Numerical Simulation of Moisture Diffusion in Pultruded GFRP
Composite Profile
Haohui Xin
1,2 a
, Ayman Mosallam
3b
, Yuqing Liu
2,* c
1
School of Human Settlements and Civil Engineering, Xi’an Jiaotong University, Xi’an,China;
2
Department of Bridge Engineering,Tongji University,Shanghai,China
3
Department of Civil and Environment Engineering,University of California, Irvine,CA, USA
Keywords: Pultruded fiber-reinforced polymer (FRP) materials; Non-Fick Moisture Diffusion; Numerical Simulation.
Abstract: Long-term exposure of fiber-reinforced polymer (FRP) profile to harsh in-service environment will lead to
irreversible degradation of mechanical properties. Understanding the exposure “aging” effects on pultruded
FRP composites is important for their application in bridge structures. The moisture diffusion process plays
a very important role to understand material degradation of GFRP laminations exposed to hydrothermal
environment. In this paper, the moisture diffusion process with focusing on pultruded GFRP composites used
in bridge applications is numerically simulated. The parameters of moisture diffusion are calibrated by
gravimetric tests of thin plates.
1 INTRODUCTION
Pultruded glass fiber-reinforced polymer (GFRP) is
favorable by civil engineers because its economic
elegant performance(Bank, 2006; Mosallam,
Bayraktar, Elmikawi, Pul, & Adanur, 2014). Several
GFRP profiles have been exploited in bridge
structures(Bank, 2006; Mosallam et al., 2014; Xin,
Liu, & Du, 2015; Xin, Liu, He, Fan, & Zhang, 2015;
Xin, Liu, Mosallam, He, & Du, 2017; Xin et al., 2020;
Xin, Mosallam, Liu, Veljkovic, & He, 2019; Xin,
Mosallam, Liu, Wang, & Zhang, 2017a; Xin,
Mosallam, Liu, Wang, & He, 2018; Xin, Mosallam,
Liu, Xiao, et al., 2017; Xiong, Liu, Zuo, & Xin, 2019;
Zhang et al., 2019; Zuo, Mosallam, Xin, Liu, & He,
2018). Bridge structures are generally exposed to
harsh in-service environment. The temperature and
humidity varied a lot (Xin, Liu, Mosallam, & Zhang,
2016; Xin, Liu, Mosallam, Zhang, & Wang, 2016;
Xin, Mosallam, Liu, & Wang, 2018; Xin, Mosallam,
Liu, Wang, & Zhang, 2017b; Xin, Mosallam, Liu,
Yang, & Zhang, 2017). Long-term exposure of fiber-
reinforced polymer (FRP) profile to harsh in-service
environment will lead to irreversible degradation of
mechanical properties. The performance degradation
a
https://orcid.org/0000-0002-6205-5248
b
https://orcid.org/0000-0002-1897-1775
c
https://orcid.org/0000-0002-1211-0018
due to aging may lead to catastrophic failure of bridge
structural component. While the moisture diffusion
process plays a very important role to understand
material degradation of GFRP laminations exposed to
hydrothermal environment.
Hence, it is essential to understand the moisture
diffusion process with focusing on pultruded GFRP
composites used in bridge applications. The authors’
previous publication(Xin, Liu, Mosallam, & Zhang,
2016) showed that the moisture uptakes of pultruded
GFRP plate could be divided into three stages:
diffusion-dominated uptake, a polymer relaxation-
dominated uptake and a composite damage-dominated
uptake. The non-Fick moisture diffusion is quite
important to understand material degradation of GFRP
laminations exposed to hydrothermal environment.
Investigation of non-Fick moisture diffusion process
with time will benefit to reveal the aging degradation
mechanism of GFRP profiles serviced as components
of bridge structures. Numerical simulation is an
efficient tool to model the moisture diffusion of bridge
profile with complicated geometry.
The moisture progression with focusing on
pultruded GFRP profiles serviced as components of
bridge structures is numerically simulated in this
paper. The parameters of moisture diffusion are
calibrated by gravimetric tests of thin plates
(100.0mm×6.0mm×2.3mm) at different temperature
and different environment.
