Jtam.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

2, 39, 2001

RELIABILITY PROFILES FOR STEEL GIRDER BRIDGES
WITH REGARD TO CORROSION AND FATIGUE

Andrzej S. Nowak

Maria M. Szerszen

Department of Civil and Environmental Engineering, University of Michigan, USA

e-mail: nowak@umich.edu

Reliability-basedmodels aredeveloped for time-varying changes in struc-
tural performance due to corrosion and fatigue. The fatigue limit state
is one of the important considerations in the design of bridges. Accumu-
lated load cycles can cause cracking or even failure. Reliability analysis
is performed for the fatigue limit state function of flexure. Prediction of
the remaining fatigue life for steel and concrete beams is illustrated on
examples of existing bridge girders.Corrosion causes a loss of the section
and reduction of the load carrying capacity. The rate of corrosion is a
random variable. Three levels of corrosion are considered. Changes in
the reliability are evaluated as a function of time, covering the life-time
of the bridge.

Key words: bridges, corrosion, fatigue, reliability, steel girders, limit
states

1. Introduction

Corrosion is one of the most important causes of deterioration for steel
bridges. The major parameters include the rate (annual loss), pattern (loca-
tion, concentration), and correlation with fatigue strength. A statistical data
base has been established for steel girder bridges. Thus it is important to es-
tablish the relationship between the reliability and the effect of corrosion on
steel bridges.Also, by developing a procedure for calculating theprobability of
failure for different time stages during the life time of the considered structure,
rational criteria for the evaluation of existing bridges can be established. Ulti-
mate limit states are considered in this study for moment and shear. Selected
bridges are slab on girder type structures. Short and medium span existing



340 A.S.Nowak, M.M.Szerszen

bridges are included. The corrosion patterns and rates are modeled for steel
girder bridges on the basis of empirical relationships from laboratory tests and
field observation of existing bridges.

Fatigue performance depends on strength and load spectra. Themost im-
portant load parameters are amplitude and frequency of a loading. To inve-
stigate the fatigue of bridges loaded with heavy trucks, it is convenient to use
the loadmodel based onweigh-in-motion (WIM)measurements.WIM can be
used to calculate statistical stress parameters for girders. The results indicate
that themagnitude and frequency of a truck loading are strongly site-specific.
Thematerial response has been studied bymany researchers. For steel girders,
the so called S-Ncurveswere developed for various categories of details in steel
structures. The distribution of the number of cycles to failure can be appro-
ximated as normal, with the coefficient of variation decreasing for decreasing
stress levels. For reinforced concrete components, the fatigue-caused reduction
of strength applies to reinforcing steel and/or concrete. It was observed that
the concrete strength under a cyclic loading can be drastically reduced. The
limit state function for fatigue can be expressed in terms of two variables, the
number of cycles to failure under the given stress history, and the number of
applied cycles. Both are random variables and they can be described by their
cumulative distribution functions.

Accumulated damage in a composite material such as concrete results in
micro-cracks and reduced ultimate strength. Then, the load carrying capacity
offlexuralmembers canbegovernedby theability of compression zone tocarry
the load (as in the case of an over-reinforced beam). The fatigue model for
concrete is basedon the theoryofplasticity for compositematerials andreflects
the real behavior of concrete subjected to cyclic compression. It is a convenient
way to predict the remaining life of existing concrete bridges, specially those
which were designed without regard to cyclic character of the live load and
rheological changes in thematerial.Reliability analysis is performed for fatigue
limit state in steel bridge girders. The limit state function for the fatigue is
formulated in terms of number of load cycles. The parameters of the load
(number of cycles applied) and resistance (number of cycles to failure) are
derived from the available test data. However, the available data base is rather
limited and there is a need for further verification.

Recently, a considerable research effort has been devoted to bridge design
and evaluation inEurope andNorthAmerica.Therefore, this paper focuses on
the reliability models developed in conjunction with calibration of the AASH-
TO LRFD code in the USA, OHBDC and CHBDC in Canada, and BS 5400
in the United Kingdom. The reliability is calculated for selected structures.



Reliability profiles for steel girder bridges... 341

The obtained reliability spectra can serve as a basis for the development of
rational criteria for the evaluation of existing bridge structures.

