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DEVELOPMENT OF SPECIFICATION CRITERIA TO
MITIGATE TOP-DOWN CRACKING
By
ADAM PAUL JAJLIARDO
A THESIS PRESENTED TO THE GRADUATE SCHOOL OF THE UNIVERSITY OF FLORIDA IN PARTIAL FULFILLMENT
OF THE REQUIREMENTS FOR THE DEGREE OF MASTER OF ENGINEERING
UNIVERSITY OF FLORIDA
2003
Copyright 2003
by
Adam Paul Jajliardo
ACKNOWLEDGMENTS
I would like to first thank my advisor and my committee chairman, Dr. Reynaldo
Roque for his advice, guidance and support. Without his technical and personal
expertise, this would not have been possible. I would also like to acknowledge my other
committee members, Dr. Bjorn Birgisson and Dr. Mang Tia, who have lent their
knowledge and experience.
Special thanks go to Mr. George Lopp for his support in the laboratory and his
valuable advice. My deepest thanks go to all the members of the Civil Engineering
materials group for their friendship and support during the past two years. They include
Tait Karlson, Oscar Garcia, Tipakorn Samarnrak, Jagannatha Katkuri, Claude Villiers,
Jeff Frank, JaeSeung Kim, SungHo Kim, Booil Kim, and Boonchi Sangpetngam.
I would like to express a very sincere appreciation to my wife Wendy for her love,
support, and friendship. I would also like to thank all my family and friends back home
who have also supported me during this time.
iii
TABLE OF CONTENTS Page ACKNOWLEDGMENTS ................................................................................................. iii
LIST OF TABLES............................................................................................................ vii
LIST OF FIGURES ........................................................................................................... ix
ABSTRACT……............................................................................................................. xiii
CHAPTER 1 INTRODUCTION ........................................................................................................1
1.1 Background.............................................................................................................1 1.2 Objectives ...............................................................................................................2 1.3 Scope.......................................................................................................................2 1.4 Research Approach.................................................................................................2
2 LITERATURE REVIEW .............................................................................................4
2.1 Fracture in Asphalt Pavements ...............................................................................4 2.2 Mechanisms of Fracture in Asphalt Pavements......................................................4
2.2.1 Traditional Fatigue Approach.......................................................................4 2.2.2 Fracture Mechanics Method .........................................................................6 2.2.3 Dissipated Creep Strain Energy....................................................................7
2.3 Mixture Properties Related to Fatigue Resistance..................................................8 2.3.1 Mixture Stiffness ..........................................................................................8 2.3.2 Air Void Content ..........................................................................................9 2.3.3 Voids in the Mineral Aggregate (VMA) ......................................................9 2.3.4 Asphalt Content and Theoretical Film Thickness ........................................9 2.3.5 Binder Viscosity .........................................................................................10 2.3.6 Aggregate Gradation ..................................................................................11
2.4 Previous Studies....................................................................................................11 2.5 Summary...............................................................................................................12
3 DESCRIPTION OF TEST SECTIONS......................................................................14
3.1 Locations and Age ................................................................................................14 3.2 Pavement Structure...............................................................................................15 3.3 Traffic Volume .....................................................................................................16
iv
3.4 Environmental Conditions ....................................................................................16 3.5 Performance of the Sections .................................................................................16
3.5.1 Overview ....................................................................................................16 3.5.2 Field Observations......................................................................................17
4 MATERIALS AND METHODS ...............................................................................21
4.1 Extraction of the Field Cores................................................................................21 4.2 Measuring and Cutting the Field Cores ................................................................22 4.3 Selecting Samples for Testing ..............................................................................22 4.4 Crack Rating .........................................................................................................23 4.5 Mixture Testing ....................................................................................................24 4.6 Asphalt Extractions and Binder Testing ...............................................................25 4.7 Aggregate Tests ....................................................................................................25 4.8 Volumetric Properties...........................................................................................26
5 ANALYSIS AND FINDINGS ...................................................................................29
5.1 Volumetric Properties and Extraction-Recovery Results .....................................29 5.11 Air Void Content .........................................................................................29 5.1.2 Effective Asphalt Content ..........................................................................31 5.1.3 Aggregate Gradation ..................................................................................31 5.1.4 Theoretical Film Thickness ........................................................................36 5.1.5 Binder Viscosity .........................................................................................37
5.2 Mixture Results.....................................................................................................37 5.2.1 Resilient Modulus.......................................................................................38 5.2.2 Creep Compliance ......................................................................................39 5.2.3 Tensile Strength..........................................................................................40 5.2.4 Failure Strain ..............................................................................................40 5.2.5 m-value .......................................................................................................41 5.2.6 Fracture Energy Density and Dissipated Creep Strain Energy ..................42
5.3 Non-Destructive Testing (FWD) ..........................................................................44 5.3.1 Pavement Structures ...................................................................................44 5.3.2 Loading Stresses.........................................................................................46
5.4 Crack Growth Model ............................................................................................47 5.5 Individual Analysis of the Sections ......................................................................53
5.5.1 I-75 1U and 1C ...........................................................................................53 5.5.2 I-75 2U and 3C ...........................................................................................54 5.2.3 SR-80 2U and 1C........................................................................................54
6 FURTHER ANALYSIS .............................................................................................56
6.1 Section Data and Mixture Test Results ................................................................56 6.2 Mixture Fracture Toughness.................................................................................57 6.3 Mixture Properties ................................................................................................64 6.4 Traffic ...................................................................................................................71
v
7 SUMMARY, CONCLUSIONS, AND RECOMMENDATIONS .............................76
7.1 Summary and Conclusions ...................................................................................76 7.2 Recommendations.................................................................................................77
APPENDIX A SUMMARY OF NON-DESTRUCTIVE TESTING (FWD) .....................................78
B SUMMARY OF FDOT FLEXIBLE PAVEMENT CONDITION SURVEY ...........94
C SUMMARY OF VOLUMETRIC PROPERTIES......................................................97
D MIXTURE TEST RESULTS ...................................................................................100
E SUMMARY OF CRACK GROWTH MODEL RESULTS.....................................105
F SUMMARY OF SECTION DATA FOR ALL SECTIONS....................................109
LIST OF REFERENCES................................................................................................116
BIOGRAPHICAL SKETCH ...........................................................................................118
vi
LIST OF TABLES
Table page 3.1 Location of the Sections...........................................................................................14
3.2 Age of the Sections ..................................................................................................15
3.3 Thickness of the layers (in) ......................................................................................15
3.4 Layer Moduli for each Section (ksi) ........................................................................16
3.5 Traffic Volumes for each Section (Millions) ...........................................................16
4.1 Average thickness ....................................................................................................23
4.2 Average Bulk Specific Gravity ................................................................................23
4.3 Cracking Criteria (After Sedwick, 1998) .................................................................24
4.4 Crack Ratings ...........................................................................................................24
5.1 Air void content........................................................................................................30
5.2 Layer Moduli from FWD Analysis ..........................................................................45
5.3 E1/E2 Ratios.............................................................................................................46
A.1 Deflection (mils0 From I-75 1U...............................................................................79
A.2 Deflection (mils) From I-75 1C ...............................................................................79
A.3 Deflections for I-75 2U ............................................................................................82
A.4 Deflections for I-75 3C ............................................................................................82
A.5 Deflections for SR-80 2U.........................................................................................85
A.6 Deflections for SR-80 1C.........................................................................................85
C.1 Bulk Specific Gravity for each Sample....................................................................98
C.2 Effective Asphalt Content, Film Thickness and VMA ............................................99
vii
D.1 Resilient Modulus ..................................................................................................101
D.2 Tensile Strength......................................................................................................101
D.3 Creep Compliance ..................................................................................................102
D.4 M-value, Failure Strain, Fracture Energy, DCSE, Initial Tangent Modulus, D0, and D1 .............................................................................................................103
D.5 Dissipated Creep Strain Energy Calculation..........................................................104
E.1 Estimated Loading Stresses (psi) ...........................................................................106
E.2 Nf to Initiation for DCSE .......................................................................................107
E.3 Nf to Initiation for FE .............................................................................................107
E.4 Nf to Propagate 50mm............................................................................................108
F.1 Summary of Traffic Loading (Annual ESALS in 1000)........................................110
F.2 Summary of Loading Stress (psi)...........................................................................110
F.3 Summary of Mixture Test Results Needed for Cracking Model............................111
F.4 Number of Cycles to Propagate Crack Length of 50mm .......................................111
viii
LIST OF FIGURES
Figure page 2.1 Fatigue Crack Growth Behavior (after Jacobs, 1995)................................................7
2.2 Dissipated Creep Strain Energy (after Zhang et al., 2001) ........................................8
3.1 Overview of Uncracked I-75 Section.......................................................................18
3.2 Overview of Cracked I-75 Section...........................................................................18
3.3 Overview of SR-80 2U.............................................................................................19
3.4 Overview of SR-80 1C.............................................................................................19
3.5 Longitudinal Crack from SR-80 1C .........................................................................20
4.1 Cutting Machine.......................................................................................................26
4.2 IDT Testing Device..................................................................................................27
4.3 Dehumidifying Chamber..........................................................................................27
4.4 Temperature Controlled Chamber............................................................................28
4.5 Testing Sample with Extensometers Attached.........................................................28
5.1 Air Void Content and Comparison Between WP and BWP Sections......................30
5.2 Effective Asphalt Content (%) .................................................................................31
5.3 Gradation Curves for I-75 1U and 1C......................................................................33
5.4 Gradation Curves for I-75 2U and 3C......................................................................34
5.5 Gradation Curves for SR-80 1C and 2U ..................................................................35
5.6 Film Thickness (µm) ................................................................................................36
5.7 Binder Viscosity (Poise)...........................................................................................37
5.8 Resilient Modulus (GPa) ..........................................................................................38
ix
5.9 Creep Compliance at 100 sec. (1/GPa) ....................................................................39
5.10 Tensile Strength (MPa) ............................................................................................40
5.11 Failure Strain (microstrain) ......................................................................................41
5.12 m-value.....................................................................................................................42
5.13 Fracture Energy Density (KJ/m3) .............................................................................43
5.14 DCSE (KJ/m3) ..........................................................................................................44
5.15 Loading stresses (psi) ...............................................................................................47
5.16 Number of Cycles to Failure for DCSE at 0° C .......................................................49
5.17 Number of Cycles to Failure for DCSE at 10° C .....................................................49
5.18 Number of Cycles to Failure for DCSE at 20° C .....................................................49
5.19 Number of Cycles to Failure for FE at 0° C.............................................................50
5.20 Number of Cycles to Failure for FE at 10° C...........................................................50
5.21 Number of Cycles to Failure for FE at 20° C...........................................................50
5.22 Comparison between Nf of DCSE and FE limits at 0° C .........................................51
5.23 Comparison between Nf of DCSE and FE limits at 10° C .......................................51
5.24 Comparison between Nf of DCSE and FE limits at 10° C .......................................51
5.25 Number of Cycles to Failure to 50mm at 0° C.........................................................52
5.26 Number of Cycles to Failure to 50mm at 10° C.......................................................52
5.27 Number of Cycles to Failure to 50mm at 20° C.......................................................52
6.1 D1max for values of DCSE and m-value....................................................................57
6.1 Nf to propagate 50mm ..............................................................................................58
6.3 Relationship between a, St, and σ .............................................................................60
6.3 KHMA Ratio for all sections.......................................................................................62
6.4 KHMA Ratio for sections 0.75 KJ/m3 < DCSEf < 2.5 KJ/m3 .....................................63
6.5 Gradations of Low KHMA Ratio Sections with 12.5mm Nominal Aggregate Size ..65
x
6.6 Gradations of High KHMA Ratio Sections with 12.5mm Nominal Aggregate Size..66
6.7 Gradations of Low KHMA Ratio Sections with 9.5mm Nominal Aggregate Size ....67
6.8 Gradations of High KHMA Ratio Sections with 9.5mm Nominal Aggregate Size....68
6.9 Case 1 Gradation Comparison for 12.5mm Nominal mixes ....................................69
6.10 Case 2 Gradation Comparison for 12.5mm Nominal mixes ....................................69
6.11 Case 1 Gradation Comparison for 9.5mm Nominal mixes ......................................70
6.12 Case 2 Gradation Comparison for 9.5mm Nominal mixes ......................................70
6.13 Relationship Between Nf and Required KHMA Ratio................................................71
6.14 FT vs. Traffic loading (ESALS/year x 1000)...........................................................72
6.15 Relationship Between Traffic Level and FS .............................................................73
6.16 FS vs. Traffic (ESALS/year x 1000).........................................................................74
6.17 Minimum KHMA Ratio Required vs. Traffic Levels .................................................75
A.1 Deflections for I-75 1U ............................................................................................80
A.2 Deflections for I-75 1C ............................................................................................81
A.3 Deflections for I-75 2U ............................................................................................83
A.4 Deflections for I-75 3C ............................................................................................84
A.5 Deflections for SR-80 2U.........................................................................................86
A.6 Deflections for SR-80 1C.........................................................................................87
A.7 Measured and Computed Deflections for I-75 1U Location 03...............................88
A.8 Measured and Computed Deflections for I-75 1U Location 06...............................88
A.9 Measured and Computed Deflections for I-75 1U Location 09...............................88
A.10 Measured and Computed Deflections for I-75 1C Location 03 ...............................89
A.11 Measured and Computed Deflections for I-75 1C Location 08 ...............................89
A.12 Measured and Computed Deflections for I-75 1C Location 10 ...............................89
A.13 Measured and Computed Deflections for I-75 2U Location 02...............................90
xi
A.14 Measured and Computed Deflections for I-75 2U Location 09...............................90
A.15 Measured and Computed Deflections for I-75 2U Location 02...............................90
A.16 Measured and Computed Deflections for I-75 1C Location 03 ...............................91
A.17 Measured and Computed Deflections for I-75 1C Location 04 ...............................91
A.18 Measured and Computed Deflections for I-75 1C Location 06 ...............................91
A.19 Measured and Computed Deflections for SR-80 2U Location 05 ...........................92
A.20 Measured and Computed Deflections for SR-80 2U Location 09 ...........................92
A.21 Measured and Computed Deflections for SR-80 2U Location 01 ...........................92
A.22 Measured and Computed Deflections for SR-80 1C Location 02............................93
A.23 Measured and Computed Deflections for SR-80 1C Location 03............................93
A.23 Measured and Computed Deflections for SR-80 1C Location 03............................93
B.1 Cracking Ratings from I-75 1U and 1C ...................................................................95
B.2 Cracking Ratings from I-75 2U and 3C ...................................................................95
B.3 Cracking Ratings from SR-80 2U and 1C................................................................96
F.1 Effective Asphalt Content (%) ...............................................................................112
F.2 Percent Air Voids (%) ............................................................................................113
F.3 Theoretical Film Thickness (microns) ...................................................................114
F.4 VMA (%)................................................................................................................115
xii
Abstract of Thesis Presented to the Graduate School
of the University of Florida in Partial Fulfillment of the Requirements for the Degree of Master of Engineering
DEVELOPMENT OF SPECIFICATION CRITERIA TO MITIGATE TOP-DOWN CRACKING
By
Adam Paul Jajliardo
May 2003
Chair: Dr. Reynaldo Roque Major Department: Civil and Coastal Engineering
One of the most common types of pavement distress in the State of Florida is
surface initiated longitudinal wheel path cracking, which is commonly refereed to as top-
down cracking. Prior research has indicated that top-down cracking is initiated by critical
tensile stresses in the surface of the asphalt pavement due to modern radial truck tires.
