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                                                                 J. Toribio et alii, Frattura ed Integrità Strutturale, 33 (2015) 221-228; DOI: 10.3221/IGF-ESIS.33.28 
 

221 
 

Focussed on characterization of crack tip fields 

 
 
 
  
Crack tip fields and mixed mode fracture behaviour of  
progressively drawn pearlitic steel 
 
 
J. Toribio, B. González, J.C. Matos 
University of Salamanca 
toribio@usal.es 
 

 
ABSTRACT. This paper deals with the influence of the cold drawing process on the fracture behaviour of 
pearlitic steels. To this end, fracture tests under axial loading were performed on steel wires with different 
drawing degree (from a hot rolled bar to a commercial prestressing steel wire), transversely pre-cracked by 
fatigue, analyzing in detail the changes in fracture micromechanisms. The deflection angles of the fracture path 
were measured by longitudinal metallographic sections and the characteristic parameters of the load-
displacement plot were related to different fracture events. Results allowed a calculation of critical stress 
intensity factors for different fracture angles and drawing degrees, thus evaluating the strength anisotropy and 
obtaining a sort of directional toughness. 
  
KEYWORDS. Progressively drawn pearlitic steel; Strength anisotropy; Crack path deflection; Mixed mode 
fracture; Directional toughness.  
 
 
 
INTRODUCTION 
 

he micro-mechanisms taking place during the fracture process of metals and alloys, as well as the fracture toughness, 
change with the temperature, the loading rate, and the cold work [1-3]. In the particular case of pearlitic steel used to 
produce high-strength cold-drawn prestressing wires, the cold drawing process affects the phenomenon of the 

fracture, so that the most heavily drawn steels (undergoing severe plastic deformation) exhibit strength anisotropy, and a 
change in the crack propagation direction, which approaches the wire axis or drawing direction [4]. This leads to the 
calculation of two values of the angular fracture toughness, one in the radial direction and the other in the axial one, the first 
being much greater than the second for steels with severe plastic deformation [5-7]. In wires with axisymmetric notches, the 
degree of the fracture anisotropy also depends on the notch geometry [8]. 
The fracture surface of pearlitic steel presents a change in the fracture mechanism as the wire is drawn [6]. In the hot rolled wire 
the fracture is produced through cleavage, while in the early stages of cold drawing there appears fracture caused by growth and 
coalescence of microvoid and then cleavage. On the other hand, the heavily drawn steels exhibit, after the propagation of 
microvoids in mode I, a step at about 90º followed by a mixed propagation of microvoids and cleavage [4]. The fracture 
behaviour of pearlitic steel mainly depends on the size of the prior austenite grain [9-11]: the smaller the size of the grain, the 
greater the fracture toughness. If the pearlitic steel is cold drawn, then the pearlite colony, rather than the prior austenite grain, is 
the critical fracture unit determining the size of the cleavage facet [12]. 
This paper deals with the anisotropic fracture behaviour of eutectoid pearlitic steel wires with different degree of cold 
drawing (distinct level of strain hardening and diverse microstructural arrangements) exhibiting strength anisotropy. The 
analysis is focused on the crack path deflection angle and the directional toughness.  

T 



 

J. Toribio et alii, Frattura ed Integrità Strutturale, 33 (2015) 221-228; DOI: 10.3221/IGF-ESIS.33.28                                                                   
 

222 
 

 
EXPERIMENTAL PROCEDURE 
 

 progressively drawn pearlitic steel, eutectoid chemical composition (Tab. 1), was used in this work: from the hot-
rolled bar (not cold drawn at all) to the cold drawn wire (obtained after seven cold drawing steps and a stress-
relieving treatment), as well as the intermediate steps. The code used to designate the steel consists of the letter B 

followed by a digit indicating the number of drawing steps applied to each one.  
 

%C %Mn %Si %P %Cr %V 

0.789 0.681 0.210 0.010 0.218 0.061 

Table 1: Chemical composition (wt %) of the steels. 
 
