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TRANSCRIPT
Sigurdur ErlingssonAbubeker Ahmed
The Svappavaara road test sections
Field coring and laboratory tests
VTI notat 30A-2015 | The Svappavaara road test sections. Field coring and laboratory tests
www.vti.se/en/publications
VTI notat 30A-2015Published 2015
VTI notat 30A-2015
The Svappavaara road test sections
Field coring and laboratory tests
Sigurdur Erlingsson
Abubeker Ahmed
VTI notat 30A-2015
Preface
This VTI note describes and gives results from the laboratory testing of specimens taken from four
new instrumented test road sections that have been built on E45 close to the Svappavaara municipality
in Norrbotten County in Northern Sweden. The structures are situated on road E45 close to the
intersection to road E10. The structures are instrumented with road performance and climate sensors.
The structures will be monitored over the years to come.
As a part of the monitoring programme drilled asphalt specimens were taken from the road structure
and tested at VTI’s material testing laboratory in Linköping. Furthermore, samples from the unbound
base course have been taken and tested.
The aim of this report is to briefly describe the laboratory testing process as well as the testing results.
The Swedish Transport Administration (STA) has financed the project. The contact person has been
Johan Ullberg.
Linköping, November 2015
Sigurdur Erlingsson and Abubeker Ahmed
VTI notat 30A-2015
Quality review
Internal peer review was performed by Björn Kalman. Sigurdur Erlingsson and Abubeker Ahmed has
made alterations to the final manuscript of the report. The research director Björn Kalman examined
and approved the report for publication on 24 November 2015. The conclusions and recommendations
expressed are the author’s/authors’ and do not necessarily reflect VTI’s opinion as an authority.
Kvalitetsgranskning
Intern peer review har genomförts av Björn Kalman. Sigurdur Erlingsson och Abubeker Ahmed har
genomfört justeringar av slutligt rapportmanus. Forskningschef Björn Kalman har därefter granskat
och godkänt publikationen för publicering 24 november 2015. De slutsatser och rekommendationer
som uttrycks är författarens/författarnas egna och speglar inte nödvändigtvis myndigheten VTI:s
uppfattning.
VTI notat 30A-2015
Table of content
Summary .................................................................................................................................................7
Sammanfattning .....................................................................................................................................9
1. Introduction .....................................................................................................................................11
2. The test sections ...............................................................................................................................12
3. Coring ...............................................................................................................................................15
4. Laboratory test results ....................................................................................................................17
4.1. Volumetric properties tests ........................................................................................................17 4.2. Stiffness tests..............................................................................................................................18
4.2.1. Indirect tensile stiffness modulus test ...................................................................................18 4.2.2. Frequency sweep stiffness modulus test ...............................................................................22 4.2.3. Frequency sweep shear modulus test ....................................................................................24
4.3. Fatigue test .................................................................................................................................27 4.4. Unbound granular base course ...................................................................................................28
5. Conclusions ......................................................................................................................................32
References .............................................................................................................................................33
Appendix A ...........................................................................................................................................35
VTI notat 30A-2015 7
Summary
The Svappavaara road test sections. Field coring and laboratory tests
by Sigurdur Erlingsson (VTI) and Abubeker Ahmed (VTI)
This report describes laboratory testing of specimens taken from four new instrumented test road
sections that have been built on E45 close to the Svappavaara municipality in Norrbotten County in
Northern Sweden. The structures are located about 100 km north of the Arctic Circle in a climate that
is characterized by long cold winters and short mild summers.
The four test sections were built in a conventional manner. Each structure is about 200–250-metre-
long with a central 100-metre-long part defined as the actual test section. All structures are in total
60 centimetres in thickness resting on top of a 70-centimetre-thick old existing road. The bitumen
bound part of all the four structures consists of four layers; a thin surface course layer, two binder
layers and a road base layer. All structures have the same wearing course, TSK 16 with a standard
160/220 penetration grade bitumen. The main difference between the structures lies in the binder as
well as the two road base layers. In structure 01 polymer modified binder were used in the binder layer
as well as in both road base layers whilst in structure 02 only the binder layer was polymer modified.
Structure 03 consists on the other hand of a binder layer and road base layers mixed with conventional
penetration grade bitumen materials. Structure 04 has a binder layer with conventional penetration
grade bitumen but the road base layers consists of a 2 × 90-millimetre-thick layers of large aggregates
mixed with a cold emulsion.
As a part of the monitoring programme drilled asphalt specimens were taken in 2013 from the road
structure and tested at VTI's material testing laboratory in Linköping. Furthermore, samples were
taken from the unbound base course and tested. This report presents the test results for asphalt bound
layers as well as for the unbound base course. For the bound layers the testing procedure included
volumetric properties, stiffness modulus and fatigue tests for the different types of conventional and
polymer modified asphalt mixtures. The tests were conducted in accordance with the Swedish or the
equivalent European standards. For the unbound base course fundamental properties were estimated as
well as stiffness and permanent deformation properties for different moisture contents.
The project is sponsored by the Swedish Transport Administration.
VTI notat 30A-2015 9
Sammanfattning
Test sträckor på E45 vid Svappavaara – provkärnor och laboratorietestning
av Sigurdur Erlingsson (VTI) och Abubeker Ahmed (VTI)
Denna rapport beskriver laboratorieprovningar av provkroppar tagna från fyra instrumenterade
vägsträckor på E45 nära samhället Svappavaara i Norrbottens kommun. Sträckorna ligger omkring
100 kilometer norr om polcirkeln i ett klimat som kännetecknas av långa kalla vintrar och korta milda
somrar.