These cracks then propagate downward by the combined effects of temperature and
loads.
Several roadway sections were chosen for this study that exhibited top-down
cracking. Crack free sections were also studied that had similar structures and traffic as
the cracked sections. Asphalt Concrete cores were taken from each section for laboratory
testing to determine properties and characteristics of the mixture, binder, and aggregate.
xiii
Traffic volume, structure, and age data were collected for each section and Falling
Weight Deflectometer (FWD) tests were performed to determine the moduli of the
structural layers.
The mixture was tested using the Superpave Indirect Tensile Test (IDT). Resilient
modulus, creep compliance, and tensile strength tests were performed. The results of the
IDT test were used in the crack growth model developed at the University of Florida to
determine whether the number of cycles predicted to initiate and to propagate cracking in
the pavement correlated well with observed field cracking performance.
The analysis led to the identification of a mixture fracture toughness parameter
(KHMA(min)), which allows for the evaluation of mixture top-down cracking performance
by incorporating the affects of mixture properties and pavement structural characteristics.
The parameter did an excellent job indicating cracked from uncracked sections. It was
concluded that the parameter is suitable for the development of specification criteria to
mitigate top-down cracking and specific recommendations were made for its
implementation. The parameter (KHMA Ratio) was also defined that allows pavement
sections to be compared according to their cracking resistance.
xiv
CHAPTER 1 INTRODUCTION
1.1 Background
Surface-initiated longitudinal wheel path cracking is one of the most common types
of pavement distress in Florida today. Conventional load-induced cracking has been
commonly assumed to initiate at the bottom of the pavement and propagate upwards.
Cores and trenched sections taken from substandard sections have clearly illustrated the
phenomenon of top down cracking.
Myers (1997) identified the potential mechanisms of longitudinal surface initiated
wheel path cracking. She determined that this mode of distress is caused by a tensile
failure due to high stresses under the ribs of radial truck tires combined with thermal
stresses. Myers (2000) also found that surface initiated longitudinal cracking occurs
primarily under critical conditions. Therefore, existing design and evaluation methods
that consider only average conditions are not adequate in explaining this distress. These
approaches do not characterize the actual contact stresses or the discontinuities that exist
in the field. Myers (2000) also found that temperature gradients had a strong effect on
the development of stresses, which are also not considered in traditional fatigue
approaches.
Through the study of field cores, Garcia (2002) found that that there was no clear
relationship between any one mixture property and the mixture performance. However,
he found that the cracking model developed at the University of Florida appeared to
adequately explain the differences in mixture performance observed in the field.
1
2
Surface initiated longitudinal wheel path cracking has resulted in significant
rehabilitation costs. A better understanding of the mechanisms of surface cracking and
the key mixture properties and characteristics is necessary. The development of
specifications and design criteria will result in more crack resistant mixtures.
1.2 Objectives
The primary objectives of this research are summarized below:
• Evaluate field sections to identify the mixture properties and characteristics that most strongly influence surface cracking performance.
• Develop a design specification for asphalt mixtures that would mitigate surface cracking in pavements.
1.3 Scope
This study focuses on the analysis of the key mixture properties and characteristics
that affect surface initiated longitudinal wheel path cracking. To accomplish this, over
300 cores were extracted from six field sections throughout the state of Florida. Data was
also included from past studies and includes a total of twenty two sections.
1.4 Research Approach
The first step in this study was to conduct a literature review in order to understand
the different approaches to understanding fatigue in pavements. The different mixture
properties and characteristics were also evaluated to determine their influence in the
cracking performance of mixtures.
Next, the field sections were chosen from a number of potential sections through
visual inspection. Data from each of these sections was collected including the age,
structure, and traffic. Cracking performance over the life of the pavement was taken
from the FDOT Flexible Pavement Condition Survey Database.
3
Field cores were extracted from the roadway and each core was measured and cut
into test specimens. Mixture properties were determined using the Superpave Indirect
Tension Test (IDT). The specimens were broken down and the binder was extracted.
Binder and aggregate were obtained for evaluation.
Falling Weight Deflectometer (FWD) tests were performed on all of the sections in
order to determine the moduli of each pavement layer. The results were used to calculate
pavement stresses which were used to predict number of cycles to failure using the crack
growth model developed at the University of Florida.
The results of the crack growth model were analyzed in combination with results
from past studies at the University of Florida. The purpose of this was to evaluate the
effects of structure, environment, and mixture properties and characteristics on cracking
performance to develop specification criteria that would mitigate surface cracking in
asphalt pavements.
CHAPTER 2 LITERATURE REVIEW
A literature review was undertaken in order to understand the mixture
characteristics and properties that affect crack development and propagation. Several
different fatigue approaches were reviewed and their significance was determined when
discussing longitudinal surface-initiated top down cracking. It was also important to
review previous studies that investigated surface cracking in the field.
2.1 Fracture in Asphalt Pavements
Among all the types of failure in pavement, cracking is one of the most
predominant. Many factors influence cracking in pavement such as the pavement
structure and the mixture characteristics.
There are two main types of cracking in asphalt pavements. These are thermal
cracking and fatigue cracking. Thermal cracking is caused by the stresses that are
induced when low ambient temperatures cool the surface of the road. Fatigue cracking is
associated with traffic loading and is generated through repeated stresses. Myers (1997)
found that a probable cause of longitudinal surface initiated wheel path cracking is the
high tensile stresses caused by modern radial truck tires at the tire-pavement interface.
These stresses may be intensified by thermal stresses at the surface.
2.2 Mechanisms of Fracture in Asphalt Pavements
2.2.1 Traditional Fatigue Approach
The traditional fatigue approach is based on the assumption that the maximum
tensile strains are located at the bottom of the asphalt concrete layer. These strains
4
5
develop cracks and propagate from the bottom upward into the AC layer. Several fatigue
models have been developed to explain this phenomenon.
One of the first fatigue models was presented by Monismith et al. (1985). The
following relationship defines the fatigue behavior of a particular mixture:
c
mix
b
tf S
AN
=
11ε
where, Nf is the number of load applications to failure, A is a factor based on asphalt
content and degree of compaction, εt is the tensile strain, Smix is the mixture stiffness and
a and b are constants determined from beam fatigue tests.
The Asphalt Institute developed the following empirical relationship in 1982 for a
standard mix with an asphalt volume of 11% and an air void volume of 5%:
( ) ( ) 854.291.3 *0796. −−= EN tf ε
where, Nf is the number of load applications to cause fatigue cracking in 20% of the
pavement area, εt is the tensile strain at the bottom of the surface layer, and E* is the
dynamic modulus of the asphalt mixture.
Another equation used to calculate the fatigue life of a mixture was developed
under the SHRP program (Sousa et al., 1996). As in the previous two equations for
fatigue life, it is a function of the mixture stiffness and asphalt content.
720.2
0077.0
0510738.2 −∗∗= SexSN VFB
ff
where, Nf is the number of load cycles to failure, e is the base of the natural logarithm,
VFB is the voids filled with bitumen, εt is the tensile strain, S0 is the loss of stiffness, and
Sf is a factor that converts laboratory measurements to anticipated field results. The
value of Sf is 10 for a pavement that is 10% cracked.
6
All of these models show that there are many variables that affect the fatigue
cracking performance of asphalt mixtures including mixture stiffness, AC content and air
voids. Also, this shows that there is no simple or reliable way to predict the fatigue life
of an asphalt mixture.
Myers (2000) found that the addition of a stiffness gradient in cracked asphalt
concrete significantly increased the tensile stresses in the surface of the AC layer. None
of the traditional fatigue approaches considers discontinuities (i.e. the presence of a
crack) in the asphalt layer or stiffness gradients in the asphalt layer that may be caused by
temperature or aging. The position of the load was also found to be a contributing factor.
Traditional approaches also do not allow for the possibility of changes in the load
positioning (wander) in the field. She concluded that current methods for the design and
evaluation are inadequate for longitudinal top-down cracking because they consider only
average conditions and this mechanism occurs primarily under critical conditions.
2.2.2 Fracture Mechanics Method
Another method to explain fracture in asphalt mixtures is the fracture mechanics
method, which introduces the concept of crack propagation. The rate of crack
propagation can be predicted using the following relationship known as “Paris Law”:
( )nKAdNda
∆=
where a is the crack length, N is the number of load repetitions, A and n are parameters
depending on the mixture and K∆ is the difference between maximum and minimum
stress intensity factors during repeated loading. According to Ewalds and Wanhill
(1986), the fracture mechanics approach identifies three different stages. These are the
initiation phase where micro-cracks develop, the propagation phase where the micro-
7
cracks develop into macro-cracks and where crack growth becomes stable, and the
disintegration phase where the material fails, and crack growth is unstable.
Figure 2.1. Fatigue Crack Growth Behavior (after Jacobs, 1995)
2.2.3 Dissipated Creep Strain Energy
Roque et al. (1997) found that the Dissipated Creep Strain Energy (DCSE) limit is
one of the most important factors that control crack performance in asphalt concrete
mixtures. The DCSE limit is the difference between the fracture energy (FE) and the
elastic energy (EE) at the instant of failure. The fracture energy is obtained from a
strength test as the area under the stress strain curve up to the point where the specimen
begins to fracture. The elastic energy can be obtained from the resilient modulus (MR).
Zhang (2000) introduced the concept of a threshold between micro-damage and
macro-cracking. Micro-damage was defined to be damage that was determined to be
healable. Macro-cracking was determined to be non-healable damage, even over long
rest periods and temperature increases. Zhang (2000) found that if the threshold was not
reached, cracks would not initiate and the mixture would be able to heal. Conversely, if
the threshold was reached the crack would grow and the mixture would not be able to
8
heal. She determined that the dissipated creep strain energy limit (DCSEf) was a suitable
threshold. Zhang introduced a fundamental crack growth law that is based on this work.
Figure 2.2. Dissipated Creep Strain Energy (after Zhang et al., 2001)
2.3 Mixture Properties Related to Fatigue Resistance
Many different material properties influence the fatigue resistance of asphalt
concrete mixtures. Therefore, it is necessary to review each of these properties to obtain
a clear understanding of fatigue resistance in asphalt pavements.
2.3.1 Mixture Stiffness
The mixture stiffness is defined as the ratio of the stress to the strain. For asphalt
mixtures, the stiffness is a function of time, temperature, and loading. The stiffness of an
asphalt mixture is affected by the binder stiffness, gradation, air void content, and asphalt
content. As a mixture ages the stiffness increases due to oxidation of the binder. This
increases the stiffness of the mixture and produces a mix that is more brittle and less
crack resistant.
9
2.3.2 Air Void Content
The amount of permeable air voids in a mix is related to the degree that the binder
is exposed to air and water. The exposure of binder to air and water results in the
oxidation of the binder and an increase in the rate of age hardening. The increase in age
hardening increases the stiffness and brittleness of a mixture.
The air void content is a function of aggregate gradation and degree of compaction.
Monismith et al. (1985) found that by increasing the air void content excessively resulted
in a decreased fatigue life.
2.3.3 Voids in the Mineral Aggregate (VMA)
VMA is the volume of the inter-granular void space between the aggregate particles
of a compacted pavement mixture. This void space includes the air voids and the asphalt
not absorbed into the aggregate. VMA is a function of degree of compaction, aggregate
gradation, aggregate shape, and air voids. It is an important factor in the durability of
asphalt mixtures. Generally, increased VMA values will increase the durability of a
mixture. Excessive VMA with high asphalt content will affect the durability adversely
because the high binder content tends to allow the aggregate particles to be pushed apart.
In the Superpave Mix Design Procedure (SHRP, 1993), minimum VMA is a
function of the nominal maximum aggregate size. Nukunya (2001) questioned the use of
the same VMA criteria for both fine and coarse mixes and recommended that
requirements should differ for the two.
2.3.4 Asphalt Content and Theoretical Film Thickness
Asphalt content is a very important factor in the cracking resistance of a mixture.
Asphalt content affects many material properties including air void content and film
thickness.
10
Lower asphalt content has been generally associated with inadequate amounts of
asphalt in a mixture. Monismith (1981) found that there is an upper limit to the amount
of asphalt that can be incorporated in a mixture, but that this limit should be approached
in order to increase the fatigue resistance. Pell and Taylor (1969) found that once the
optimum asphalt content is exceeded, there will be a decrease in fatigue resistance.
Valkering and Van Gooswilligen (1989) found that an approximate 1% decrease in the
binder content was found roughly to halve the traffic-related fatigue life.
The theoretical asphalt film thickness is a function of the effective asphalt content
and the surface area of the aggregate particles. For any given asphalt content, as the
surface area of the aggregate particles increases the theoretical asphalt film thickness
decreases. Very thin asphalt films contribute to excessive aging of the binder and in turn,
more brittle mixes and decreased cracking resistance. Thicker asphalt films contribute to
a more flexible and durable mixture. Kandhal and Chakraborty (1996) suggested a
minimum asphalt film thickness to produce durable mixtures. They concluded that an
optimum film thickness for HMA, compacted to 4 to 5% air void content, should be
higher than 9 to 10 microns.
2.3.5 Binder Viscosity
Pell and Taylor (1969) concluded that an increase in binder viscosity resulted in an
increase in fatigue resistance. Malan et al. (1989) concluded that higher viscosity
asphalts proved to be more crack resistant on lightly trafficked roads, while lower
viscosity asphalts resulted in better crack resistant mixtures on highly trafficked roads.
