Partition of Cyclic Plasticity in an Austenitic-Ferritic Duplex Stainless Steel and its Significance for Fatigue Crack Initiation under High and Very High Cycle Fatigue Loading Conditions

Benjamin Dönges; Marcus Söker; Alexander Giertler; Ulrich Krupp; Claus Peter Fritzen; Hans-Jürgen Christ

doi:10.4028/www.scientific.net/AMR.891-892.1424

Paper Titles

Fatigue Behaviour of Laser Beam Welded Circular Weld Seams under Multi-Axial Loading
p.1397

Notch Effects on Fatigue Behavior of Thermoplastics
p.1403

High-Temperature Ultrasonic Fatigue Testing at 1000°C
p.1413

Initiation from Low Cycle Fatigue to Gigacycle Fatigue
p.1419

Partition of Cyclic Plasticity in an Austenitic-Ferritic Duplex Stainless Steel and its Significance for Fatigue Crack Initiation under High and Very High Cycle Fatigue Loading Conditions
p.1424

Influence of Frequency and Testing Technique on the Fatigue Behaviour of Quenched and Tempered Steel in the VHCF-Regime
p.1430

Formation Mechanism of Specific Fracture Surface Region in the Sub-Surface Fracture of Titanium Alloy
p.1436

Influence of Weld Imperfections on the Fatigue Behaviour of Resistance Spot Welded Advanced High Strength Steels
p.1445

On the Effect of Electrodischarge Drilling on the Fatigue Life of Inconel 718
p.1451

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 891-892Partition of Cyclic Plasticity in an...

Partition of Cyclic Plasticity in an Austenitic-Ferritic Duplex Stainless Steel and its Significance for Fatigue Crack Initiation under High and Very High Cycle Fatigue Loading Conditions

Abstract:

The present study documents that at loading amplitudes close to the fatigue limit, cyclic irreversible plastic deformation in form of slip band generation in the austenitic-ferritic duplex stainless steel X2CrNiMoN22-5-3 (318 LN) mainly takes place in few austenite grains without any microcrack initiation in these grains. This was shown by means of focused ion beam (FIB) cutting in combination with high resolution scanning electron microscopy (SEM) at pronounced extrusion-intrusion-pairs in several austenite grains. Investigations by means of confocal laser scanning microscopy (CLSM) revealed that the slip band density in these grains increases with the number of loading cycles and remains constant in the very high cycle fatigue (VHCF) regime. Under such loading conditions, fatigue cracks frequently initiate in the ferrite phase due to anisotropy stresses which are strongly superimposed by stress intensifications at the tip of austenite slip bands. TEM investigations revealed that austenite slip bands, which are piling up against phase boundaries, cause localized dislocation generation and motion in neighboring ferrite grains. The cyclic irreversible motion of these dislocations on several parallel slip planes is correlated with the stage of fatigue crack initiation. A crystal plasticity model based on a finite element program, which considers anisotropic elasticity, allows for the determination of crack initiation sites in real microstructures according to the above mentioned mechanisms. Crystallographic orientations, measured by means of the electron back scatter diffraction (EBSD) technique, serve as input parameters for the calculations regarding microcrack initiation as well as for the analysis of the subsequent short fatigue crack propagation, which is strongly affected by microstructural barriers such as grain and phase boundaries.

You might also be interested in these eBooks

View Preview

Info:

Periodical:

Advanced Materials Research (Volumes 891-892)

Pages:

1424-1429

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.891-892.1424

Citation:

Cite this paper

Online since:

March 2014

Authors:

Benjamin Dönges*, Marcus Söker, Alexander Giertler, Ulrich Krupp, Claus Peter Fritzen, Hans-Jürgen Christ

Keywords:

Fatigue Crack Initiation, Microstructural Barrier Strength, Short Fatigue Crack Propagation, Very High Cycle Fatigue (VHCF)

Export:

RIS, BibTeX

Price:

Permissions CCC:

Request Permissions

Permissions PLS:

Request Permissions

Сopyright:

Citation:

* - Corresponding Author

References

[1] T. Sakai, Review and Prospects for Current Studies on Very-High Cycle Fatigue of Metallic Materials for Machine Structural Use, J. Solid Mech. Mater. Eng. 3 (2009) 425-439.

DOI: 10.1299/jmmp.3.425

Google Scholar

[2] Y. Murakami, M. Endo, Effects of Defects, Inclusions and In-Homogeneities on Fatigue Strength, Int. J. Fatigue 16 (1994) 163.

DOI: 10.1016/0142-1123(94)90001-9

Google Scholar

[3] I. Roth, M. Kübbeler, U. Krupp, H. -J. Christ, C. -P. Fritzen, Crack Initiation and Short Crack Growth in Metastable Austenitic Stainless Steel in the High Cycle Fatigue Regime, Proc. Eng. 2 (2010) 941-948.

DOI: 10.1016/j.proeng.2010.03.102

Google Scholar

[4] U. Krupp, H. Knobbe, H. -J. Christ, P. Köster, C. -P. Fritzen, The Significance of Microstructural Barriers during Fatigue of a Duplex Steel in the High- and Very-High-Cycle Fatigue (HCF/VHCF) Regime, Int. J. Fatigue 32 (2010) 914-920.

DOI: 10.1016/j.ijfatigue.2009.09.010

Google Scholar

[5] O. Düber, B. Künkler, U. Krupp, H. -J. Christ, C. -P. Fritzen, Experimental Characterization and Two-Dimensional Simulation of Short-Crack Propagation in an Austenitic-Ferritic Duplex Steel, Int. J. Fatigue 28 (2006) 983.

DOI: 10.1016/j.ijfatigue.2005.07.048

Google Scholar

[6] E.O. Hall, The Deformation and Aging of Mild Steel: II Characteristics of the Lüders Deformation, Proc. of the Royal Society 64B (1951) 747-753.

Google Scholar

[7] N.J. Petch, The Cleavage Strength of Polycrystals, Journal of the Iron and Steel Institute (1953) 25-28.

Google Scholar

[8] U. Essmann, U. Gösele, H. Mughrabi, A model of Extrusions and Intrusions in Fatigued Metals - I. Point-Defect Production and the Growth of Extrusions, Phil. Mag. A 44 (1981) 405-426.

DOI: 10.1080/01418618108239541

Google Scholar

[9] J. Polák, On the Role of Point Defects in Fatigue Crack Initiation, Mater. Sci. Eng. 92 (1987) 71-81.

Google Scholar

[10] K. Tanaka, T. Mura, A Dislocation Model for Fatigue Crack Initiation, J. Appl. Mech. 48 (1981) 97-103.

DOI: 10.1115/1.3157599

Google Scholar

[11] Y. Huang, A User-Material Subroutine Incorporating Single Crystal Plasticity in the Abaqus Finite Element Program, Harvard University, Cambridge (1991).

Google Scholar