Determining the rheological properties of asphalt

IJRET: International Journal of Research in Engineering and Technology eISSN: 2319-1163 | pISSN: 2321-7308
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IC-RICE Conference Issue | Nov-2013, Available @ http://www.ijret.org 192
DETERMINING THE RHEOLOGICAL PROPERTIES OF ASPHALT
BINDER USING DYNAMIC SHEAR RHEOMETER (DSR) FOR
SELECTED PAVEMENT STRETCHES
Chetana Joshi1
, Amit Patted2
, Archana M.R3
, M S.Amarnath4
1, 2
Student, M.Tech, 3
Assistant Professor, Department of Civil Engineering, RVCE, Bangalore
4
Professor-Civil Engineering, Bangalore University, Bangalore
csjoshi89@gmail.com, amit.patted@gmail.com, archana.mosale@gmail.com, amaranth_ms@gmail.com
Abstract
This paper aims to study the rheological properties of the binder taken from four years old flexible pavement stretch. The stretch was
divided into six different sections based on the thickness of the surface course. Originally, 60/70 grade asphalt binder was used
throughout the pavement stretch. The binder was obtained from the process of extraction and recovery. Dynamic shear rheometer
(DSR) test was conducted on the recovered asphalt binder to determine the various parameters viz., Complex modulus G*
, Elastic and
viscous modulus, Complex viscosity and the phase angle δ. The major pavement distress modes namely, rutting and fatigue cracking
were addressed by these output parameters of DSR. Rutting is caused by permanent deformation of paving mix while fatigue is related
to the energy absorbed during repeated load application to pavement. The test results indicated that the 60/70 binder extracted from
the selected stretches were stiff enough to resist rutting and fatigue failure.
Keywords: Rheology, Dynamic shear rheometer, Complex modulus, phase angle, Rutting, fatigue.
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1. INTRODUCTION
Rheology is a very powerful tool for characterizing and
quantifying material properties. It has been well established
that the rheological properties of asphalt binder affects the
pavement performance. Since the rheological properties of
asphalt change during production and continue to change
subsequently in service, there is necessity to study the
phenomenon of ageing. The first significant hardening of
asphalt takes place in pug mill or drum mix plant where heated
aggregate is mixed with hot asphalt cement. Substantial
rheological changes such as decrease in penetration and
increase in viscosity of asphalt binder takes place during short
mixing period from both air oxidation and loss of more
volatile components. Age hardening of asphalt continues,
although at much slower rate, while the HMA is processed
through a surge or storage silo, transported to the paving site,
laid, and compacted. After the HMA pavement has cooled and
been opened to traffic, age hardening continues at a
significantly slower rate for first two to three years until the
pavement approaches its limiting density under traffic.
Thereafter the rate of age hardening is further reduced at
longer time periods are needed to decide to changes in the
rheological properties of asphalt cement.
Rutting resistance depends mainly on aggregate properties and
mix design although binder characteristics are a secondary
factor. The behavior is characterized in the SUPERPAVE
specification by the complex shear modulus measured using
dynamic shear rheometer (DSR). G*/Sin δ is the rutting
resistance parameter, while G* Sin δ is the fatigue resistance
parameter, according to SUPERPAVE specifications.
1.1 Objectives of Present Paper
1) To select the flexible pavement stretches for asphalt
binder extraction.
2) To evaluate the change in basic binder property like
softening point.
3) To evaluate the visco-elastic behavior of extracted neat
bitumen of grade 60/70 by direct shear rheometer test.
4) To determine the rutting and fatigue resistance of binder
under existing pavement conditions.
2. LITERATURE REVIEW
Conventional Bituminous materials have tended to perform
satisfactorily in most highway pavement and airfield runway
applications. With conventional methods such as penetration,
viscosity, ductility and ring and ball softening point may still
adequately describe the rheological characteristics of
conventional bitumen, they have limited ability to accurately
predict the relative performance of modified materials.