This can be explained by the constant kneading effect of the moving loads on high traffic
pavements. This kneading effect brings the volatiles to the surface of the pavement and
prevents excessive viscosity gradients.
11
The viscosity of an asphalt binder is influenced by aging and maybe more
importantly, by temperature. To prevent premature cracking, the binder viscosity is
chosen based on the climate of the region where the mixture will be placed. In low
temperature climates, unusually low viscosity binders should not be used because of the
risk of extreme temperature shrinkage.
2.3.6 Aggregate Gradation
Aggregate gradation plays a very important role in the structure of a mixture. The
quality of aggregate interlock is primarily responsible for the mixture’s response to load.
The aggregate gradation affects VMA and asphalt film thickness.
The opinions on the effect of gradation on fatigue resistance are divided.
Monismith et al. (1985) found there is an insignificant effect on fatigue resistance that is
not explained by air void content and asphalt content. Malan et al. (1989) concluded that
continuously graded asphalt mixture designs are less susceptible to surface cracking than
gap graded and semi-gap-graded designs. Continuously-graded mixtures tend to have
higher asphalt film thickness and are more able to dissipate the shrinkage stresses.
2.4 Previous Studies
Sedwick (1998) conducted a study on top-down longitudinal wheel path cracking
that examined cores taken from the field. He used these cores to identify the mixture
properties and characteristics that would lead to the development of surface cracking. He
determined that fracture energy density was a good indicator of cracking performance
when other conditions such as pavement structure, traffic, and environmental effects are
the same. He also found that samples from the field with fracture energy densities lower
that 1.0KJ/m3 indicated a poor crack resistant mixture.
12
Garcia (2002) also conducted a study on longitudinal wheel path cracking using
field cores. He used these cores to identify the key factors that contribute to the
development of surface cracking. He determined that there was no clear relationship
between any single material property that would adequately describe the cracking
performance. However, the results of the HMA fracture mechanics based model
developed at The University of Florida appeared to properly explain the difference in
mixture performance. He also determined that the effects of the pavement structure and
thermal stresses were significant when comparing the relative cracking performance of
pavement sections.
2.5 Summary
• Traditional fatigue approaches do not adequately explain the phenomenon of longitudinal wheel path cracking.
• Fracture mechanics provides a solid foundation for understanding cracking in asphalt pavements. It introduces the concept of initiation, propagation, and disintegration.
• Dissipated Creep Strain Energy is one of the most important factors when considering the cracking performance of asphalt mixtures. The Dissipated Creep Strain Energy limit (DCSEf) can be used as a threshold between micro-damage and macro cracking.
• Mixture stiffness is a function of temperature, time, and loading. Excessively stiff mixtures are generally less crack resistant.
• Permeable air voids affect the degree of age hardening. Excessively high air voids will decrease the crack resistance of a material.
• Film thickness is a function of gradation and asphalt content. Thicker film thickness results in a mixture that is more durable, flexible, and crack resistant.
• Aggregate gradation plays a defining role in the structure of a mixture. Mixtures that are more continuously graded are more crack resistant.
• In previous studies, it was found that there was no clear relationship between any one-mixture property and cracking performance. All of the material properties, as
13
well as the pavement structure must be examined in order to describe a mixture’s cracking performance.
• The crack growth model developed at The University of Florida appears to adequately represent the cracking mechanisms of asphalt mixtures in the field.
CHAPTER 3 DESCRIPTION OF TEST SECTIONS
Six sections from three locations were chosen for this study. These sections were
chosen in pairs of good and poor performance with similar structure, loading, and age,
but with different mixtures. This chapter provides a description of the sections.
3.1 Locations and Age
The six sections were all extracted from locations in southwest Florida. Sections
1U and 1C were taken from I75 in Charlotte County. Sections 2U and 3C were taken
from I75 in Lee County. SR 80 sections were also taken from Lee County. Table 3.1
summarizes the locations of the sections.
Table 3.1. Location of the Sections Section Number
Section Name Condition Code County Section Limits
State Mile Posts
1 Interstate 75 U I75-1U Charlotte MP 149.3 - MP 161.1 0 - 11.8 Section 1
2 Interstate 75 C I75-1C Charlotte MP 161.1 - MP 171.3 11.8 - 22.0 Section 1
3 Interstate 75 U I75-2U Lee MP 115.1 - MP 131.5 0 - 16.4 Section 2
4 Interstate 75 C I75-3C Lee MP 131.5 - MP 149.3 16.4 - 34.1 Section 3
5 State Road 80 C SR 80-2C Lee From East of CR 80A 10.8 - 13.6 Section 1 To West of Hickey Creek Bridge
6 State Road 80 U SR 80-1U Lee From Hickey Creek Bridge 13.6 - 18.3 Section 2 To East of Joel Blvd.
The age of the sections is defined as the time from the most recent resurfacing. The
age of each section is summarized in Table 3.2.
14
15
Table 3.2. Age of the Sections Section Year Let Age as of 2003
I75-1U 1989 14 I75-1C 1988 15 I75-2U 1989 14 I75-3C 1988 15
SR 80-2U 1984 19 SR 80-1C 1987 16
3.2 Pavement Structure
The layer moduli were determined with the Falling Weight Deflectometer (FWD).
The values were then back calculated using elastic layer analysis. The FWD procedure
used the standard SHRP configuration for the sensors (i.e. 8”, 12”, 18”, 24”, 36”, and
60”). For each section, ten tests were conducted in the travel lane in the wheel path at
relatively undamaged locations, on both sides of the coring area. A half-inch hole was
drilled in the pavement and filled with mineral oil or glycol for heat transfer and the
pavement temperatures were recorded. The pavement surface and ambient temperatures
were also recorded. A 9-kip seating load was applied, followed by 7, 9, and 11kip loads.
Deflection measurements at each of the sensors were recorded. The layer thickness and
back-calculated moduli appear in Tables 3.3 and 3.4, respectively. The base and sub-
base thickness were not available so a typical thickness of 12 inches was assumed for the
back calculation analysis.
Table 3.3. Thickness of the layers (in) Section Friction Course AC Base Sub-base I75-1U 0.44 6.23 12 12 I75-1C 0.51 6.54 12 12 I75-2U 0.46 7.42 12 12 I75-3C 0.62 6.47 12 12
SR 80-2U 0.80 6.29 12 12 SR 80-1C 0.37 3.38 12 12
16
Table 3.4. Layer Moduli for each Section (ksi) Section AC Base Sub-base Sub-gradeI75-1U 1000 64 51 36 I75-1C 800 55 50 30 I75-2U 1000 107 90 31 I75-3C 900 60 35 36
SR80-2U 500 57 46 19 SR80-1C 800 44 61 28
3.3 Traffic Volume
The traffic volumes for each section are shown in table 3.5. These values are
expressed in thousands of ESALS. The traffic volumes vary from 207 K for section SR-
80 2U to 674 K for section I-75 3C.
Table 3.5. Traffic Volumes for each Section (Millions) Section Traffic (ESALS/year x 1000)I75-1U 558 I75-1C 573 I75-2U 576 I75-3C 674
SR80-2U 207 SR80-1C 221
3.4 Environmental Conditions
The environmental conditions were similar for all the test sections. Florida has a
humid climate with average yearly temperatures between 20° and 25° C. Pavement
temperatures during the summer months can increase considerably.
3.5 Performance of the Sections
3.5.1 Overview
The Flexible Pavement Condition Survey Database is a record maintained by the
Florida Department of Transportation. This record contains ratings on the ride, rutting,
and cracking performance of every pavement section supported by the FDOT. The
primary purpose of this record is to prioritize pavement sections for rehabilitation.
17
The ratings for cracking are based on crack width and cracked surface area. Values
between 0 and 10 are given to a pavement section depending on the size of the crack
widths and the surface area of the pavement that is cracked. The value of 10 is given to a
pavement that is crack free. Appendix B contains the crack ratings of all the sections.
Unfortunately, this rating judges only the appearance of the surface and gives no
indication of the actual depth of the cracks. For example, a pavement with a high amount
of cracking in the friction course would be given a low crack rating even if the cracks did
not propagate further into the pavement. Also, a pavement with a small number of cracks
would be given a high rating even though the cracks may extend well into the pavement.
Therefore, to gauge the actual extent of the cracking, it was necessary to core the
pavement directly though the crack and measure the crack depths manually.
3.5.2 Field Observations
Before the coring was performed, a field trip was taken to each section to observe
and take pictures. Figure 3.1 shows a typical uncracked section for I-75. Figure 3.2
shows a cracked section. The uncracked section appears to be in an acceptable condition.
The cracked section exhibits a moderate amount of cracking as well as wheel rim
markings. The cracks appear in and to the side of the wheel paths in the travel lane.
Figures 3.3 and 3.4 show the uncracked (SR80 2U) and cracked (SR80 1C) sections
respectively. The uncracked section appears to be in a very acceptable condition with a
surface free from cracks. The cracked section is heavily cracked with continuous cracks
appearing in the wheel paths of both lanes. Figure 3.5 shows a close-up of a crack.
18
Figure 3.1. Overview of Uncracked I-75 Section
Figure 3.2. Overview of Cracked I-75 Section
19
Figure 3.3. Overview of SR-80 2U
Figure 3.4. Overview of SR-80 1C
20
Figure 3.5. Longitudinal Crack from SR-80 1C
CHAPTER 4 MATERIALS AND METHODS
After the cores were extracted from the roadway, they were measured and saw-cut
into individual testing specimens. The bulk specific gravity of each specimen was
measured. The specimens were then tested using the Superpave indirect tensile test
(IDT) developed by Roque et al. (1997). One specimen was used to determine the
Maximum Theoretical Density using the Rice test. The binder and the aggregate were
separated from representative specimens from each section. These were used for further
testing.
4.1 Extraction of the Field Cores
Several cores were taken from each of the six sections. Cores were extracted from
the wheel path as well as between the wheel paths. Cores were also taken through the
crack in order to measure the actual crack depths. The cores were marked for traffic
direction. This is necessary because the failure that was observed in the field is a tensile
failure perpendicular to the direction of traffic. It was important to keep the direction
consistent when performing the IDT tests. A total of 46 cores were extracted from each
section. Eighteen cores each were taken from the wheel path and eighteen from between
the wheel paths. Ten cores were taken through the cracks for each section. All of the
cores were extracted using a truck mounted coring rig. The truck-mounted rig was used
to minimize damage that may occur to the samples during the coring process.
21
22
4.2 Measuring and Cutting the Field Cores
Upon inspection in the laboratory, the thickness of each lift was measured and
recorded. The crack depths were also measured and recorded. Since the cracks originate
at the surface, the layer immediately beneath the friction surface is primarily responsible
for crack initiation and propagation. This layer was chosen for the purposes of this study.
This layer was identified for each core and marked for cutting. Figure 4.1 shows a
picture of the machine used to cut the samples.
The thickness of the sample used for the IDT testing is typically between 1 to 2
inches. The actual thickness of the specimens varied from 1 to 1.81 inches, depending on
the thickness of the layer as well as the quality of the cores. The average thickness of the
samples for each section is shown in Table 4.1.
After the specimens were cut, they were marked for future identification. Since the
cutting process involves water, the specimens were placed in an air-conditioned
environment for several days until their natural moisture content was reached. The bulk
specific gravity of each specimen was measured.
4.3 Selecting Samples for Testing
Nine specemins were needed from each section in order to test the mixture at three
temperatures. The samples were chosen by selecting nine samples having a bulk specific
gravity (Gmb) closest to the average Gmb of the section. Table 4.2 shows the average bulk
specific gravities for each section.
23
Table 4.1. Average thickness Section Thickness
(in.) I75-1U 1.17 I75-1C 1.10 I75-2U 1.00 I75-3C 1.06
SR 80-2U 1.31 SR 80-1C 1.81
Table 4.2. Average Bulk Specific Gravity Average Gmb
Section WP BWP I75-1U 2.302 2.241 I75-1C 1.860 2.274 I75-2U 2.284 2.221 I75-3C 2.281 2.208
SR 80-2U 2.232 2.181 SR 80-1C 2.267 2.204
Note: WP: Wheel Path BWP: Between Wheel Path
4.4 Crack Rating
The cracked cores were taken and the crack depths were measured and recorded.
Sedwick (1998) defined a crack rating criteria based on the average crack depth measured
for a given section. This criteria assigns a value between 0 and 10 based on the length of
the measured crack depths. Table 4.3 shows the rating criteria used by Sedwick. Table
4.4 shows the average crack depths for the six sections and their corresponding
performance rating. Cracking was found to be especially severe in section SR-80 1C
where in some cases the cracks extended completely through the cores.
24
Table 4.3. Cracking Criteria (After Sedwick, 1998) Crack Depth (in) Rating
< 0.25 10 0.26 - 0.75 8 0.76 - 1.25 6 1.26 - 2.00 4 2.01 - 3.00 2
> 3.00 0 Table 4.4. Crack Ratings
Average Cracking Performance Section Depth (in) Rating
I75-1U Uncracked 10 I75-1C 2.21 2 I75-2U Uncracked 10 I75-3C 2.32 2
SR 80-2U Uncracked 10 SR 80-1C 2.56* 2
*Some samples cracked completely through
4.5 Mixture Testing
The testing procedures used in this study were developed for the FDOT by Roque
et al, (1997). The following tests were performed: Resilient Modulus, Creep
Compliance, and Tensile Strength. These tests were performed at three temperatures:
0°C, 10°C, and 20°C. The results from the three tests were analyzed using software
developed at the University of Florida. This provided Resilient Modulus (GPa), Creep
compliance as a function of time (1/GPa), Tensile Strength (MPa), Failure strain
(microstrain), Fracture Energy (KJ/m3), m-value (the slope of the linear portion of the
creep compliance-time curve), and the Dissipated Creep Strain Energy to failure.
Poisson’s ratio is also calculated for each of the three tests.
A gage placement jig was used to mount four aluminum gage points on each face
of the testing specimens. The samples were then placed in a relatively low humidity
25
chamber for forty-eight hours to eliminate any moisture that would affect testing. Before
testing, the samples were placed in the temperature-controlled chamber overnight to
stabilize the temperature. Before testing, the samples were fitted with knife edged gage
mounting blocks. A set of spring-loaded extensometers was placed on the knife-edges to
measure deformations. Figures 4.2 through 4.5 show pictures of the IDT testing
machine, the dehumidifying chamber, the temperature-controlled chamber, and a sample
with the extensometers attached.
