References
- Brinkman CR, Alexander DJ, Maziasz PJ. Modified 9Cr-1Mo steel for advanced steam generator applications; Proc. of ASME/IEEE Power Gen. Conf. 1990; Boston (USA).
- Abson DJ, Rothwell JS. Review of type IV cracking of weldments in 9-12% cr creep strength enhanced ferritic steels. International Materials Reviews. 2013;58(8):437–473. doi: 10.1179/1743280412Y.0000000016
- Francis JA, Mazur W, HKDH B. Review type IV cracking in ferritic power plant steels. Materials Science And Technology. 2006;22(12):1387–1395. doi: 10.1179/174328406X148778
- Shibli IA, Holdsworth SR, Merckling G. In-service type IV cracking in a modified 9Cr (Grade 91) header. In: Proc. ECCC creep conf. London (UK): DEStech publications.: 2005. pp. 563–572.
- Ellis FV, Viswanathan R. Review of type IV cracking. In: Proc. Of the 1998 ASME/JSME joint pressure vessels and piping conf. On fitness-for-service evaluations in petroleum and fossil power plants. Vol. 380. San Diego (USA): PVP; 1980. pp. 59–76.
- Yaguchi M. Remaining creep life prediction method for in-service boiler pipe weldment using small scale specimen. Mat Performance Characterization. 2022;11(3):402–423. doi: 10.1520/MPC20210104
- Yaguchi M, Kanai M, Komazaki S, et al. Assessment of effect of miniature sample scoop on creep life of 9Cr steel piping test. Trans JSME. 2020;86(883):1–17. doi: 10.12299/transjsme.19-00362
- Komazaki S, Obata K, Yaguchi, M, et al. Creep property assessment of 9Cr steel boiler piping by small punch test. Journal Of System And Management Sciences. 2021;70(2):125–132. doi: 10.2472/jsms.70.125
- Dymáček P, Jarý M, Dobeš F, et al. Tensile and creep testing of Sanicro 25 using miniature specimens. Materials. 2018;11(1):142. doi: 10.3390/ma11010142
- Tsurui M, Hisaka C, Takahashi, K, et al. Optimization and verification of ultra-miniature specimen for evaluating creep property of in-service component material under uniaxial loading. Mat Performance Characterization. 2022;11(3):385–400. doi: 10.1520/MPC20210106
- Hart RV. Assessment of remaining creep life using accelerated stress-rupture tests. Mechanical Engineering Technology. 1976;3(1):1–7. doi: 10.1179/030716976803391746
- Goldhoff RM. Towards the standardization of time-temperature parameter usage in elevated temperature data analysis. J Test Eval. 1974;2(5):387–424. doi: 10.1520/JTE10123J
- Haque MS, Stewart CM. Metamodeling time-temperature creep parameters. Journal Of Pressure Vessel Technology. 2020;142142(33):14. doi: 10.1115/1.4045887
- Larson FR, Miller J. A time temperature relationship for rupture and creep stress. Trans ASME. 1952;74(5):765–771. doi: 10.1115/1.4015909
- Kimura K, Yaguchi M. Re-evaluation of long-term creep strength of base metal of ASME Grade 91 type steel. In: Proc the ASME 2016 pressure vessels and piping conf. Vancouver (Canada); 2016pp. VP2016–63355. 10.1115/PVP2016-63355
- Yaguchi M, Nakamura K, Nakahashi S. Re-evaluation of long-term creep strength of welded joint of ASME Grade 91 type steel; Proc the ASME 2016 pressure vessels and piping conf. Vancouver (Canada): 2016. pp. VP2016–63316. doi:10.1115/PVP2016-63316.
- Maruyama K, Nakamura J, Yoshimi K. Prediction of long-term creep rupture life of Grade 122 steel by multiregion analysis. Journal Of Pressure Vessel Technology. 2015;137(2):1–5. doi: 10.1115/1.4028203
- Manson SS, Haferd AM. A linear time temperature relation for extrapolation of creep and stress-rupture data. Technical Note No. 2890: National Advisory Committee for Aeronautics; 1953. Washington, DC, USA.
- Monkman FC, Grant NJ. An empirical relationship between rupture life and minimum creep rate in creep-rupture tests. Proc The ASTM. 1956;56:593–620.
- Nitta A. Life assessment of fossil power plants. Journal Of The Japan Society Of Mechanical Engineers. 1995;98(915):117–120. doi: 10.1299/jsmemag.98.915_117