De fyra teststräckorna är byggda på konventionellt sätt. Varje delsträcka är omkring 200–250 meter
lång med en central del på 100 meter som utgör den egentliga teststräckan. Alla konstruktionerna har
en överbyggnadstjocklek på 60 centimeter och ligger ovanpå en gammal vägkonstruktion som
uppskattas till 70 centimeter i tjocklek. Den bitumenbundna delen består av fyra lager, ett ytlager,
bindlager samt två bundna bärlager. Ytlagret är identiskt på alla sträckorna TSK 16 med 160/220
standard bitumen. Huvudskillnaden i strukturerna ligger i sammansättningen av bindlagret samt de två
bundna bärlagren. I struktur 01 används polymerer i bindlagret samt de två bundna bärlagren men i
struktur 02 är endast bindlagret polymermodifierade. Struktur 03 och 04 är sedan helt utan polymerer.
Struktur 04 har sedan ett 2 × 90 millimeter bundet bärlager som består av storstensskelett makadam
blandad med kall emulsion (Viacomac från NCC).
Som en del i uppföljningsprogrammet togs på hösten 2013 borrade kärnor från alla sträckorna som
sedan testades i VTI:s laboratorium i Linköping. Dessutom togs det prov från det obundna bärlagret
som också testades. Denna rapport presenterar resultaten av laboratorietesterna. För de bundna lagren
bestämdes sammansättning, styvhet samt utmattningsmotstånd. Alla tester utfördes enligt svensk eller
ekvivalent europeisk norm. För det obundna bärlagret bestämdes några fundamentala egenskaper samt
styvhet och permanenta deformationsegenskaper vid olika fuktkvoter.
Projektet är finansierat av Trafikverket.
VTI notat 30A-2015 11
1. Introduction
Four new Long Term Pavement Performance (LTPP) pavement test structures were built in
Norrbotten County in Northern Sweden in 2012. The structures are situated on the road E45 close to
the intersection to road E10 near the village Svappavaara. This is about 100 km north of the Arctic
Circle in a climate that is characterized by long cold winters with short mild summers where the
duration of the thawing period exceeds two months. The structures are instrumented with road
performance and climate sensors. The structures will be monitored over the years to come.
The Norrbotten County is a sparsely populated area where the pavement structures usually consist of
thin pavements and the traffic volume is low. In terms of traffic volume, the AADT for the sections
was 1325 in the year 2010 with 14% classified as heavy vehicles. In 2012 a local iron ore operator
received a special permission to transport ore along 160 km of the road network using vehicles that are
25 m long with a 90 tonnes gross weight, instead of the permissible 60 tonnes. The vehicles consist of
a single wheel steering axle and three tridem axles. The axle’s weights are 1 × 9 + 3 × 27 = 90 tonnes.
Thus, the individual axle loads fulfil the current legislation but as the vehicles are longer with more
axles and their total weight exceeds the current legislation.
Due to this new ore transport it was deemed necessary to strengthen the local road network. As a part
of evaluating pavement performances for very heavy vehicles four test structures were selected and
built with the main objectives to increase the knowledge about pavement response and performance
under heavy loading in cold climate with seasonal variation.
The four test sections were built in a conventional manner. All structures were in total 60 cm in
thickness resting on top of an old existing road. The bitumen bound part of all the four structures
consist of four layers; a thin surface course layer, a binder layer and two road base layers. All
structures have the same wearing course TSK 16, a thin layer asphalt course with 16 mm maximum
chipping size, with 160/220 penetration grade bitumen. The main difference between the structures
lies in the structures binder and road base layers. Structure 01 has a polymer modified binder course
and road base layers whilst structure 02 has the same polymer modified binder course as structure 01
over a more conventional road base layers. Structure 03 consists of conventional bound materials, with
70/100 penetration grade bitumen for the binder course as well as for the two road base layers.
Structure 04 has a conventional binder course but the two road base layers consists of a large
aggregate skeleton layers mixed with a cold mix emulsion with 160/220 penetration grade bitumen.
As a part of the monitoring programme drilled asphalt specimens were taken from the road structure
and tested at VTI´s material testing laboratory in Linköping. Furthermore, samples were taken from
the unbound base course and tested.
The aim of this report is to briefly describe the laboratory testing process as well as the testing results.
12 VTI notat 30A-2015
2. The test sections
The four test sections are located on E45 close to the intersection with E10 in the vicinity of the
Svappavaara village (see Figure 1). The test structures were built in the summer of 2012. The wearing
course was placed in the beginning of July 2013.
Each test section is around 200–250 m long, with a central 100 m long part defined as the actual test
section. In the remaining parts between the sections some overlapping of layers can occur.
Figure 1. Overview of the four test sections.
The test sections were built in a conventional manner on top of an existing road that had been rebuilt
in 1975. The old pavement structure was a thin flexible structure with 5 cm AC on top of 15 cm of
unbound gravelly base course over a subbase consisting of 65 cm of natural gravel. The top 15 cm of
the old pavement were milled and widened in accordance with the new geometric design, leaving a
sandy gravel layer on top of the native soil. The remains of the old road structure can therefore be
expected to consist of approximately 70 cm of sandy gravel resting on top of the native silty sand
subgrade.
