Jtam.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

47, 4, pp. 751-759, Warsaw 2009

INFLUENCE OF THE NOTCH RADIUS ON CHANGES OF

THE ∆J PARAMETER UNDER FATIGUE CRACK
GROWTH RATE

Dariusz Rozumek

Opole University of Technology, Faculty of Mechanical Engineering, Opole, Poland

e-mail: d.rozumek@po.opole.pl

In the paper, the influence of the notch radius on changes of the ∆J
parameter under low and high-cycle fatigue is discussed. The tests were
carried out on plates made of FeP04-UNI 8092 deep-drawing steel. The
specimens were characterised by double symmetric lateral notches with
the notch root radius ranging from 0.2mm to 10mm. The MTS 809
servo-hydraulic device was used for tests performed at the Department
ofManagement andEngineering inVicenza (PadovaUniversity). All fa-
tigue tests were performed under force control, by imposing a constant
value of the nominal load ratio, R = 0, and a load amplitude Pa = 6
and7kN (which corresponded to the nominal amplitude of normal stres-
ses σa = 100, 117MPa before the crack initiation). The test frequency
ranged from 13 and 15Hz.

Key words: fatigue crack growth, number of cycles, ∆J parameter, load
ratio, notch

Notations

a – crack length
a0 – notch depth
da/dN – fatigue crack growth rate
n′ – cyclic strain hardening exponent
w – specimen width
E – Young’s modulus
Kt – theoretical stress concentration factor
K′ – cyclic strength coefficient
N – number of cycles
Pa – amplitude of load
R – load ratio



752 D. Rozumek

Y – correction factor
ν – Poisson’s ratio
ρ – notch tip radius
σmax – maximum stress
σnom – nominal stress
σu – ultimate tensile stress
σy – yield stress
∆J – energy parameter
∆εp – plastic strain range

1. Introduction

Fatigue crack growth is directly connected with existing stress concentrators
in a material. Cracks usually initiate in the notch (micro notch). In many ca-
ses, shape of the notch influences life of the tested material (element). That
problem was discussed in a paper by Williams (1952). He showed that, ac-
cording to theory of elasticity, the asymptotic stress state near a re-entrant
corner is singular and its degree of singularity just depends on the notch ope-
ning angle. The stress field intensity is a function of the overall geometry of
the component and the far-field loading. Since Williams’s pioneering work,
several studies have been undertaken to determine the stress field present at
various notch geometry andat singular pointswhere the interface between two
elastic solids intersects the traction-free edge. Some recent papers (Lazzarin
et al., 1997; Taylor, 1999) suggest that there exists a strong relation between
the dimension of this critical zone and El-Haddad et al. (1979) length para-
meter l0(∆Kth0). Averaging the maximum principal stress in a finite volume
ahead of the notch tip could be a valid idea from the engineering point of
view, but presents some drawbacks from the theoretical point of view. In fact,
the more l0 increases, the greater the influence of the other principal stresses
becomes (values of l0 equal 3.0mm have been determined in some cast irons
byTaylor et al.) (1996)). It is the authors’ opinion that an energetic approach
is undoubtedly preferable, despite the fact that it necessarily results in some
algebraic complications. The approach to fatigue crack growth using the J
parameter seems to be themost promising (Tanaka, 1983). The ∆J parame-
ter allows one to estimate changes of local and global energies while fatigue
crack growth in the tested element (Rozumek et al., 2006; Berto andLazzarin,
2007; Rozumek, 2008).



Influence of the notch radius... 753

The aim of this paper is taking into account the influence of the notch
radius on changes of the ∆J parameter under fatigue crack growth rate.

2. Materials and test procedure

The tests were carried out on plates made of FeP04-UNI 8092 deep-drawing
steel,weakened by symmetric lateral notches of varying acuity. In the tests, the
MTS 809 servo-hydraulic device was used at the Department of Management
and Engineering in Vicenza (Padova University). Table 1 contains chemical
compositions of the material, and its some mechanical properties are shown
in Table 2.