Currently, dynamic shear rheometer is identified as a powerful
tool to study the rheological characteristics.

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Cho proposed a new experimental method called dynamic
shear rheometer. This method was used to measure asphalt-
aggregate interfacial properties. A degree of moisture damage
relating to the interfacial properties was then quantified using
linear viscoelastic concepts to propose a meaningful
parameter, called wet to dry yield shear stress ratio. [1]
Apeagyei et al., adopted the use of higher recycled asphalt
pavement (RAP) percentages with locally available binders.
The results indicated that measured binder stiffness of high-
RAP mixtures were not significantly affected by RAP amount.
The correlation between binder stiffness and flow number for
the selected high-RAP mixtures considered was good. The
study concluded that the addition of higher amounts of RAP to
asphalt concrete mixtures did not result in excessively
stiffened mixture. [2]
A study was conducted to estimate E values of two commonly
used hot mix asphalt (HMA) mixes. They observed that
rotational viscometer (RV) test data overestimate the E values
in the case of stiff binders. Conversely, dynamic shear
rheometer (DSR) test data predict significantly lower E values
of asphalt mixes. The study provided transportation
professionals with a better understanding of material input
parameters that influence E values of asphalt mixes [3]
Badawy et al., investigated two models for Levels 2 and 3 hot-
mix asphalt (HMA) dynamic modulus (E) predictions using
dynamic shear rheometer. The two models were NCHRP 1-
37A and NCHRP 1-40D. The primary difference between the
two is the binder stiffness parameter; viscosity or shear
modulus. The influence of the binder characterization input
level on the performance of the predictive models was
evaluated. [4]
The viscoelastic behavior of asphalt mixtures can be
conveniently presented in the form of a stiffness master curve
in various engineering applications. Kalapi G. Biswas(2007)
described and compared the methods for constructing asphalt
mixture master curves utilizing stiffness predictive equations
for asphalt binders and mixtures, in addition to using
laboratory measurements, as an alternative to FWD back
calculation analysis. [5]
An effort to characterize asphalt emulsions that are typically
used in cold in-place recycling applications for asphalt binders
was done. Four asphalt emulsions were investigated: CRS-2P,
CSS-1, EE, and HFMS-2P. The air-cured samples were aged
in the pressure aging vessel. The residues were tested using
the bending beam rheometer at low temperatures and the
dynamic shear rheometer at high and intermediate
temperatures. The methods described in AASHTO M320 and
MP1a specifications were used to determine critical
temperatures for four asphalt emulsions and master curves of
absolute value of the complex modulus G* were obtained to
investigate rheological behavior of the residues. [6]
With increasing use of modified asphalt binders, the correct
compaction temperature range for asphalt mixtures containing
these binders needs to be determined. However, the current
procedure often provides unacceptably high temperatures for
modified binders. In one of the studies, the shear properties of
the mixture compacted at four temperatures was evaluated.
These properties improved to some extent with an increase in
temperature, except for strain-controlled fatigue damage.
Finally, it was concluded that the changes in the shear stiffness
of the asphalt binder was one of the responsible factors for the
changes in mixture shear properties. [7]
Tan Yi-Qiu et al., investigated the interactions between
granites and asphalts based on rheology. The rheological
properties of asphalt mastics using different granite powders
and different filler-asphalt ratios were measured using a
dynamic shear rheometer. Statistically significant relations
between the rheological properties of the granite-asphalt
mastics and the moisture stability of granite-asphalt mixtures
were found. For practical application, the selection criteria for
selecting granite aggregates for use in roads were developed.
[8]
3. METHODOLOGY
The study stretch selected was From Sirsi circle to RV college
of Engineering along Bangalore – Mysore State Highway 17.
