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The Journal of Engineering Research   Vol. 8  No. 1  (2011)  44-52

________________________________
*Corresponding author’s e-mail: lakhwinder_ymca@hot

mail.com

Influence of Residual Stress on Fatigue Design of AISI 304
Stainless Steel

L. Singh*a, R.A. Khanb and  M.L. Aggarwala

*aMechanical Engineering Department, YMCA Institute of Engineering, Faridabad -121006, Haryana , India.  
bMechanical Engineering Department, Jamia Millia Islamia, New Delhi-110025.

Received  5 August 2009; accepted  14 February 2010

Abstract: Austenitic stainless steel cannot be hardened by any form of heat treatment, in fact, quench-
ing from 10000C merely softens them. They are usually cold worked to increase the hardness. Shot peen-
ing is a cold working process that changes micro-structure as well as residual stress in the surface layer.
In the present work, the compressive residual stress and fatigue strength of AISI 304 austenitic stainless
steel have been evaluated at various shot peening conditions. The improvement in various mechanical
properties such as hardness, damping factors and fatigue strength was noticed. Compressive residual
stress induced by shot peening varies with cyclic loading due to relaxation of compressive residual stress
field. The consideration of relaxed compressive residual stress field instead of original compressive
residual stress field provides reliable fatigue design of components.  In this paper, the exact reductions
in weight and control of mechanical properties due to shot peening process are discussed.

Keywords: Hardness, Fatigue, Shot peening, Weight reduction

Nomenclature

CRSF compressive residual stress field
RCRSF relaxed compressive residual stress field
A Almen 'A' scale
Sy yield point stress
Ssp permissible stress
Ssp/ permissible stress after shot peening
FOS factor of safety
P applied load at the spring end

AISI 304



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1. Introduction

Shot Peening is a method of cold working in which
compressive stresses are induced in the exposed sur-
face layers of metallic parts by the impingement of a
stream of shots directed at the metal surface at high
velocity under controlled conditions. The major appli-
cations are related to improvement and restoration of
fatigue life and reliability of machine elements by
increasing their fatigue strength, straightening and
forming of machine elements (metal parts), pretreat-
ment prior to plating, pretreatment for components to
be metalized or coated with plastics, enhancement to
resistance to stress corrosion cracking and corrosion
fatigue, etc. Shot peening improves the fatigue and
abrasion resistance of metal parts. Very fine cracks are
generated in plastically deformed layer by shot peen-
ing. Existing dislocations are interacting with these
dislocations in the deformed zone and results in no
sharp slip steps. This effect leads to homogeneous
deform surface zone and therefore leads to retardation
of crack initiation (Pandey and Deshmukh, 2001).   It
is applicable to ferrous and non-ferrous parts but is
mostly used on steel surfaces. It consists of throwing
hardened steel balls at the surface to be peened. The
steel balls, or shots, are thrown against the surface
either by compressed air or by centrifugal force as
rotating wheel fires the shot. The intensity of the
process can be varied by regulating the size of shot, the
hardness of shot, speed at which it is fired, the length
of time and the work is exposed to the shot. The result
of the interaction of material parameters with the shot
peening parameters are generation of residual stresses,
strain hardening of the surface and sub surface layers,
changes in microstructure and substructure of materi-
al, change in surface conditions and hardening charac-
teristics of the material. 

Mitsubayashi, et al. 1995,  suggested a method of
improvement in fatigue strength by shot peening and
selection of most effective peening condition. Shaw, et
al. 2003,  illustrated the role of residual stress on the
fatigue strength of high performance gearing.
Aggarwal, et al. 2005 and Aggarwal, 2006  found that
the controlled shot peening improves hardness, causes
relaxation of residual stress and increases fatigue
strength of EN45A spring steel.

