial to improve the processes in order to enhance the performance of superalloy. It was known that the magnetic field effect is very obvious during the melt solidification process, which has been realized in the directional solidification of silicon, while the research on the magnetic field effect during the superalloy solidification process is few. So it is necessary to research the effect of magnetic field on directionally solidified superalloy. In this paper, the influence of horizontal magnetic field (≦0.8 T) on the microstructures of the superalloy DZ417G during directional solidification was investigated. It was found that the magnetic field can induce the appearance of freckle-like macrosegregation and the decrease of the primary dendrite arm spacing at a low growing speed, however, with the increase of the growth speed, the effects become weak. Based on the thermoelectric magnetic convection (TEMC) induced by the magnetic field during solidification and the effect of the convection on the microstructure, the above experimental results were discussed and analyzed.

Key words: Ni-based superalloy horizontal magnetic field directional solidification thermoelectric magnetic convection

Received: 08 July 2009

ZTFLH:

TG146

Fund:

Supported by Program for Changjiang Scholars and Innovative Research Team in University No.IRT0739), Shanghai Science and Technology Committee (Nos.071005130 and 08dj1400404), Shanghai Educational Committee, and National Natural Science Foundation of China (Nos.50801045 and 50701031)

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	DONG Jian-Wen
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https://www.ams.org.cn/EN/ OR https://www.ams.org.cn/EN/Y2010/V46/I1/71

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