The stretch is a four lane divided highway scheduled for up
gradation to six lanes. The pavement composition along the
arterial road stretch included of surface, base and sub-base
course upon sub grade. The existing flexible pavement crust
thickness and compositions were noted along the roadway at
shoulder level. Based on the composition and thickness of the
individual layers, the stretch was divided into six sections and
the details are as given in Table 1. As per BBMP records the
age of pavement varied between 3 to 4 years.
Table 1: Section number and composition for the study sections
Section Section
number
Details
R.V. College of Engineering to
Bangalore University
C1 BC+DBM=200mm, Base=200mm, Sub-Base=200mm
Bangalore University to Gopalan C2 BC+DBM=150mm, Base=200mm, Sub-Base=200mm

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Arcade
Gopalan Arcade to Pipeline Road C3 BC+DBM=100mm, Base=200mm, Sub-Base=200mm
Deepanjali Nagar to Satellite Bus
Station
C4 BC+DBM=150mm, Base=200mm, Sub-Base=100mm
Satellite Bus Station to Gopalan Mall C5 BC+DBM=80mm, Base=200mm, Sub-Base=100mm
Gopalan Mall to Sirsi Circle C6 BC+DBM=80mm, Base=200mm, Sub-Base=120mm
The original asphalt binder used for construction was 60/70
grade. The details of the basic properties of this asphalt binder
are as shown in Table 2.
Table 2: Basic properties of original asphalt binder
Basic tests Result Limit as per IS-73-1961 & 2006
Penetration test @ 25°C, 0.1 mm, 100
g, 5 secs
65 60-70
Specific gravity @ 25°C, mm 0.982 0.99
Water % by mass (max) 0.207 0.20
Softening point 44 40-55
Solubility in tri-chloroethylene %,
mm
98.30 99
RAP samples were obtained from these sections. Samples
were taken from the test pits dug to a depth equal to thickness
of the surface layer. Samples were then subjected to extraction
process using Centrifugal extractor to separate binder from
aggregates.
3.1 Extraction Process
Extraction of asphalt cement for rheological testing was done
as per IRC SP 11-1998. The paving mixture was repeatedly
washed and filtered with solvents in the centrifugal extractor
apparatus. A known weight of sample was weighed and placed
in the bowl of extractor apparatus and covered with
commercial grade of benzene. Sufficient time was allowed for
the solvent to disintegrate the sample before running the
centrifuge. The cover of the bowl was clamped tightly. A
beaker was placed under to collect the extract. The machine
was revolved slowly and then gradually at a speed of 3600
revolutions per minute. The speed was maintained till the
solvent ceases to flow from the drain. The machine was
allowed to stop and 200ml of benzene was added and the
above procedure was repeated.
3.2 Recovery Process
Recovery of asphalt cement was done by Abson method of
distillation as per ASTM D1856. This method covers the
recovery by the Abson method of asphalt from a solution from
a previously conducted extraction. The asphalt was recovered
with properties substantially the same as those it possessed in
the bituminous mixture and in quantities sufficient for further
testing. In this process the solvent of benzene and bitumen was
heated at 135°C until all the benzene vaporizes and gets
collected in a beaker passing through the condenser. Asphalt
cement was left out as a residue in the round bottom flask
placed in a heating mantle. Similarly asphalt cement samples
of all the six sections were obtained.
Softening point test was conducted on reclaimed binder and
the results are as presented in Table 3.
Table 3: Softening point test results
Section
Softening point on(°C) :
Reclaimed binder Original binder Specification
C1 48
44 40-55
C2 47
C3 47
C4 48
C5 46
C6 47

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The average value of softening point was found to be 47°C.
3.3 Dynamic Shear Rheometer
To study the rheological properties of these asphalt cement
samples, dynamic shear rheometer test was conducted at
pavement service temperature as per IRC 53-2010.
