An Empirical Approach to Analyze Creep Rupture Behavior of P91 Steel

Muhammad Junaid Aslam; Cemil Hakan Gur

Korean Journal of Materials Research, Vol.31, No.5, 255-263, May, 2021

DOI10.3740/MRSK.2021.31.5.255 Export Citation

An Empirical Approach to Analyze Creep Rupture Behavior of P91 Steel

Muhammad Junaid Aslam^{1, †}, and Cemil Hakan Gur^{1, 2}

¹Department of Metallurgical and Materials Engineering, Middle East Technical University, Ankara, Turkey
²Welding Technology and NDT Research/Application Center, Middle East Technical University, Ankara, Turkey

E-mail:

P91 steel has been a highly researched material because of its applicability for high-temperature applications. Considerable efforts have been made to produce experimental creep data and develop models for creep life prediction. As creep tests are expensive and difficult to conduct, it is vital to develop authenticated empirical methods from experimental results that can be utilized for better understanding of creep behavior and can be incorporated into computational models for reliable prediction of creep life. In this research, a series of creep rupture tests are performed on the P91 specimens within a stress range of 155 MPa to 200 MPa and temperature range of 640 °C(913 K) to 675 °C (948 K). The microstructure, hardness, and fracture surfaces of the specimens are investigated. To analyze the results of the creep rupture tests at a macro level, a parameter called creep work density is derived. Then, the relationships between various creep parameters such as strain, strain rate, time to rupture, creep damage tolerance factor, and creep work density are investigated, and various empirical equations are obtained.

Keywords:P91 Type 2 steel;creep life;creep damage;creep work density;strain energy density

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[2] Sikka VK, Patriarca P, Analysis of weldment mechanical properties of modified 9 Cr-1Mo steel, Retrieved May 1, 1984.

[3] Spigarelli S, Int. J. Press. Vess. Pip., 101, 64 (2013)

[4] Maddi L, Barbadikar D, Sahare M, Ballal AR, Peshwe DR, Paretkar RK, Laha K, Mathew MD, Trans. Ind. Inst. Met., 68, 259 (2015)

[5] Abro MA, Lee DB, Coatings, 7, 31 (2017)

[6] Akhtar M, Khajuria A, Pandey MK, Ahmed I, Bedi R, Mater. Res. Express, 6, 12 (2019)

[7] Sanhueza JP, Rojas D, Garcia J, Melendrez MF, Toledo E, Montalba C, Alvarado MI, Jaramillo AF, Mater. Res. Express, 6, 11 (2019)

[8] Abro MA, Hahn J, Lee DB, Korean J. Met. Mater., 57, 236 (2019)

[9] Pandey C, Mater. Res. Express, 6, 9 (2019)

[10] Swei M, Sedmak AS, Petrovski B, Golubovi ZZ, Sedmak SA, Katini M, Azzab KI, Therm. Sci., 23, 1203 (2019)

[11] Vivier F, et al., Proceedings of 17th European Conference on Fracture, p. 1095, Brno, Czech Republic (2008).

[12] Panait C, Bendick W, Fuchsmann A, Gourgues-Lorenzon AF, Besson J, Int. J. Press. Vess. Pip., 87, 326 (2010)

[13] Huijun L, Mitchell D, Steel Res. Int., 84, 1302 (2013)

[14] Committee A01 of American Society for Testing and Materials, 19, 2 (2019).

[15] Yunxiang C, Yan W, Ping H, Yiyin S, Yang K, Acta Metall. Sin., 47, 1372 (2011)

[16] Besson J, Leclercq S, Gaffard V, Gourgues-Lorenzon AF, Eng. Fract. Mech., 76, 1460 (2009)

[17] Wilshire B, Scharning PJ, Mater High Temp., 25, 55 (2014)

[18] Masse T, Lejeail Y, Nucl. Eng. Des., 246, 220 (2012)

[19] Kimura K, Suzuki K, Toda Y, Kushima H, Abe F, 2, p. 43, Stuttgart, Germany (2002).

[20] Sedmak A, Swei M, Petrosvski B, Fatig. Fract. Eng. Mater. Struct., 40, 1267 (2017)

[21] Whittaker MT, Harrison WJ, Mater. High Temp., 31, 233 (2014)

[22] Wilshire B, Whittaker MT, Acta Mater., 57, 4115 (2009)

[23] Dyson F, Gibbons TB, Acta Metall, 35, 2355 (1987)

[24] Raj A, Roy N, Roy BN, Ray AK, High Temp. Mater. Processes, 34, 731 (2015)

[25] Ashby MF, Dyson BF, Proceedings of 6th International Conference on Fracture (ICF6), p. 3, New Delhi, India (1984).

[26] Aslam MJ, Gur CH, Proceeding of the 7th International Iron & Steel Symposium, p. 374, Izmir, Turkey (2019).

[27] Committee E28 of American Society for Testing and Materials, Stress-Rupture Tests of Metallic Materials (ASTM A139/ A139M), 11, 4 (2018).

[28] El-Azim MEA, Ibrahim OH, El-Desoky OE, Mater. Sci. Eng. A-Struct. Mater. Prop. Microstruct. Process., 560, 678 (2013)

[29] Nassif O, Truster TJ, Ma R, Cochran KB, Parks DM, Messner MC, Sham TL, Model. Simulat. Mater. Sci. Eng., 27 (2019)

[30] Choudhary BK, Edwin IS, J. Nucl. Mater., 412, 82 (2011)

[31] Gaffard V, PhD Thesis, p. 161, Paris School of Mines, Paris (2004).

[32] Kimura K, Kushima H, Sawada K, Mater. Sci. Eng. A-Struct. Mater. Prop. Microstruct. Process., 510-511, 58 (2009)

[33] Shrestha T, Basirat M, Charit I, Potirniche GP, Rink KK, Mater. Sci. Eng. A-Struct. Mater. Prop. Microstruct. Process., 565, 382 (2013)

[34] An L, et al., Proceeding of the 10th International Conference on Science Computing, p. 184, Las Vegas, USA (2013).

[35] Choudhary BK, Phaniraj C, Raj B, Tran. Ind. Inst. Metals, 63, 675 (2010)