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金属学报 1983

粒子强化高温合金的滞弹性松弛、循环蠕变和应力断裂行为

, PP. 26-38

庄毅

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Abstract:

研究了两种有代表性的粒子强化(氧化物弥散强化和γ′沉淀强化)镍基高温合金的循环蠕变和应力断裂行为。研究表明,在760℃和一定的循环载荷下,试验频率从0.05至6cycles/h变化时,循环蠕变速率随频率提高而下降,而断裂寿命则一般随频率增加而增加(但对于沉淀强化高温合金,在所采用的最高频率下,断裂寿命反而下降,这是由于频率使平面滑移程度增加的结果)。分析了在加载和卸载期间的塑性和滞弹性应变以及在循环蠕变中的位错结构。结果表明,在循环加载时所观察到的行为及明显的材料强化,并不是循环应变硬化效应所造成的,而是滞弹性应变效应的结果。这种滞弹性应变在加载期间被累积,而在卸载期间则被恢复。在滞弹性机构的基础上,导出了一个循环蠕变或蠕变疲劳交互作用减速因素的现象学模型,这一模型与实验所观察到的行为相符合。

References

[1]	1 Matejczyk, D. E.; Zhuang, Y. (庄毅); Tien, J. K., J. Met. 32 (1980) , №. 8, 24．
[2]	2 Matejczyk, D. E.; Zhuang, Y. (庄毅); Tien, J. K., ibid., 32 (1980) , №. 12, 4．
[3]	3 Tien, J. K.; Matejczyk, D. E.; Zhuang, Y. (庄毅); Howson, T. E., Creep and Fracture of Engineering Materials and Structures, Proc. of the Int. Conf. Held at University College, Swansea, Eds. Wilshire, B.; Qwen, D. R. J., Prineridge Press, Swansea, U. K., 1981, p. 433．
[4]	4 Matejczyk, D. E.; Zhuang, Y. (庄毅); Tien, J. K., Metall. Trans., 14A(1983) , 241．
[5]	5 Zhuang, Y. (庄毅); Matejczyk, D. E.; Tien, J. K., to be published.
[6]	6 Shetty, D. K.; Meshii, M., Metall. Trans., 6A (1975) , 349．
[7]	7 Bradley, W. L.; Nam, S. W.; Matlock, D. K., ibid., 7A (1976) , 425．
[8]	8 Coutinho, C. B.; Matlock, D. K.; Bradley, W. L., Mater. Sci. Eng., 21 (1975) , 239．
[9]	9 Morris, D. G.; Harries, D. R., J. Mater. Sci., 13 (1978) , 985．
[10]	10 Koterazawa, R., Mechanical Behavior of Materials, Vol. 3, The Society of Materials Science, Japan, 1972, p. 135．
[11]	11 Rosen, A.; Weiss, L; Baruch, J.; Tzelinik, E., Metall. Trans., 6A (1975) , 1311．
[12]	12 Lupinc, V.; Gabrielli, F., Mater. Sci. Eng., 37 (1979) , 143．
[13]	13 Morris, D. G., J. Mater. Sci., 13 (1978) , 1849．
[14]	14 Gibbons, T. B.; Lupinc, V.; McLean, D., Mater. Sci., 9 (1975) , 437．
[15]	15 Howson, T. E.; Stulga, J. E.; Tien, J. K., Metall, Trans., 11A (1980) , 1599．
[16]	16 Howson, T. E., Unpublished Research, 1979．
[17]	17 Yen, C. T., Unpublished Research, 1981．
[18]	18 Orgen, F. E.; Gell, M., Metall. Trans., 2 (1971) , 943．
[19]	19 Gell, M.; Leverant, G. R., Mechanisms of High Temperature Fatigue, ASTM STP 520, 1973, p. 37．
[20]	20 Lubahn, J. D., Trans. ASM, 45 (1953) , 787．
[21]	21 Evans, W. J.; Harrison, G. F., Scr. Metall., 9 (1975) , 239．
[22]	22 Gittus, J. H., ibid., 6 (1972) , 247．
[23]	23 Gittus, J. H., ibid., 6 (1972) , 481．
[24]	24 Meshii, M.; Ueki, M.; Chiou, H. D., Strength of Metals and Alloys, Vol. 1, Proc. of the 5th Int. Conf., Aachen, W. Germany, Aug. 1979, Eds. Haasen, P; Gerold, V.; Kostorz, G., Pergamon Press, New York, 1979, p. 245．
[25]	25 Parker, J. D.; Wilshire, B., Philos. Mag., 41 (1980) , 665．A

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