Local Strain Measurement for Prediction of Fatigue Macrocrack Initiation in Notched Specimens

Fatigue &Amp; Fracture of Engineering Materials &Amp; Structures

Larsen

Gangloff

2011

A B S T R A C T Research on fatigue crack formation from a corroded 7075-T651 surface provides insight into the governing mechanical driving forces at microstructure-scale lengths that are intermediate between safe life and damage tolerant feature sizes. Crack surface marker-bands accurately quantify cycles (N i ) to form a 10-20 μm fatigue crack emanating from both an isolated pit perimeter and EXCO corroded surface. The N i decreases with increasingapplied stress. Fatigue crack formation involves a complex interaction of elastic stress concentration due to three-dimensional pit macro-topography coupled with local microtopographic plastic strain concentration, further enhanced by microstructure (particularly sub-surface constituents). These driving force interactions lead to high variability in cycles to form a fatigue crack, but from an engineering perspective, a broadly corroded surface should contain an extreme group of features that are likely to drive the portion of life to form a crack to near 0. At low-applied stresses, crack formation can constitute a significant portion of life, which is predicted by coupling macro-pit and micro-feature elastic-plastic stress/strain concentrations from finite element analysis with empirical low-cycle fatigue life models. The presented experimental results provide a foundation to validate next-generation crack formation models and prognosis methods.Keywords AFGROW; aluminium; corrosion fatigue; finite element analysis; fatigue at notches; fatigue crack initiation; hydrogen embrittlement; life prediction. N O M E N C L A T U R Eb = fatigue strength exponent c = fatigue ductility exponent E = Young's modulus f = loading frequency K = stress intensity factor K IC = plane strain fracture toughness K max = maximum stress intensity k t−e = elastic stress concentration factor k t−ep = elastic-plastic stress concentration factor k ε = strain concentration factor K = stress intensity range L = longitudinal (rolling) grain orientation direction L p = pit height along the L-direction N i = crack formation cycles to ≈ 20 μm N f = total cycles to failure (N i + N p ) N p = crack propagation cycles to failureCorrespondence: James T. Burns.

supporting

confidence: 81%

Section: Resultsmentioning

confidence: 99%

Driving forces for localized corrosion-to-fatigue crack transition in Al-Zn-Mg-Cu

Fatigue &Amp; Fracture of Engineering Materials &Amp; Structures

Larsen

Gangloff

2011

“…Computationally intensive and mechanistically rigorous efforts have been put forth to model the crack formation life from fixed local defects [174]. However, empirically-based stress/strain life models of crack formation [175] that capture the effects of local defect geometry on the stress/strain inputs have been demonstrated to be accurate and are likely more feasible for engineering applications [42,170,[176][177][178]. Specifically, a mean stress modified Smith-Watson-Topper [175] based approach was highly accurate in predicting the crack formation life from pre-corrosion damage in aerospace Al-alloys [42].…”

Section: Macro-scale Modeling Impactmentioning

confidence: 99%

Effect of chloride concentration on the corrosion–fatigue crack behavior of an age-hardenable martensitic stainless steel

Donahue

International Journal of Fatigue

2016

Crack growth rate and S-N fatigue testing of Custom 465-H950 was performed in 0.0006-3M NaCl with different levels of pre-exposure. Custom 465-H950 exhibited a strong corrosion resistance to various NaCl-based exposures. Concurrent exposure and loading did not result in corrosion damage sufficiently severe to drive crack formation away from microstructure features (TiC particles). The total fatigue life of precorroded specimens (pit depth ≈40 μm, surface diameter ≈175 μm) increased 4-9 fold as [Cl-] decreased from 3.0M to 0.0006M. Detailed analysis demonstrated that the varying [Cl-] most strongly influenced the initiation life, with secondary contributions from the long-and short-crack propagation regimes.

“…3,15,26,27 Two engineering considerations motivate the investigation of the factors that govern the crack formation Nomenclature: CL1, Corrosion level 1 (severe corrosion); CL2, Corrosion level 2 (moderate corrosion); UNS S17400, 17-4 martensitic steel process from a broadly corroded surface. 15 Various modelling approaches have been proposed to quantitatively calculate the crack formation life [46][47][48][49][50][51][52][53][54] ; however, these methods typically only consider an isolated corrosion damage location. [28][29][30][31][32][33][34][35][36][37] Generally, these approaches use the pit size as an initial flaw size in LEFM calculations of the initial crack tip driving force and assume that the crack progresses as a periphery crack about the initial flaw size.…”

Section: Introductionmentioning

confidence: 99%

“…Second, by definition, LEFM estimates of fatigue life only consider the crack propagation stage; however, for relatively low loading levels and smooth pit morphologies, it has been observed that the crack initiation life can be significant. 15 Various modelling approaches have been proposed to quantitatively calculate the crack formation life [46][47][48][49][50][51][52][53][54] ; however, these methods typically only consider an isolated corrosion damage location. A critical knowledge gap is to understand how the crack formation process is dependent on the characteristics of the global pit damage distribution.…”

Section: Introductionmentioning

confidence: 99%

The effect of pit size and density on the fatigue behaviour of a pre‐corroded martensitic stainless steel

McMurtrey

Mills

Fatigue Fract Eng Mat Struct

2018

UNS S17400 steel is used in turbines for the aerospace and utility industries. While it is generally corrosion resistant, it is susceptible to pitting when exposed to aqueous chloride environments. Effects of pitting characteristics, such as depth, width, and local density on fatigue life, have been studied in this work to better inform criteria for component replacement or repair. While pit depth correlates well with cracking, the deepest pit never initiated the crack that ultimately led to failure. The clustering of pits, or local pitting density, also correlated well with crack initiation location; however, the densest region of pitting was not always the location where cracking occurred. There is likely no single metric that directly correlates pitting with fatigue cracking, rather there is a combination of pitting characteristics that ultimately lead to cracking. The results from this work suggest that pit depth and local pitting density are among the more important metrics.