References
- Yu HY, Chi CY, Dong JX, et al. 650 °C long-term structure stability study on 18Cr10NiNb heat-resistant steel. Adv Mater Res. 2012;399–401:180–184.
- Sawaragi Y, Otsuka N. ‘Development of a new 18-8 austenitic steel tube (ST3Cu) with high elevated temperature strength for fossil fired boilers’, (ed. O. Kazuhiro et al.). Sumitomo Met. 1991;43(6):24–31.
- Zhou HW, He YZ, Cui M. ‘Dependence of dynamic strain aging on strain amplitudes during the low-cycle fatigue of TP347H austenitic stainless steel at 550 °C’, (ed. C. Mian et al.). Int J Fatigue. 2013;56:1–7.10.1016/j.ijfatigue.2013.07.010
- Tohyama A, Hayakawa H, Minami Y. Development of high strength steel boiler tube (TEMPALOY AA-1). NKK Tech Rev. 2001;84:30–35.
- Kaneko K, Fukunaga T. ‘Formation of M23C6-type precipitates and chromium-depleted zones in austenite stainless steel’, (ed. K. Yamada et al.). Scr Mater. 2011;65(6):509–512.10.1016/j.scriptamat.2011.06.010
- Bai X, Pan J, Chen G, et al. Effect of high temperature aging on microstructure and mechanical properties of HR3C heat resistant steel. Mater Sci Technol. 2014;30(2):205–210.10.1179/1743284713Y.0000000347
- Bhambroo R, Roychowdhury S. ‘Effect of reverted austenite on mechanical properties of precipitation hardenable 17-4 stainless steel’, (ed. K. Vivekanand et al.). Mater Sci Eng A. 2013;568:127–133.10.1016/j.msea.2013.01.011
- Garcia EG, Sanchez MA, Romo MAR. ‘Electrochemical extraction technique and SEM study of precipitated carbides at grain boundaries in austenitic stainless steel’, (ed. M. Palomar-Pardavé et al.). ECS Trans. 2013;47(1):149–156.10.1149/04701.0149ecst