Shot Peening Processes to obtain Nanocrystalline surfaces in metal alloys:


 

J. Toribio et alii, Frattura ed Integrità Strutturale, 41 (2017) 62-65; DOI: 10.3221/IGF-ESIS.41.09                                                                        
 

62 
 

Focused on Multiaxial Fatigue 

 
 
 
  
Influence of crack micro-roughness on the plasticity-induced 
fatigue propagation in high strength steel 
 
 
J. Toribio, J.C. Matos, B. González 
Fracture and Structural Integrity Research Group (FSIRG), University of Salamanca (USAL) 
E.P.S., Campus Viriato, Avda. Requejo 33, 49022 Zamora, Spain 
toribio@usal.es, jcmatos@usal.es, bgonzalez@usal.es 
 
 
 
ABSTRACT. This article deals with the locally multiaxial fatigue behaviour of 
high strength steel. To this end, the influence of the cracking path deflections 
(at the micro level) on the plasticity-induced fatigue crack growth is analyzed. 
With regard to this, a modelling by means of the finite element method was 
performed for a given stress intensity factor in the Paris regime, considering 
the existence of micro-roughness in the crack path (local micro-deflections 
with distinct micro-angles as a function of the microstructure of the material). 
The numerical results allow one to obtain the fatigue crack propagation rate 
and compare it with that for the same material in the absence of micro-
roughness (with no micro-crack deflections, i.e., uniaxial fatigue behaviour). 
  
KEYWORDS. Crack tip; Micro-roughness; Crack deflection; Plasticity-induced 
fatigue crack propagation; Finite element method. 
 

 

 
 

Citation: Toribio, J., Matos, J.C., González, 
B., Influence of crack micro-roughness on the 
plasticity-induced fatigue propagation in high 
strength steel, Frattura ed Integrità Strutturale, 
41 (2017) 62-65. 
 
Received: 28.02.2017  
Accepted: 15.04.2017  
Published: 01.07.2017  
 
Copyright: © 2017 This is an open access 
article under the terms of the CC-BY 4.0, 
which permits unrestricted use, distribution, 
and reproduction in any medium, provided 
the original author and source are credited. 

 

 
 
INTRODUCTION  
 

atigue cracks exhibit surface micro-roughness caused by material microstructure, e.g., pearlitic steel shows 
continuous deflections in the fatigue crack path [1]. The non-linear crack configuration should be taken into 
account in the matter of crack-morphological aspects in fracture mechanics [2], since variations in crack deflection 

features influence considerably the fatigue crack propagation rates and threshold stress intensity factor range [3]. Elastic-
plastic finite element simulations of growing fatigue cracks are used to study the plastic crack advance and the so-called 
crack closure phenomenon. With regard to plastic crack advance, the Laird-Smith mechanism of propagation by cyclic 
blunting and re-sharpening, which transfers material from the crack tip towards its flanks, is visualized in [4]. With this 
sort of modeling procedure, the rate per cycle reproduced common trends of the fatigue cracking dependence on loading 
range and overload [5]. Paris-like equations obtained from the numerical modeling of plastic crack advance showed good 
agreement with experimental results [6]. In the matter of plasticity-induced fatigue crack closure, a strong controversy still does 
exist, with researchers raising doubts about its mere existence [4,5], and others obtaining it as a numerical result [7], 
although the total length of closed crack at minimum load in plane strain is shown to be a small fraction of the total crack 
length [8]. 
 

F 



 

                                                                      J. Toribio et alii, Frattura ed Integrità Strutturale, 41 (2017) 62-65; DOI: 10.3221/IGF-ESIS.41.09 
 

63 
 

NUMERICAL PROCEDURE 
 

or the study of fatigue propagation by plastic crack advance, a numerical simulation by the finite element method 
(FEM) under small scale yielding (SSY) was performed using the MSC.Marc software (nonlinear finite element 
code). Material was characterized as elastic–perfectly-plastic and the von Mises yield criterion was employed to 

define the plastic zone in the vicinity of the crack tip. Large strains and large geometry changes were used with an updated 
lagrangian formulation. Material properties (Young’s modulus E=200GPa, yield strength σY=600MPa and Poisson 
coefficient ν=0.3) were those associated with a typical high-strength steel. 
The geometry used in the computations is a symmetric double-edge-cracked panel under remote tension fatigue (Fig. 1). 
The undeformed crack was a parallel-flanks slot, where the kink length l0 (representing 0.0012 times the total crack length) 
is deflected an angle α0 (Fig. 2) and exhibits a semicircular shape (smooth blunting [9]) with b0=5µm, i.e., 0.055l0. Four-
node isoparametric quadrilateral elements (for plane strain applications) were used. Finally, a convergence study was 
performed to determine the optimal finite element mesh size and the most adequate number of steps required in the 
computations. 
 