Austenitic stainless steel cannot be hardened by any
form of heat treatment, in fact, quenching from
1000oC merely softens them (Devdutt and Aggarwal,
2006).   In the present work, the exact reductions in
weight due to relaxation of residual stress and control
of mechanical properties by shot peening, are dis-
cussed for AISI 304 stainless steel.

2. Experimental Procedure

The chemical composition of austenitic stainless
steel AISI 304 used was shown in Table 1. The
mechanical properties of parent material are: yield
strength 210MPa, ultimate tensile strength 560MPa,
fatigue limit 176MPa and elongation 40%. The speci-
mens were made according to ASTM standards. The
specimen used for determining the fatigue strength is
shown in Fig 1.  Some specimens were shot peened for
the purpose of comparing the peening effect.  A-type
Almen strip, 76X19X1.3mm thick was used to meas-
ure the intensity of shot peening.

W/T = 2 to 6
L W
R 8 W to minimize Kt of

specimens
Taking, T = 5mm (thickness of the

specimens
W = 13mm (width of specimen)
L = 42mm
R = 117mm

Almen intensity was expressed as arc height of
Almen strip. 0.15mm camber value was designated as
6A. Shot peening was doing with centrifugal wheel
system: diameter of wheel 495 mm, operating speed
2250 rpm. The cast steel spherical shots of 0.6mm
diameter were used. The hardness of the shots was
56HRC to 60HRC.  Shot flow rate was varied to obtain
various shot peening intensities. The material was
treated with Almen intensities; 3A, 6A, 8A and 15A.
The coverage of shot peening is 90%.  In fatigue test a
stress ratio (R) equal to 0.1 was used. The specimens
are testing in axial fatigue testing machine MTS model
810, at a frequency 30Hz, at room temperature.

L half the length of span
N total number of leaves
B width of each leaf 
T the thickness of the each leaf
LT total length of the leaf spring

density of leaf spring material.



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The residual stress induced by shot peening was
measured by X-ray diffraction method.  A Cr tube
operating at 30kV with current 8mA was used for pro-
jecting k 1 X-rays. The diffraction angle 2 without
strain was taken as 135.4o.

3. Fatigue Design

Information flow diagram for improvement in
fatigue design of a component is shown in Fig. 2.  The
essential characteristics to be known for the fatigue
design are: (i) S/N curve (ii) CRSF (iii) RCRSF. The
data obtained from these characteristics and the
mechanical properties of the material helps in fatigue
design of the component.

Basic material data obtained on simple specimen is
used for prediction model suggested by (Schijve,
2003).  The various design factors should be judicious-
ly chosen and the decision is based on data calculated,
governing conditions, statistical variations and appli-
cation. In laboratory testing maximum and minimum
load is applied at operating frequency to ascertain
whether the component will sustain the definite num-
ber of cycles or not. 

4. Results and Discussion

Fatigue design of shot peened AISI 304 stainless
steel leaf spring has been illustrated with an example.
The design shows the improvement in fatigue life,
fatigue strength, reduction in weight and reliability.
Also the hardness of the component improves with
shot peening. 

4.1 Mechanical Properties
Three mechanical properties are discussed for reli-

able fatigue design of shot peened leaf springs:

4.1.1 Hardness
Due to shot peening treatment, the effect of change

in hardness was observed in the surface layer. The
average value of hardness for base material ie. un-shot
peened sample (USP) was 198 HV for AISI 304 stain-
less steel. Depending on the shot peening intensity, the
hardness varied from 242 HV to 328 HV for shot
peened samples (Table 2). The increase in hardness
was seen because of the plastic deformation of metals
on the metal surface. Also after shot peening the
austenite phase is partially converted into martensite
phase. The microstructure of unpeened austenitic
stainless steel (austenite phase) and microstructure of
shot peened austenitic stainless steel (martensite +
austenite phase) shown in Fig. 3 and Fig. 4.  The phase
transformation also improves the hardness (Goa
Yukui, 2004).   The effect of shot peening was limited
to a very small depth, 0.25 to 0.60 mm from the sur-
face. It may be noticed that the depth of deformed
layer is found to vary with shot peening intensity. 