2. Deterioration model for corrosion

Deterioration of steel bridges depends on atmospheric environment, expo-
sureof component (interior or exterior), protective treatment to steel, influence
of de-icing and traffic volume. Also, type of material used (weathering steel,
carbon steel, etc.) and construction details may affect the overall performance
of the bridge. Corrosion is one of the most important causes of deterioration
on steel bridges. The primary cause of corrosion is the accumulation of water
and salt (marine environment and de-icing salt) on steel surfaces.
Load carrying capacity can be affected by corrosion. Loss of material re-

sults in reduction of section area, moment of inertia, and section modulus.
Furthermore, it can lead to premature local buckling (loss of stability). An
increase in traffic volume may also lead to critical conditions with regard to
fatigue. Thus it is important to establish the relationship between the relia-
bility and degree of deterioration. The reduction of section net area, build up
of debris, and reduction of the fatigue life are the main consequences of cor-
rosion. In a steel girder, corrosion may affect the capacity in bending, shear,
and bearing. For simple span steel girder bridges, corrosion can occur at the
end supports and along the bridge due to deck joint leakage, accumulation of
salt and dust on the steel surface of the girders.

The type of corrosion that will most likely occur at themid-span of a steel
girder bridge is a section loss on the top surface of the lower flange and on the
lower one quarter of the web. The maximum flexural and torsional moments
occur at the midspan. The maximum shear and bearing stresses occur at the
supports. The typical section loss near the support for a simple span bridge
is characterized by the section loss over the whole web surface and on the top
surface of the lower flange (Kayser and Nowak, 1989a,b).

The rate of corrosion is a subject to considerable variation. There is so-
me data on laboratory tests however, little is available on the actual field
conditions. Based on the available literature and field observations, three de-
terioration rate curves (high, medium and low) are considered. The rate of
corrosion is assumed to be practically zero for the first 10 to 15 years, until
the paint and/or protective cover deteriorates (cracks and peels off). As the
deterioration starts developing on the steel surface, an accelerated corrosion
process may take place, as shown in Fig.1 (Park et al., 1999).



342 A.S.Nowak, M.M.Szerszen

Fig. 1. Considered rates of corrosion

3. Deterioration model for fatigue

Bridge components are subjected to repeated load cycles. Each passage
of a heavy truck can be considered as an application of two and sometimes
even more time-varying forces. In their service life, bridges are exposed to
traffic loads, sometimes very heavy, in particular, on high volume roads.Mul-
tiple application of a dynamic load may lead to fatigue-specific changes in
the structure andmaterials. In particular, the fatigue damage can affect short
span bridges, with a dominating live load and a relatively low level of dead
load. The available data, used to develop the fatigue load model, show that
the number of trucks in the slow lane of highways can reach 5,000 per day,
which is equivalent to over 180 million vehicles during the life time of 100
years. Taking into account, that one vehicle usually produces more than one
cycle, the number of load cycles during the service life of a bridge can be large
enough to cause fatigue problems. The bridge performance depends on the
structural durability and load spectrum. Both parameters can be treated as
random variables. Durability is a function of strength of materials and con-
nectors. The important load parameters are the amplitude and frequency of a
loading.

Evaluation of the fatigueperformanceof bridges involves a considerablede-
gree of uncertainty in both the load and resistancemodels. In general,Miner’s
law is proposed to establish the relationship between the variable-amplitude
fatigue behavior and constant-amplitude behavior.The equivalent stress range
concept or equivalent fatigue vehicle to represent the regular truck traffic are
based on this rule. There are procedures available to determine the allowable



Reliability profiles for steel girder bridges... 343

stress for the trafficvolume anddesign life. Thenumber of load cycles depends
on truck types. However, there is a need to include the future traffic growth.

The evaluation procedure, suggested by Moses et al. (1988), includes the
calculation of the remaining life and the remaining safe life of a detail (the
difference is in the probability of failure). The basic evaluation procedure does
not cover the effects of secondarybending, the evaluation and repair of cracked
members, and the effects of corrosion and mechanical damage. It does apply
to members that have received normal repairs during fabrication.

In general, in the fatigue evaluation procedure, there are three steps in-
volved:

Step 1. Calculation of the variable-amplitude stress spectrum caused by the
actual loading.

Step 2. Development of a relationship between this stress spectrum and the
equivalent constant-amplitude stress, for example using the cumulative
damage approach.