The degree of cold drawing is characterized by means of the cumulative plastic strain εp as a function of the diameter 
reduction according to the following expression, 
 

 p 0
i

ln
D

D
   (1) 

 

where Di is the diameter of the wire after i drawing steps and D0 that corresponding to the initial steel wire. 
The stress-strain curves (Fig. 1) and the conventional mechanical properties were obtained by means of a standard tension 
test. The cold drawing process does not modify the Young’s modulus E (~200 GPa), and produces a clear improvement 
of material strength in the form of increase of both yield strength σY and ultimate tensile strength (UTS) σR (Fig. 2). 
 

0.0

0.5

1.0

1.5

2.0

0.00 0.02 0.04 0.06 0.08

B7
B6
B5
B4

B3
B2
B1
B0


 (

G
P

a
)



0.0

0.5

1.0

1.5

2.0

0.0 0.2 0.4 0.6 0.8 1.0 1.2


R


Y


 (

G
P

a
)



Figure 1: Stress-strain curves σ-ε (standard tension tests). Figure 2: Mechanical properties as a function of the strain 
hardening level.

 
To evaluate the fracture toughness, a standard measurement procedure could not be applied because of the scarcity of the 
material (supplied in either bar or wire form with different diameters). The method applied in this paper is based in the 
calculation (from experimental measurements) of a critical stress intensity factor (SIF) and the use of a local fracture 
criterion, as explained elsewhere [13]. 
To perform the fracture tests, samples of 300 mm were taken from the wires, with diameters of 12 mm in the hot rolled 
bar and 7 mm in the cold drawn wire. Samples were precracked by means of axial tensile fatigue with a sinusoidal wave (at 
a frequency of 10 Hz and R-ratio equal to 0) under load control and decreasing loading steps. The maximum value of the 
stress intensity factor at the end of precracking was 25-30 MPam1/2. After this fatigue precracking, specimens were 
subjected to monotonic tensile loading under displacement control up to fracture, the crosshead speed being 3 mm/min. 
An extensometer was placed in front of the crack mouth (symmetrically in relation to the crack faces), so that both the 
load applied on the sample (F) and the relative displacement by the extensometer (u) were recorded to plot the load-
displacement curve F-u. 
 
 

A 



 

                                                                 J. Toribio et alii, Frattura ed Integrità Strutturale, 33 (2015) 221-228; DOI: 10.3221/IGF-ESIS.33.28 
 

223 
 

EXPERIMENTAL RESULTS 
 
Microstructural analysis 

igure 3 shows the microstructure of hot rolled bar and prestressing steel wire, longitudinal section, where the 
horizontal size of the micrograph corresponds to the radial direction and the vertical size is associated with the 
axial direction in the longitudinal cut. The drawing process produces important microstructural changes in the steel 

at the two basic microstructural levels of pearlitic colonies and lamellae. The colonies become progressively enlarged and 
oriented in axial direction with cold drawing. With regard to the lamellae, they are also axially oriented after drawing and, 
at the same time, the pearlite interlamellar spacing decreases with the level of cumulative plastic strain. Therefore, the 
microstructure becomes progressively packed and oriented with cold drawing. 
 

     
Figure 3: Microstructure, longitudinal section, B0 (left) and B7 (right). 

 
Fracture surface 
Fig. 4 shows the fracture surface for the different steels, where the fatigue surface, starting from a small mechanical cut 
(on the left side of the photographs), appears with a semi-elliptical final front from which the fracture initiates. 
Macroscopically, the fracture surfaces of the slightly drawn steels propagate perpendicularly to the applied stress, 
following the fatigue crack. On the contrary, in heavily drawn steels, the fracture is very anisotropic, with abundant 
deflections and longitudinal cracking. 
Symmetrical longitudinal cuts were made in the fracture-tested specimens, they were photographed (Fig. 5), and the 
fracture angle was measured. In these photographs the fatigue growth is shown on the left, with a flatter profile, in 
addition to the fracture appearing after such a fatigue growth. As the plastic deformation increases with the number of 
drawing steps, so does the roughness of the fracture surface, as well as the fracture angle θ (in relation to the cross section 
of the wire), which implies the occurrence of a fracture in mixed mode. Furthermore, in heavily-drawn steels, the 
existence of a step oriented with an angle of 90º (in relation to the cross section of the wire) can be observed at the 
beginning of the fracture event. 
 