The cross sections of the four test structures are shown in Figure 2. A more detailed description of the
layer composition is further provided in Table 1. The layer thicknesses of structures 01–03 are
identical but structure 04 has a thicker road base course, consisting of a cold asphalt concrete mix, and
a reduced subbase thickness in order to have the same total thickness as the other structures.
The bitumen bound part of all the four structures consists of four layers; a thin surface course layer, a
binder layer and two road base layers. All structures have the same wearing course TSK 16 with
160/220 penetration grade standard bitumen. Structure 01 has a polymer modified binder course as
well as the two road base layers whilst structure 02 has the same polymer modified binder course as
structure 01 but a more conventional road base layers. Structure 03 consists of conventional bound
materials, with a 70/100 penetration grade bitumen for the binder course as well as for the two road
base layers. Structure 04 has a conventional binder course but the two road base layers consists of a
large aggregate skeleton layers mixed with cold emulsion with 160/220 penetration grade bitumen.
1 2
3 4
VTI notat 30A-2015 13
Figure 2. Cross sections of the test sections. Structures 01 to 03 have same layer thicknesses.
Structure 01, 02 and 03
0.0
2.0
8.0
20.0
30.0
60.0
Depth [cm]
Unbound Base Course
Crushed rock 0/31.5
Asphalt Road base
2 × 60 mm layers
Binder Course
Surface Course
Structure 04
0.0
2.0
8.0
26.0
36.0
130.0
Depth [cm]
Unbound Base Course
Crushed rock 0/31.5
Asphalt Road base
2 × 90 mm layers
Binder Course Surface Course
Subbase Crushed rock 0/90 Subbase
Crushed rock 0/90
Subbase Sandy gravel
(old existed road)
Subbase Sandy gravel
(old existed road)
Subgrade
Gravelly till / sandy silt Subgrade Gravelly till / sandy silt
130.0
60.0
14 VTI notat 30A-2015
Table 1. Properties of the layers for the four different test structures.
Structure
01 02 03 04
Wearing course
20 mm
asphalt surfacing TSK16 160/220
20 mm
asphalt surfacing TSK16 160/220
20 mm
asphalt surfacing TSK16 160/220
20 mm
asphalt surfacing TSK16 160/220
Binder course 60 mm
ABb22 with Nypol 64-34
60 mm
ABb22 with Nypol 64-34
60 mm
ABb22 70/100
60 mm
ABb22 70/100
Road base
60 mm
AG22 40/100-75
+
60 mm
AG22 90/150-75
2 x 60 mm
AG22 160/220
2 x 60 mm
AG22 70/100
2 x 90 mm
Large aggregate AC (Viacomac 32) 160/220
Unbound base course
100 mm
Crushed rock 0/31.5
100 mm
Crushed rock 0/31.5
100 mm
Crushed rock 0/31.5
100 mm
Crushed rock 0/31.5
Subbase
300 mm
Crushed rock 0/90
+
300 mm
Crushed rock 0/90
+
300 mm
Crushed rock 0/90
+
240 mm
Crushed rock 0/90
+
≈ 700 mm
Sandy gravel
(old existed road)
≈ 700 mm
Sandy gravel
(old existed road)
≈ 700 mm
Sandy gravel
(old existed road)
≈ 700 mm
Sandy gravel
(old existed road)
Subgrade Gravelly till / sandy silt
Gravelly till / sandy silt
Gravelly till / sandy silt
Gravelly till / sandy silt
A more detailed description of the composition of the bound layers can be found in Erlingsson and
Carlsson (2014).
VTI notat 30A-2015 15
3. Coring
Figure 3 gives an overview of the test road structures.
Figure 3. The test road structures after opening the road for traffic.
The coring took place on September 23, 2013. A specific scheme as given in Figure 4 was used for the
coring.
Figure 4. Overview of the coring scheme that was applied at all test sections. The coring area were
situated between the wheel paths.
100 m
Coring areas
5 m
To Svappavaara
5 m 10 m 10 m 10 m 10 m 10 m 10 m 10 m 10 m 10 m
N
S
Pole with a data logger box
Instrumentation
To Vittangi
16 m
16 VTI notat 30A-2015
An overview of the number of cores is given in Table 2.
Table 2. Overview of the number of cylindrical cores drilled from the test roads.
Cylindrical cores
Section = 100 mm = 150 mm = 300 mm
1 4 10
2 3 10
3 15 10
4 1 10 4
Besides the cylindrical cores, a disturbed sample was taken from the unbound base course.
Based on the cores, thickness of each layer was estimated. The average results are given in Table 3
and thickness of each drilled core is given in Appendix A.
Table 3. Average thickness [mm] of each layer based on the drilled cores.
Section 1 2 3 4
Wearing course 16.5 16.3 18.2 17.2
Binder course 65.8 58.7 60.9 62.3
Road base upper 63.6 56.2 63.0 93.5
Road base lower 66.6 65.6 67.2 110.6
Total 212.4 196.8 209.2 283.5
VTI notat 30A-2015 17
4. Laboratory test results
Laboratory tests were conducted on samples cored from the test structures described in the preceding
sections. The laboratory tests carried out cover the volumetric properties, stiffness, fatigue and shear
modulus tests of the bound layers. The stability of the large aggregate cold mix used as road base in
structure 4 was poor and therefore it was not possible to carry out any testing on them. They have
therefore been excluded from this report. Repeated load triaxial tests (RLT) were performed on the
unbound aggregate base. The results are summarized in the subsequent sections.