Step 3. Comparison of the resulting applied stress and the fatigue strength
(obtained fromtheS-Ncurve). If theapplied stress is below theallowable
stress value for the desired design life then calculate the fatigue life.

Some of the available procedures consider a variable-amplitude fatigue li-
mit that is a fraction of the constant-amplitude fatigue limit. If the equivalent
or applied stress level is below this variable-amplitude fatigue limit, the fatigue
life of the bridge is assumed to be infinite. Otherwise, there is a finite fatigue
life, although some researchers assume that the fatigue life is still infinite, if
all the variable-amplitude stress cycles are in compression.

Because load and resistance parameters are randomvariables, probabilistic
methods are the most convenient way to provide the required safety level for
various design cases. The stress range is the main parameter in design and
evaluation procedures, but the effect of themean stress can also be considered.
Safety factors are usually applied to the stress level, strength parameter, or
design life.

In general, fatigue models predict changes in material characteristics such
as fatigue strength or modulus of elasticity under a cyclic loading. The ma-
terial response has been studied by a number of researchers. The material
degradation can be described using the S-N curves based on the regression
lines obtained during fatigue tests. For steel girders, the S-N curves were de-
veloped for various categories of details. The number of cycles to failure can
be considered as a normal random variable, with the coefficient of variation
decreasing for decreasing stress levels. In case of steel, the relationship between



344 A.S.Nowak, M.M.Szerszen

the applied stress level and the number of cycles to failure, using a logarithmic
scale, can be described by a linear equation. It is generally accepted, that the
fatigue strength of steel (the endurance limit), which depends on the stress le-
vel and amplitude/frequency of the loading, can be established after 2million
cycles.
For reinforced concrete components, the fatigue-causeddegradationapplies

to reinforcing steel, concrete and bond properties. It was observed that the
strength of concrete under a cyclic loading can be drastically reduced. The
process depends on the amplitude and frequency of the applied load, themean
stress value and max/min stress ratio. In fact, there is no fatigue limit for
concrete and the degradation process is nonlinear. Nevertheless, it can be
considered as linear up to a certain stress limit, which is about 70% of the
ultimate concrete strength.Above this limit, the degradation process is highly
nonlinear (nonlinear creeping) and leads to unconditional failure.
In the fatigue analysis, resistance is the ability of the structure to resist

cyclic loads. For steel girders, the number of load cycles to failure Nf can
be determined from the S-N curves. For each girder, the load amplitude va-
ries. Most of the available material tests were performed for a constant load
amplitude.

In concrete structures, a cyclic loading can also result in a higher damage
rate compared with a sustained load. This should be taken into account, in
the prediction of the remaining life of a concrete bridge. Fatigue changes in
concrete may be difficult to monitor because they are inside of the material,
but they can lead to adecrease in strength of the concrete and reduction of the
modulus of elasticity. Such changes obviously affect the load carrying capacity
and deflection. In particular, this applies to girders, which support the slow
lane traffic.
Miner’s rule (1945) provides a simple way to allow for the rate of cycle

dependent damage. The damage factor Dn accumulates in a linear way in
terms of the cycle ratio to failure

dDn =
dn

Nf
(3.1)

Thenumber of cycles Nf corresponds to pure fatigue failure. For higher levels
of the loading, the number of cycles at failure proves to be more sensitive to
the parameters of the cyclic stress. A convenient way to express the rate of
the creep damage Dt, at any time t is (Szerszen et al., 1995)

Ḋt(t)=
β

r+1

(σ

f ′c

)k

(1−Dt)
−r (3.2)



Reliability profiles for steel girder bridges... 345

where β, k and r are material coefficients (Szerszen et al., 1994).

A convenient load model for fatigue investigation can be based on weigh-
in-motion (WIM)measurements.TheWIMcanbeused to calculate statistical
stress parameters for girders. Also, the frequency of load cycles is associated
with the stress history. The field measurement results indicate that the ma-
gnitude and frequency of the truck loading are strongly site-specific. The limit
state function for fatigue can be expressed in terms of two random variables,
the number of applied cycles, and the number of cycles to failure under the
given stress history. The fatigue limit state function, in the case of bridge
girders, can also be presented as a difference between the moment carrying
capacity of the section and the applied load moment.

4. Reliability analysis procedure

Structural performance is measured in terms of the reliability index β
(Nowak andCollins, 2000). The reliability index is defined as a function of the
probability of failure PF

β=−Φ−1(PF) (4.1)

where Φ−1 is the inverse standard normal distribution function.

