• Title/Summary/Keyword: Inconel 706

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Analysis of Mechanical Properties and Microstructure of Inconel 706 Alloy using Rotary Forging (회전단조에 따른 Inconel 706 합금의 미세조직 및 기계적 특성 분석)

  • H.G. Kim;S.W. Jo;E.Y. Yoon;Y.S. Lee;Y.Y. Woo
    • Transactions of Materials Processing
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    • v.32 no.3
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    • pp.145-152
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    • 2023
  • The Inconel 706 alloy is a nickel-based super alloy and requires a large load for hot forging due to its excellent mechanical properties at high temperature. Rotary forging process is an innovative metal forging process where workpiece is gradually deformed by the revolving conical upper die with an inclination angle. This process allows that the workpiece is partially in contact with an upper die during the process so that the press force is considerably lower compared with the conventional upsetting process. In this study, experiments of rotary forging process and conventional upsetting process for cylindrical parts using Inconel 706 where conducted to investigate the formability of rotary forging process. And microstructure analysis and mechanical properties of Inconel 706 were performed to investigate the effect of rotary forging process on the material property.

Analysis of Microstructural Refinement for Inconel 706 during Hot Forging Process through Reheating and Strain (Inconel 706의 열간단조 공정 중 재가열과 변형양에 따른 결정립 미세화에 대한 분석)

  • S. G. Seong;H. J. Kang;Y. S. Lee;S. Y. Lee;U. J. Lee;H. I. Jae;J. H. Shin;E. Y. Yoon
    • Transactions of Materials Processing
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    • v.32 no.5
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    • pp.239-246
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    • 2023
  • To reduce the forming load due to the temperature drop, during the hot forging process, a reheating hot forging process design is required that to repeat heating and forging. However, if the critical strain required for recrystallization is not induced during forging and grain growth becomes dominant due to the reduction in dislocation density due to repeated heating, the mechanical properties may deteriorate. Therefore, in this study, Inconel 706 alloy was applied, and the grain refinement behavior was comparatively analyzed according to the number of reheating times and effective strain during reheating hot forging process. Reheating was carried out with a total compression rate of 40% up to 4 times. The Inconel 706 compression test specimens heated once showed finer grains as the effective strain increased due to the dynamic recrystallization phenomenon. However, as the number of heating increases, grain refinement was observed even in a low effective strain distribution of 0.43 due to static recrystallization during reheating. Moreover, grain growth occurs at a relatively low effective strain of 0.43 when the number of reheating is four or more. Therefore, it was effective to apply an effective strain of 0.43 or more during hot forging to Inconel 706 in order to induce crystallization through grain refinement and improve the properties of forged products. In addition, we could notice that up to three reheating times condition was appropriate to prevent grain growth and maintain fine grain size.

Heat Source Modeling and Study on the Effect of Thickness on Residual Stress Distribution in Electron Beam Welding

  • Rajabi, Leila;Ghoreishi, Majid
    • Journal of Welding and Joining
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    • v.35 no.1
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    • pp.49-54
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    • 2017
  • In this study, the volumetric heat source in electron beam welding (EBW) is modeled through finite element method taking advantage of ABAQUS software package. Since this welding method is being applied in plates with different thicknesses and also considering that residual stresses reduce the strength of these weldments, the effect of thickness in the distribution and magnitude of residual stresses after welding is studied. Regarding the vast application of Inconel 706 super-alloy in aerospace industries, this material was selected in the current research. In order to validate the finite element model, the obtained results were compared to those of other researchers in this area, and good agreement was observed. The simulation results revealed that increase in the plate thickness leads to increase in the residual stresses. In addition heat treatment in the base metal (before welding) increases the residual stresses significantly.