    
 

    
Figure 4: Fracture surfaces, B0 to B7. 

F 



 

J. Toribio et alii, Frattura ed Integrità Strutturale, 33 (2015) 221-228; DOI: 10.3221/IGF-ESIS.33.28                                                                   
 

224 
 

    
 

    
Figure 5: Longitudinal section of the fracture, B0 to B7. 

 
Crack fronts are characterized by a semi-elliptical geometry centred on the surface of the wire. In slightly-drawn steels, a 
micro-void coalescence (MVC) zone appears at the fracture surface after fatigue crack, with an extension of a few tenths 
of a micron, whose surface increases with the cold-drawing process. Then the fracture propagates by cleavage and ends 
with a small external ring of MVC. The initial MVC zone is not taken into account in the calculations (due to its small 
size); instead of it, the crack front used in the calculations is that created by fatigue. It is modelled as a part of an ellipse of 
semiaxes af and bf, with af coincident with the crack depth. 
In heavily drawn steels, the main fracture micro-mechanisms are MVC and vertical walls consisting of elongated cleavage. 
Such walls appear surrounding the fatigue crack in the form of abundant secondary radial cracking, and their sizes increase 
in extension with cold drawing. The final external ring of MVC has a greater surface than in slightly drawn steels. The 
crack growth area prior to the first propagation step (oriented with an angle of 90º) has a size on the order of hundreds of 
microns, and is taken into account in the calculations, resulting in the appearance of two critical crack sizes during the 
fracture: the fatigue crack (with semiaxes af and bf), and the crack existing at the time of growth of the afore-said 90º crack 
propagation step (with semiaxes ae and be). 
 
Load-displacement curve 
The records obtained for the load-displacement curve F-u are different for slightly- and heavily-drawn steels (Fig. 6). Both 
have an initial linear zone that becomes a curve, with this curvature being generally greater as the drawing process 
increases, although it could also depend on other factors. The curves were characterized from two parameters: the load at 
the end of the linear behaviour portion of the curve (Fe) and the maximum load (Fmax). In heavily drawn steels, a 
characteristic load (FY) also appears that can be associated with a micro-tearing phenomenon called pop-in [14], which is 
accompanied by a characteristic tearing noise. By performing interrupted tests [15], it has been observed that the 
phenomenon of pop-in is physically associated with the occurrence of vertical cracking. 
 

u

F

F
e

F
max

         
u

F

F
e

F
max

F
Y

 
Figure 6: Load-displacement curve, B0 (left) and B7 (right). 

 
Fracture toughness 
The value of the critical SIF, obtained for cracked cylindrical specimens, is the fracture toughness of the material, being 
independent of the wire’s diameter and of the crack size. Once the fracture tests were carried out, the critical SIF 



 

                                                                 J. Toribio et alii, Frattura ed Integrità Strutturale, 33 (2015) 221-228; DOI: 10.3221/IGF-ESIS.33.28 
 

225 
 

corresponding to the macroscopic angle of the fracture surface (KCθ) was calculated, as well as the critical SIF associated 
with the pop-in phenomenon (KC90º) for those steels where a vertical step existed. To calculate these characteristic values, 
the maximum SIF was considered over practically the whole crack front in which plane strain conditions occur (the points 
at the wire surface were not taken into account in the calculations of the characteristic SIF). 
On the basis of previous research [16], the dimensionless SIF Y used in the computations is that proposed by Shin and 
Cai [17] in the form of a three-parameter expression as a function of the relative crack depth a/D, the crack aspect ratio 
a/b and the position along of the crack front x/h: 
 

 I0º I0º ( , , ) , ,
a a x

K K F a b Y a
D b h

     
 

 (2) 

 

To obtain the SIF of a secondary crack with angle θ from the main one (Fig. 7), it has been considered that the local SIFs 
at the tip of a secondary crack ( *1k ,  

*
2k ) are related with the global SIFs from the main crack (KI, KII) for the case in which 

the secondary crack length tends to zero [18]. The expression of the local SIFs, for the crack tip in deflection, is given by: 
 

 
I

II

*
11 121

*
21 222

K K Kk

K K Kk

    
    
   

 (3) 

 

where the coefficients Kij only depend on the value of the deflection angle θ. For the calculations, the coefficients obtained by 
Amestoy [18] were used, fitted to third-order polynomial expressions with high regression coefficients. 
 