2 GRAVIMETRIC TESTS
Pultruded GFRP laminations for the tests are cut form
GFRP profiles serviced as a component of bridge
structures(ASTM D5229/D5229M-14 Standard,
2014). The laminates include three types of lamina,
namely Roving, axial compound fabric and biaxial
compound fabric, see Fig. 1. The experiment is
conducted in four hygrothermal environment, namely
T_W(water) and T _SW(artificial seawater), T=40°C
and 60°C, based on the ASTM D5229/D5229M
procedures(ASTM D5229/D5229M-14 Standard,
2014). The details of gravimetric experiment can be
referred to (Xin, Liu, Mosallam, & Zhang, 2016).
Figure 1: Configurations of GFRP laminate (Xin, Liu,
Mosallam, & Zhang, 2016)
The gravimetric tests of thin plates with a
dimension of 100.0mm×6.0mm×2.3mm were used
for the one dimensional moisture diffusion of
pultruded GFRP laminates in the authors’ previous
publication(Xin, Liu, Mosallam, & Zhang, 2016).
D11 denoted the specimens along the roving direction
while D22 denoted the specimens vertical to the
roving direction. The parameters of time-varying
boundary conditions are calibrated by gravimetric
tests of this thin plates at different temperature and
environment.
3 MASS DIFFUSION
SIMULATION OF GFRP
LAMINATIONS
Mass diffusion analysis is performed using three-
dimensional solid elements DC3D8 with a 1mm mesh
size based on commercial finite element software
ABAQUS(Abaqus, 2019). Eq. (1) is used to obtain
the mass concentration through a Python script to
read the ABAQUS simulation data.
1
1
n
ii
i
n
i
i
CtV
Ct
V
(1)
Where: C
i
is the mass concentration of the i
th
integration point, and V
i
is the volume of the i
th
integration point.
The experimental results were given as weight
gain M(t) in percentage against time (Xin, Liu,
Mosallam, & Zhang, 2016). The average
concentration could be converted to the weight-gain
data by equations (2).
=
water
GFRP
M
tCt
(2)
Where: ρ
GFRP
=2000 kg/m
3
is the density of the
pultruded GFRP laminations, ρ
water
=1000kg/m
3
is the
density of the water.
The moisture diffusion coefficients of pultruded
GFRP laminates can be referred to the reference (Xin,
Liu, Mosallam, & Zhang, 2016). For the one-
dimensional diffusion, the time-varying boundary is
applied to the largest cross section, see Fig. 2. Based
on the experimental results(Xin, Liu, Mosallam, &
Zhang, 2016), the moisture uptake along the roving
direction is larger than it vertical to roving direction.
The magnitude of mass concentration is assumed to
be 1.0. The non-Fick behavior of moisture diffusion
is mainly controlled by the amplitude of multi-stage
points of amplitude function.
Figure 2: Illustration of time-varying boundary conditions
of one-dimensional diffusion
4 EXPOSED TO ENVIRONMENT
WITH A TEMPERATURE OF
40°C
The values of multi-stage points of the amplitude
function were determined by conducting the fit on the
moisture uptake at the temperature of 40°C. The
comparisons between FE simulation and
experimental moisture uptake of specimens at the
temperature of 40°C are shown in Fig.3 and Fig.4,
respectively. A good agreement is observed. The
fitted time-varying boundary conditions could
effectively describe the one-dimensional moisture
migration of GFRP specimens exposed to 40°C
hygrothermal environment.
(a)
(b)
Figure 3: Comparisons between FE simulation and
experimental moisture uptake of specimens exposed to
water environment at 40°C
(a)
(b)
Figure 4: Comparisons between FE simulation and
experimental moisture uptake of specimens exposed to
artificial seawater environment at 40°C
The moisture diffusion process of D11 and D22
specimens at the temperature of 40°C is shown in
Fig.5 and Fig.6. The minimum CONC at the inner
side reached to 97.3% and 99.2% times of CONC at
the out surface for D11 specimen at 1.70×106 s and
1.70×107 s respectively, and increased to 88.0% and
99.2% times of CONC at the out surface for D22
specimen at 1.73×106 s and 1.70×107 s respectively.