4.1. Volumetric properties tests
The volumetric properties of the different types of mixes used in the test sections were determined
according to the European standards (SS-EN12697-5, SS-EN12697-6 and SS-EN12697-8). Table 4
presents the compact densities and the air voids of the asphalt layers of the different test structures.
Figures 5 and 6 show the compact densities and air voids with their corresponding standard deviations.
The binder contents of the mixes were determined using the solvent extraction method and
subsequently the grain size distributions of the mixes were obtained in accordance with the European
standards SS-EN 12697-1 and SS-EN 12697-2, respectively. The grain size distribution curves of the
different mixes are shown in Figure 7.
Table 4. Volumetric properties of the layers for the four different test structures.
Structure Layer Mix type
Compact
density
[g/cm3]
Air void
[%]
Binder
cont.
[%]
1 & 2 Binder Course ABb22 Nypol 64-34 2.50 2.20 4.95
3 & 4 Binder Course ABb22 70/100 2.51 3.37 4.53
1 Road base – upper AG22 40/100-75 2.50 2.73 4.95
1 Road base – lower AG22 90/150-75 2.48 2.87 4.69
2 Road base – upper & lower AG22 160/220 2.50 2.91 4.42
3 Road base – upper & lower AG22 70/100 2.51 3.67 4.93
Figure 5. Compact densities of the different mixes with their standard deviations.
2,40
2,42
2,44
2,46
2,48
2,50
2,52
2,54
ABb22 Nypol 64-34 ABb22 70/100 AG22 40/100-75 AG22 90/150-75 AG22 160/220 AG22 70/100
Max
imum
den
sity
(gm
/cm
3)
Mixture
18 VTI notat 30A-2015
Figure 6. Air voids of the different mixes with their standard deviations.
Figure 7. Grain size distribution curves of the different mixes.
4.2. Stiffness tests
Three different types of stiffness tests were carried out in accordance with the Swedish industry
standard (FAS method), a sinusoidal indirect stiffness modulus test, a frequency sweep stiffness
modulus test and a dynamic shear modulus.
4.2.1. Indirect tensile stiffness modulus test
The stiffness test was carried out at three temperatures (3, 10 and 20C) in accordance with the
Swedish industry standard FAS 454. Figure 8 shows the actual test setup and Figure 9 shows the load
pulses. The load pulse consists of 0.1 sec loading and 2.9 sec rest period. Figures 10 and 11 present the
stiffness modulus of the binder course and the asphalt road base course mixes, respectively.
0,00
0,50
1,00
1,50
2,00
2,50
3,00
3,50
4,00
4,50
ABb22 Nypol 64-34 ABb22 70/100 AG22 40/100-75 AG22 90/150-75 AG22 160/220 AG22 70/100
Air
vo
id (
%)
Mixture
0%
10%
20%
30%
40%
50%
60%
70%
80%
90%
100%
0,01 0,1 1 10 100
Per
ssen
t p
assi
ng
Sieve size (mm)
St. 1 &2 Binder course ABb22 Nypol 64-34
St. 3 & 4 Binder course ABb22 70/100
St. 1 Upper asphalt base course AG22 40/100-75
St. 1 Lower asphalt base course AG22 90/150-75
St. 2 Upper and lower asphalt base courses AG22 160/220
St. 3 Upper and lower asphalt base courses AG22 70/100
VTI notat 30A-2015 19
Figure 8. Indirect stiffness modulus test setup.
Figure 9. Load pulses for stiffness modulus test.
0
200
400
600
800
1000
1200
0 2 4 6 8 10 12 14
Lo
ad (
N)
Time (sec)
20 VTI notat 30A-2015
Figure 10. (a) Stiffness modulus for the binder course mixtures of the test structures at three test
temperatures. (b) Curve fitted data.
0
2000
4000
6000
8000
10000
12000
St. 1 Binder course
ABb22 Nypol 64-34
St. 2 Binder course
ABb22 Nypol 64-34
St. 3 Binder course
ABb22 70/100
St. 4 Binder course
ABb22 70/100
Sti
ffnes
s m
od
ulu
s (M
Pa)
Mixture
3°C 10°C 20°C
(a)
0
2000
4000
6000
8000
10000
12000
14000
0 5 10 15 20 25
Sti
ffnes
s m
od
ulu
s (M
Pa)
Temperature (C)
St. 1 and 2 Binder course ABb22 Nypol 64-34
St. 3 and 4 Binder course ABb22 70/100
(b)
VTI notat 30A-2015 21
Figure 11. (a) Stiffness modulus for the asphalt base course mixtures of the test structures at three
temperatures. (b) Curve fitted data.
The measured stiffness data is fitted using exponential function, shown in Equation (1). The curve
fitting parameters are given in Table 5.
refTTb
ref eEtE
(1)
where E is the stiffness modulus, Eref is the reference stiffness modulus at a reference temperature of
Tref = 10C, T is temperature in °C, and b is a regression constant.
Table 5. Curve fitting parameters for stiffness modulus data.