4.6 Asphalt Extractions and Binder Testing
Two samples from each section were broken down to determine the Theoretical
Maximum Specific Gravity (Gmm) or Rice Gravity according to AASHTO T 209-94. The
Gmm value for each section made it possible to calculate the air void content for each
sample. These samples were then placed in an asphalt extraction device that uses
trichloroethylene (TCE) to separate the binder from the aggregate. The binder-TCE
mixture was then placed in an extraction device, which evaporated the TCE. Viscosity
tests were performed on the binder at 60C using the Brookfield Thermosel Apparatus.
These tests were performed according to ASTM D 4402-87.
4.7 Aggregate Tests
Once the aggregate was separated from the binder, it was placed in an oven
overnight to evaporate any remaining TCE. Following this, a washed sieve analysis was
performed according to ASTM C117 to determine the amount of material passing the No.
200 sieve. A dry sieve analysis was then performed to determine the gradation of each
mixture following ASTM C136. The specific gravity and absorption of the fine and
coarse aggregates was performed according to ASTM C128 and ASTM C127
respectively.
26
4.8 Volumetric Properties
Using the results of the binder and aggregate tests, several volumetric properties
were calculated. These were the effective asphalt content, the Voids in the Mineral
Aggregate (VMA), and the theoretical film thickness. The effective asphalt content was
calculated using the results from the extraction-recovery process as well as the percent
absorption. The VMA was calculated using the bulk specific gravity of the mixture, the
specific gravity of the aggregate and the aggregate content. The theoretical film
thickness was obtained from the Hveem method. The Hveem method calculates the film
thickness by approximating the surface of the aggregate using surface area factors. These
surface area factors are multiplied by the percentage passing for each sieve. The film
thickness is calculated by dividing this surface area by the volume of effective asphalt.
The calculations of these volumetric properties are summarized in Appendix C.
Figure 4.1. Cutting Machine
27
Figure 4.2. IDT Testing Device
Figure 4.3. Dehumidifying Chamber
28
Figure 4.4. Temperature Controlled Chamber
Figure 4.5. Testing Sample with Extensometers Attached
CHAPTER 5 ANALYSIS AND FINDINGS
This chapter presents the results of the mixture and binder results as well as the
analysis of the Falling Weight Deflectometer Test (FWD). This chapter also provides
analysis as to the material properties that were related to the cracking performance of the
mixtures. This analysis was conducted through the comparison of sections with similar
age, pavement structure, and traffic conditions.
5.1 Volumetric Properties and Extraction-Recovery Results
The cores that were obtained in the field were cut and specimens were used to
determine the bulk specific gravity of the mixture. Samples from each section were
broken down and their Theoretical Maximum Specific Gravity was determined. These
samples were also put through an extraction and recovery process to determine the
asphalt content and viscosity as well as several aggregate properties. From these results,
several volumetric properties were calculated including effective asphalt content, VMA,
and theoretical film thickness. Results are shown in the sections that follow.
5.11 Air Void Content
The air void content for each section was calculated using the bulk specific gravity
of the mixture (Gsb) and the theoretical maximum specific gravity (Gmm). The average
void content and standard deviation for each of the sections is shown in Table 5.1. The
comparisons between the sections are shown in Figure 5.1.
29
30
Table 5.1. Air void content WP BWP
Air Void Standard Air Void StandardSection Content Deviation Content Deviation
I75-1U 1.86 0.13 3.21 0.35 I75-1C 2.88 0.18 5.39 0.52 I75-2U 3.72 0.57 6.93 0.82 I75-3C 4.37 0.51 7.24 0.88
SR 80-2U 4.72 1.10 7.53 0.69 SR 80-1C 2.77 0.55 5.71 0.53
0.00
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
I75-1U I75-1C I75-2U I75-3C SR 80-2U SR 80-1C
Section
% A
ir V
oid
Con
tent
WPBWP
Figure 5.1. Air Void Content and Comparison Between WP and BWP Sections.
For all the sections, there seemed to be a similar difference in air void content
between the WP cores and the BWP cores. The I-75 sections 1U and 1C showed a
difference in air voids with values ranging between 2% and 3% for the WP cores and 3%
and 5.5% for the BWP cores. The I-75 sections 2U and 3C exhibited approximately the
same percentage of air voids with approximately 4% for the WP cores and 7% for the
BWP cores. The SR-80 sections 2U and 1C also showed a difference in air voids. The
values ranged from approximately 5% for section 2U to 3% for section 1C for the WP
31
cores and from 7.5% for 2U and 5% for 1C for the BWP cores. There was no clear
relationship between the air void content and the cracking performance.
5.1.2 Effective Asphalt Content
The effective asphalt content was determined from the percent asphalt absorbed
using the aggregates from the extraction-recovery process. Low asphalt content means
poor coating of the aggregate particles and poor fatigue resistance. The FDOT requires
effective asphalt contents to be greater than 5%. The figure below shows that none of
these sections met the requirement. There was little difference between the cracked and
uncracked pairs and no visible relationship between effective asphalt content and
cracking performance.
0.00
1.00
2.00
3.00
4.00
5.00
6.00
I75-1U I75-1C I75-2U I75-3C SR-80 2U SR-80 1C
Section
Eff
ectiv
e A
spha
lt C
onte
nt (%
)
Figure 5.2 Effective Asphalt Content (%)
5.1.3 Aggregate Gradation
The aggregate gradation for each of the sections is shown in figures 5.3 to 5.5. The
gradations shown below are expected to be finer than the in place gradations. This is
because the aggregates used to compute the distributions were taken from samples cut
32
from cores and the sizes of the specimens were less than the 2500 grams required for a
gradation test. The resulting gradations will be finer than the actual gradations in the
field but since the size of the specimens were approximately the same it was assumed that
the shift in gradation due to these two effects was the same for all samples.
The aggregates from I-75 sections 1U and 1C have a similar aggregate gradation
distribution. Each section has low dust contents and a significant amount of material
between the #100 and #8 sieves.
I-75 sections 2U and 3C are compared in Figure 5.3. The grain size distributions
for the two sections are also similar. Each has a low dust content, a significant amount of
material between the #100 and #30 sieves and a gap between the #30 and #8 sieves.
Section 3C appears to be a slightly more gap-graded mixture. Previous studies (Sedwick,
1998) found that gap graded mixtures are generally less crack resistant than more
continuously-graded mixtures. Section 3C appears to be slightly finer than section 2U.
SR-80 sections 2U and 1C are compared in Figure 5.4. Their distribution curves
are similar in that they both have a large amount of material between the #200 and #50
sieves and both have low dust contents. Section 2U has a finer distribution than section
1C. A finer gradation has also been linked to poor cracking performance because of the
greater tendency for the mixtures to have low asphalt film thickness. However, there
does not appear to be a strong relationship between the relative fineness of the mixture
and the cracking performance.
0
10
20
30
40
50
60
70
80
90
100
Sieve sizes
% P
assi
ng
I75-1C
I75-1U
0 200 100 50 30 16 8 4 3/8 1/2 3/4 1
Max DensityLine
33
Figure 5.3 Gradation Curves for I-75 1U and 1C
0
10
20
30
40
50
60
70
80
90
100
Sieve sizes
% P
assi
ng
I75-3C
I75-2U
0 200 100 50 30 16 8 4 3/8 1/2 3/4 1
Max DensityLine
34
Figure 5.4 Gradation Curves for I-75 2U and 3C
0
10
20
30
40
50
60
70
80
90
100
Sieve sizes
% P
assi
ng
SR80-1C
SR80-2U
0 200 100 50 30 16 8 4 3/8 1/2 3/4 1
Max DensityLine
35
Figure 5.5 Gradation Curves for SR-80 1C and 2U
36
5.1.4 Theoretical Film Thickness
The theoretical film thickness was calculated using the Hveem method. The
Hveem method calculates the film thickness from the aggregate gradation and the asphalt
content. As previously discussed in Chapter 2, Kandhal proposed a minimum film
thickness of 9 to 10µm. From the data below in Figure 5.6, all of the sections have
theoretical film thickness of less than 9µm and are generally below 6µm, which is
considered excessively low. This may be due to the excessively low effective asphalt
contents. For the I-75 1U and 1C and the SR-80 sections the uncracked sections had
higher film thickness than the cracked sections, while the reverse was found for the I75
2U and 3C sections.
4.40
4.60
4.80
5.00
5.20
5.40
5.60
5.80
I75-1U I75-1C I75-2U I75-3C SR-80 2U SR-80 1C
Section
Film
Thi
ckne
ss ( µ
m)
Figure 5.6 Film Thickness (µm)
37
0100002000030000400005000060000700008000090000
100000
I75-1U I75-1C I75-2U I75-3C SR 80-2U
SR 80-1C
Section
Bin
der V
isco
sity
(Poi
se)
WPBWP
Figure 5.7 Binder Viscosity (Poise)
5.1.5 Binder Viscosity
Figure 5.7 shows a comparison of the binder viscosities between the sections.
The binder viscosity values follow a similar trend with the air void content. Sections
with higher air void contents also exhibit higher binder viscosities. This can be explained
by the age hardening that occurs due to oxidation. A higher air void content generally
allows for an increased amount of oxidation that results in a higher rate of age hardening.
The SR80 sections show much higher binder viscosities than other sections. This may be
partially due to the older age of the pavement sections.
5.2 Mixture Results
The mixture test performed were resilient modulus, creep compliance at 100
seconds and tensile strength. These tests were performed at 0° C, 10° C, and 20° C. The
mixture properties that were obtained from these tests were the resilient modulus, creep
compliance, m-value, tensile strength, fracture energy density, failure strain, initial
38
tangent modulus, and the dissipated creep strain energy limit (DCSEf). The following is
a summary of the test results and a detailed analysis of each mixture property and how it
relates to mixture cracking performance.
5.2.1 Resilient Modulus
The resilient modulus (MR) is a measure of a material’s elastic stiffness. This is a
function of the binder stiffness and the degree of aggregate interlock. Figure 5.8 shows
the values of MR for each of the sections at each of the three test temperatures.
02468
101214161820
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Res
ilien
t Mod
ulus
(GPa
)
0° 10° 20°
Figure 5.8 Resilient Modulus (GPa)
The I-75 1U and 1C sections exhibited almost the same MR values for 10° and 20°.
Section 1C had slightly higher MR values at 0° with values only 13% over those of
Section 1U. I-75 sections 2U and 3C also had similar values of MR. At 20°, the values
were almost equal, at 10° section 3C was greater than 2U by 12.5% and at 0° section 2U
was greater than 3C by 10%. The results for the SR80 sections are similar to those of the
I-75 sections. The resilient modulus values for SR-80 2U and 1C are also close to equal.
39
At 0° and 10°, the results for the two sections are almost identical. At 20° the value for
section 2U is higher than 1C by 20%. The data suggests that there is no clear relationship
between resilient modulus and cracking performance. However, tensile stresses will be
greater in the sections that have slightly greater resilient modulus values.
5.2.2 Creep Compliance
Creep compliance is related to the ability of a mixture to relax stresses especially
thermal stresses. Mixtures with higher creep compliances can relax stresses more quickly
than mixes with low creep compliances. Figure 5.9 shows the creep compliances at 100
seconds for each test section. For the I-75 1U and 1C sections, the compliance values
were slightly higher for section 1U than those for 1C. In contrast, the compliance values
for I-75 2U and 3C were very similar. For sections SR 80 2U and 1C, the uncracked
section had lower compliance values than the cracked section. There appears to be no
relationship between creep compliance and the cracking performance of the sections.
0.000
0.500
1.000
1.500
2.000
2.500
3.000
3.500
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Cre
ep C
ompl
ianc
e at
100
sec
(1/G
Pa)
0° 10° 20°
Figure 5.9 Creep Compliance at 100 sec. (1/GPa)
40
5.2.3 Tensile Strength
Tensile strength is the maximum tensile stress that the mixture can withstand
before failure. The indirect tensile strengths for each section at all three temperatures are
shown in Figure 5.10. The uncracked sections possessed slightly higher tensile strengths
than the cracked sections.
0.00
0.50
1.00
1.50
2.00
2.50
3.00
3.50
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Ten
sile
Str
engt
h (M
Pa)
0° 10° 20°
Figure 5.10 Tensile Strength (MPa)
5.2.4 Failure Strain
Failure strain is the horizontal strain that is measured during the indirect tensile
strength test when cracking occurs. Failure strain is a direct measurement of the
brittleness of a mixture. In general, mixtures with high failure strains are more crack
resistant. The failure strains for each section at each temperature are shown in Figure
5.11. For all sections, the uncracked sections displayed higher failure strains than the
cracked sections excluding I-75 sections 2U and 3C at 20° C, which were close to equal.
41
0
500
1000
1500
2000
2500
3000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Failu
re S
trai
n (m
icro
stra
in
0° 10° 20°
Figure 5.11 Failure Strain (microstrain)
5.2.5 m-value
The m-value is defined as the slope of the linear portion of the log creep
compliance log time curve. It is calculated by fitting the following relationship to the
creep compliance data:
( ) mtDDtD 10 +=
where, D(t) is compliance at time t, D0 and D1 are model parameters, and m is the m-
value. The m-value is an indirect measurement of the creep rate of a mixture. A mixture
with a higher m-value has a higher creep rate, which implies a higher rate of damage for a
given stress. However, it also means a higher rate of stress relaxation. Also higher m-
values are typically associated with softer binders and mixtures with higher Fracture
Energy thresholds.
Figure 5.12 shows the m-values for each section at all three temperatures. The
most significant difference in m-values between paired sections was found on SR-80.
42
The m-value for section SR-80 1C was higher than section 2U for all temperatures.
These values agree with the lower binder viscosity for SR-80 1C.
0.0
0.1
0.2
0.3
0.4
0.5
0.6
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
m-V
alue
0° 10° 20°
Figure 5.12 m-value
5.2.6 Fracture Energy Density and Dissipated Creep Strain Energy
Fracture energy density is defined as the energy per unit volume that is required to
fracture an asphalt mixture. It is calculated from the indirect tensile strength test by
computing the area under the stress-strain curve up to the point the sample starts to fail.
