Microstructure formation in high-Strength ductility high oxygen concentration additively manufactured Ti alloys

• Project/Area Number: 20K05155
• Research Category: Grant-in-Aid for Scientific Research (C)
• Allocation Type: Multi-year Fund
• Section: 一般
• Review Section: Basic Section 26050:Material processing and microstructure control-related
• Research Institution: Osaka University
• Principal Investigator: Umeda Junko 大阪大学, 接合科学研究所, 教授 (50345162)
• Project Period (FY): 2020-04-01 – 2024-03-31
• Project Status: Completed (Fiscal Year 2023)
• Budget Amount: ¥4,290,000 (Direct Cost: ¥3,300,000、Indirect Cost: ¥990,000); Fiscal Year 2023: ¥910,000 (Direct Cost: ¥700,000、Indirect Cost: ¥210,000); Fiscal Year 2022: ¥1,040,000 (Direct Cost: ¥800,000、Indirect Cost: ¥240,000); Fiscal Year 2021: ¥1,170,000 (Direct Cost: ¥900,000、Indirect Cost: ¥270,000); Fiscal Year 2020: ¥1,170,000 (Direct Cost: ¥900,000、Indirect Cost: ¥270,000)
• Keywords: チタン / 積層造形体

Outline of Research at the Start

選択的レーザ溶融法(SLM)により作製した高濃度酸素（α-Ti相安定化元素）含有チタン積層造形体において，固溶強化による顕著な強度向上と同時に高延性を有する新奇な力学挙動の解明を目的に，急速凝固・冷却過程で形成される特異な組織形態（acicular α/α’マルテンサイト相）と結晶配向性および酸素固溶分布に着目し，これらの組織構造因子と変形機構の関係を解き明かす．その結果に基づき，延性低下が著しいチタン積層造形体において，高強度と高延性の同時発現を可能とする新規な材料・プロセス設計原理の構築を目指す．

Outline of Final Research Achievements

Focusing on oxygen as a stabilizing element of the α-phase, which was considered to be a negative material factor, it was clarified that a small amount of oxygen contributes to the formation of a specific crystal structure through microscopic structural analysis of the behavior of oxygen atoms during the layer fabrication process. The dissociated oxygen atoms after decomposition of TiO2 particles, which are the source of oxygen, were found to solid-solubilize into α-Ti grains, and the transformation from coarse columnar grains to fine needle-like martensite phase was observed.

Academic Significance and Societal Importance of the Research Achievements

チタン材料では，酸素成分の粒界偏析に起因した脆化現象が報告されており，特に規格上限値を超える高濃度では，伸び値が激減する．しかし，酸素は本当に負の因子であるのか？と問い，レアメタルの代替物質として酸素に着目した．積層造形時の溶融・超急冷凝固過程での酸素原子の振舞いを理解し，チタン材の延性低下を招く結晶粒界近傍での酸素濃化による化合物相の形成を抑制し，酸素元素をα-Ti内に均一固溶することで結晶粒径や集合組織を制御することで，高強度と高延性の同時発現が可能であることを明らかにした．その結果，チタン合金の高強度化に必須であるレアメタル使用撤廃の可能性を示したことは学術的な意義であると考える．

Research Products

• [Int'l Joint Research] Chinese Academy of Sciences/Xi’an University of Technology(中国)
• [Int'l Joint Research] Chinese Academy of Sciences/Xi’an University of Technology(中国)
• [Journal Article] Mechanical Functionalization of Additively Manufactured Titanium with Light Elements (2024)
  • Author(s): 近藤勝義, 市川絵理, A. Issariyapat, 梅田純子
  • Journal Title: Journal of the Japan Society of Powder and Powder Metallurgy Volume: 71 Issue: 12 Pages: 586-595
  • DOI: 10.2497/jjspm.23-00031
  • ISSN: 0532-8799, 1880-9014
  • Year and Date: 2024-12-15
  • Peer Reviewed / Open Access
• [Journal Article] Tribological Behavior of Titanium-Sintered Composites with Ring-Shaped TiN Dispersoids (2022)
  • Author(s): 21.J. Umeda, H. Fujii, R. Takizawa, T. Teramae, A. Issariyapat, S. Kariya, Y. Yang, S. Li, K. Kondoh
  • Journal Title: Lubricants Volume: 10 Issue: 10 Pages: 254-254
  • DOI: 10.3390/lubricants10100254
  • Peer Reviewed / Open Access / Int'l Joint Research
• [Presentation] 軽元素を利用したチタン積層造形材の力学機能化 (2023)
  • Author(s): 近藤勝義, A. Issariyapat, 梅田純子，市川絵理
  • Organizer: 粉体粉末冶金協会2023年度春季大会
• [Presentation] High Strength Ti-Zr Alloys With Balanced Ductility Fabricated By Powder Metallurgy And Additive Manufacturing Routes (2022)
  • Author(s): Katusyoshi Kondoh
  • Organizer: PM2022
  • Int'l Joint Research / Invited
• [Presentation] SLM Induced Carbon Solid Solution in Titanium Alloys (2021)
  • Author(s): J. E. Peterson, E. Ichikawa, J. Umeda, K. Kondoh
  • Organizer: 粉末冶金協会2021年度秋季大会
• [Presentation] Additively Manufactured High－Performance Commercially Pure Titanium Strengthened with Ubiquitous Light Elements (2021)
  • Author(s): A. Issariyapat, J. Umeda, K. Kondoh
  • Organizer: LightMAT 2021
  • Int'l Joint Research