4.1.2. Damping Factor
The damping capacity in a system is characterized

by a ratio called damping ratio or damping factor.  It is
the ratio of damping to critical damping. Damping fac-
tor is an important surface characteristic, which varies
with shot peening conditions and depth from the sur-
face of materials (Aggarwal, 2008).  Damping ratio or
damping factor of shot peened sample is measured by

Table 1.  Chemical composition of AISI 304 (wt %)

Figure 1.  ASTM flat specimen for fatigue strength



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The Journal of Engineering Research   Vol. 8  No. 1  (2011)  46-52

using an experimental set-up consisting of a CRO,
accelerometer and amplifier. The damping factor is
calculated from the logarithmic decrement ( )
(Meriam and Kraige 2002). 

Damping factor is critical property of the material
to control the vibrations. Table 3 shows the damping
factor of un-treated sample at different depth from the
surface.  It was also found that with increase in depth
of deform layer, damping factor increases (Table 4).
This was due to the induction of compressive stress on
the thin layer of the surface by changing shot peening
intensity.

4.2 S/N Curves 
Shot peeing improves the fatigue strength of the

components. It repairs micro cracks and hence, the ini-
tiation of fatigue crack over the surface can be delayed

by cold working of the surface with the shots (Goa et
al 2003 and Sharma 2001).      

S-N curves for the base material and the shot
peened specimens were determined using an axial
fatigue-testing machine. The four stress levels
210MPa, 225MPa, 240MPa and 265MPa were tested
and more tests were conducted near the endurance
limit. Fifteen specimens (SAE Annual Book, 1977)
were tested in order to plot an S/N curve. Only the
average points were presented for each level (Fig. 5).
At different stress levels shot peening influence the
fatigue strength. The effect of shot peening was negli-
gible if the magnitude of the applied stress is above the
endurance limit. 

It is important to note that there is reduction in
fatigue strength at higher Almen intensities.  At Almen
intensity 15A fatigue strength of the specimen is less

Figure 2.  Flow diagram for improving design

Table 2.  Variation of hardness and depth of deformed layer with shot penning



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The Journal of Engineering Research   Vol. 8  No. 1  (2011)  46-52

as compare the Almen intensity 8A (Fig. 5). This
reduction in fatigue life at higher Almen intensities is
due to damage of surface material, which leads to
crack initiation on the surface. Hence, it is not neces-
sary that increase in shot peening intensity will always
increase fatigue strength (Goa et al. 2003). 

4.3 Reduction in Weight

4.3.1. Compressive Residual Stress Field (CRSF)
Measurement of CRSF was carried out by X-Ray

diffraction method. The measurement of residual
stress with X-rays utilizes the interatomic spacing of

Figure 3.  Microstructure of austenitic stainless steel without short peening

Figure 4.  Microstructure of austenitic stainless steel with shot penning



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certain lattice planes as the gage length for measuring
strain, Fig. 6.  In essence, the interatomic spacing (d)
for a given lattice plane is determined for the stress-
free condition and for the same material containing
residual stress. The change in lattice spacing is related
to residual stress. Bragg's law expresses the relation-
ship between the distance between a give set of lattice
planes (d), and the wavelength of X-ray radiation ( ),
the order of diffraction (n), and the measured diffrac-
tion angle ( ): 

2d sin = n (1)

The strain normal to the surface, which is measured
by X-rays:

(2)

e   =     normal strain
d1 =    lattice spacing with shot peening, A0
d0 =    lattice spacing without shot peening,  A0

(3)

Table 3.  Damping factor for un-treated specimen

Table 4.  Effect of shot penning on damping factor

Figure 5.  S/N curve of leaft spring at various shot peened intensities

Residual compressive stress = - E



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1A0 = 10-8 cm, E = Young's Modulus of the Material