Previous studies (Sedwick, 1997) have determined that fracture energy is a reliable
indicator of the crack resistance of a mixture when other conditions such as pavement
structure and traffic are similar. He suggested that mixtures with fracture energy
densities of less that 1 KJ/m3 at 0° or 10° performed poorly in the field. Garcia (2002)
found that the pavement structure and thermal stresses were also important when
comparing the relative performance of asphalt mixtures.
The fracture energy densities are shown below in Figure 5.13 for all the sections at
the three temperatures. As the data indicates, the fracture energy densities for the
43
uncracked sections are greater than their paired cracked sections with the exception of the
I-75 2U and 3C sections at 20°. The values of fracture energy for all cracked sections
were below 1 KJ/m3. All uncracked sections had fracture energy values equal to or
greater than 1 KJ/m3 at 10°C. The fracture energy of the SR-80 uncracked section at 0°C
was less than 1 KJ/m3. The much smaller traffic levels experienced by this section may
explain it’s good performance in the field.
0.0
0.5
1.0
1.5
2.0
2.5
3.0
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Frac
ture
Ene
rgy
(KJ/
m3)
0° 10° 20°
Figure 5.13 Fracture Energy Density (KJ/m3)
The dissipated creep strain energy at failure (DCSEf) is defined as the fracture
energy minus the elastic energy (Zhang, 2000). The values of DCSEf for each section are
shown below in Figure 5.14 at the three test temperatures. Since DCSE is a function of
the fracture energy, it is reasonable that the results would display a similar trend. From
the results of the data, it can be seen that the uncracked sections posses higher DCSE
values than their respective cracked pairs except for sections I-75 2U and 3C at 20°.
44
0.0
0.5
1.0
1.5
2.0
2.5
3.0
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
DC
SE (K
J/m
3)
0° 10° 20°
Figure 5.14 DCSE (KJ/m3)
5.3 Non-Destructive Testing (FWD)
Falling Weight Deflectometer (FWD) testing was performed on each of the section
in order to determine the layer moduli in the pavement system. Back calculation analysis
was used to interpret the testing data. These modulus values were used including
information about the layer thickness to calculate the stresses at the bottom of the AC
layer. The measured deflections for each sensor and location are shown in Appendix A.
5.3.1 Pavement Structures
FWD testing was run at three deflection levels: high, intermediate, and low. The
deflection basin data was used to back calculate the moduli of each layer in the pavement
system using BISDEF at three locations along the length of each section. Table 5.2 shows
a summary of the results.
45
Table 5.2 Layer Moduli from FWD Analysis Section AC Base Sub-base Sub-grade I75-1U 1000 64 51 36 I75-1C 800 55 50 30 I75-2U 1000 107 90 31 I75-3C 900 60 35 36
SR80-2U 500 57 46 19 SR80-1C 800 44 61 28
The results of the back calculation show that there are some differences in the
structure of the pavement sections. I-75 sections 1U and 1C have similar base and sub-
base moduli although the base modulus for 1U is slightly higher than 1C. One of the
largest differences is in the base and sub-base moduli for I-75 sections 2U and 3C. The
base and sub-base moduli for section 2U are almost double those of section 3C. This had
a significant impact upon lowering the tensile stresses in section 2U. The structures for
the SR-80 sections were similar although the base stiffness for section 2U was slightly
greater that that of 1C. The sub-base stiffness is higher for section 1C but this may be
attributed to fitting error in the back calculation analysis and does not have a significant
effect on the pavement stresses.
The ratio of the asphalt concrete modulus to the base modulus (E1/E2) is a good
indicator of the bending stresses in the AC layer. A larger E1/E2 ratio generally indicates
higher bending stresses. Table 5.3 shows the E1/E2 ratios for each section. For each
paired cracked and uncracked section, the E1/E2 ratios were larger for the cracked
section. For the I-75 sections 2U and 3C, the ratios were doubled for section 3C.
46
Table 5.3 E1/E2 Ratios Section Temp E1/E2
0 34 I75-1U 10 25
20 17 0 45
I75-1C 10 29 20 21 0 25
I75-2U 10 14 20 10 0 41
I75-3C 10 28 20 20 0 46
SR80-2U 10 34 20 28 0 62
SR80-1C 10 45 20 30
5.3.2 Loading Stresses
Using the layer thickness and the layer moduli calculated from the FWD data, the
loading stresses were calculated at the bottom of the AC layer with BISAR. These
stresses were calculated at three loading levels: 7,000 lbs., 9,000 lbs., and 11,000 lbs. and
at the three testing temperatures of 0°, 10°, and 20°. A complete summary of the loading
stresses appears in Appendix E. The modulus values used in the stress calculation were
the MR values calculated in the laboratory. Figure 5.4 shows the stresses for a 9,000-lb
load at all three temperatures. For any given temperature and load, the estimated stresses
in the bottom of the AC layer were greater for the cracked sections than for the uncracked
sections. The stresses for I-75 sections 1U and 1C are almost identical and indicate
similar structural characteristics. The other sections displayed much greater differences
the their stresses.
47
I-75 section 3C had approximately 60% greater stresses than section 2U. The stresses for
SR-80 section 1C were in some cases double those of section 2U.
050
100150200250300350400450
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Stre
ss (p
si)
0 10 20
Figure 5.15. Loading stresses (psi)
5.4 Crack Growth Model
As mentioned earlier in Chapter 2, Zhang (2001) developed a fracture mechanics
based crack growth model at The University of Florida. This model was used to
determine the relative cracking performance of each roadway section.
The crack growth model explains two phases of crack development: initiation and
propagation. The initiation phase predicts the number of cycles of loading required to
exceed a threshold point and begin macro cracks. The propagation phase predicts the
number of cycles that are required to grow a crack a given distance starting with an initial
user-defined crack length. The stresses that were used as inputs for both phases of the
cracking model were calculated using BISAR at the bottom of the asphalt layer. Since
the stresses were calculated at the bottom and not at the top of the asphalt layer, the
results of the initiation and propagation phases of the cracking model can only be used to
compare the cracking performance in a relative manner.
48
For the initiation phase, the number of cycles required to achieve macro cracking -
were calculated for low, medium, and high loading levels (7000, 9000, and 11000 Lbs.)
at the three test temperatures of 0°, 10°, and 20° C. The model calculates the number of
cycles for both dissipated creep strain energy and fracture energy limits. The results of
the initiation phase appear in Figures 5.16 through 5.21.
For each temperature and for each load, it was found that the uncracked sections
required more cycles to reach their thresholds and initiate a crack than their paired
uncracked sections. In all cases, there were significant differences in Nf. I-75 section 1U
required almost two times the Nf of section 1C to reach its threshold. I-75 section 2U
required three times the Nf of section 3C to reach its threshold and SR-80 section 2U
required almost six times the Nf of SR-80 section 1C. A comparison between Nf for the
DCSE limit and Nf for the FE limit for all three temperatures with a 9000 lb. load is
shown in Figures 5.22 through 5.24. For all cases, Nf was lower for DSCE than for FE.
This indicates that DSCE is more critical for all of these sections.
The results of the propagation phase were also analyzed for these sections
individually and appear below in Figures 5.25 through 5.27. The Nf for the propagation
phase is defined as the number of cycles that are required to propagate the crack from an
initial length of 4mm to a final length of 50mm.
49
0
10000
20000
30000
40000
50000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Nf t
o In
itiat
ion
7000 9000 11000
Figure 5.16 Number of Cycles to Failure for DCSE at 0° C
0
10000
20000
30000
40000
50000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Nf t
o In
itiat
ion
7000 9000 11000
Figure 5.17 Number of Cycles to Failure for DCSE at 10° C
0
10000
20000
30000
40000
50000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Nf t
o In
itiat
ion
7000 9000 11000
Figure 5.18 Number of Cycles to Failure for DCSE at 20° C
50
0
10000
20000
30000
40000
50000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Nf t
o In
itiat
ion
7000 9000 11000
Figure 5.19. Number of Cycles to Failure for FE at 0° C
0
10000
20000
30000
40000
50000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Nf t
o In
itiat
ion
7000 9000 11000
Figure 5.20. Number of Cycles to Failure for FE at 10° C
0
10000
20000
30000
40000
50000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Nf t
o In
itiat
ion
7000 9000 11000
Figure 5.21. Number of Cycles to Failure for FE at 20° C
51
0
10000
20000
30000
40000
50000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Nf t
o In
itiat
ion
DCSE FE
Figure 5.22. Comparison between Nf of DCSE and FE limits at 0° C
0
10000
20000
30000
40000
50000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Nf t
o In
itiat
ion
DCSE FE
Figure 5.23. Comparison between Nf of DCSE and FE limits at 10° C
0
10000
20000
30000
40000
50000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Nf t
o In
itiat
ion
DCSE FE
Figure 5.24. Comparison between Nf of DCSE and FE limits at 10° C
52
05000
10000150002000025000300003500040000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Nf t
o Pr
opog
ate
50m
m
7000 9000 11000
Figure 5.25. Number of Cycles to Failure to 50mm at 0° C
05000
10000150002000025000300003500040000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Nf t
o Pr
opog
ate
50m
m
7000 9000 11000
Figure 5.26. Number of Cycles to Failure to 50mm at 10° C
05000
10000150002000025000300003500040000
I75-1U I75-1C I75-2U I75-3C SR80-2U SR80-1C
Section
Nf t
o Pr
opog
ate
50m
m
7000 9000 11000
Figure 5.27. Number of Cycles to Failure to 50mm at 20° C
53
For each case at all temperatures and loadings, the uncracked sections required
more cycles to propagate a crack to 50mm than their paired cracked sections. There were
significant differences in Nf between the paired sections. I-75 section 1U required
approximately twice the cycles of section 1C to propagate to 50mm. I-75 section 2U
required close to 2.5 times the cycles of section 3C. SR-80 section 2U required over six
times the cycles of section 1C. The values of Nf for SR-80 section 1C are the same
across all three temperatures due to the extremely high stress that this section
experienced. This caused the material to fail immediately according to the cracking
model.
5.5 Individual Analysis of the Sections
5.5.1 I-75 1U and 1C
Low dissipated creep strain energy was the primary reason for the failure of section
I-75 1C. 1C and 1U had similar structures, m-value and D1. The DCSE value of 1U was
almost two times that of section 1C. From the extraction-recovery results it was found
that 1U had a much lower air void content, slightly lower asphalt content but higher film
thickness than section 1C. The air void content of section 1C was 68% higher than
section 1U. From the gradation curves, there was no significant difference between the
two sections. Both were very similar and followed the same trend. The binder viscosity
test showed that 1C had 33% higher viscosity than 1U.
The mixture property tests showed that the MR and the creep compliance values
were close to equal. Section 1C had almost 15% higher tensile strength than 1U and the
failure strain for section 1U was almost twice that of section 1C.
54
5.5.2 I-75 2U and 3C
The probable causes for failure in section 3C are related to the structural effects and
low DCSE values. The stresses calculated at the bottom of the asphalt for 3C are 60%
higher than those for 2U. These higher stress values resulted from lower modulus base
and sub base layers. The extraction-recovery results show significant differences. 3C
had slightly higher AC contents and 5% greater film thickness. The gradation results
showed that while both mixtures tended to be gap graded, section 3C was slightly more
gap graded. The binder viscosity for section 3C was approximately 25% greater than for
section 2U.
The mixture test results also displayed important differences between the two
sections. While the MR values were similar, the creep compliance results at 100 sec were
slightly lower for 3C at 10° C. The tensile strength of 3C was 25% lower than that of 2U.
Also, failure strain for 2U was 45% higher than for 3C.
5.2.3 SR-80 2U and 1C
The cause for failure in section 1C was due to structural effects, low DCSE values,
and high m-values. The calculated stresses for section 1C were extremely high and were
50% higher than those for section 2U. This was at least partially due to the low thickness
of the AC layer.
The trend in air void content for these two sections is the opposite of the I-75
sections. Section 2U has as much as 70% higher air voids than section 1C. The results of
the extraction-recovery process also show many differences. Section 2U had slightly
higher AC content and film thickness than 1C. The viscosity of the binder was 86%
greater for the uncracked section. Although the gradation plots showed a similar trend,
2U was a much finer mix than section 1C.
55
The mixture test results also showed significant differences. The MR results were
close to equal for the two sections. The creep compliance however, for section 1C was
90% greater than that of section 2U. The ultimate tensile strength of 2U was 20% higher
than 1C and the failure strain was slightly higher. The m-value and DCSE values were
also significant. For all temperatures, the cracked section had much higher m-values and
section 2U had almost 40% greater DCSE values.
CHAPTER 6 FURTHER ANALYSIS
This chapter presents the results of an analysis of the pavement sections previously
discussed as well as pavement sections studied by Garcia (2002) and Sedwick (1998).
This chapter also introduces two parameters: the minimum mixture fracture toughness as
well as the mixture fracture toughness ratio.
6.1 Section Data and Mixture Test Results
A summary of the pavement section data for the sections studied by Garcia and
Sedwick are included in Appendix F. These include traffic and the stresses calculated
from BISAR. The traffic is displayed in units of millions of ESALS/Year. The stresses
were calculated as the maximum tensile stress at the bottom of the asphalt layer. A
thorough presentation of the additional section data including layer thickness and moduli
appears in Garcia (2002) and Sedwick (1998).
A summary of the mixture test results for all sections also appears in Appendix F.
As mentioned earlier, the values for m, D0, and D1 are calculated from fitting the
following equation to the creep compliance test results:
( ) mtDDtD 10 +=
where, D(t) is compliance at time t, D0 and D1 are model parameters, and m is the m-
value. It should be noted that the D1 and m-value parameters were calculated by using a
constant D0 value of 3.33×10-7 psi for all sections. This was done to provide consistent
values of D1 and m.
56
57
6.2 Mixture Fracture Toughness
The number of cycles to propagate a crack 50 mm was calculated with the HMA
crack growth model for each section. Figure 6.1 shows the comparisons of Nf. Each
uncracked section clearly requires more cycles to achieve a crack length of 50mm than its
paired cracked section. It should be noted that SR-16 sections 6U and 4C were both
pavement sections that exhibited cracking in the field. However, section 4C displayed a
greater amount of cracking. All of the cracked sections also had Nf values of less than
6000. This value was chosen as the critical Nf value that separates the cracked sections
from the uncracked.