Table 1.Chemical composition (in wt%) of FeP04 steel

C Mn Si P S Al Cu Fe

0.05 0.30 0.05 0.032 0.02 0.043 0.07 balance

Table 2.Monotonic quasi-static tension properties of FeP04 steel

σy [MPa] σu [MPa] E [GPa] ν

210 330 191 0.30

Coefficients of the Ramberg-Osgood equation describing the cyclic strain
curve under tension-compression with R = −1 for FeP04 steel are the follo-
wing: the cyclic strength coefficient K′ =838MPa, the cyclic strain hardening
exponent n′ =0.220. All fatigue tests were performed under force control, by
imposing a constant value of the nominal load ratio, R = 0, and a load am-
plitude Pa = 6 and 7kN (which corresponded to the nominal amplitude of
normal stresses σa = 100, 117MPa before crack initiation). The test frequ-
ency ranged from 13 and 15Hz. The specimens had double symmetric lateral
notcheswith notch root radii ranging from0.2mmto 10mm(Fig.1). The the-
oretical stress concentration factor in the specimen under tension Kt =9.61,
4.30, 3.23 and 1.85 was estimated by making use of the model (Thum et al.,
1960). The surfaces of the specimens, w = 50mm wide, had been accurately
polished in order to make the cracks originated from the notch tip easily di-
stinguishable. The fatigue crack increments weremeasuredwith amicrometer
located in a portable microscope withmagnification of 20 times and accuracy
0.01mm. At the same time, the number of loading cycles N was registered.



754 D. Rozumek

Fig. 1. Geometry of specimens characterised by: (a) sharp and (b) blunt notches;
all dimensions in mm

3. Experimental results and discussion

The tests of fatigue crack growth in FeP04 steel subjected to tension were
performed in the lowandhighcycles fatigueundera controlled loading.During
the tests, a number of cycles to the crack initiation Ni, (i.e. to themoment of
occurrence of a visible crack) was determined, and fatigue crack lengths were
measured. The test results were shown as graphs of the crack length a versus
the number of cycles N and fatigue crack growth rate da/dN versus the ∆J
parameter. The cracks initiated (minimal observable crack length about 0.1 to
0.2mm) at the same time on the left and on the right of the slot. From Fig.2
presenting the crack length a versus number of cycles N it appears that after
changing the notch root radii ρ from 0.2 to 10mm, the fatigue life increases.
It is evident that with the highest radii, the initiation phase, which depends
on the stress conditions at the notch tip, prevails.
The author proposed to describe the fatigue crack growth range according

to the energy approach based on the ∆J parameter, which could be written
as (Rozumek, 2004)

∆J1 =πY
2
1

(∆σ2nom
E
+
∆σnom∆εp
√
n′

)

a (3.1)



Influence of the notch radius... 755

Fig. 2. Fatigue crack length versus number of cycles for different radii of the notch
root

If Eq. (3.1) is related to short cracks and includes Kt, it takes the following
form

∆J2 =πY
2
1

(∆σ2max
E
+
∆σmax∆εp
√
n′

)

a (3.2)

where: ∆σmax = Kt∆σnom is the maximum stress range, ∆σnom – nomi-
nal stress range, a is the crack length, Y1 – correction factor dependent on
specimen geometry and loading type

Y1 =1.12+0.203
(2(a+a0)

w

)

−1.197
(2(a+a0)

w

)2

+1.930
(2(a+a0)

w

)3

a0 –notch depth, ∆εp –plastic strain range corresponding to the stress range.
In Eqs. (3.1), (3.2) and (3.3), the exponent n′ concerns the functions in

which materials slightly harden or are cyclically stable (Rozumek and Pawli-
czek, 2004). A next modification of Eq. (3.1) including the notch influence by
introduction of the correction factor Y2, allowing its application for short and
long cracks, can be expressed as

∆J3 =πY
2
1Y
2
2

(∆σ2nom
E
+
∆σnom∆εp
√
n′

)

a (3.3)

where

Y2 =
√

1+e−β with β=
3ρ(w−2a0)a

ρ+w−2a0

and ρ – notch tip radius.