 


da     0

,K KI II  
* *
1 2,k k  

Figure 7: Crack tip deflection. 
 
The energy release rate value satisfies the following expression [18, 19]: 
 

 
*2 *2
1 2( )k kG

E





 (4) 

 

where E'=E/(1-2) in plane strain and E'=E in plane stress.  
In the matter of the materials that exhibit an anisotropic fracture behaviour, the fracture specific energy depends on the angle 
of propagation, θ, with respect to the crack plane (contained in the wire cross section). The directional energy release rate, 
G(θ), can be related to the energy release rate at 0º, G(0º), and similarly their critical values: 
 

 2 211 21( ) ( ) (0º )G K K G    (5) 
 

For the slightly drawn steels, Eq. 6 allows the calculation of the directional fracture toughness, keeping in mind the 
maximum load and the size of the fatigue crack: 
 

 C I0º f f
2 2
11 21 max( , , )K K K K F a b    (6) 

 

In heavily drawn steels, the critical SIF was calculated in mode I at 90º, from the pop-in load. In the fracture step, 
corresponding to the vertical cleavage burst (Fig. 8), the relationship between the energy release rate in the axial direction (for 
the 90º angle) and in the radial direction (for 0º) [18] permits the calculation of the critical SIF at 90º.  
 

 
90º

da     0

 
Figure 8: Crack tip deflection towards 90º. 

 
The critical SIF at 90º can be obtained as follows [6, 7]: 



 

J. Toribio et alii, Frattura ed Integrità Strutturale, 33 (2015) 221-228; DOI: 10.3221/IGF-ESIS.33.28                                                                   
 

226 
 

 C90º I0º Y e e0.2615 ( , , )K K F a b  (7) 
 

In the crack propagation from the vertical cleavage wall, which appears in the heavily drawn steels, the energy release rate 
for crack growth in the fracture plane oriented with an angle θ can be obtained after simplification by neglecting the 
vertical deflection length (Fig. 9). 
 

 

90º

a     0

da     0


 

 



da     0

 
Figure 9: Crack tip deflection towards θ. 

 
Thus, the critical SIF at θ can be calculated as: 
 

 C I0º e e
2 2
11 21 max( , , )K K K K F a b    (8) 

 

Fig. 10 shows the results related to the critical SIF in mode I for the fracture angle θ of each drawing step, as well as those 
linked with the critical SIF in mode I for the fracture angle 90º in those steels where the anisotropy takes place in the form 
of vertical cracking. Both directional toughness values increase with the drawing process, but the increase of critical SIF 
associated with the θ angle is much more pronounced than that related to the 90º angle, the former reaching values as high 
as 110 MPam1/2. To assure the adequacy of using the SIF as the key parameter governing the fracture process (through its 
critical value at the fracture instant), an estimation was performed of the plastic zone size in the vicinity of the crack tip at 
such a moment in the cases in which the fracture process develops in mode I (precisely the most brittle fracture events) or 
with a negligible component of mode II. In those cases crack tip plasticity is confined in the near tip region, because the 
plastic zone size never exceeds 10% of the uncracked ligament, thereby indicating that the critical SIF is adequate as a key 
parameter governing fracture. For heavily drawn steels the situation is not so clear, because mixed mode propagation 
appears and thus the plastic zone size cannot be easily estimated. However, even in these more ductile cases the SIF can 
be considered as an adequate parameter due to the global constraint (triaxiality) provided by the plane strain stress state in 
the inner points of the crack front. 
 

0

20

40

60

80

100

120

0.0 0.2 0.4 0.6 0.8 1.0 1.2

K
C

K
C90º

K
C
 (

M
P

a
m

1
/2

)

p  
Figure 10: Fracture toughness, KC and KC90º. 

 
 

DISCUSSION 
 

old drawing is an effective process for increasing the strength of pearlitic steel, resulting in a considerable 
improvement in the matter of fracture behaviour (this is very important from the practical engineering viewpoint) 
while at the same time a strong anisotropy appears during fracture, it being related to microstructural anisotropy 

produced by plastic deformation as a consequence of cold drawing. Similar results were obtained in a fully pearlitic rail 
steel subjected to large shear strains by equal channel angular pressing (ECAP) [3] and by high-pressure torsion (HPT) 
[20].  