Using the value of 6000 as the critical Nf value, relationships were developed
between DCSE and D1max for different m-values. These are shown in Figure 6.2 for
constant values of stress and tensile strength. D1max is defined as the D1 value that
produces an Nf value of 6000 for a given DCSEf and m-value. A minimum DCSEf value
of 0.75 KJ/m3 was used for the analysis because all sections with a lower value
performed poorly.
0.00E+00
5.00E-07
1.00E-06
1.50E-06
2.00E-06
2.50E-06
3.00E-06
3.50E-06
4.00E-06
0 0.5 1 1.5 2 2.5
DCSE (KJ/m3)
D1m
ax (1
/psi
) 0.350.40.450.50.550.6
m-value
Figure 6.1. D1max for values of DCSE and m-value
0
2000
4000
6000
8000
10000
12000
14000
I75-1U I75-1C I75-2U I75-3C SR80-2U
SR80-1C
SR 16-6U
SR 16-4C
SR 375-1U
SR 375-2C
TPK 1U TPK 2C NW 39-2U
NW 39-1C
Section
Nf t
o Pr
opag
ate
50m
m
58
Figure 6.1. Nf to propagate 50mm
59
It was noted that the relationship presented in Figure 6.2 could be expressed using a
single function of the following form:
(6.1) bmDCSEaD −××=(max)1
where D1(max) (1/psi) is the maximum acceptable D1 value that will achieve in good
cracking performance, DCSE is the dissipated creep strain energy limit (KJ/m3), m is the
m-value, and a and b are regression constants. The coefficient b was determined to be
2.98, while a was determined to be a function of tensile strength and tensile stress as
follows:
(6.2) ( ) 810.32 1046.236.61099.2 −−− ×+−×= tSa σ
where St (MPa) is the ultimate tensile strength and σ (psi) is the tensile stress in the
asphalt layer. The HMA mixture fracture toughness (KHMA) was defined as the inverse of
D1. Therefore, a minimum fracture toughness can be defined as the inverse of D1(max)
which can be expressed as follows:
( )[ ]DCSESmK
tHMA 810.32
98.2
(min) 1046.236.61099.2 −−− ×+−×=
σ (6.3)
60
0.0E+00
2.0E-08
4.0E-08
6.0E-08
8.0E-08
1.0E-07
1.2E-07
1.4E-07
0 1 2 3 4 5 6 7
St (MPa)
a 100
120
150
σ (psi)
Figure 6.3. Relationship between a, St, and σ
Furthermore, a KHMA Ratio is defined as the ratio of the mixture fracture
toughness to the minimum mixture fracture toughness as follows:
(min)HMA
HMAHMA K
KRatioK = (6.4)
where, KHMA equals 1/D1 and KHMA(min) is determined by Equation 6.3.
The KHMA Ratio allows the comparison of the cracking resistance of different
pavement sections. A mixture with a KHMA Ratio value greater than 1 will have good
cracking performance, while a mixture with a KHMA ratio value of less than 1 will have
poor cracking performance. Figure 6.4 shows a comparison of the field sections and their
respective KHMA ratios. From the figure, it can be seen that all cracked sections exhibited
a fracture toughness ratio of less than one except for those sections with a DCSEf value of
less than 0.75KJ/m3. Each of the uncracked sections exhibited a KHMA Ratio of greater
than one excluding section I-10 MW1which had an unusually large DCSEf value.
61
Figure 6.5 displays the KHMA ratios for all sections with DCSEf values between
0.75 KJ/m3 and 2.5KJ/m3. For this range of DCSEf values, it appears that the KHMA ratio
is accurate in predicting the cracking performance of the pavement sections.
0.00
0.50
1.00
1.50
2.00
2.50
3.00
US301-B
SSR80
-1CI10
-DE
I10-D
WSR 16
-4CI10
-MW
2SR 16
-6CNW
39-1C
TPK 2CI75
-3CI75
-1CSR 37
5-2C
US301-B
NI95
-SJNI10
-MW
1I75
-1UI75
-2UTPK 1USR80
-2UNW
39-2U
SR 375-1
UI95
-DN
Section
KH
MA R
atio
Uncracked Cracked
*
*+
note: * DCSE < 0.75 KJ/m3 + DCSE > 2.5 KJ/m3
62
Figure 6.3. KHMA Ratio for all sections
0.00
0.50
1.00
1.50
2.00
2.50
3.00
US301-BS
SR80-1C
I10-DE
I10-DW
SR 16-4C
I10-MW2
SR 16-6C
NW39-1C
TPK2C
I75-3C I75-1C SR375-2C
I75-1U I75-2U TPK1U
SR80-2U
NW39-2U
SR375-1U
I95-DN
Section
KH
MA
Rat
io
Uncracked Cracked
63
Figure 6.4. KHMA Ratio for sections 0.75 KJ/m3 < DCSEf < 2.5 KJ/m3
64
6.3 Mixture Properties
An analysis was performed on all of the pavement sections to identify the key
mixture properties that affect cracking performance. Appendix F displays the various
mixture properties for each section including binder viscosity, effective asphalt content,
theoretical film thickness, percent air voids, and VMA. From these figures, it is clear that
no clear relationship exists between any of these properties and the relative cracking
performance.
However, several trends were observed when analyzing the gradations of each
section. The KHMA ratios were calculated for each section with a constant stress of 120
psi. This was done to eliminate the effect of structure in the calculation. The gradations
were then grouped according to high and low KHMA ratios as well as mix designation to
observe any trends between gradation characteristics and KHMA ratio. These gradations
are shown for all sections in Figures 6.5 through 6.8 below.
Two primary differences in gradation are apparent between the low KHMA ratio
sections and the high KHMA sections. The low KHMA sections move away and remain
further away from the max density line. These sections either remain fine relative to the
line or approach it and then gap dramatically at the finer sieves. The gradation curves for
the high KHMA sections are parallel and remain close to the max density line. They also
appear coarser with respect to the line without gapping drastically at the finer sieves. A
summary of these trends is illustrated in Figures 6.9-6.12.
0
10
20
30
40
50
60
70
80
90
100
Sieve sizes
% P
assi
ng
SR16-4C
SR16-6C
SR80-1C
I-10 DW
0 200 100 50 30 16 8 4 3/8 1/2 3/4 1
Max DensityLine
0.25
0.42
0.38
0.30
KHMA Ratio
65
Figure 6.5. Gradations of Low KHMA Ratio Sections with 12.5mm Nominal Aggregate Size
0
10
20
30
40
50
60
70
80
90
100
Sieve sizes
% P
assi
ng
SR 375-1U
SR80-2U
I-95 DN
SR 375 2C
NW 39 1C
I 75 3C
0 200 100 50 30 16 8 4 3/8 1/2 3/4 1
Max DensityLine
2.103.120.860.881.210.90
KHMA Ratio
66
Figure 6.6. Gradations of High KHMA Ratio Sections with 12.5mm Nominal Aggregate Size
0
10
20
30
40
50
60
70
80
90
100
Sieve sizes
% P
assi
ng
US301 BS
US301 BN
I-10 DE
I-10 MW2
0 200 100 50 30 16 8 4 3/8 1/2 3/4 1
Max DensityLine
0.050.690.220.48
KHMA Ratio
67
Figure 6.7. Gradations of Low KHMA Ratio Sections with 9.5mm Nominal Aggregate Size
0
10
20
30
40
50
60
70
80
90
100
Sieve sizes
% P
assi
ng
TPK 1U
NW 39-2U
I75-2U
I75-1U
I-10 MW1
TPK 2C
I75 1C
0 200 100 50 30 16 8 4 3/8 1/2 3/4 1
Max DensityLine
1.403.890.971.781.260.910.97
KHMA Ratio
68
Figure 6.8. Gradations of High KHMA Ratio Sections with 9.5mm Nominal Aggregate Size
69
0
10
20
30
40
50
60
70
80
90
100
Sieve sizes
% P
assi
ng
Low KHMA
High KHMA
0 200 100 50 30 16 8 4 3/8 1/2 3/4
Max DensityLine
Figure 6.9. Case 1 Gradation Comparison for 12.5mm Nominal mixes
0
10
20
30
40
50
60
70
80
90
100
Sieve sizes
% P
assi
ng
Low KHMA
High KHMA
0 200 100 50 30 16 8 4 3/8 1/2 3/4 1
Max DensityLine
Figure 6.10. Case 2 Gradation Comparison for 12.5mm Nominal mixes
70
0
10
20
30
40
50
60
70
80
90
100
Sieve sizes
% P
assi
ng
Low KHMA
High KHMA
0 200 100 50 30 16 8 4 3/8 1/2 3/4 1
Max DensityLine
Figure 6.11. Case 1 Gradation Comparison for 9.5mm Nominal mixes
0
10
20
30
40
50
60
70
80
90
100
Sieve sizes
% P
assi
ng
High KHMA
Low KHMA
0 200 100 50 30 16 8 4 3/8 1/2 3/4 1
Max DensityLine
Figure 6.12. Case 2 Gradation Comparison for 9.5mm Nominal mixes
71
6.4 Traffic
Traffic has an important effect on the initiation and propagation of surface cracks in
pavements. A higher level of traffic generally means a higher number of load repetitions
and a higher likelihood of high critical loads. It may be important to require higher
minimum KHMA ratios for higher traffic sections during the design process.
It was assumed that a road with a higher volume of traffic would require a
pavement system that would provide a higher number of cycles until a crack develops.
Average values of σ, St, DCSEf, m-value, and D1 were chosen that would result in 6000
Nf at a crack length of 2 in. or a KHMA Ratio of 1. The D1 value was varied while all
other values were held constant to produce different KHMA ratios. The resulting Nf values
were calculated using the HMA fracture mechanics model. Figure 6.13 below shows the
relationship between KHMA Ratio and Nf. Nf is directly proportional to traffic loading.
Figure 6.13 shows that an increase in traffic by a factor of two will require a pavement
system with two times the KHMA ratio.
0
0.5
1
1.5
2
2.5
0 2000 4000 6000 8000 10000 12000 14000
Nf
KH
MA R
atio
Figure 6.13. Relationship Between Nf and Required KHMA Ratio
72
From the relationship between Nf and KHMA ratio, the factor FT was defined. This
factor accounts for the increased KHMA ratio that would be required for increased traffic.
This relationship between traffic level and required KHMA ratio was compared to actual
field section data. The uncracked section with the lowest KHMA ratio in this study was
section I75-1U with a value of 1.27. This section also possessed a traffic loading of
approximately 500,000 ESALS/year. The relationship shown in Figure 6.13 above was
calibrated to this value where at a traffic level of 500,000 ESALS/year, the FT factor
equals 1.3. Figure 6.14 below shows FT vs. traffic level.
0
0.5
1
1.5
2
2.5
3
0 200 400 600 800 1000 1200
Traffic (ESALS/year x1000)
F T
Figure 6.14. FT vs. Traffic loading (ESALS/year x 1000)
This calculation does not however consider the structural differences that typically
exist between pavement sections with considerably different traffic loading. An analysis
was performed on theoretical pavement sections with differing traffic loadings. Several
pavement sections corresponding to different traffic loads were generated using the
AASHTO pavement design method. These were generated for sections with traffic
ranging from 50,000 ESALS/year to 1x106 ESALS/year. The design life of the pavement
was assumed to be 20 years. Constant values of layer moduli, reliability, and standard
73
deviation were assumed. A sample calculation appears in Appendix G. The layer
thicknesses were calculated as well as the maximum tensile stress at the bottom of the
AC layer. Using these stresses, the resulting KHMA ratios were calculated. Pavement
sections with higher traffic loads resulted in thicker AC layers as well as lower stresses at
the bottom of the AC layer and therefore possessed higher KHMA ratios. The factor FS
considers the effect of the increase in structural capacity on the increase in KHMA ratio.
The resulting relationship between traffic loading and FS is shown in Figure 6.15 below.
0
0.2
0.4
0.6
0.8
1
1.2
0 200 400 600 800 1000 1200
Traffic (ESALS/year x1000)
F S
Figure 6.15. Relationship Between Traffic Level and FS
The FS factor was also calibrated to the field section I75-1U with a traffic level of
approximately 500,000 ESALS/year. Figure 6.16 below shows the resulting relationship.
74
0
1
2
3
4
5
6
0 200 400 600 800 1000 1200
Traffic (ESALS/year x 1000)
F S
Figure 6.16. FS vs. Traffic (ESALS/year x 1000)
Considering the effect of traffic as well as the change in structure results in the
following equation:
STHMA FFquiredRatioK ∗=Re (6.5)
where KHMA Ratio Required is the minimum required KHMA ratio, FT is the traffic
factor, FS is the structural factor, and KHMA Ratio is the ratio of actual KHMA to the
minimum required KHMA. Figure 6.17 shows the minimum required KHMA ratio for
different traffic loads. The value of 1 was used for sections with traffic levels less than or
equal to 250k ESALS/yr.
75
0
0.5
1
1.5
2
2.5
0 200 400 600 800 1000 1200
Traffic (ESALS/year x1000)
Min
KH
MA R
atio
Req
uire
d
Figure 6.17 Minimum KHMA Ratio Required vs. Traffic Levels
CHAPTER 7 SUMMARY, CONCLUSIONS, AND RECOMMENDATIONS
7.1 Summary and Conclusions
The findings of this study may be summarized as follows:
• The important effects of mixture properties and pavement structure on top-down cracking performance was verified.
• It appears that HMA fracture mechanics properly accounts for effects of mixture properties. The relative cracking performance predicted by thee HMA fracture model developed at the University of Florida agrees with field observations
• In some cases excessively low DCSEf appeared to control cracking. It appears that cracking develops within relatively few cycles in these cases, such that cumulative DCSEf may not appropriately represent be the mode of failure.
• A single parameter (KHMA (min)) was identified and defined that allows designers to determine whether a mixture will experience top-down cracking. This parameter accounts for the effects of both mixture properties and pavement structure. It is based on MR, Creep, and Strength test results.
• The following relationship was developed for KHMA(min) based on calibration to actual field cracking performance of mixtures:
( )[ ]DCSESmK
tHMA 810.32
98.2
(min) 1046.236.61099.2 −−− ×+−×=
σ
• Furthermore, a mixture fracture toughness ratio was defined that allows relative comparisons between different mixtures and pavement sections:
(min)HMA
HMAHMA K
KRatioK = where, 1
1D
K HMA = , and
If KRatio > 1 No Cracking
If KRatio < 1 Cracking
• The KHMA Ratio was shown to predict field cracking performance for all field sections evaluated (22) except for three sections with very low or very high DCSEf.