(a) t = 9.0 s
(b) t = 4.1×10
5
s
(c) t=1.7×10
6
s
(d) t=1.70×10
7
s
Figure 5:One dimensional diffusion of D11 specimen
exposed to water environment at 40°C
(a) t = 9.0 s
(b) t=7.31×10
5
s
(c) t=1.7×10
6
s
(d) t=1.7×10
7
s
Figure 6: One dimensional diffusion of D22 specimen
exposed to water environment at 40°C
5 EXPOSED TO ENVIRONMENT
WITH A TEMPERATURE OF
60°C
The values of multi-stage points of the amplitude
function were determined by conducting the fit on the
moisture uptake at the temperature of 60°C. The
comparisons between FE simulation and experimental
moisture uptake at 60°C are shown in Fig. 7 and Fig.
8, respectively. A good agreement is observed,
indicating that the fitted time-varying boundary
conditions could effectively describe the one-
dimensional moisture migration of GFRP specimens
exposed to 60°C hygrothermal environment.
(a)
(b)
Figure 7: Comparisons between FE simulation and
experimental moisture uptake of specimens exposed to
water environment at 60°C
(a)
(b)
Figure 8. Comparisons between FE simulation and
experimental moisture uptake of specimens exposed to
artificial seawater environment at 60°C
The moisture diffusion process of D11 and D22
specimens exposed to artificial seawater environment
is shown in Fig.9 and Fig.10. With the diffusion time
increasing, the CONC of inner side gradually
increased. The mass concentration presented gradient
distribution along the thickness direction. The
minimum CONC at the inner side reached 96.3% and
100.0% times of CONC at the out surface for D11
specimen at 1.7×10
6
s and 1.7×10
7
s, respectively, and
increased to 98.7% and 99.6% times of CONC at the
out surface for D22 specimen at 1.7×10
6
s and
1.7×10
7
s, respectively. The mass concentration
distribution gradually tended to be uniform along the
thickness direction when the diffusion time is larger
than 1 million seconds.
(a) t=9.0s
(b) t=7.3×10
5
s
(c) t=1.7×10
6
s
(d) t=1.7×10
7
s
Figure 9. One dimensional diffusion of D11 specimen
exposed to artificial seawater environment at 60°C
(a) t=9.0s
(b) t=7.3×10
5
s
(c) t=1.7×10
6
s
(d) t=1.7×10
7
s
Figure 10. One dimensional diffusion of D22 specimen
exposed to artificial seawater environment at 60°C
6 CONCLUSIONS
Long-term exposure of fiber-reinforced polymer
(FRP) profile to harsh in-service environment will
lead to irreversible degradation of mechanical
properties. Understanding the exposure “aging”
effects on pultruded FRP composites is important for
their application in bridge structures. The moisture
diffusion process plays a very important role to
understand material degradation of GFRP
laminations exposed to hydrothermal environment.
The parameters of moisture diffusion are
calibrated by gravimetric tests of thin plates (one-
dimensional diffusion). The calibrated mass diffusion
parameters are validated by comparing the average
time-dependent moisture concentration obtained
from non-Fick FE simulation with experimental
observation.
For one-dimensional moisture diffusion of thin
plates, with the diffusion time increasing, the CONC
of inner side gradually increased. With the diffusion
time increasing, the CONC of inner side gradually
increased. The mass concentration presented gradient
distribution along the thickness direction gradually.
The mass concentration distribution gradually tended
to be uniform along the thickness direction when the
diffusion time is larger than 1 million seconds.
ACKNOWLEDGEMENTS
The authors gratefully acknowledge the financial
support provided by the National Natural Science
Foundation (Grants #51808398 and 52078362) of the
People’s Republic of China.
REFERENCES
Abaqus, V. (2019). 2019 Documentation. Dassault
Systemes Simulia Corporation, 651.
ASTM D5229/D5229M-14 Standard. (2014). Standard
Test Method for Moisture Absorption Properties and
Equilibrium Conditioning of Polymer Matrix
Composite Materials. STM International,100 Barr
Harbor Drive, PO Box C700, West Conshohocken, PA,
19428-2959 USA.
Bank, L. C. (2006). Composites for Construction. In
Composites for Construction: Structural Design with
FRP Materials.
https://doi.org/10.1002/9780470121429
Mosallam, A. S., Bayraktar, A., Elmikawi, M., Pul, S., &
Adanur, S. (2014). Polymer Composites in
Construction : An Overview. Review Article of SOJ
Materials Science & Engineering.
