SLIP-STEP DISSOLUTION AND MICROMECHANICAL ANALYSIS TO MODEL STRESS-CORROSION CRACK-GROWTH OF TYPE-321 STAINLESS-STEEL IN BOILING MGCL2

被引：5

作者：

MAO, X

LI, D

机构：

[1] Department of Mechanical Engineering, University of Calgary, Calgary

来源：

METALLURGICAL AND MATERIALS TRANSACTIONS A-PHYSICAL METALLURGY AND MATERIALS SCIENCE | 1995年 / 26卷 / 03期

关键词：

D O I：

10.1007/BF02663913

中图分类号：

T [工业技术];

学科分类号：

08 ;

摘要：

It is hypothesized that for ductile austenitic stainless steels exposed to boiling MgCl2 solution, the relevant crack propagation mechanism is slip dissolution. This model relates crack advance to oxidation or anodic dissolution that occurs on the bare surface that is created when a thermodynamically stable, protective film at the crack tip mechanically ruptured. Based on the model of slip-bare metal dissolution repassivation and crack-tip strain analysis, a theoretical equation of stress-corrosion crack growth rate as a function of crack-tip strain rate and potential for 321 stainless steel in boiling 42 pet MgCl2 solution is proposed. The theoretical prediction shows that when the crack-tip strain rate changes from 10(-4) to 10(-2) s(-1) the crack propagation rate changes from 0.01 to 3 mm/h at the free corrosion potential (-0.35 V-SCE). if the crack-tip strain rate is above 10(-2)/s, the crack propagation rate should correspond to the upper bound determined by the maximum metal dissolution rate. When the crack-tip rate is below 10(-4)/s, the crack propagation rate is below 0.01 mm/h. The slip-step dissolution model predicted that there exists a critical potential E(c), above which the crack propagation rate is independent on potential, but below which the crack propagation rate decreased with decreasing potential. The theoretical prediction has been verified by slow strain rate tests of 321 stainless steel under potential control (above -0.35 V-SCE) in 42 pet MgCl2 solution.

引用

页码：641 / 646

页数：6

共 39 条

[1] SLOW STRAIN RATE STRESS-CORROSION TESTING AT ELEVATED-TEMPERATURES AND HIGH-PRESSURES [J].

ANDRESEN, PA ;

DUQUETTE, DJ .

CORROSION SCIENCE, 1980, 20 (02) :211-&

[2] LIFE PREDICTION BY MECHANISTIC MODELING AND SYSTEM MONITORING OF ENVIRONMENTAL CRACKING OF IRON AND NICKEL-ALLOYS IN AQUEOUS SYSTEMS [J].

ANDRESEN, PL ;

FORD, FP .

MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, 1988, 103 (01) :167-184

[3]

BECK TR, 1974, CORROSION 30, V11, P408

[4] ANODIC BEHAVIOR OF SCRATCHED SILVER ELECTRODES IN ALKALINE-SOLUTION [J].

BURSTEIN, GT ;

NEWMAN, RC .

ELECTROCHIMICA ACTA, 1980, 25 (08) :1009-1013

[5] EARLY STEPS IN THE ANODIC-OXIDATION OF IRON IN AQUEOUS-SOLUTION [J].

BURSTEIN, GT ;

ASHLEY, GW .

CORROSION, 1983, 39 (06) :241-247

[6] KINETICS OF REPASSIVATION OF SCRATCH SCARS GENERATED ON IRON IN AQUEOUS-SOLUTIONS [J].

BURSTEIN, GT ;

ASHLEY, GW .

CORROSION, 1984, 40 (03) :110-115

[7] THE ELECTROCHEMICAL-BEHAVIOR OF SCRATCHED IRON SURFACES IN AQUEOUS-SOLUTIONS [J].

BURSTEIN, GT ;

DAVIES, DH .

JOURNAL OF THE ELECTROCHEMICAL SOCIETY, 1981, 128 (01) :33-39

[8] GROWTH OF PASSIVATING FILMS ON SCRATCHED 304L STAINLESS-STEEL IN ALKALINE-SOLUTION [J].

BURSTEIN, GT ;

MARSHALL, PI .

CORROSION SCIENCE, 1983, 23 (02) :125-137

[9] ENVIRONMENTALLY CONTROLLED CRACK-GROWTH RATE OF ALSL-304 STAINLESS-STEEL IN HIGH-TEMPERATURE SULFATE-SOLUTIONS [J].

CHUNG, P ;

YOSHITAKE, A ;

CRAGNOLINO, G ;

MACDONALD, DD .

CORROSION, 1985, 41 (03) :159-168

[10] THE STRESS-CORROSION CRACKING OF REACTOR PRESSURE-VESSEL STEEL IN HIGH-TEMPERATURE WATER [J].

CONGLETON, J ;

SHOJI, T ;

PARKINS, RN .

CORROSION SCIENCE, 1985, 25 (8-9) :633-650

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