76
77
• Specific gradation characteristics were associated with poor cracking performance. It was concluded that the KHMA Ratio may be increased by changes in the gradation such as the degree to which the gradation curve is parallel to the max density line as well as the severity of gap grading in the finer sieves.
• A procedure was established to rationally account for the effects of traffic on the minimum required KHMA Ratio. The following recommendations resulted from the work:
Traffic Minimum ESALS/year x 1000 KHMA Ratio
<250 1 400 1.2 500 1.3 1000 1.95
7.2 Recommendations
The specific condition and mechanism associated with top-down cracking is yet to
be determined. The relations developed were based on relative tensile stress as
determined at the bottom of the asphalt concrete layer. The critical tensile stresses at the
top of the pavement may involve the introduction of a crack and a temperature gradient
into the calculation as well as the residual stresses that may be induced by creep.
APPENDIX A SUMMARY OF NON-DESTRUCTIVE TESTING (FWD)
Table A.1: Deflection (mils0 From I-75 1U Sensor Spacing (in) Load
Milepost 0 8 12 18 24 36 60 Lbs. 2.01 5.53 4.42 3.72 2.91 2.28 1.44 0.8 9142 2.02 5.95 4.89 4.19 3.22 2.49 1.5 0.76 9002 2.03 5.8 4.71 4 3.09 2.38 1.45 0.76 9086 2.04 5.98 4.82 4.11 3.17 2.43 1.54 0.85 9094 2.05 5.33 4.38 3.79 2.93 2.32 1.59 0.87 9121 2.06 5.46 4.35 3.69 2.89 2.3 1.46 0.85 8954 2.07 5.78 4.66 3.91 3.15 2.43 1.51 0.87 9089 2.08 6.09 4.91 4.2 3.25 2.5 1.6 0.89 9050 2.09 6.04 4.89 4.19 3.26 2.448 1.53 0.85 9007 2.1 5.63 4.58 3.89 3 2.36 1.52 0.86 8938
Table A.2: Deflection (mils) From I-75 1C
Sensor Spacing (in) Load Milepost 0 8 12 18 24 36 60 Lbs.
1.01 6.41 5.15 4.32 3.33 2.57 1.63 1.01 8943 1.02 6.56 5.19 4.34 3.26 2.55 1.6 0.91 8803 1.03 6.28 5.01 4.21 3.15 2.46 1.62 0.94 8911 1.04 6.27 5.07 4.29 3.26 2.56 1.66 1 8891 1.05 6.38 5.17 4.37 3.36 2.65 1.69 0.96 8856 1.06 6.39 5.22 4.47 3.51 2.74 1.77 1 8771 1.07 6.3 5.16 4.4 3.47 2.77 1.79 0.95 8681 1.08 6.38 5.23 4.43 3.5 2.79 1.81 1.05 8811 1.09 6.15 5.05 4.32 3.43 2.71 1.82 1.01 8800 1.1 6.87 5.64 4.79 3.76 2.94 1.85 1 8800
79
0
2
4
6
8
10
12
14
16
18
20
0 10 20 30 40 50 60 70
Sensor Spacing (in)
Def
lect
ions
(mils
)
2.012.022.032.042.052.062.072.082.092.1
80
Figure A.1 Deflections for I-75 1U
0
2
4
6
8
10
12
14
16
18
20
0 10 20 30 40 50 60 70
Sensor Spacing (in)
Def
lect
ion
(mils
)
1.011.021.031.041.051.061.071.081.091.1
81
Figure A.2 Deflections for I-75 1C
82
Table A.3: Deflections for I-75 2U Sensor Spacing (in) Load Milepost 0 8 12 18 24 36 60 lbs.
1.01 4.69 3.74 3.24 2.68 2.31 1.65 0.99 8883 1.02 4.39 3.5 3.03 2.5 2.08 1.5 0.91 9046 1.03 4.67 3.52 3.02 2.5 2.08 1.49 0.91 9094 1.04 4.4 3.45 2.95 2.41 2.07 1.57 0.92 8792 1.05 4.49 3.37 2.88 2.41 1.99 1.49 0.9 9022 1.06 4.73 3.81 3.28 2.72 2.25 1.66 0.91 9007 1.07 4.83 3.87 3.26 2.72 2.26 1.62 0.94 9026 1.08 4.78 3.79 3.17 2.61 2.14 1.47 0.81 8954 1.09 4.68 3.83 3.31 2.67 2.26 1.74 1.02 9054 1.1 4.64 3.68 3.09 2.57 2.18 1.61 0.93 8962
Table A.4: Deflections for I-75 3C Sensor Spacing (in) Load Milepost 0 8 12 18 24 36 60 lbs.
2.01 6.16 5.01 4.13 3.24 2.5 1.52 0.79 8943 2.02 6.16 4.85 4.11 3.2 2.52 1.62 0.8 8962 2.03 6.34 4.91 4.14 3.23 2.54 1.63 0.83 8943 2.04 5.89 4.83 4.02 3.21 2.43 1.57 0.8 8819 2.05 6.5 5.08 4.15 3.22 2.44 1.52 0.8 8927 2.06 6.69 5.41 4.58 3.59 2.8 1.75 0.82 8840 2.07 6.59 5.41 4.52 3.47 2.68 1.66 0.82 8859 2.08 6.36 5.04 4.24 3.31 2.56 1.63 0.8 8856 2.09 6.24 4.99 4.12 3.25 2.51 1.57 0.82 8803 2.1 5.94 4.72 3.93 3.07 2.44 1.56 0.82 8851
0
2
4
6
8
10
12
14
16
18
20
0 10 20 30 40 50 60 70
Sensor Spacing (in)
Def
lect
ion
(mils
)
1.011.021.031.041.051.061.071.081.091.1
83
Figure A.3 Deflections for I-75 2U
0
2
4
6
8
10
12
14
16
18
20
0 10 20 30 40 50 60 70
Sensor Spacing (in)
Def
lect
ion
(mils
)
2.012.022.032.042.052.062.072.082.092.1
84
Figure A.4 Deflections for I-75 3C
85
Table A.5: Deflections for SR-80 2U Sensor Spacing (in) Load Milepost 0 8 12 18 24 36 60 lbs.
2.01 7.48 5.77 4.97 4.1 3.39 2.18 1 9054 2.02 7.15 5.98 5.22 4.27 3.5 2.27 1.07 8906 2.03 7.59 6.48 5.55 4.46 3.66 2.42 1.14 8800 2.04 8.55 6.7 5.53 4.41 3.59 2.35 1.13 8967 2.05 9.79 7 5.94 4.6 3.62 2.19 1.07 8864 2.06 7.25 6.18 5.36 4.37 3.52 2.24 1.14 9018 2.07 7.68 6.2 5.35 4.32 3.45 2.19 1.07 8994 2.08 8.16 6.73 5.81 4.58 3.73 2.39 1.21 8970 2.09 8.51 6.26 5.33 4.07 3.23 2.02 1.09 8720 2.1 9.35 6.71 5.64 4.38 3.5 2.16 1.11 8668
Table A.6: Deflections for SR-80 1C Sensor Spacing (in) Load Milepost 0 8 12 18 24 36 60 lbs.
1.01 10.99 7.75 5.44 3.33 2.26 1.21 0.76 8613 1.02 10.91 7.49 5.44 3.41 2.24 1.32 0.81 8450 1.03 10.31 7.02 5.07 3.02 2.07 1.19 0.78 8414 1.04 9.88 6.78 4.85 3.11 2.09 1.31 0.83 8593 1.05 11.75 8.24 5.78 3.52 2.27 1.26 0.83 8477 1.06 14.06 10.22 7.61 5.07 3.51 2.17 1.29 8315 1.07 17.67 12.91 9.74 6.54 4.56 2.72 1.51 8307 1.08 18.84 13.7 10.13 6.56 4.63 2.85 1.59 8347 1.09 17.02 12.54 9.62 6.68 4.85 2.91 1.63 8334 1.1 17.12 13.12 10.34 7.44 5.37 3.22 1.71 8318
0
2
4
6
8
10
12
14
16
18
20
0 10 20 30 40 50 60 70
Sensor Spacing (in)
Def
lect
ion
(mils
)
2.012.022.032.042.052.062.072.082.092.1
86
Figure A.5 Deflections for SR-80 2U
0
2
4
6
8
10
12
14
16
18
20
0 10 20 30 40 50 60 70
Sensor Spacing (in)
Def
lect
ion
(mils
)
1.011.021.031.041.051.061.071.081.091.1
87
Figure A.6 Deflections for SR-80 1C
88
01234567
0 10 20 30 40 50 60
Sensor Spacing (in)
Def
lect
ion
(mils
)
70
Measured Computed
01234567
0 10 20 30 40 50 60 7
Sensor Spacing (in)
Def
lect
ion
(mils
)
0
Measured Computed
Figure A.8 Measured and Computed Deflections for I-75 1U Location 06
01234567
0 10 20 30 40 50 60
Sensor Spacing (in)
Def
lect
ion
(mils
)
70
Measured Computed
Figure A.9 Measured and Computed Deflections for I-75 1U Location 09
Figure A.7 Measured and Computed Deflections for I-75 1U Location 03
89
012345678
0 10 20 30 40 50 60 7
Sensor Spacing (in)
Def
lect
ion
(mils
)
0
Measured Computed
Figure A.10 Measured and Computed Deflections for I-75 1C Location 03
012345678
0 10 20 30 40 50 60 7
Sensor Spacing (in)
Def
lect
ion
(mils
)
0
Measured Computed
Figure A.11 Measured and Computed Deflections for I-75 1C Location 08
012345678
0 10 20 30 40 50 60
Sensor Spacing (in)
Def
lect
ion
(mils
)
70
Measured Computed
Figure A.12 Measured and Computed Deflections for I-75 1C Location 10
90
012345678
0 10 20 30 40 50 60 7
Sensor Spacing (in)
Def
lect
ion
(mils
)
0
Measured Computed
Figure A.13 Measured and Computed Deflections for I-75 2U Location 02
012345678
0 10 20 30 40 50 60
Sensor Spacing (in)
Def
lect
ion
(mils
)
70
Measured Computed
Figure A.14 Measured and Computed Deflections for I-75 2U Location 09
012345678
0 10 20 30 40 50 60
Sensor Spacing (in)
Def
lect
ion
(mils
)
70
Measured Computed
Figure A.15 Measured and Computed Deflections for I-75 2U Location 02
91
012345678
0 10 20 30 40 50 60
Sensor Spacing (in)
Def
lect
ion
(mils
)70
Measured Computed
012345678
0 10 20 30 40 50 60 7
Sensor Spacing (in)
Def
lect
ion
(mils
)
0
Measured Computed
Figure A.17 Measured and Computed Deflections for I-75 1C Location 04
012345678
0 10 20 30 40 50 60 7
Sensor Spacing (in)
Def
lect
ion
(mils
)
0
Measured Computed
Figure A.18 Measured and Computed Deflections for I-75 1C Location 06
Figure A.16 Measured and Computed Deflections for I-75 1C Location 03
92
0
2
4
6
8
10
12
0 10 20 30 40 50 60 7
Sensor Spacing (in)
Def
lect
ion
(mils
)
0
Measured Computed
Figure A.19 Measured and Computed Deflections for SR-80 2U Location 05
0
2
4
6
8
10
12
0 10 20 30 40 50 60 7
Sensor Spacing (in)
Def
lect
ion
(mils
)
0
Measured Computed
Figure A.20 Measured and Computed Deflections for SR-80 2U Location 09
0
2
4
6
8
10
12
0 10 20 30 40 50 60 7
Sensor Spacing (in)
Def
lect
ion
(mils
)
0
Measured Computed
Figure A.21 Measured and Computed Deflections for SR-80 2U Location 01
93
0
2
4
6
8
10
12
0 10 20 30 40 50 60 7
Sensor Spacing (in)
Def
lect
ion
(mils
)
0
Measured Computed
0
2
4
6
8
10
12
0 10 20 30 40 50 60 7
Sensor Spacing (in)
Def
lect
ion
(mils
)
0
Measured Computed
Figure A.23 Measured and Computed Deflections for SR-80 1C Location 03
0
2
4
6
8
10
12
0 10 20 30 40 50 60 7
Sensor Spacing (in)
Def
lect
ion
(mils
)
0
Measured Computed
Figure A.23 Measured and Computed Deflections for SR-80 1C Location 03
Figure A.22 Measured and Computed Deflections for SR-80 1C Location 02
APPENDIX B SUMMARY OF FDOT FLEXIBLE PAVEMENT CONDITION SURVEY
0
2
4
6
8
10
12
1990 1992 1994 1996 1998 2000 2002Year
Cra
ck R
atin
g
I75-1U I75-1C
Figure B.1 Cracking Ratings from I-75 1U and 1C
0
2
4
6
8
10
12
1990 1992 1994 1996 1998 2000 2002Year
Cra
ck R
atin
g
I75-2U I75-3C
Figure B.2 Cracking Ratings from I-75 2U and 3C
95
96
0
2
4
6
8
10
12
1990 1992 1994 1996 1998 2000 2002Year
Cra
ck R
atin
g
SR 80-2U SR 80-1C
Figure B.3 Cracking Ratings from SR-80 2U and 1C
APPENDIX C SUMMARY OF VOLUMETRIC PROPERTIES
98
Table C.1 Bulk Specific Gravity for each Sample
I75-1U I75-1C I75-2U I75-3C SR 80-2U SR 80-1CSample WP BWP WP BWP WP BWP WP BWP WP BWP WP BWP
