The structural materials of the coils of superconducting magnets utilized in thermonuclear fusion reactors are used at liquid helium (4.2 K) temperatures and are subjected to repeated thermal stresses and electromagnetic forces. A high strength, high toughness austenitic stainless steel (12Cr-12Ni-10Mn-5Mo-0.2N) has recently been developed for large, thick-walled components used in such environments. This material is non-magnetic even when subjected to processing and, because it is a forging material, it is advantageous as a structural material for large components. In the current research, a large forging of 12Cr-12Ni-10Mn-5Mo-0.2N austenitic stainless steel, was fabricated to a thickness of 250 mm, which is typical of section thicknesses encountered in actual equipment. The tensile fatigue crack growth properties of the forging were examined at liquid helium temperature as function of specimen location across the thickness of the forging. There was virtually no evidence of variation in tensile strength or fatigue crack growth properties attributable to different sampling locations in the thickness direction and no effect of thickness due to the forging or solution treatment associated with large forgings was observed. It has been clarified that there are cases in which small scale yielding (SSY) conditions are not fulfilled when stress ratios are large. ΔJ was introduced in order to achieve unified expression inclusive of these regions and, by expressing crack growth rate accordingly, the following formula was obtained at the second stage (middle range). da/dN = CJ ΔJmJ, CJ = AJ/(ΔJ0)mJ, where, AJ = 1.47 × 10−5 mm/cycle, ΔJ0 = 2.42 × 103N/m.

1.
ASTM Book of Standards, 1989, Section 3, E813, Vol. 03.01, pp. 732–746.
2.
ASTM Book of Standards, 1991, Section 3, E647, Vol. 03.01, pp. 674–701.
3.
Dowing, N. E., 1976, “Geometry Effects and the J-Integral Approach to Elastic-Plastic Fatigue Crack Growth,” Cracks and Fracture, ASTM STP 601, American Society for Testing and Materials, pp. 19–32.
4.
Inoue
A.
, et al.,
1989
, “
Fatigue Crack Growth Rate of Structural Materials for Cryogenic Use
,”
Journal of the Society of Materials Science, Japan
, Vol.
38
, No.
432
, pp.
1047
1052
(in Japanese).
5.
Kitagawa, H., and Misumi, M., 1972, “Estimation of effective stress intensity factor for fatigue crack growth considering the mean stress,” Proc. 1st. Int. Conf. Mech. Behav. Mater., Kyoto, Vol. 2, pp. 225–232.
6.
Masuda
C.
,
Tanaka
K.
, and
Nishijima
S.
,
1978
,
Transaction of the Japan Society of Mechanical Engineers
, Vol.
46
, No.
403
, pp.
247
257
(in Japanese).
7.
NRIM Data Sheet, 1982, No. 31, 1985, No. 46, and 1986, No. 54.
8.
Nakajima
H.
, et al.,
1990
, “
Development of New Cryogenic Steels for the Superconducting Magnets of the Fusion Experimental Reactor
,”
ISIJ International
, Vol.
30
, No.
8
, pp.
567
578
.
9.
Paris
P. C.
, and
Erdogan
F.
,
1963
, “
A Critical Analysis of Crack Propagation Laws
,”
ASME Journal of Basic Engineering
, Vol.
85
, pp.
528
539
.
10.
Saxena
A.
, and
Hudak
S. J.
,
1978
, “
Review and Extension of Compliance Information for Common Crack Growth Specimens
,”
International Journal of Fracture
, Vol.
14
, No.
5
, pp.
453
468
.
11.
Suzuki
K.
, et al.,
1989
, “
Near-Theshold Fatigue Crack Growth of 316L Stainless Steel at Liquid Helium Temperature
,”
Journal of the Society of Materials Science
, Japan, Vol.
38
, No.
434
, pp.
1309
1315
.(in Japanese).
12.
Suzuki, T., and Hirano, K., 1993, “Cryogenic Fatigue Crack Growth Characteristics of Structural Material for the Superconducting Generator,” Asian Pacific Conference on Fatigue and Strength ’93, JSME, pp. 117–121.
13.
Sawaki
Y.
, et al.,
1993
, “
Near-Threshold Crack Propagation Behaviour at Low Temperature
,”
Transaction of the Japan Society of Mechanical Engineers
, Vol.
59
, No.
558
, pp.
305
310
.(in Japanese).
14.
Thielen
P. N.
and
Fine
M. E.
,
1975
, “
Fatigue Crack Propagation in 4140 Steel
,”
Metal Trans.
,
6A-11
, pp.
2133
2141
.
15.
Tobler, R. L., and Reed, R. P., 1976, “Fatigue Crack Growth Rates of Structural Alloy at 4K,” Adv. Cryo. Eng., Vol. 22, Plenum Press, New York, pp. 35–46.
16.
Tobler, R. L., and Reed, R. P., 1978, “Fatigue Crack Growth Resistance of Structural Alloys at Cryogenic Temperatures,” Adv. Cryo. Eng., Vol. 24, Plenum Press, New York, pp. 82–90.
17.
Yokobori
T.
, and
Aizawa
T.
,
1973
, “
Some Notes to the Kinetic Theory of Fatigue Crack Propagation Rate
,”
Rep. Res. Inst. Strength & Fracture of Materials
, Tohoku Univ., Vol.
9
, No.
2
, pp.
65
67
.
18.
Yokobori
T.
, and
Yoshida
M.
,
1974
, “
Kinetic Theory Approach to Fatigue Crack Propagation in Terns of Dislocation Dynamics
,”
International Journal of Fracture
, Vol.
10
, No.
4
, pp.
467
470
.
This content is only available via PDF.
You do not currently have access to this content.