756 D. Rozumek

Figures 3 and 4 show the fatigue crack growth rate da/dN versus ∆J
relations under different notch root radii and load amplitude conditions. Fi-
gure 3 presents a comparison of the parameter ∆J with and without the
coefficient Kt, and in Fig.4 one can see the influence of different correction
factors Y1 and Y2 on variations of the parameter ∆J. Equation (3.2) can be
applied only for short fatigue cracks growthbecause local stress concentrations
cause high stresses and accompanying strains (see Fig.3), and in the case of
long cracks the values calculated according to Eq. (3.2) are overestimated.
From Fig.3 it also appears that the smaller is the notch root radius, the gre-
ater is the influence of stress concentration. That conclusion can be proved by
literature. Lazzarin et al. (1997) proposed the correction factor Y2 including
occurrence of the notch for the least (theoretical) notch radius ρ= 0. Intro-
ducing the relationships proposed by Lazzarin et al. (1997) into Eq. (3.3), we
obtain results in which the values including the notch influence are smaller
than the values with no influence of the notch. For the notch radius ρ clo-
se to zero, the results described by Eqs. (3.1) and (3.3) coincided, and for
ρ= 10mm the greatest differences were obtained. It is inconsistent with the
real behaviour of the notch and cracks in the elements (see Rozumek, 2008).

Fig. 3. Fatigue crack growth rate da/dN versus the ∆J parameter with and
without the factor Kt

In order to obtain real results, the notch root radius ρ approaching infinity
(ρ → ∞) was assumed and the correction factors Y2 and β were corrected.
Then, for the least notch radius ρ, we obtain the greatest differences between
the values obtained from Eqs. (3.1) and (3.3) (see Fig.4).



Influence of the notch radius... 757

Fig. 4. Fatigue crack growth rate da/dN versus the ∆J parameter with and
without the correction factor Y2 for (a) ρ=0.2, 1.25mm and (b) ρ=2.5, 10mm

FromFig. 4 it appears that the is the greater the notch radius, the smaller
is the difference between the results obtained from Eqs. (3.1) and (3.3). The
greatest notch influencewas observed for ρ=0.2mm, up to about a=6mm.
Figure 4wasdivided intoFigs.4a and4b.Figure 4a showshow the range of the
parameter ∆J varies versus the fatigue crack growth rate for the notch radius
ρ = 0.2 and 1.25mm with and without the correction factor Y2. Figure 4b
presents the influence of the correction factor Y2 and its lack (Eq. (3.1) and
Eq. (3.3)) for the notch radius ρ=2.5 and 10mm.

As the notch radius increases from ρ = 0.2 to 10mm, the value of ∆J3
increases in relation to ∆J1. From Fig.4b it appears that for the notch root
radius ρ=10mm the results coincide. However, for ρ=0.2 to 2.5mm there
is a significant difference between the results including and not including the
notch effect. The difference can be seen during crack growth and the notch
influence, then it disappears. From Figs.3 and 4 it appears that the notch
strongly influences variation of the ∆J parameter both globally and locally.
In the elastic-plastic range, the stresses and strains were calculated bymeans
of the finite element software FRANC2D. The cyclic stress-strain curve ba-
sed on the nonlinear material model was introduced into FRANC2D. In that
case, the cyclic stress-strain curve for FeP04 steel described by the Ramberg-
Osgood relation was used. It was decided that calculations would be based on
incremental elastic-plastic analysis including the kinematic model of material
hardening. The calculations were performed for two-dimensional geometrical
models of notched specimens. The geometrical model of the specimen was si-



758 D. Rozumek

mulated in the CASCA software. The finite element mesh was automatically
generated and it containedmore than 3900 six-nodal triangular elements. The
crack growth direction was assumed on the basis of observation of the current
crack path obtained from the tests. Such simulation of the crack propaga-
tion allowed one to obtain the strain and stress maps for each realised crack
increment.

4. Conclusions

The presented results of the fatigue crack growth in the plane notched spe-
cimens made of FeP04 steel and subjected to tension loading allow one to
formulate the following conclusions:

• Equation (3.2) can be applied only for short fatigue cracks growth be-
cause local stress concentrations cause high stresses and accompanying
strains.