C 



 

                                                                 J. Toribio et alii, Frattura ed Integrità Strutturale, 33 (2015) 221-228; DOI: 10.3221/IGF-ESIS.33.28 
 

227 
 

With regard to the relationship between the macroscopic fracture behaviour of the wires and the microstructure of the 
progressively drawn pearlitic steels, Fig. 11 represents the fracture angle θ (macroscopic) and the pearlite lamellae angle θm 
(microscopic), both measured in relation to the cross section of the wire, and plotted as a function of the cumulative 
plastic strain (a measure of the strain hardening level or cold drawing degree in the steel wires). It is seen in Fig. 11 shows 
how both macro- and micro-angles increase with plastic deformation, thereby showing how the cumulative plastic strain 
(and its associated microstructural orientation inside the material) affects the fracture performance of the wires in the 
form of strength anisotropy, crack path deflection and mixed mode propagation. 
 

0
5

10
15
20
25
30
35
40
45

45

50

55

60

65

70

75

0.0 0.2 0.4 0.6 0.8 1.0 1.2




m

 
(º

)


m

 (º)

p

0

20

40

60

80

100

120

140

160

0.0 0.2 0.4 0.6 0.8 1.0 1.2

K
C0º

K
C90º

K
C
 (

M
P

a
m

1
/2

)

p

Figure 11: Fracture angle. Figure 12: Fracture toughness, KC0º and KC90º.
 
The calculation of the critical SIF in mode I at 0º was carried out in a linear way when values were available for both 
angles. When only the critical SIF for an angle different from 0º was available, the slope was not considered, because it 
was small. Results show that the steel becomes more anisotropic in its fracture behaviour as the number of wire drawing 
steps increases (Fig. 12). Furthermore, KC0º markedly increases with plastic deformation, tripling itself, while KC90º only 
slightly increases. 
For high deformations, KC90º is significantly lower than KC0º, which explains the presence of vertical cleavage walls on the 
fracture surfaces (and specially the first propagation step oriented 90º in relation to transverse section). This phenomenon 
can be related to the existence of a rounded crack tip causing a cleavage stress in the horizontal direction, tending to open 
a vertical cleavage crack [15], in addition to the microstructural anisotropy caused by the wire drawing itself. 
 
 
CONCLUSIONS 
 

old drawing in pearlitic steel induces strength anisotropy associated with a deflection angle in the crack path, 
changing from being transversal to the wire (in the non-drawn steel) to producing crack deflection with an ever 
increasing angle as the degree of cold drawing increases during manufacture. 

The directional toughness (or directional critical stress intensity factor, SIF) depends on the deflection angle (macroscopic) 
of the fracture crack path, such an angle being in turn a function of the microstructural orientation angle of the pearlite 
lamellae (which tend to be oriented in the wire axis or cold drawing direction). 
The cold drawing process improves the fracture behavior in mode I for a 0º angle in pearlitic steel (by increasing the 
fracture toughness and improving the engineering performance), but it induces a marked anisotropy in its fracture 
behaviour (strength anisotropy, greater with increasing amount of plastic deformation after drawing) due to the strong 
microstructural anisotropy. 
 
 
ACKNOWLEDGEMENTS 
 

he authors wish to acknowledge the financial support provided by the following Spanish Institutions: Ministry for 
Science and Technology (MICYT; Grant MAT2002-01831), Ministry for Education and Science (MEC; Grant 
BIA2005-08965), Ministry for Science and Innovation (MICINN; Grants BIA2008-06810 and BIA2011-27870) 

C 

T 



 

J. Toribio et alii, Frattura ed Integrità Strutturale, 33 (2015) 221-228; DOI: 10.3221/IGF-ESIS.33.28                                                                   
 

228 
 

and Junta de Castilla y León (JCyL; Grants SA067A05, SA111A07 and SA039A08) and the steel supplied by EMESA 
TREFILERÍA (La Corun ̃a, Spain). 
 
 
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