Parameters ABb22 Nypol
64-34
ABb22
70/100
AG22
40/100-75
AG22
90/150-75
AG22
160/220
AG22
70/100
b 0.090 0.079 0.096 0.095 0.091 0.082
Eref 3851.6 6756.2 4186.9 4013.1 5767.1 6569.8
R2 0.979 0.990 0.979 0.964 0.981 0.966
0
2000
4000
6000
8000
10000
12000
St. 1 Upper asphalt
base course
AG22 40/100-75
St. 1 Lower asphalt
base course
AG22 90/150-75
St. 2 Upper and lower
asphalt base course
AG22 160/220
St. 3 Upper and lower
asphalt base course
AG22 70/100
Sti
ffnes
s m
od
ulu
s (M
Pa)
Mixture
3°C 10°C 20°C
(a)
0
2000
4000
6000
8000
10000
12000
14000
0 5 10 15 20 25
Sti
ffnes
s m
od
ulu
s (M
Pa)
Temperature (C)
St. 1 Upper asphalt base course AG22 40/100-75
St. 1 Lower asphalt base course AG22 90/150-75
St. 2 Upper and lower asphalt base course AG22 160/220
St. 3 Upper and lower asphalt base course AG22 70/100
(b)
22 VTI notat 30A-2015
4.2.2. Frequency sweep stiffness modulus test
The cyclic stiffness modulus test or the cyclic indirect stiffness modulus test consists of applying a
certain number of cyclic (sinusoidal) loading along the vertical diametral plane of a cylindrical
specimen to achieve a constant peak tensile strain along the horizontal diametral plane perpendicular
to the loading plane. The samples extracted from the test structures were tested at four temperatures
(-5, 0, 10 and 15 oC) and six loading frequencies (16, 8, 4, 1, 0.5 and 0.1 Hz). A similar test setup and
procedure as shown in Figure 8 was employed. The test results of the cyclic IDT tests are presented in
Figures 12 and 13 as master curves of the dynamic modulus and phase angle at a reference
temperature of 10 oC. A fitting function shown in Equation (2) was used to fit the master curve for
phase angle and a sigmoidal fitting function was used for dynamic modulus shown in Equation (3).
Arrhenius equation, Equation (4), was used as a shifting function:
2
11
1
b
af
c
e
ed
re
af
e
af
r
r
(2)
rf
Elogexp1
log
(3)
273
1
273
1log
ref
TTT
Ra (4)
T
rT
f
fa (5)
where is phase angle; a, b, c, d and e are phase angle master curve fitting parameters; E is the
dynamic modulus, fr is the reduced frequency, fT is the frequency at temperature T; α, β, γ and δ are
sigmoidal fitting function parameters for dynamic modulus master curve; aT is the shift factor, T is the
temperature in °C, Tref = 10C is the reference temperature and R is constant.
The speed, depth and loading frequency relationship shown in Equation (5) can be used to convert
speed into frequency (Said et al., 2013, Ahmed and Erlingsson, 2014):
Vzt log94.02.05.0log (6)
where t is the loading time in sec, z is the depth in meters and V is the speed in km/h.
The frequency at reference temperature fT is given as:
t
fT2
1 (7)
The curve fitting parameters are given in Table 6.
VTI notat 30A-2015 23
Figure 12. Master curves of dynamic modulus for different types of mixes at a reference temperature
of 10C.
Figure 13. Master curves of phase angle for different types of mixes at a reference temperature of
10C.
0
5000
10000
15000
20000
25000
1,E-02 1,E-01 1,E+00 1,E+01 1,E+02 1,E+03 1,E+04
Dyn
amic
mo
du
lus
(MP
a)
Reduced frequency (Hz)
St. 1 &2 Binder course ABb22 Nypol 64-34
St. 3 & 4 Binder course ABb22 70/100
St. 1 Upper asphalt base course AG22 40/100-75
St. 1 Lower asphalt base course AG22 90/150-75
St. 2 Upper and lower asphalt base courses AG22 160/220
St. 3 Upper and lower sphalt base courses AG22 70/100
0
10
20
30
40
50
60
1,E-02 1,E-01 1,E+00 1,E+01 1,E+02 1,E+03 1,E+04
Phas
e an
gle
()
Reduced frequency
St. 1 &2 Binder course ABb22 Nypol 64-34
St. 3 & 4 Binder course ABb22 70/100
St. 1 Upper asphalt base course AG22 40/100-75
St. 1 Lower asphalt base course AG22 90/150-75
St. 2 Upper and lower asphalt base courses AG22 160/220
St. 3 Upper and lower sphalt base courses AG22 70/100
24 VTI notat 30A-2015
Table 6. Fitting parameters for dynamic modulus and phase angle master curves.