• Equation (3.3) well describes the results including an additional influ-
ence of the notch during fatigue crack growth and it can be applied for
determination of length and quality of the notch influence.

• It has been shown that the notch strongly influences variation of the ∆J
parameter, both globally and locally.

References

1. BertoF., LazzarinP., 2007,RelationshipsbetweenJ-integral and the strain
energy evaluated in a finite volume surrounding the tip of sharp and blunt V -
notches, Int. J. of Solids and Structures, 44, 4621-4645

2. El Haddad M.H., Topper T.H., Smith K.N., 1979, Prediction of non-
propagating cracks,Engineering Fracture Mechanics, 11, 573-584

3. Lazzarin P., Tovo R., Meneghetti G., 1997, Fatigue crack initiation and
propagation phases near notches in metals with low notch sensitivity, Interna-
tional Journal of Fatigue, 19, 647-657

4. Rozumek D., 2004, The ∆J-integral range applied for the description of fa-
tigue crack growth rate, Proc. of the 12th International Conference on Expe-
rimental Mechanics (ICEM12), Bari, Italy, Edit. C. Pappalettere, 275-276 and
CD, ps 8



Influence of the notch radius... 759

5. Rozumek D., 2008, Influence of the notch radius on the ∆J-integral range
under cyclic tension,Proc. of the Sixth Int. Conference on Low Cyclic Fatigue
(LCF6), Berlin, Germany, Edit. P.D. Portella et al., DVM, 505-510

6. Rozumek D.,MachaE., Lazzarin P.,Meneghetti G., 2006, Influence of
the notch (tip) radius on fatigue crack growth rate, Journal of Theoretical and
Applied Mechanics, 44, 127-137

7. Rozumek D., Pawliczek R., 2004, A description of crack growth and ma-
terials fatigue in an energy approach, Studies and Monographs, 165, Opole
University of Technology, p.165 [in Polish]

8. TanakaK., 1983,The cyclic J-integral as a criterion for fatigue crack growth,
Int. J. Fracture, 22, 91-104

9. Taylor D., 1999, Geometrical effects in fatigue: a unifying theoretical model,
Int. Journal of Fatigue, 21, 413-420

10. Taylor D., Hughes M., Allen D., 1996, Notch fatigue behaviour in cast
irons explained using a fracture mechanics approach, Int. Journal of Fatigue,
18, 439-445

11. Thum A., Petersen C., Swenson O., 1960, Verformung, Spannung und
Kerbwirkung,VDI, Düsseldorf

12. Williams M.L., 1952, Stress singularities resulting from various boundary
conditions in angular corners of plates in extension, J. Appl. Mechanics, 19,
526-528

Wpływ promienia karbu na zmiany parametru ∆J przy prędkości
wzrostu pęknięć zmęczeniowych

Streszczenie

W pracy przedstawiono wpływ promienia karbu na zmiany parametru ∆J pod-
czas badań wykonywanych w zakresie niskiej i wysokiej liczby cykli zmęczeniowych.
Badaniompoddanopróbki płaskiewykonane ze stali FeP04-UNI8092.Próbki charak-
teryzowały się dwustronnymi symetrycznymi zewnętrznymi karbami z promieniami
dna karbu w zakresie od 0,2 do 10mm. Wyniki badań prezentowane w pracy wy-
konywano na maszynie hydraulicznej MTS 809 w Department of Management and
EngineeringwVicenzy (UniversytetwPadwie).Wszystkie badanie zmęczeniowebyły
wykonywane przy obciążeniu z kontrolowaną siłą przy stałej wartości współczynnika
asymetrii cyklu R=0 i amplitudzie obciążenia Pa =6 i 7kN (która korespondowała
z nominalną amplitudą naprężenia normalnego σa = 100, 117MPa przed inicjacją
pęknięcia). Badania wykonywanow zakresie częstotliwości obciążenia 13 i 15Hz.

Manuscript received October 29, 2008; accepted for print February 11, 2009