Change in Electrochemical Property of 12%Cr Ferritic Steel in 1M-KOH Solution Due to Creep

Abe, Yousuke; Komazaki, Shin‐ichi; Mitsueda, Toshiki; Kohno, Yutaka

doi:10.4028/www.scientific.net/amr.89-91.1

Cited by 3 publications

(1 citation statement)

References 10 publications

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“…In this case, it was seen that the peak current density I p for Gr.92 increased with thermal aging and creep, and corresponded to the selective dissolution volume of M 23 C 6 and Laves phase. Figure 13 [44] shows electrochemical measurement results for Gr.122 under similar test conditions indicating two peak current densities at around À 250 mV and þ 250 mV, respectively, and increase of these peaks in terms of creep life fraction. However there is no effect of stress for the I p1 which should be the thermally dominant factor, in contrast the effect of stress is significantly observed for I p2 if the data are compared between grip portion and gauge portion.…”

Section: Electrochemical Methodsmentioning

confidence: 97%

Advanced technology in creep life prediction and damage evaluation for creep strength enhanced ferritic steels

Masuyama¹

2011

Materials at High Temperatures

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Creep damage mechanisms of recently developed boiler and steam-turbine steels are not well clarified, however, creep life prediction technology for such creep strength enhanced ferritic steels, grades 91, 92 122, etc. with tempered martensitic structure including welds has been strongly demanded by power plant operators and equipment manufacturers. In this paper, the technologies related to the creep life prediction and damage evaluation for creep strength enhanced ferritic steels being studied from the various aspects in Japan will be surveyed and presented. The creep life prediction of this type of steel must be grounded on the findings on microstructural degradation and creep softening in martensitic structure composed of very fine martensite lath, block, packet and prior austenite grains, and precipitation and dislocation structures. Physical properties response to the creep degradation and measurement and detection of localized creep damageystrength would be useful tools to develop diagnostic techniques for life prediction of creep strength enhanced ferritic steels. Other important techniques to support the creep life prediction based on creep-strainyrupture data are creep modelling and data analysis which have been successfully investigated to date.

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Section: Electrochemical Methodsmentioning

confidence: 97%

Advanced technology in creep life prediction and damage evaluation for creep strength enhanced ferritic steels

Masuyama¹

2011

Materials at High Temperatures

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Evaluation of microstructure degradation during creep of P91 steel using electrochemical detection technique

Zhu

Liu

Fan

et al. 2023

Materials Today Communications

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Characterization of Creep Degradation of Modified 9Cr-1Mo Steel Using Magnetic Measurement

Zhu

Liu

Fan

et al. 2020

Journal of Testing and Evaluation

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Microstructure evolution during the creep of a modified 9Cr-1Mo heat-resistant steel was characterized by a nondestructive method of magnetic hysteresis loop (MHL) technique at 893 K (620°C). Two parameters of coercivity and remanence were introduced to evaluate the magnetic properties of interrupted crept specimens. Experimental results suggested that both the parameters were significantly sensitive to the microstructures, such as dislocations, precipitates, and microcracks. During the primary and secondary creep stage, the coercivity and remanence increased with creep time, which was mainly attributed to the increase in pinned dislocations and number density of precipitates. However, because of the coarsening of M23C6 carbides and presence of a demagnetizing field induced by the nonmagnetic precipitates and microcracks, the coercivity and remanence decreased during the tertiary creep stage. It suggested that the MHL technique has great potential to evaluate the microstructure evolution during creep degradation of heat-resistant steels.

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Change in Electrochemical Property of 12%Cr Ferritic Steel in 1M-KOH Solution Due to Creep

Cited by 3 publications

References 10 publications

Advanced technology in creep life prediction and damage evaluation for creep strength enhanced ferritic steels

Advanced technology in creep life prediction and damage evaluation for creep strength enhanced ferritic steels

Evaluation of microstructure degradation during creep of P91 steel using electrochemical detection technique

Characterization of Creep Degradation of Modified 9Cr-1Mo Steel Using Magnetic Measurement

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