Preparing Test Specimens:- The surfaces of the test plates
were carefully cleaned and dried so that the specimen adheres
to both plates uniformly and strongly. The chamber is brought
to approximately 45°C so that the plates are preheated prior to
the mounting of the test specimen. This will provide sufficient
heat so that the asphalt binder may be squeezed between the
plates for trimming and to ensure that the asphalt binder
adheres to the plates. The test procedure is as follows:
1. Bring the specimen to the test temperature + 0.1°C.
2. Set the temperature controller to the desired test
temperature, including any difference as required.
Allow the temperature to come to the desired
temperature.
3. The test shall be started only after the temperature
has remained at the desired temperature + 0.1 °C for
at least 10 minutes.
4. After temperature equilibration, anneal the specimen
for 5 minutes.
5. Strain Control Mode--When operating in a strain
controlled mode, determine the strain value according
to the value of the complex modulus. Control the
strain within 20 % of the target value calculated by
equation given below:
γ = 12.0/ (G*) 0.29
(1)
Where:
γ = shear strain in percent
G* = complex modulus in kPa
6. Stress-Controlled Mode: When operating in a stress-
controlled mode, determine the stress level according
to the value of the complex modulus. Control the
stress within 20% of the target value calculated by
equation below:
τ = 0.12(G*) 0.71
(2)
Where:
τ = shear stress in kPa
7. Software is available with the dynamic shear
rheometer that will control the stress level
automatically without control by the operator.
8. When the temperature has equilibrated, condition the
specimen by applying the required strain for 10
cycles at a frequency of 10 rad/s.
9. Obtain test measurements by recording data for an
additional 10 cycles.
10. The data acquisition system automatically acquires
and reduces the data when properly activated.
4. ANALYSIS OF RESULTS
To determine the rheological parameters for selected stretch of
flexible pavement, dynamic shear rheometer test was
conducted on the reclaimed binder samples, test results are as
presented in Table 4. The test was conducted under stress
controlled mode (constant stress σ(Pa): 2.45e+03) at a
frequency of 10 rad/s. and at a constant temperature of 46°C.
Table 4: Test results of dynamic shear rheometer
Secti
on
num
ber
Phase
angle
δ(°)
Complex
modulus G*
(Pa)
Elastic
modulus
G‫׳‬(Pa)
Viscous
modulus
G‫׳׳‬(Pa)
Complex
viscosity
Ƞ* (Pas)
Strain
γ
G*/sin δ
(Rutting
parameter)
kPa
G* sin δ
(Fatigue
parameter)
kPa
C1 52.54 31.98e+04 19.5e+04 25.4e+04 31.9e+03 76.45e-02 402.90 253.80
C2 58.51 9.767e+04 5.10e+04 8.33e+04 9.74e+03 2.5033e-02 114.53 83.22
C3 55.86 22.13e+04 12.4e+04 18.3e+04 22.1e+03 1.105e-02 267.32 182.91
C4 77.35 3.116e+04 6.83e+03 3.04e+04 3.11e+03 7.8469e-02 31.936 30.34
C5 62.91 20.79e+04 9.47e+04 18.52e+04 20.74e+03 1.176e-02 233.60 185.09
C6 70.59 8.276e+04 2.75e+04 7.81e+04 8.25e+03 2.954e-02 87.748 77.99

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The Relation between G’, G” and G* of all the six stretches
with varying phase angles is as shown in Figure 1.
Fig1: Graph representing relation between Elastic modulus
(G’), viscous modulus (G”), Complex modulus (G*) and
phase angle δ
SUMMARY
The binder of grade 60/70, reclaimed from selected flexible
pavement stretches was subjected to DSR test. The main
findings have been summarized below.
1) From Table 3, the softening point test results indicated
that the binder exhibited a small increase in the softening
point temperature which indicated that the binder has
become harder with its age, while it still remains within
specification limits.
