1988
DOI: 10.1016/0025-5416(88)90564-2
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Life prediction by mechanistic modeling and system monitoring of environmental cracking of iron and nickel alloys in aqueous systems

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Cited by 251 publications
(57 citation statements)
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“…This contrasts with the "moderate" (still very low) potential Initial efforts to extend SCC prediction algorithms developed by Ford and Andresen [22,23] for stainless steels: and nickel alloys in 288 "C pure water environments hold piomise. While the temperature is much lower and the solutions are mot similar to "pure water", the materials are highly resistant in this environment and are therefore expected to have rapid repassivation rates.…”
mentioning
confidence: 78%
“…This contrasts with the "moderate" (still very low) potential Initial efforts to extend SCC prediction algorithms developed by Ford and Andresen [22,23] for stainless steels: and nickel alloys in 288 "C pure water environments hold piomise. While the temperature is much lower and the solutions are mot similar to "pure water", the materials are highly resistant in this environment and are therefore expected to have rapid repassivation rates.…”
mentioning
confidence: 78%
“…In the area of environmentally assisted cracking (such as SCC), coalescence of microscopically small cracks will take place and develop into deeper cracks. Andresen and Ford (1988) used a crack size of 0.05 mm (50 pm) as an equivalent defect from which to start propagating SCC cracks.…”
Section: Crack Initiationmentioning
confidence: 99%
“…For the systems of interest, the slip dissolutiodfilm rupture mechanism has been chosen. This cracking mechanism has been successfully applied to model SCC for stainless steel, low-alloy steel, and nickel-based alloys in light water reactor environments Andresen and Ford 1988). where n is the repassivation parameter to be determined experimentally and KI is the stress intensity factor in MPa (m)'".…”
Section: Slip Dissolution/film Rupture Model For Scc Crack Growthmentioning
confidence: 99%
“…The active-path-corrosion type SCC (APC-SCC) grows when oxidation film is ruptured by plastic deformation at a crack tip. Andresen and Ford [16], Shoji et al [17], and Hall [18] suggested theoretical expressions of corrosion crack growth rate taking account of slip deformation at a crack tip on the basis of the model of rupture-dissolution of passivation film. Recently, it has been reported that crack growth rate under large scale yielding (LSY) condition was characterized using the J integral, which is an elastic-plastic fracture mechanics parameter.…”
Section: Introductionmentioning
confidence: 99%
“…For micro-crack behavior in stages (I) to (III), constant strain tests, constant load tests and slow strain rate tests were conducted to investigate initiation and coalescence of micro-cracks by SCC [8][9][10][11]. For macro-crack behavior in stage (IV), SCC growth tests were conducted to investigate crack growth using a fracture mechanics specimen, such as a compact tension (CT) specimen and wedge-opening-load (WOL) specimen [12][13][14][15][16][17][18][19][20][21][22][23]. The growth rate of a stress corrosion crack has been characterized by the stress intensity factor, which is a linear elastic fracture mechanics parameter [3,[12][13][14][15].…”
Section: Introductionmentioning
confidence: 99%