Kota Sawada
(Research Center for Structural Materials/Materials Evaluation Field/Creep Property Group, National Institute for Materials Science
)
;
Yasushi Taniuchi
(Research Network and Facility Services Division/Materials Data Platform/Creep Data Unit, National Institute for Materials Science)
;
Takehiro Nojima
(Research Network and Facility Services Division/Materials Data Platform/Creep Data Unit, National Institute for Materials Science)
;
Kazuhiro Kimura
(Research Center for Structural Materials, National Institute for Materials Science)
;
Takahiro Kimura
(IHI Corporation)
;
Kyohei Nomura
(IHI Corporation)
;
Noriko Saito
(IHI Corporation)
;
Akira Morita
(The Kansai Electric Power)
;
Hiroyuki Hayakawa
(Kyushu Electric Power Co., Inc.)
;
Takao Sugiuchi
(The Chugoku Electric Power)
;
Kazushige Ohbitsu
(The Chugoku Electric Power)
;
Masatsugu Yaguchi
(Central Research Institute of Electric Power Industry (CRIEPI)/電力中央研究所)
;
Koju Nishizawa
(Tokyo Electric Power Company Holdings)
;
Hiroshi Ozaki
(Tokyo Electric Power Company Holdings)
;
Hayato Fukunishi
(Tokyo Electric Power Company Holdings)
;
Kouji Ohi
(Tokyo Power Technology)
;
Tomoya Nishioka
(Nippon Steel Technology)
;
Naoya Emi
(Nippon Steel Technology)
;
Hirokazu Okada
(Nippon Steel Technology)
;
Nobuyoshi Komai
(Mitsubishi Heavy Industries, Ltd.)
;
Kyohei Hayashi
(Mitsubishi Heavy Industries, Ltd.)
;
Kimihiko Tominaga
(Mitsubishi Heavy Industries, Ltd.)
コレクション
引用
説明:
(abstract)Nondestructive phased array ultrasonic testing (PAUT), eddy current testing with a high-temperature superconductor, direct current, and superconducting quantum interference device (ECT• HTS-dc-SQUID) and observation of a replica were conducted to detect creep damage of Grade 91 steel welds. Creep strain measurements were also performed for residual life assessment of the welds. PAUT showed that the threshold of creep damage detection was between 60% and 80% of the creep life. In the case of ECT• HTS-dc-SQUID, the threshold was between 80% and 90% of the creep life. Creep voids were observed on the replica just before creep rupture. A capacitive strain sensor, laser displacement meter, and SPICA strain measurement were used to detect changes in the strain during creep exposure. The capacitive strain sensor can continuously measure the strain during creep exposure. The laser displacement meter was used after creep interruption. Creep curves obtained by the capacitive strain sensor and laser displacement meter w
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Copyright © 2024 ASM International. All rights reserved.
Copyright ASM International. This paper was published in Advances in Materials for Power Plants, 2024 Conference Proceedings, and is made available as an electronic reprint with the permission of ASM International. One print or electronic copy may be made for personal use only. Systematic or multiple reproduction, distribution to multiple locations via electronic or other means, duplications of any material in this article for a fee or for commercial purposes, or modification of the content of this article is prohibited.
キーワード: Gr.91 steel welds, creep, damage, nondestructive evaluation
刊行年月日: 2024-10-15
出版者: ASM International
掲載誌:
- Advances in Materials for Power Plants p. 960-968 am-epri-2024p0960
会議:
研究助成金:
原稿種別: 出版者版 (Version of record)
MDR DOI:
公開URL: https://doi.org/10.31399/asm.cp.am-epri-2024p0960
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更新時刻: 2024-11-06 16:31:04 +0900
MDRでの公開時刻: 2024-11-06 16:31:04 +0900
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