2) The dynamic shear rheometer (DSR) is used to
characterize the viscous and elastic behavior
of asphalt binders at medium to high temperatures. As
with other Superpave binder tests, the actual temperatures
anticipated in the area where the asphalt binder will be
placed determine the test temperatures used. The typical
values of complex modulus (G*) can range from about
0.07 to 0.87 psi (500 to 6000 Pa), while the phase angle
(δ) can ranges from about 50 to 90°. A phase angle of 90°
is essentially complete viscous behavior.
3) The phase angle (δ) is the lag between the applied shear
stress and the resulting shear strain. From the results
obtained it was observed that the phase angle ranges from
52.54° to 77.35° for the six sections of pavement. Larger
the phase angle, more viscous the material. The test
results indicated that binder from all the stretches were
highly viscous.
4) G* and δ are used as predictors of HMA rutting and
fatigue cracking. Early in pavement life rutting is the
main concern, while later in pavement life fatigue
cracking becomes the major concern. According to
SUPERPAVE Specifications, rutting parameter (G*/sinδ)
for an aged asphalt binder shall be ≥ 2.2 kPa. The range of
rutting parameter values obtained range from 31.938 to
402.9 kPa. Similarly, SUPERPAVE specification for
fatigue parameter (G*sinδ) shall be ≤ 5000 kPa. The
range obtained is from 30.34 to 253.80 kPa. The section
C4 has the least resistance to rutting and fatigue while
section C1 has the highest. But, the values for all the
sections are within permissible limits.
5) The DSR test results indicated that the binder, even after
3 to 4 years of performance, was stiff enough to resist
fatigue and rutting failures. The presence of patches of
rutting/ fatigue failure could be as a result of subgrade
condition, drainage system and traffic load repetitions.
REFERENCES
[1]. Dong-Woo Cho and Hussain U. Bahia, “New Parameter
to Evaluate Moisture Damage of Asphalt-Aggregate Bond in
Using Dynamic Shear Rheometer”, Journal of materials in
Civil Engineering, ASCE, Volume 22, No 3, Pages 267-276
(2010).
[2].Alex K. Apeagyei, Trenton M. Clark, and Todd M. Rorrer,
“Stiffness of High-RAP Asphalt Mixtures: Virginia’s
Experience” Journal of materials in Civil Engineering, ASCE,
Volume 25, No 6, Pages 747-754 (2013).
[3].Zahid Hossain, S. and Musharraf Zaman,“Sensitivity of
Oklahoma Binders on Dynamic Modulus of Asphalt Mixes
and Distress Functions”, Journal of materials in Civil
Engineering, ASCE, Volume 24, No 8, Pages 1076-1088
(2012).
[4].Sherif El-Badawy, Fouad Bayomy and Ahmed Awed,
“Performance of MEPDG Dynamic Modulus Predictive
Models for Asphalt Concrete Mixtures: Local Calibration for
Idaho”, Journal of materials in Civil Engineering, ASCE,
Volume 24, No 11, Pages 1412-1421 (2012).
[5].Kalapi G. Biswas and Terhi K. Pellinen, “Practical
Methodology of Determining the In Situ Dynamic Complex
Moduli for Engineering Analysis”, Journal of materials in
Civil Engineering, ASCE, Volume 19, No 6, Pages 508-514
(2007).
[6].Mihai O. Marasteanu and Timothy R. Clyne, “Rheological
Characterization of Asphalt Emulsions Residues”, Journal of
materials in Civil Engineering, ASCE, Volume 18, No 3,
Pages 298-307 (2006).
[7]. Haleh Azari, Richard H. McCuen and Kevin D. Stuart,
“Optimum Compaction Temperature for Modified Binders”,
Journal of materials in Civil Engineering, ASCE, Volume
129, No 5, Pages 531-537 (2003).
[8].Tan Yi-qiu, Xiaolin Li and Xingye Zhou, “Interactions of
Granite and Asphalt Based on the Rheological Characteristics”
Journal of materials in Civil Engineering, ASCE, Volume 22,
No 8, Pages 820-825 (2010).

Determining the rheological properties of asphalt

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