Effect of Crystallographic Orientation on Fracture Mechanism of Ni-Base Superalloy

Chang-Suk Han; Sang-Yeon Lim

Korean Journal of Materials Research, Vol.25, No.11, 630-635, November, 2015

DOI10.3740/MRSK.2015.25.11.630 Export Citation

Effect of Crystallographic Orientation on Fracture Mechanism of Ni-Base Superalloy

Chang-Suk Han^†, and Sang-Yeon Lim¹

Department of Defense Science & Technology, Hoseo University, Korea
¹Department of Nanobiotronics, Hoseo University, Hoseo-ro 79 beon-gil, Baebang-Myun, Asan City, Chungnam 336-795, Korea

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The fatigue strength of a nickel-base superalloy was studied. Stress-controlled fatigue tests were carried out at 700 ℃ and 5 Hz using triangular wave forms. In this study, two kinds of testing procedures were adopted. One is the conventional tension-zero fatigue test(R = 0). The other was a procedure in which the maximum stress was held at 1000 MPa and the minimum stress was diverse from zero to 1000 MPa at 24 and 700 ℃. The results of the fatigue tests at 700 oC indicate that the fracture mechanism changed according to both the mean stress and the stress range. At a higher stress range, γ' precipitates are sheared by a/2<110> dislocation pairs coupled by APB. Therefore, in a large stress range, the deformation occurred by shearing of γ' by a/2<110> dislocations, which brought about crystallographic shear fracture. As the stress range was decreased, the fracture mode gradually changed from crystallographic shear fracture to gradual growth of fatigue cracks. At an intermediate stress range, as it became more difficult for a/2<110> dislocation pairs to shear γ' particles, cracks started to propagate in the matrix, avoiding the harder γ' particles. High mean stress induced creep deformation, that is, γ' particles were sheared by {111}<112> slip systems, which led to the formation of stacking faults in the precipitates. Thus, the change in fracture mechanism brought about the inversion of the S-N curves.

Keywords:fatigue strength;nickel-base superalloy;S-N behavior;creep deformation

[References]

Paulson RR, Fritzemeier LG, Tien JK, Metall. Mater. Trans. A-Phys. Metall. Mater. Sci., 14A, 727 (1983)
Oh CS, Kim YC, Kil SC, Han CS, Asian J. Chem., 26, 1301 (2014)
Bretz PL, Denda T, Tien JK, Elect. Beam Melting & Refining, State of the Art 1989, 282 (1989).
Bae DH, Oh CS, Han CS, Asian J. Chem., 26, 4107 (2014)
Coakley J, Dye D, Basoalto H, Acta Mater., 59, 854 (2011)
Miller MK, Babu SS, Vitek JM, Intermetallics, 15, 757 (2007)
Bellows RS, Schwarzkopf EA, Tien JK, Metall. Mater. Trans. A-Phys. Metall. Mater. Sci., 19A, 479 (1988)
Sakaki T, Kakehi K, Adachi T, Tanaka T, Creep and Fracture of Engineering Materials and Structures, Ed. by Wilshire B, Evans RW, Swansea, 313 (1990).
Milligan WW, Jayaraman N, Mater. Sci. Eng., 82, 127 (1986)
Crompton JS, Martin JW, Metall. Mater. Trans. A-Phys. Metall. Mater. Sci., 15A, 1711 (1984)

[1] Paulson RR, Fritzemeier LG, Tien JK, Metall. Mater. Trans. A-Phys. Metall. Mater. Sci., 14A, 727 (1983)

[2] Oh CS, Kim YC, Kil SC, Han CS, Asian J. Chem., 26, 1301 (2014)

[3] Bretz PL, Denda T, Tien JK, Elect. Beam Melting & Refining, State of the Art 1989, 282 (1989).

[4] Bae DH, Oh CS, Han CS, Asian J. Chem., 26, 4107 (2014)

[5] Coakley J, Dye D, Basoalto H, Acta Mater., 59, 854 (2011)

[6] Miller MK, Babu SS, Vitek JM, Intermetallics, 15, 757 (2007)

[7] Bellows RS, Schwarzkopf EA, Tien JK, Metall. Mater. Trans. A-Phys. Metall. Mater. Sci., 19A, 479 (1988)

[8] Sakaki T, Kakehi K, Adachi T, Tanaka T, Creep and Fracture of Engineering Materials and Structures, Ed. by Wilshire B, Evans RW, Swansea, 313 (1990).

[9] Milligan WW, Jayaraman N, Mater. Sci. Eng., 82, 127 (1986)

[10] Crompton JS, Martin JW, Metall. Mater. Trans. A-Phys. Metall. Mater. Sci., 15A, 1711 (1984)