Creep behavior of mullite short fiber reinforced ZL109 alloy composites at high temperature

Abstract

Abstract: The creep behavior of Al2O3. SiO2 fiber reinforced ZL109 composites has been investigated at four temperatures ranging from 553 to 623 K. The results show high stress exponent and high apparent creep activation energy. A good correlation between the normalized creep rate and normalized effective stress means that the true stress exponent of minimum creep strain rate of the composite is very close to 5, and the minimum creep strain rate is matrix lattice diffusion controlled. The threshold stress decreases with increasing temperature linearly and disappears at a temperature close to 623 K. It is assumed that the long range internal back stresses generated in creep reduce the load transfer to fibers and the interaction between dislocations and strengthening precipitates decreases at high temperature. At a high temperature where the long range internal back stresses is very close to the applied stress, the threshold stress disappears.

Key words:

Shanling WANG, Baoluo SHEN Shengji GAO, Da LI, Mingjing TU, Weicheng YU, Ge YAO. Creep behavior of mullite short fiber reinforced ZL109 alloy composites at high temperature[J]. J Mater Sci Technol, 2001, 17(04): 429-432.

References

[1] T.G.Nieh: Metall. Trans. A, 1984, 15A, 136.
[2] T.G.Nieh, K.Xia and T.G.Langdon: J Eng. Mater.Technol., 1988, 110, 77.
[3] K.J.Cade and M.Pahutova: Mater. Sci.Eng. A, 1994,20, 141.
[4] Kyung-Tae Park and F.A.Mohamed: Metall.Trans.A, 1995, 26A, 3119.
[5] Y.Li and F.A.Mohamed: Acta Mater., 1997, 11(45),4775.
[6] P.K.Krajewski, J.W.Jones and J.E.Allison: Metall.Mater.Trans. A, 1995, 26A, 3107.
[7] L.C.Davis and J.E.Allison: Metall. Mater. Trans. A,1995, 26A, 3081.
[8] A.B.Pandey R.S.Mishra and Y.R.Mahaian: Metall.Mater.Trans. A, 1996, 27A, 305.
[9] O.D.Sherby R.H.Klundt and A.K.Miller: Metall.Trans., 1977, 8A, 843.
[10] F.A.Mohamed, K.T.Park and E.J.Lavernia: Mater.Sci. Eng., 1992, A150, 21.
[11] J.Cadek, V.Sustek and M.Pahutova: Mater.Sci.Eng, 1994, A174, 141.
[12] J.Cadek, H.Oikawa and V.Sustek: Mater.Sci.Eng.,1995, A190, 9.
[13] J.A.Stefani, V.C.Nardone and J.K.Tien: Script. Met-all., 1987, 21,1.
[14] V.C.Nardone and J.R.Strife: Metall.Trans. A, 1987,18A, 109.
[15] A.B.Pandey R.S.Mishra and Y.R.Mahaian: J Mater.Sci., 1993, 28, 2943.
[16] F.A.Mohamed and T.G.Langdon: Acta Metall., 1974,22, 779.
[17] F.A.Mohamed, Kyung-Tae Park and E.J.Lavernia:Mater. Sci.Eng, 1992, A150, 21.
[18] K.T.Park, E.J.Lavernia and F.A.Mohamed: ActaMetall., 1990, 38, 2149.
[19] Liangming PENG, Shijie ZHU, Haoran CHEN, Fu-gang WANG, Zongyi MA and Jing BI: J Mater. Sci.Technol., 1998, 14, 527.
[20] P.Yavari, F.A.Mohamed and T.G.Langdon: Acta Met-all., 1981, 29, 1495.
[21] G.Gonzales-Doncel and O.D.Sherby: Acta Metall.Mater., 1993, 41, 2797.
[22] J.Cadek, V.Sustek and M.Pahutova: Mater. Sci.Eng, 1998, A246, 252.
[23] T.L.Dragone and W.D.Nix: Acta Metall. Mater.,1990, 38, 1893.
[24] PL.Liu, Z.G.Wang and W.L.Wang: Mater. Sci. Tech-nol., 1997, 13, 667.
[25] P.L.Liu, Z.G.Wang, H.Toda and T.Kobayashi: Script.Metall.,1997, 36, 807.D