The relaxation behaviour of compressive residual
stresses is an essential problem for performance and

life prediction of shot peened material and structure.
The variation of CRSF at different depths for all the
peening conditions is shown in Fig. 7.   It is common
to all of the materials that the shot peening induced

Figure 6.  Reflextion of X-rays by equidistant parallel atomic planes

Figure 7.  CRSF for various shot peening intensities

Figure 8.  Relaxation of CRSF at different shot peening conditions



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compressive residual stress must be released during
cyclic loading when the superimposed stress of resid-
ual and applied ones is beyond the static and cyclic
yield strength.  It is usually admitted that the benefit of
shot peening is more pronounced for components
under a high cyclic region.  Figure 8 shows the relax-
ation of stress at different shot peenig intensities.
Relaxed compressive residual stress field is also meas-
ured by X-ray diffraction.   

4.3.2. Exact Reduction in Weight
The compressive residual stress generated on upper

surface due to shot peening protects the part against
tensile service load. Note that the sign of residual
stress is important because if the part were reverse
loaded in service to the point of yielding, it would
relieve beneficial compressive stress and compromise
the part life. The Ssp in the component is given as:

(4)

FOS has been applied on CRSF because of meas-
urement error, wear of surface and variation in shot
size.

Compressive residual stress induced by shot peen-
ing varies with cyclic loading due to relaxation of
CRSF. Relaxation of CRSF is due to micro yielding
and depends upon ductility of the material, number of
cycles and stress applied. Therefore, the Ssp/ taking
into account the relaxation of CRSF is stated as:

(5)

The CRSF should be added to yield stress for stat-
ic loading and RCRSF should be added to yield stress
for fatigue loading.

Aggarwal et al. 2006  illustrated that the results of
EN45A spring steel specimens and heavy leaf springs
used in commercial vehicles, differ from each other.
During the present analysis, it is assumed that while
working with simple AISI 304 stainless steel leaf
springs, results are slightly lower than specimen
results and it can be accommodated in factor of safety
during fatigue design. A factor of safety 1.6 was cho-
sen from the Eq. (6). The variations of the following
eight, measure the factor of safety:

a) Contribution due to material properties (FSM).

b) Contributions due to incomplete knowledge of
load / stress (FSS).

c) Contribution due to geometry resulting from toler-
ance (FSG).

d) Contribution due to accuracy of failure analysis
and the confidence one has put on them (FSFA).

e) Contribution because of reliability desired (FSR).
f) Contribution because of environment (FSE).
g) Factor to consider danger to personnel (FSD).
h) Factor to consider economic impact (FSEl).

FOS = FSM X FSS X FSG X FSFA X FSR X FSE
X FSD X FSE1 (6)

The effect of shot peening intensity on fatigue
design of semi-elliptical leaf spring with dimensions:
P = 300N, L = 425mm, t = 40mm, b = 60mm, n = 6, LT
= 3.635 m and = 7900Kg/m3, is shown in Table 5.

Bending stress for leaf springs ( b) was calculated
using (Aaron 1985), 

b = 6PL / nbt2 (7)

Weight of leaf spring was calculated as,

W = LTbt X (8)

5.   Conclusions

The following conclusions were drawn from the
above discussion:

1) The CRSF relaxes due to fatigue loading. Relaxed
compressive residual stress field (RCRSF) due to
fatigue loading must be considered for reliable
fatigue design of stainless steel AISI 304 leaf
springs.

2) The weight reduction is higher in case of static
loading but it is lesser in case of dynamic loading.
It may be observed that there is a 10-20% weight
reduction at optimum shot peening intensity.  The
designer must include the effect of shot peening,
in calculation if he wants to remain competitive. 

3) Shot peening is also found to be effective process
for controlling mechanical properties such as
damping factor, hardness and fatigue life in metal-
lic surfaces.  



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Table 5.  Effect of almen intensities of fatigue design