Xin, H., Liu, Y., & Du, A. (2015). Thermal analysis on
composite girder with hybrid GFRP-concrete deck. 5.
Xin, H., Liu, Y., He, J., Fan, H., & Zhang, Y. (2015).
Fatigue behavior of hybrid GFRP-concrete bridge
decks under sagging moment. 4, 925–946.
Xin, H., Liu, Y., Mosallam, A. S., He, J., & Du, A. (2017).
Evaluation on material behaviors of pultruded glass
fiber reinforced polymer (GFRP) laminates. Composite
Structures, 182, 283–300.
https://doi.org/10.1016/j.compstruct.2017.09.006
Xin, H., Liu, Y., Mosallam, A., & Zhang, Y. (2016).
Moisture diffusion and hygrothermal aging of
pultruded glass fiber reinforced polymer laminates in
bridge application. Composites Part B: Engineering,
100, 197–207.
https://doi.org/10.1016/j.compositesb.2016.04.085
Xin, H., Liu, Y., Mosallam, A., Zhang, Y., & Wang, C.
(2016). Hygrothermal aging effects on flexural
behavior of pultruded glass fiber reinforced polymer
laminates in bridge applications. 127, 237–247.
Xin, H., Mosallam, A., Correia, J. A. F. O., Liu, Y., He, J.,
& Sun, Y. (2020). Material-structure integrated design
optimization of GFRP bridge deck on steel girder.
Structures, 27, 1222–1230. Elsevier.
Xin, H., Mosallam, A., Liu, Y., Veljkovic, M., & He, J.
(2019). Mechanical characterization of a unidirectional
pultruded composite lamina using micromechanics and
numerical homogenization. Construction and Building
Materials, 216, 101–118.
Xin, H., Mosallam, A., Liu, Y., & Wang, C. (2018).
Hygrothermal aging effects on axial behaviour of
pultruded web–flange junctions and adhesively bonded
build-up bridge members. Journal of Reinforced
Plastics and Composites, 37(1), 13–34.
Xin, H., Mosallam, A., Liu, Y., Wang, C., & Zhang, Y.
(2017a). Analytical and experimental evaluation of
flexural behavior of FRP pultruded composite profiles
for bridge deck structural design. 150, 123–149.
Xin, H., Mosallam, A., Liu, Y., Wang, C., & Zhang, Y.
(2017b). Impact of hygrothermal aging on rotational
behavior of web- fl ange junctions of structural
pultruded composite members for bridge applications.
Composites Part B, 110, 279–297.
https://doi.org/10.1016/j.compositesb.2016.09.105
Xin, H., Mosallam, A., Liu, Y., Xiao, Y., He, J., Wang, C.,
& Jiang, Z. (2017). Experimental and numerical
investigation on in-plane compression and shear
performance of a pultruded GFRP composite bridge
deck. Composite Structures, 180, 914–932.
https://doi.org/10.1016/j.compstruct.2017.08.066
Xin, H., Mosallam, A., Liu, Y., Yang, F., & Zhang, Y.
(2017). Hygrothermal aging effects on shear behavior
of pultruded FRP composite web-flange junctions in
bridge application. Composites Part B: Engineering,
110, 213–228.
https://doi.org/10.1016/j.compositesb.2016.10.093
Xin, H., Mosallam, A. S., Liu, Y., Wang, C., & He, J.
(2018). Experimental and numerical investigation on
assessing local bearing behavior of a pultruded GFRP
bridge deck. Composite Structures, 204, 712–730.
Xiong, Z., Liu, Y., Zuo, Y., & Xin, H. (2019). Experimental
evaluation of shear behavior of pultruded GFRP
perforated connectors embedded in concrete.
Composite Structures, 222, 110938.
Zhang, Y., Mosallam, A., Liu, Y., Sun, Y., Xin, H., & He,
J. (2019). Assessment of Flexural Behavior of
Pultruded GFRP Laminates for Bridge Deck
Applications. Advances in Materials Science and
Engineering, 2019.
Zuo, Y., Mosallam, A., Xin, H., Liu, Y., & He, J. (2018).
Flexural performance of a hybrid GFRP-concrete
bridge deck with composite T-shaped perforated rib
connectors. Composite Structures, 194, 263–278.