Fitting
parameters
Mixture
ABb22 Nypol
64-34
ABb22
70/100
AG22
40/100-75
AG22
90/150-75
AG22
160/220
AG22
70/100
4.52 4.56 4.29 4.43 4.52 4.54
-3.38 -7.24 -2.23 -2.99 -4.41 -10.91
0.70 2.01 0.53 0.62 1.34 2.50
-0.49 -0.36 -0.73 -0.56 -0.48 -0.37
a 1.32 -0.16 0.74 -0.13 -0.78 -2.16
b 28.36 23.56 27.79 3.12 2.85 4.19
c 8.81 5.09 10.34 25.66 28.51 22.98
d 33.61 47.24 32.65 22.84 23.86 45.60
e 0.88 1.55 0.87 0.84 1.10 1.58
R 10279.82 12137.01 9975.38 9999.53 11411.17 12232.36
4.2.3. Frequency sweep shear modulus test
The dynamic shear modulus test was conducted in accordance with the method and the equipment
developed at Swedish National Road and Transport Research Institute, VTI. According to this method,
the two sides of a cylindrical asphalt specimen having diameter of 150 mm and thickness of ¼ of the
sample diameter are glued to two steel plates using epoxy. Then the glued specimen is mounted on the
shear box device where one of the plates is rigidly fixed and the other is then exposed to a vertical
sinusoidal cyclic loading over a range of frequencies. Further details on the testing procedure can be
found in Said et al. (2013). The dynamic shear testing procedure involves testing at four temperatures:
-5, 10, 30 and 50oC, and eight loading frequencies: 16, 8, 4, 2, 1, 0.5, 0.1 and 0.05 Hz. Figure 14
shows the shear box apparatus. The master curves for the dynamic shear modulus and the phase angle
are presented in Figures 15 and 16. The curve fitting parameters according to Equations (2), (3) and
(4) are given in Table 7.
VTI notat 30A-2015 25
Figure 14. Dynamic shear modulus test setup.
Table 7. Fitting parameters for dynamic shear modulus and phase angle master curves.
Fitting
parameters
Mixture
ABb22 Nypol
64-34
ABb22
70/100
AG22
40/100-75
AG22
90/150-75
AG22
160/220 AG22 70/100
3.65 3.71 3.71 3.67 3.65 3.67
-1.47 -1.57 -1.58 -1.41 -1.51 -1.59
0.38 1.14 0.56 0.49 0.98 1.15
-0.85 -0.64 -0.77 -0.76 -0.79 -0.70
a -0.98 -2.33 -1.24 -1.17 -1.64 -2.07
b 1.91 2.16 1.96 2.04 1.92 2.22
c 26.40 22.24 26.18 24.26 30.38 25.58
d 11.66 10.20 11.61 9.20 5.54 6.39
e 5.59 7.52 5.84 7.35 8.67 8.70
R 9714.08 10898.16 9761.96 10092.93 10980.30 10991.12
26 VTI notat 30A-2015
Figure 15. Master curves for dynamic shear modulus of the asphalt mixes at a reference temperature
of 10C.
Figure 16. Master curves for phase angle of the asphalt mixes at a reference temperature of 10C.
0
500
1000
1500
2000
2500
3000
3500
4000
4500
5000
1,E-08 1,E-06 1,E-04 1,E-02 1,E+00 1,E+02 1,E+04
Dynam
ic m
od
ulu
s (M
Pa)
Reduced frequency (Hz)
St. 1 &2 Binder course ABb22 Nypol 64-34
St. 3 & 4 Binder course ABb22 70/100
St. 1 Upper asphalt base course AG22 40/100-75
St. 1 Lower asphalt base course AG22 90/150-75
St. 2 Upper and lower asphalt base courses AG22 160/220
St. 3 Upper and lower asphalt base courses AG22 70/100
0
5
10
15
20
25
30
35
40
45
50
1,E-08 1,E-06 1,E-04 1,E-02 1,E+00 1,E+02 1,E+04
Phas
e an
gle
()
Reduced frequency (Hz)
St. 1 &2 Binder course ABb22 Nypol 64-34
St. 3 & 4 Binder course ABb22 70/100
St. 1 Upper asphalt base course AG22 40/100-75
St. 1 Lower asphalt base course AG22 90/150-75
St. 2 Upper and lower asphalt base courses AG22 160/220
St. 3 Upper and lower asphalt base courses AG22 70/100
VTI notat 30A-2015 27
4.3. Fatigue test
The fatigue test was conducted in accordance with the VTI notat 38-1995 or SS-EN 12697-24
Appendix E. The method involves applying a certain number of load pulses along the vertical
diametral plane of a cylindrical sample thus inducing a tensile stress along the horizontal diametral
plane perpendicular to the loading plane. The load pulse consists of 0.1 sec loading and 0.4 sec rest
period as shown in Figure 17. Figure 18 presents the results of the fatigue tests conducted for lower
asphalt road base mixes of the test structures 1, 2 and 3.
Figure 17. Load pulses for fatigue test.
Figure 18. Fatigue test results.
Equation (8) was used to fit the measured fatigue test data.
n
t
f KN
1 (8)
0
500
1000
1500
2000
2500
0 0,5 1 1,5 2 2,5 3
Lo
ad (
N)
Time (sec)
10
100
1000
1E+3 1E+4 1E+5 1E+6 1E+7
St
rain
(µ
stra
in)
Load cycle
St. 1 AG22 90/150-75
St. 2 AG22 160/220
St. 3 AG22 70/100Nf = K (1/)n
28 VTI notat 30A-2015
where Nf is the number of load cycle to failure, t is the initial tensile strain; K and n are regression
constants. The curve fitting parameters are given in Table 8.
Table 8. Curve fitting parameters for fatigue test results.
Parameters St 1.
AG22 90/150-75
St. 2
AG22 160/220
St 3.
