Several methods of estimating strain range at a structural discontinuity have been developed in order to assess component reliability. In a component design at elevated temperature, estimation of strain range is required to evaluate the fatigue and creep-fatigue damage. Therefore, estimation of strain range is one of the most important issues when evaluating the integrity of a component during its lifetimes. To verify the methods of estimating strain range for discontinuous structures, low cycle fatigue tests were carried out with notched specimens. All the specimens were made of Mod.9Cr-1Mo steel, because it is a candidate material for a primary and secondary heat transport system components of Japan Sodium-cooled Fast Reactor (JSFR). Displacement control fatigue tests and thermal fatigue tests were performed by ordinary uniaxial push–pull test machine and equipment generating the thermal gradient in the notched plate by induction heating. Several notch radii were employed to vary the stress concentration level in both kinds of tests. Crack initiation and propagation process during the tests were observed by a digital microscope and the replica method to define the failure cycles. Elastic and inelastic finite element analyses were also performed to estimate strain range for predicting fatigue life. Then, these predictions were compared with the test results. Several methods such as stress redistribution locus (SRL) method, simple elastic follow-up (SEF) method, Neuber's law, and the procedures employed by elevated temperature design codes were applied. Through these comparisons, the applicability and conservativeness of these strain range estimation methods, which is the basis of the fatigue and creep-fatigue life prediction, are discussed.
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December 2012
Research-Article
Verification of the Estimation Methods of Strain Range in Notched Specimens Made of Mod.9Cr-1Mo Steel
Masanori Ando,
Masanori Ando
Japan Atomic Energy Agency
,4002 Narita, Oarai
,Ibaraki 311-1393
, Japan
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Yuichi Hirose,
Yuichi Hirose
Mitsubishi heavy industry, Ltd.
,5-717-1 Fukahori, Nagasaki
,Nagasaki 851-0392
, Japan
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Shingo Date,
Shingo Date
Mitsubishi heavy industry, Ltd.
,2-1-1 Shinhama, Arai, Takasago
,Hyogo 676-8686
, Japan
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Sota Watanabe,
Sota Watanabe
Mitsubishi heavy industry, Ltd.
,1-1-1 Wadamisaki, Hyogo, Kobe
,Hyogo 652-8585
, Japan
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Yasuhiro Enuma,
Yasuhiro Enuma
Mitsubishi FBR systems
,2-34-17, Jingumae, Shibuya
,Tokyo 150-0001
, Japan
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Nobuchika Kawasaki
Nobuchika Kawasaki
Japan Atomic Energy Agency
,4002 Narita, Oarai
,Ibaraki 311-1393
, Japan
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Masanori Ando
Japan Atomic Energy Agency
,4002 Narita, Oarai
,Ibaraki 311-1393
, Japan
Yuichi Hirose
Mitsubishi heavy industry, Ltd.
,5-717-1 Fukahori, Nagasaki
,Nagasaki 851-0392
, Japan
Shingo Date
Mitsubishi heavy industry, Ltd.
,2-1-1 Shinhama, Arai, Takasago
,Hyogo 676-8686
, Japan
Sota Watanabe
Mitsubishi heavy industry, Ltd.
,1-1-1 Wadamisaki, Hyogo, Kobe
,Hyogo 652-8585
, Japan
Yasuhiro Enuma
Mitsubishi FBR systems
,2-34-17, Jingumae, Shibuya
,Tokyo 150-0001
, Japan
Nobuchika Kawasaki
Japan Atomic Energy Agency
,4002 Narita, Oarai
,Ibaraki 311-1393
, Japan
Contributed by the Pressure Vessel and Piping Division of ASME for publication in the JOURNALOF PRESSURE VESSEL TECHNOLOGY. Manuscript received March 28, 2011; final manuscript received March 22, 2012; published online October 18, 2012. Assoc. Editor: Osamu Watanabe.
J. Pressure Vessel Technol. Dec 2012, 134(6): 061403 (12 pages)
Published Online: October 18, 2012
Article history
Received:
March 28, 2011
Revision Received:
March 22, 2012
Citation
Ando, M., Hirose, Y., Date, S., Watanabe, S., Enuma, Y., and Kawasaki, N. (October 18, 2012). "Verification of the Estimation Methods of Strain Range in Notched Specimens Made of Mod.9Cr-1Mo Steel." ASME. J. Pressure Vessel Technol. December 2012; 134(6): 061403. https://doi.org/10.1115/1.4006902
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