  
(a) (b) 

 

Figure 1:  Finite element mesh: (a) general view; (b) crack tip. 
 

 
 

Figure 2: Scheme and dimensions of the deflected crack kink. 
          

The key variable analyzed in this research work is the deflection angle of the kink in relation to the main crack. The four 
values α0=0, 15, 30 and 45º were used. The stress intensity factor (SIF) range used in the numerical procedure was 
ΔK=25MPam1/2 (associated with the Paris regime of fatigue crack propagation).  
 
 
NUMERICAL RESULTS 
 

ig. 3 shows the cumulative equivalent plastic strain in the deformed geometry of the cracked solid with the 
deflected crack kink after the main crack. The initial geometry of the solid before loading (initial crack profile) is also 
shown. Results are obtained after applying 20 loading cycles (fatigue) with ΔK=25MPam1/2. 

It is observed how the crack, independently of the deflection angle, tends to propagate in mode I when subjected to 
remote mode I (opening) tensile loading. In addition, the distribution of cumulative equivalent plastic strain becomes 
more non-symmetric and exhibits more elevated values as the kink deflection angle increases.  
The crack deflection provokes a retardation effect in fatigue crack growth in global mode I, this effect being more 
pronounced for elevated deflection angle, as shown in Fig. 4. 

l

α

0

0

b 0

F 

F 



 

J. Toribio et alii, Frattura ed Integrità Strutturale, 41 (2017) 62-65; DOI: 10.3221/IGF-ESIS.41.09                                                                        
 

64 
 

 

 
(a) 

 
(b) 

 
(c) 

 
(d) 

 
 

Figure 3: Cumulative equivalent plastic strain for ΔK=25MPam1/2: (a) α0=0º; (b) α0=15º; (c) α0=30º; (d) α0=45º. 

-1.556e-004

 1.374e+000

 2.748e+000

 4.121e+000

 5.495e+000

 6.869e+000

 8.243e+000

 9.617e+000

 1.099e+001

 1.236e+001

 1.374e+001



 

                                                                      J. Toribio et alii, Frattura ed Integrità Strutturale, 41 (2017) 62-65; DOI: 10.3221/IGF-ESIS.41.09 
 

65 
 

0.0

5.0 10-8

1.0 10-7

1.5 10-7

2.0 10-7

2.5 10-7

3.0 10-7

3.5 10-7

0 15 30 45
da

/d
N

 (
m

/c
ic

lo
)

α
0
 (º)  

 

Figure 4: Fatigue crack growth rate as a function of the deflection angle of the kink. 
 

 
CONCLUSIONS 
 

racks with a deflected kink in a plate subjected to remote tensile loading exhibit plastic crack advance in mode I 
with retarded fatigue crack growth when compared with a fully straight crack (with no kink). The increment of the 
crack deflection angle increases the retardation effect. 

 
 
ACKNOWLEDGEMENT 
 

he authors wish to acknowledge the financial support provided by the following Spanish Institutions: MICYT 
(Grant MAT2002-01831), MEC (Grant BIA2005-08965), MICINN (Grant BIA2008-06810), MINECO (Grant 
BIA2011-27870) and JCyL (Grants SA067A05, SA111A07 and SA039A08). 

 
 
REFERENCES 
 
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515–529. DOI: 10.1016/0013-7944(75)90052-1. 
[3] Suresh, S., Crack deflection: Implications for the growth of long and short fatigue cracks, Metall. Mater. Trans. A, 14 

(1983) 2375–2385. DOI: 10.1007/BF02663313. 
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964–967. DOI: 10.1016/j.matlet.2006.06.025. 
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[8] McClung, R.C., Thacker, B.H., Roy, S., Finite element visualization of fatigue crack closure in plane stress and plane 
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[9] Handerhan, K.J., Garrison Jr., W.M., A study of crack tip blunting and the influence of blunting behavior on the 
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7151(92)90435-H. 

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