Metal Fatigue Crack Healing by DC Pulse and High Frequency Electronic Wind Control

• Project/Area Number: 22K18761
• Research Category: Grant-in-Aid for Challenging Research (Exploratory)
• Allocation Type: Multi-year Fund
• Review Section: Medium-sized Section 18:Mechanics of materials, production engineering, design engineering, and related fields
• Research Institution: Waseda University
• Principal Investigator: Hosoi Atsushi 早稲田大学, 理工学術院, 教授 (60424800)
• Project Period (FY): 2022-06-30 – 2024-03-31
• Project Status: Completed (Fiscal Year 2023)
• Budget Amount: ¥6,370,000 (Direct Cost: ¥4,900,000、Indirect Cost: ¥1,470,000); Fiscal Year 2023: ¥1,950,000 (Direct Cost: ¥1,500,000、Indirect Cost: ¥450,000); Fiscal Year 2022: ¥4,420,000 (Direct Cost: ¥3,400,000、Indirect Cost: ¥1,020,000)
• Keywords: 疲労き裂治癒 / 高密度パルス電流 / 損傷治癒 / 疲労 / き裂治癒

Outline of Research at the Start

金属疲労はき裂の「発生」と「進展」の2つの過程を経て破壊に至る。本研究では高密度電流場の制御によって、この2つの過程の疲労損傷を治癒する技術を独自に構築し、その治癒機構を力学的に評価する。

Outline of Final Research Achievements

The purpose of this study is to experimentally and analytically clarify the crack closure mechanism and damage recovery before crack initiation in high-density pulsed current. The fatigue crack closure mechanism in high-density pulsed currents is that the current bypassing the crack densifies at the crack tip, and compressive thermal stresses act on the crack tip. The yield stress is lowered under high temperature environment, resulting in plastic deformation, and after cooling, tensile residual stress is generated. Balanced compressive stresses act in the vicinity of the crack. Localized bending deformation and crack closure are observed. On the other hand, it was also found that the growth of the slip zone was suppressed by applying a high-density pulsed current before the crack initiation.

Academic Significance and Societal Importance of the Research Achievements

機械や構造物には寿命が存在する．金属材料の疲労破壊を遅延させる技術としては，ショットピーニングや高周波焼き入れ等の手法が挙げられてきた．しかしこれらの手法ではき裂や転位等の損傷自体を修復することはできない．根本的に疲労損傷部分を修復することでインフラの長寿命化，安全性の向上を低コストで行う技術が求められており，これらの技術は脱炭素社会や持続可能な社会の実現につながる．

Research Products

• [Journal Article] Electropulsing suppresses extrusion growth in polycrystalline copper subjected to fatigue loading (2023)
  • Author(s): SASA Haruka、SHIN Jeehwan、HOSOI Atsushi、KITANO Makoto、KAWADA Hiroyuki
  • Journal Title: Mechanical Engineering Journal Volume: 10 Issue: 3 Pages: 23-00027-23-00027
  • DOI: 10.1299/mej.23-00027
  • ISSN: 2187-9745
  • Peer Reviewed
• [Presentation] 近接電極を用いた高密度パルス電流印加による熱間金型用合金鋼の疲労き裂治癒 (2024)
  • Author(s): 中山翔太，菅野雄太郎，上林友人，細井厚志，古川雄一，冨田高嗣，川田宏之
  • Organizer: 日本機械学会関東支部第30期総会・講演会
• [Presentation] 高密度電流印加による熱間金型用合金鋼の疲労き裂治癒 (2023)
  • Author(s): 中山翔太，菅野雄太郎，上林友人，細井厚志，古川雄一，冨田高嗣，川田宏之
  • Organizer: 第30回機械材料・材料加工技術講演会(M&P2023)
• [Presentation] 固執すべり帯の成長抑制におけるパルス電流密度の影響 (2023)
  • Author(s): 佐々春佳，シンジファン，細井厚志，川田宏之
  • Organizer: 日本機械学会関東支部第29期総会・講演会
• [Presentation] Suppression of persistent slip band growth in polycrystalline copper by applying high-density electropulsing and its evaluation (2022)
  • Author(s): Haruka Sasa, Jeehwan Shin, Atsushi Hosoi, Makoto Kitano, Hiroyuki Kawada
  • Organizer: 17th Asia-Pacific Conference on Failure and Strength and 13th Conference on Structural Integrity and Failure
  • Int'l Joint Research
• [Presentation] Evaluation of fatigue crack closure phenomena in steel by applying high-density pulse current (2022)
  • Author(s): Yoshitaka Iwase, Shota Nakayama, Yutaro Sugeno, Atsushi Hosoi, Makoto Kitano, Hiroyuki Kawada,
  • Organizer: 17th Asia-Pacific Conference on Failure and Strength and 13th Conference on Structural Integrity and Failure
  • Int'l Joint Research