It is assumed that the total load Q, is a normal random variable. The
resistance R, is considered as a log-normal random variable. The formula for
the reliability index can be expressed in terms of the given data (Rn, λR, VR,
mQ, σQ) and the parameter k as follows (Nowak, 1995)

β=
RnλR(1−kVR)[1− ln(1−kVR)]−mQ

√

[RnVRλR(1−kVR)]2+σ
2
Q

(4.2)

where
Rn – nominal (design) value of resistance
λR – bias factor of R
VR – coefficient of variation of R
mQ – mean load
σQ – standard deviation of the load.

The value of the parameter k depends on the location of the design point.
In practice k is about 2.

The time-related reliability of a bridge depends on its initial reliability and
on the fractional loss of resistance. The initial reliability for different bridges



346 A.S.Nowak, M.M.Szerszen

under normal traffic differs considerably. Loss of resistance (load carrying ca-
pacity) depends on loss of section due to corrosion and on degree of corrosion.
Fractional changes of the reliability with time are closely related to fractional
changes in the resistance.
At any time stage, the loss of section and the loss in load carrying capacity

(resistance) due to corrosion can be calculated. The reliability index is calcula-
ted using an iterative procedure (Nowak andCollins, 2000). It is assumed that
the total load effect is a normal randomvariable. The resistance is considered
as a lognormal variable.
The limit state function for fatigue can be written as a function of time

(the time to failure should be greater than the time of desired service), or as
a percentage of the remaining life. The limit state function for fatigue in steel
girder bridges can be expressed in terms of two variables

Nf −Nn =0 (4.3)

where
Nf – number of cycles to failure under the given stress history
Nn – number of applied cycles.

Both Nf and Nn are random variables, and they can be described by
their cumulative distribution functions (CDFs).
The other way to express the limit state function for fatigue is to calcu-

late the difference between themoment carrying capacity Mn(t) and loading
moment Map

Mn(t)−Map =0 (4.4)

This function can be used to predict the remaining life of concrete beams
because the moment carrying capacity can be based on the damage function
for concrete under the fatigue loading.
In recent studies on the ultimate limit states, the structural performance

was measured in terms of the reliability index (Nowak, 1995). It is further
assumed that the resistance and load parameters (Nf and Nn) are log-
normal randomvariables. Therefore, the reliability index β can be calculated
as follows

β=
ln
mNf
mNn

√

V 2
Nf
+V 2
nf

(4.5)

where
mNf – mean number of cycles to failure
VNf – coefficient of variation of the number of cycles to failure
mNn – mean number of applied cycles
VNn – coefficient of variation of the number of applied cycles.



Reliability profiles for steel girder bridges... 347

5. Reliability indices

Thereliability indices β are calculated for girdersdesignedusingAASHTO
Specifications (1996) and AASHTO LRFD (1998). According to AASHTO
(1996), the basic design requirement is expressed in terms of moments or
shears (Load Factor Design)

1.3D+2.17(L+ I)<φR (5.1)

where D, L and I are the moments (or shears) due to a dead load, live
load and impact, R is the moment (or shear) carrying capacity, and φ is the
resistance factor. Values of the resistance factor are φ=1.00 for themoment
and shear in steel girders, φ = 0.90 and 0.85 for the moment and shear in
reinforced concrete T-beams, respectively, φ=1.00 and 0.90 for the moment
and shear in prestressed concrete AASHTO-type girders, respectively.

The results of calculations show a considerable variation in the reliability
indices depending on the limit state and span length, from about 2 for a short
span (10m) and short girder spacing (1.2m) to over 4 for larger spans and
girder spacing. The target reliability index was selected βT =3.5.

The results of the reliability analysis served as a basis for the development
of more rational design criteria for the considered girders. The load factors
developed for LRFDAASHTOCode (1994 and 1998) are

1.25D+1.50DA+1.75(L+ I)<φRn (5.2)

where D is the deal load, DA –dead load due to asphaltwearing surface, L –
live load (static), I – dynamic load, Rn – resistance (load carrying capacity),
and φ – resistance factor.

