Anisotropy in Hydrogen Embrittlement Resistance of Drawn Pearlitic Steel Investigated by <i>in-situ</i> Microbending Test during Cathodic Hydrogen Charging

DOI DOI Web Site Web Site Web Site 9 Citations 24 References Open Access
  • Tomatsu Kota
    Steel Research Laboratories, Technical Research & Development Bureau, Nippon Steel & Sumitomo Metal Corporation
  • Amino Takafumi
    Advanced Technology Research Laboratories, Technical Research & Development Bureau, Nippon Steel & Sumitomo Metal Corporation
  • Chida Tetsushi
    Steel Research Laboratories, Technical Research & Development Bureau, Nippon Steel & Sumitomo Metal Corporation
  • Uji Shunya
    Advanced Technology Research Laboratories, Technical Research & Development Bureau, Nippon Steel & Sumitomo Metal Corporation
  • Okonogi Makoto
    Kimitsu R&D Lab., Technical Research & Development Bureau, Nippon Steel & Sumitomo Metal Corporation
  • Kawata Hikaru
    Advanced Technology Research Laboratories, Technical Research & Development Bureau, Nippon Steel & Sumitomo Metal Corporation
  • Omura Tomohiko
    Steel Research Laboratories, Technical Research & Development Bureau, Nippon Steel & Sumitomo Metal Corporation
  • Maruyama Naoki
    Advanced Technology Research Laboratories, Technical Research & Development Bureau, Nippon Steel & Sumitomo Metal Corporation
  • Nishiyama Yoshitaka
    Steel Research Laboratories, Technical Research & Development Bureau, Nippon Steel & Sumitomo Metal Corporation

Bibliographic Information

Other Title
  • 電解水素チャージ下のその場微小曲げ試験法による伸線パーライト鋼の水素脆化の異方性評価
  • デンカイ スイソ チャージ カ ノ ソノ バ ビショウ マゲ シケンホウ ニ ヨル シンセン パーライトコウ ノ スイソゼイカ ノ イホウセイ ヒョウカ

Search this article

Description

<p>To investigate causes of superior hydrogen embrittlement resistance of drawn pearlitic steel, notched microcantilevers with different notch orientations with respect to the lamellar interface were fabricated by focused ion beam, and microbending tests were conducted in air and during cathodic hydrogen charging by electrochemical nanoindentation. In air, indentation load monotonically increased with increase in indentation displacement, and no crack appeared for any notch orientations. During hydrogen charging, indentation load declined, and a crack appeared. The load reduction with respect to the displacement was larger, and the crack was deeper for the notch parallel to the lamellar interface than that normal to the lamellar interface. Furthermore, stationary cracks in the microcantilevers were observed by scanning electron microscopy and scanning transmission electron microscopy. For the notch parallel to the lamellar interface, a sharp long crack was identified along the lamellar interface. The crack stopped at the position where the cementite lamellae are disconnected. In lattice images, cementite was identified in one side of the crack, and ferrite in another side of the same crack. On the other hand, for the notch normal to the lamellar interface, a blunt short crack was identified. Thus, it was concluded that the ferrite-cementite interface is a preferential crack path, and hydrogen embrittlement resistance in the direction parallel to the lamellar interface is superior to that normal to the lamellar interface. The present results also indicate that directional lamellar alignment of the drawn pearlitic steel suppresses crack propagation in the radial direction of the drawn wire, improving the hydrogen embrittlement resistance in the drawing direction.</p>

Journal

  • ISIJ International

    ISIJ International 58 (2), 340-348, 2018

    The Iron and Steel Institute of Japan

Citations (9)*help

See more

References(24)*help

See more

Keywords

Details 詳細情報について

Report a problem

Back to top