AG70/100
n 2.61 3.15 3.62
K 4.50E+11 3.10E+12 2.80E+13
R² 0.81 0.97 0.92
4.4. Unbound granular base course
Samples were taken from the unbound granular base course material. The material was tested in
laboratory for estimation of some fundamental properties such as grain size distribution, specific
gravity, Proctor test and optimum moisture content, see Figure 19 and Table 9. Further, a repeated
load triaxial (RLT) test was carried out on 150 mm × 300 mm samples to evaluate the resilient and
permanent deformation properties. Further details on the testing procedure can be found in Rahman
and Erlingsson (2012).
Figure 19. Grain size distribution curve for the base course layer.
For the resilient testing totally seven tests on the same samples with different moisture contents were
carried out in the range 2–7.5% corresponding to 26–99% degree of saturations, see Table 9. Figure 20
shows the obtained results. Further, the obtained k1 and k2 values from Equation (10) are given in
Figure 21 as a function of degree of saturation.
Table 9. Fundamental parameters for the base course material.
GS
[-]
Fines
content
(< 75 µm)
[%]
wopt
[%]
Sopt
[%]
wsat
[%]
Maximum
dry density
[gm/cc]
Test conditions
γdry
[gm/cc]
Range
of w [%]
Range
of S [%]
Samples
tested
2.68 8.6 6.9 91.6 7.6 2.35 2.23 2-7.5 26-99 1
0
10
20
30
40
50
60
70
80
90
100
0,01 0,1 1 10 100
Pas
sing [
% b
y w
eight]
Sieve size [mm]
VTI notat 30A-2015 29
The resilient modulus MR, which is an estimate of the stiffness modulus of the specimen is expressed
as:
r
dRM
(9)
where d is the cyclic deviator stress and r is axial resilient strain.
The stiffness is highly dependent on the state of stress and is therefore frequently expressed as a
function of the bulk stress = 1 + 2 + 3. Here MR is expressed with the well known k- model
given in its non-dimensional form as:
2
1
k
a
aRp
pkM
(10)
where k1 and k2 are material parameters and pa is reference pressure taken as equal to the atmospheric
pressure, that is pa = 100 kPa.
The degree of saturation S of the specimen is related to the moisture content w of the specimen
through:
1dry
wsG
wS
(11)
where Gs is the specific gravity of the specimen, w is the unit weight of water dry is the dry unit
weight of the specimen.
Figure 20. Stiffness (resilient modulus) as a function of mean stress for the base course material.
0
100
200
300
400
500
600
700
800
900
1000
0 200 400 600 800 1000
Res
ilie
nt
modulu
s, M
R[M
Pa]
Mean stress, p [kPa]
w = 2% w = 3% w = 4% w = 5% w = 6% w = 7% w = 7.5%Model (solid lines)
30 VTI notat 30A-2015
Figure 21. The parameters k1 and k2 as a function of the degree of saturation.
The permanent deformation properties were studied based on Multi Stage (MS) RLT tests. The stress
levels for the tests were selected according to Low Stress Level (LSL) according to the European
standard. Totally 30 stress paths were applied each with 10 thousand load repetitions, thus resulting in
totally 300,000 load repetitions. Six tests were performed, see Table 10. First three tests at different
moisture content at constant degree of compaction followed by three tests at constant moisture content
but varying degree of compaction.
Table 10. Permanent deformation tests.
Fines
content
(< 75 µm)
[%]
wopt
[% by
weight]
GS
[-]
Maximum
dry
density
[gm/cc]
Tests performed with
w
[% by
weight]
S
[%]
γdry
[gm/cc]
Stress
level
Samples
tested
8.6 6.9 2.68 2.35
2 26.7 2.23 LSL 2
4 53.5 2.23 LSL 2
7 78.3 2.16 LSL 1
7 85.4 2.20 LSL 1
7 93.6 2.23 LSL 2
7 99.8 2.26 LSL 1
The results were analysed according to the model:
f
bS
p SaNN f̂ (12)
where p̂ is the accumulated permanent strain after N load repetitions and a and b are regression
parameters related to the material. The term Sf describes the effect of the stress conditions and is
expressed as:
0
250
500
750
1000
1250
1500
1750
0 20 40 60 80 100
k 1 [
-]
S [%]
0
0.2
0.4
0.6
0.8
1
1.2
0 20 40 60 80 100
k 2 [
-]
S [%]
VTI notat 30A-2015 31
a
a
f
p
p
p
q
S (13)
where q is the deviatoric stress, p is the hydrostatic stress and is parameter determined using a
regression analysis. A value of 0.75 gives usually a good agreement and that value has been used
here. Table 11 gives the curve fitting parameters.
Figure 21. Permanent deformation development with the number of load pulses from RLT test.