In the selection of resistance factors, the acceptance criterion is the close-
ness to the target value of the reliability index βT . The recommended resistan-
ce factors are φ=1.00 for themoment and shear in steel girders, φ=0.90 for
moment and shear in reinforced concrete T-beams, φ=1.00 and 0.90 for the
moment and shear in prestressed concreteAASHTO-type girders, respectively.

The reliability indices calculated for the bridges designed using the new
LRFD AASHTO code (1994) are close to the target value of 3.5 for all ma-
terials and spans. The calculated load and resistance factors produce a uni-
form spectrumof the reliability indices. For comparison, the ratio of the requ-
ired load carrying capacity by the new LRFDAASHTO code (1998) and the
AASHTO (1996) varies from 0.9 to 1.2.



348 A.S.Nowak, M.M.Szerszen

Fig. 2. Life-time normalized reliability indices for corrosion,moments

For bridges affected by corrosion, the reliability indices are calculated for
the selected structures designed according to BS-5400. The resistance is cal-
culated in terms of the moment carrying capacity and shear capacity. For the
bridges under high and low corrosion rate environments, the reliability indices
for the actual bridges, as a functionof time, are shown inFig.2 for themoment
andFig.3 for the shear. The reliability indices at each time stagewere divided
by the initial reliability indices. The initial reliability indices were high for the
selected structures, ranging between 10 and 11.9 for themoment and between
11 and 13.6 for the shear limit state.

For fatigue, the reliability analysis is performed for the steel girder bridges
designed according to BS-5400. Nine detail classes are considered for welded
and non-welded components. The reliability indices calculated using the lo-
ading parameters obtained from the weigh-in-motion (WIM) measurements
are presented in Fig.4.

In addition, the reliability analysis is also performed for reinforced concrete
beams.Fatigue of concrete is considered for several values of the effective stress
range. The results are presented in Fig.5.



Reliability profiles for steel girder bridges... 349

Fig. 3. Life-time normalized reliability indices for corrosion, shears

Fig. 4. Life-time reliability indices for various fatigue classes of detail



350 A.S.Nowak, M.M.Szerszen

Fig. 5. Reliability Indices vs. Time for Reinforced Beams (Nowak et al., 1999)

6. Conclusions

The reliability can be used as a rational measure for quantification of the
structural performance. The time dependent reliability of steel girder bridges
is considered with regard to corrosion and fatigue.

The deterioration model of steel girder bridges has been developed for
different rates of corrosion. The reliability indices are calculated for selected
bridges. The resulting reliability indices vary depending on the original design
and degree of deterioration. In general, the loss of load carrying capacity due
to corrosion is less than 10 percent for the moment and larger for the shear.
The limit state function for fatigue is formulated in terms of the number

of load cycles. The parameters of the load (number of cycles applied) and
resistance (number of cycles to failure) are derived from the available test
data. However, the available data is rather limited and there is a need for
further verification. The reliability indices vary depending on class of detail.

Acknowledgments

The researchpresented in this paper has been partially sponsoredby theNational

Science Foundation and the UK Highway Agency which is gratefully acknowledged.

The presented results and conclusions are those of the authors and not necessarily

those of the sponsors.



Reliability profiles for steel girder bridges... 351

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Niezawodność stalowych mostów belkowych z uwzględnieniem korozji
i zmęczenia

Streszczenie

Pracadotyczymodeli opartychna teorii niezawodności, uwzględniających zmiany
wczasie powstałewkonstrukcji na skutek zmęczenia i korozji. Stan graniczny jest jed-
nymz istotniejszychzagadnieńwprojektowaniumostów.Akumulacja cykli obciążenia
może spowodować zarysowanie, a nawet awariemostu.Analiza niezawodnościowa jest
przeprowadzona dla stanu granicznego zmęczenia spowodowanego zginaniem. Szaco-
wanie pozostałego czasu użytkowania konstrukcji ze względu na zmęczenie stalowych
i żelbetowych belek przedstawiono na przykładzie analizy istniejących mostów bel-
kowych. Korozja powoduje utratę przekroju elementów nośnych konstrukcji i spadek
nośności granicznej. Prędkość rozwojukorozji jest zmienną losową.Wartykule rozpa-
trzono trzypoziomywystępowaniakorozjiwbelkachmostowych.Zmianywniezawod-
ności mostu przedstawiono w funkcji czasu, obejmującej cały okres przewidywanego
użytkowaniamostu.

Manuscript received November 3, 2000; accepted for print November 23, 2000