Table 11. Curve fitting parameters for the permanent deformation tests of the unbound base course.
w
[% by
weight]
Degree of
saturation
[%]
Dry
density
[gm/cc]
Degree of
compaction
[%]
Model parameters
Quality of fit
(α = 0.75)
a b R2
Correct
shakedown
range
predictions [%]
2 26.7 2.23 95 0.0001 0.120 0.71 86.7
4 53.5 2.23 95 0.0019 0.120 0.98 73.3
7 78.3 2.16 92 0.0026 0.120 0.50 56.7
7 85.4 2.20 93.5 0.0024 0.120 0.74 63.3
7 93.6 2.23 95 0.0023 0.120 0.61 63.3
7 99.8 2.26 96 0.0023 0.120 0.82 63.3
0
0,02
0,04
0,06
0,08
0,1
0,12
0,14
0,16
0 60000 120000 180000 240000 300000
Acc
um
ula
ted
p
erm
anen
t st
rain
, εˆ
p
Number of load cycles, N
w = 2%
w = 4%
w = 7% (DOC = 96%)
w = 7% (DOC = 95%)
w = 7% (DOC = 93.5%)
w = 7% (DOC = 92%)
Sequence 1 Sequence 2 Sequence 3 Sequence 4 Sequence 5
Low stress level
32 VTI notat 30A-2015
5. Conclusions
This report presents the laboratory test procedures and results of specimens taken from the four
instrumented test road sections that have been built on E45 close to the Svappavaara municipality in
Norrbotten County in Northern Sweden. The project is sponsored by the Swedish Transport
Administration. The structures are located about 100 km north of the Arctic Circle in a climate that is
characterized by long cold winters and short mild summers.
Each test section is around 250 m long, consisting of a 100 m long inner part that constitutes the
intrinsic test section. The structures were built and instrumented in the summer of 2012 except for the
wearing course that was placed in the summer of 2013 along with the temperature sensors that are
placed in the asphalt layers.
In 2013 drilled cores were taken from all bound layers and disturbed samples from unbound layers for
further laboratory analysis. This report presents the test results for asphalt bound layers as well as for
the unbound base course. For the bound layers the testing procedure included volumetric properties,
stiffness modulus and fatigue tests for the different types of conventional and polymer modified
asphalt mixtures. The tests were conducted in accordance with the Swedish or the equivalent European
standards. For the unbound base course fundamental properties were estimated as well as stiffness and
permanent deformation properties at different moisture contents.
The testing procedure went well without any problems except for the large aggregate cold mix layer
(road base layer) in section 4. The cores were not stable and aggregates loosened while preparing the
samples in the laboratory. It was therefore not possible to carry out any testing on them. They have
therefore been excluded from this report.
VTI notat 30A-2015 33
References
Ahmed A. W. and Erlingsson, S. (2014) “Evaluation of permanent deformation model for asphalt
concrete mixtures by means of extra-large wheel tracking and full scale accelerated pavement tests,”
Road Materials and Pavement Design. DOI: 10.1080/14680629.2014.987311.
Erlingsson, S. and Carlsson, H. (2014) “The Svappavaara Road Test Sections – Instrumentation,” VTI
notat 12A-2014. http://www.vti.se/sv/publikationer/pdf/nya-testvagstrackor-pa-e45-vid-svappavaara--
instrumentering.pdf
Rahman, S. and Erlingsson, S. (2012). Moisture Sensitivity of Unbound Granular Materials,
Proceedings of the 4th European Pavement Asset Management Conference (EPAM4), September
2012, Malmö, Sweden.
Said, S., Hakim, H. and Oscarsson, E. (2013) “Rheological characterization of asphalt concrete using a
shear box,” Journal of Testing and Evaluation, Vol. 41, No. 4, pp. 602-610. DOI:
10.1520/JTE20120177. ISSN 0090-3973.
VTI notat 30A-2015 35
Appendix A
Table A1. Thickness of layers based on drilled cores.
Thickness [mm]
Section Drilling area Sub-test Test no. Surface course Binder layer Road base - Upper Road base - Lower Total
1 2 a 1-2a 16 68 62 66 211
1 2 b 1-2b 17 66 66 62 211
1 3 a 1-3a 16 63 65 70 214
1 3 b 1-3b 17 65 65 65 212
1 4 a 1-4a 15 70 63 70 218
1 4 b 1-4b 17 68 62 70 217
1 5 a 1-5a 19 60 64 65 208
1 5 b 1-5b 15 66 62 65 208
2 1 a 2-1a 16 58 51 64 188
2 1 b 2-1b 14 58 53 71 196
2 2 a 2-2a 15 55 53 60 183
2 2 b 2-2b 16 58 50 65 189
2 3 a 2-3a 18 60 58 67 203
2 3 b 2-3b 15 60 60 68 203
2 4 a 2-4a 17 60 60 65 202
2 4 b 2-4b 16 59 57 63 195
2 5 a 2-5a 17 60 60 65 202
2 5 b 2-5b 19 60 60 68 207
3 1 a 3-1a 17 60 62 70 209
3 1 b 3-1b 18 63 63 70 214
3 2 a 3-2a 18 61 60 64 202
3 2 b 3-2b 19 57 63 63 201
3 3 a 3-3a 20 60 65 67 212
3 3 b 3-3b 20 55 70 65 210
3 4 a 3-4a 17 60 60 67 204
3 4 b 3-4b 18 62 60 67 207
3 5 a 3-5a 18 65 64 70 217
3 5 b 3-5b 17 66 63 70 216
4 1 a 4-1a 16 63 81 105 264
4 1 b 4-1b 16 59 90 107 272
4 2 a 4-2a 18 55 105 110 288
4 2 b 4-2b 17 60 95 130 302
4 3 a 4-3a 17 65 104 100 286
4 3 b 4-3b 17 65 85 120 287
4 4 a 4-4a 18 60 95 104 277
4 4 b 4-4b 18 64 90 110 282
4 5 a 4-5a 18 65 95 110 288
4 5 b 4-5b 17 67 95 110 289
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