1 2.329 2.294 2.310 2.268 2.327 2.254 2.296 2.235 2.274 2.211 2.278 2.2222 2.326 2.281 2.310 2.258 2.297 2.241 2.293 2.233 2.258 2.206 2.277 2.2223 2.326 2.280 2.308 2.253 2.295 2.240 2.291 2.228 2.253 2.202 2.276 2.2194 2.326 2.290 2.280 2.308 2.252 2.289 2.235 2.225 2.252 2.197 2.275 2.2145 2.325 2.279 2.306 2.248 2.286 2.233 2.289 2.218 2.252 2.195 2.274 2.2136 2.325 2.277 2.305 2.247 2.286 2.232 2.287 2.218 2.250 2.188 2.274 2.2137 2.325 2.277 2.304 2.246 2.284 2.231 2.286 2.216 2.246 2.188 2.273 2.2108 2.324 2.275 2.303 2.242 2.282 2.226 2.283 2.213 2.238 2.179 2.272 2.2079 2.324 2.274 2.303 2.242 2.282 2.226 2.281 2.212 2.237 2.178 2.271 2.20610 2.324 2.274 2.302 2.238 2.278 2.218 2.277 2.212 2.236 2.177 2.269 2.20211 2.323 2.274 2.302 2.237 2.278 2.217 2.277 2.210 2.227 2.175 2.269 2.20112 2.323 2.270 2.301 2.236 2.277 2.216 2.277 2.206 2.226 2.175 2.269 2.20013 2.322 2.269 2.300 2.234 2.276 2.214 2.272 2.205 2.224 2.174 2.265 2.20014 2.322 2.267 2.300 2.232 2.275 2.214 2.262 2.202 2.222 2.174 2.262 2.19915 2.319 2.266 2.300 2.232 2.273 2.209 2.252 2.190 2.206 2.171 2.261 2.19616 2.318 2.264 2.296 2.231 2.272 2.200 2.190 2.200 2.167 2.259 2.19417 2.317 2.262 2.295 2.230 2.267 2.194 2.173 2.199 2.160 2.256 2.18118 2.259 2.215 2.170 2.152 2.170 2.148 2.222 2.176
Average 2.323 2.274 2.303 2.241 2.284 2.221 2.281 2.208 2.232 2.181 2.267 2.204St. Dev 0.003 0.008 0.004 0.012 0.014 0.020 0.012 0.021 0.026 0.016 0.013 0.013
99
Table C.2 Effective Asphalt Content, Film Thickness and VMA Factors Gradation
Size m2/kg ft2/lb I75 1C I75 1U I75 2 I75 3 SR80 1 SR80 2 19 0.41 2 100.00 100.00 100.00 100.00 100.00 100.00
12.5 0.41 2 99.46 97.69 97.74 90.75 92.68 93.63 9.5 0.41 2 95.74 93.71 92.47 79.54 83.57 84.79
4.75 0.41 2 75.92 74.58 68.90 58.33 60.48 64.41 2.36 0.82 4 57.68 55.58 50.47 47.54 45.51 52.38 1.18 1.64 8 46.75 44.24 41.87 42.09 35.66 41.05 0.06 2.87 14 38.67 36.78 35.18 37.11 28.47 32.69 0.03 6.14 30 27.36 25.61 22.58 25.77 21.76 25.65
0.015 12.29 60 12.83 12.30 10.67 12.99 11.51 14.60 0.0075 32.77 160 5.86 5.58 5.02 5.88 6.19 6.18
Surface area Size I75-1C I75-1U I75-2U I75-3C SR80 1 SR80 2 19 0.410 0.410 0.410 0.410 0.410 0.410
12.5 0.408 0.401 0.401 0.372 0.380 0.384 9.5 0.393 0.384 0.379 0.326 0.343 0.348
4.75 0.311 0.306 0.282 0.239 0.248 0.264 2.36 0.473 0.456 0.414 0.390 0.373 0.430 1.18 0.767 0.726 0.687 0.690 0.585 0.673 0.06 1.110 1.056 1.010 1.065 0.817 0.938 0.03 1.680 1.573 1.386 1.582 1.336 1.575
0.015 1.576 1.512 1.311 1.596 1.415 1.794 0.0075 1.920 1.829 1.645 1.927 2.028 2.025
Gse 2.61 2.57 2.61 2.62 2.56 2.60
Surface area, m2/kg 9.047 8.651 7.925 8.598 7.935 8.841 Total AC 6.78 6.20 6.15 6.640 6.450 6.760
Gsb 2.490 2.476 2.462 2.436 2.407 2.433 Effective AC, % 4.92 4.83 3.90 4.41 3.84 4.32
Gmm 2.369 2.349 2.386 2.380 2.338 2.359 Gmb 2.242 2.274 2.241 2.190 2.213 2.197 Pb 1.90 1.45 2.37 3.01 2.57 2.74
Weight of Absorbed AC, g 39.8 30.8 49.88 61.57 53.18 56.03 Effective Vol. Of AC, ml 107.83 106.07 83.90 79.62 85.37 88.16
Vol. Of AC, ml 147.61 136.91 133.78 141.19 138.55 144.19 Film thickness, micro-meters 5.70 5.75 5.03 4.53 5.20 4.87
VMA 16.05 13.84 14.58 16.06 14.00 15.80
APPENDIX D MIXTURE TEST RESULTS
Table D.1 Resilient Modulus Total Resilient Modulus (GPa) Cycle
Section Temp 1 2 3 Average 0 14.76 14.81 15.24 14.94
I75-1U 10 10.92 10.88 10.93 10.91 20 7.68 7.61 7.65 7.65 0 16.83 16.63 17.18 16.88
I75-1C 10 11.28 10.96 11.17 11.14 20 8.08 7.62 7.56 7.75 0 18.42 18.56 18.23 18.40
I75-2U 10 10.18 10.42 10.28 10.29 20 7.77 7.64 7.64 7.68 0 16.79 16.76 17.04 16.86
I75-3C 10 11.52 11.58 11.64 11.58 20 8.19 8 7.98 8.06 0 17.78 18.4 18.06 18.08
SR80-2U 10 13.6 13.5 13.24 13.45 20 11.1 10.86 11.06 11.01 0 18.24 19.09 18.14 18.49
SR80-1C 10 13.41 13.42 13.33 13.39 20 9.22 9.21 8.96 9.13
Table D.2 Tensile Strength
Tensile Strength (MPa) Poisson's Specimen
Section Temp Ratio 1 2 3 Average 0 0.34 3.00 3.20 2.69 2.96
I75-1U 10 0.38 2.29 1.83 1.92 2.01 20 0.41 1.27 1.25 1.24 1.25 0 0.38 2.77 2.77 2.34 2.63
I75-1C 10 0.46 1.61 1.60 1.73 1.65 20 0.46 1.04 0.88 1.19 1.04 0 0.37 3.38 3.42 2.90 3.23
I75-2U 10 0.34 2.03 1.88 1.77 1.89 20 0.44 1.28 1.23 1.30 1.27 0 0.38 2.92 2.54 2.33 2.60
I75-3C 10 0.49 1.56 1.87 1.60 1.68 20 0.38 1.34 1.40 1.37 1.37 0 0.23 2.71 2.96 2.82 2.83
SR80-2U 10 0.34 2.35 2.22 2.61 2.39 20 0.46 1.83 1.66 1.17 1.55 0 0.39 2.33 2.45 2.27 2.35
SR80-1C 10 0.39 1.60 1.58 1.59 1.59 20 0.32 1.21 1.02 1.82 1.35
101
102
Table D.3 Creep Compliance Creep Compliance (1/Gpa) Poisson's 1 10 100
Section Temp Ratio (sec) (sec) (sec) I75-1U 0 0.46 0.095 0.155 0.324
10 0.39 0.196 0.420 1.029 20 0.45 0.389 1.026 3.002
I75-1C 0 0.45 0.076 0.128 0.268 10 0.47 0.202 0.420 1.060 20 0.43 0.358 0.881 2.466
I75-2U 0 0.45 0.070 0.117 0.239 10 0.41 0.216 0.436 1.143 20 0.43 0.431 1.153 3.253
I75-3C 0 0.42 0.084 0.132 0.266 10 0.45 0.152 0.296 0.766 20 0.32 0.351 1.100 3.252
SR80-2U 0 0.30 0.071 0.091 0.126 10 0.39 0.103 0.164 0.324 20 0.44 0.194 0.349 0.794
SR80-1C 0 0.48 0.060 0.087 0.144 10 0.45 0.104 0.214 0.540 20 0.35 0.269 0.572 1.523
103
Table D.4 M-value, Failure Strain, Fracture Energy, DCSE, Initial Tangent Modulus, D0, and D1
Failure Fracture Strain Energy DCSE Initial Tangent
Section Temp
M-value (Microstrain)
(KJ/m3)
(KJ/m3) Modulus
D0 D1I75-1U 0 0.4366 794.77 1.5 1.207 7 4.13E-07 2.43E-07
10 0.4363 1437.44 2.0 1.814 3.7 4.72E-07 8.88E-07 20 0.5435 2810.96 2.5 2.398 1.5 1.36E-06 1.59E-06
I75-1C 0 0.4314 582.84 0.8 0.595 7.1 3.21E-07 2.07E-07 10 0.4713 1028.05 1.1 0.978 3.8 6.55E-07 7.55E-07 20 0.4648 1363.28 1.0 0.930 2.1 6.87E-07 1.89E-06
I75-2U 0 0.4187 822.53 1.7 1.416 7.6 2.87E-07 2.87E-07 10 0.5173 1066.72 1.3 1.126 4.2 8.54E-07 6.50E-07 20 0.4689 2663.56 2.5 2.395 1.7 4.75E-07 2.53E-06
I75-3C 0 0.4479 617.21 0.9 0.700 6.5 4.00E-07 1.82E-07 10 0.5192 715.74 0.8 0.678 5 6.48E-07 4.21E-07 20 0.4697 2715.98 2.7 2.584 1.9 -1.71E-14 2.57E-06
SR80-2U 0 0.3088 444.92 0.7 0.479 9 3.70E-07 1.22E-07 10 0.4176 679.15 1.0 0.787 6.3 4.66E-07 2.54E-07 20 0.4584 962.22 1.0 0.891 3.7 7.81E-07 5.65E-07
SR80-1C 0 0.3216 424.49 0.5 0.351 6.8 2.52E-07 1.66E-07 10 0.4797 495.27 0.3 0.206 3.6 3.63E-07 3.66E-07 20 0.5131 849.77 0.7 0.600 1.7 9.95E-07 8.93E-07
104
Table D.5 Dissipated Creep Strain Energy Calculation Section Temp MR ef St eO EE FE DCSE I75-1U 0 14.94 794.77 2.96 794.57 0.29 1.5 1.207
10 10.91 1437.44 2.01 1437.26 0.19 2.0 1.814 20 7.65 2810.96 1.25 2810.80 0.10 2.5 2.398
I75-1C 0 16.88 582.84 2.63 582.68 0.20 0.8 0.595 10 11.14 1028.05 1.65 1027.90 0.12 1.1 0.978 20 7.75 1363.28 1.04 1363.15 0.07 1.0 0.930
I75-2U 0 18.4 822.53 3.23 822.35 0.28 1.7 1.416 10 10.29 1066.72 1.89 1066.54 0.17 1.3 1.126 20 7.68 2663.56 1.27 2663.39 0.10 2.500 2.395
I75-3C 0 16.86 617.21 2.60 617.06 0.20 0.9 0.700 10 11.58 715.74 1.68 715.59 0.12 0.8 0.678 20 8.06 2715.98 1.37 2715.81 0.12 2.7 2.584
SR80-2U 0 18.08 444.92 2.83 444.76 0.22 0.7 0.479 10 13.45 679.15 2.39 678.97 0.21 1.0 0.787 20 11.01 962.22 1.55 962.08 0.11 1.0 0.891
SR80-1C 0 18.49 424.49 2.35 424.36 0.15 0.5 0.351 10 13.39 495.27 1.59 495.15 0.09 0.3 0.206 20 9.13 849.77 1.35 849.62 0.10 0.7 0.600
APPENDIX E SUMMARY OF CRACK GROWTH MODEL RESULTS
Table E.1. Estimated Loading Stresses (psi)
Section Temp 7000 LB 9000 LB11000
LB 0 134 172 211
I75-1U 10 119 153 188 20 102 131 160 0 138 177 216
I75-1C 10 119 152 186 20 103 132 161 0 99.3 128 156
I75-2U 10 77.6 99.8 122 20 66.3 85.2 104 0 139 178 218
I75-3C 10 122 157 191 20 106 137 167 0 149 191 234
SR80-2U 10 136 175 214 20 125 161 197 0 287 369 451
SR80-1C 10 247 318 389 20 206 264 323
106
107
Table E.2. Nf to Initiation for DCSE DCSE Nf to Failure (Initiation) Temp 7000 9000 11000 0 24598 14930 9921
I75-1U 10 12854 7776 5150 20 6329 3837 2572 0 13912 8457 5679
I75-1C 10 6422 3936 2629 20 3402 2072 1392 0 50381 30321 20413
I75-2U 10 14888 9001 6023 20 15366 9305 6245 0 16379 9988 6659
I75-3C 10 5531 3340 2256 20 6351 3802 2559 0 40051 24373 16239
SR80-2U 10 16998 10266 6865 20 7731 4660 3113 0 6462 3909 2617
SR80-1C 10 738 444 298 20 990 600 402
Table E.3. Nf to Initiation for FE
FE Nf to Failure (Initiation) Temp 7000 9000 11000 0 29986 17971 11746
I75-1U 10 13953 8354 5459 20 6513 3915 2596 0 18078 10743 7008
I75-1C 10 7025 4229 2758 20 3539 2108 1378 0 60032 35949 24054
I75-2U 10 17005 10208 6770 20 15952 9625 6431 0 20422 12204 7924
I75-3C 10 6277 3691 2413 20 6554 3891 2592 0 56088 33177 21289
SR80-2U 10 20892 12338 8017 20 8384 4938 3201 0 7617 3980 2139
SR80-1C 10 752 325 112 20 1000 545 314
108
Table E.4. Nf to Propagate 50mm Temp 7000 9000 11000 0 19254 12694 9083
I75-1U 10 11055 7272 4990 20 5990 3779 2568
0 11438 7564 5380 I75-1C 10 5933 3815 2605
20 3325 2068 1587 0 34550 22659 16382
I75-2U 10 11290 7457 5321 20 12656 8382 5900
0 13548 9076 6333 I75-3C 10 5090 3235 2238
20 5954 3721 2545 0 33063 22078 15438 SR80-2U 10 14368 9506 6629 20 7312 4581 3104 0 4155 3733 3733 SR80-1C 10 703 703 703 20 933 933 933
APPENDIX F SUMMARY OF SECTION DATA FOR ALL SECTIONS
Table F.1. Summary of Traffic Loading (Annual ESALS in 1000) Section ESALS/YR Section ESALS/YR
SR 16-4C 21 I75-1C 573 SR 16-6U 21 I75-2U 576 SR 375-2C 68 I75-3C 674 SR 375-1U 76 I-10 MW1 546 TPK 2C 166 I-95 DN 1192 NW 39-2U 182 I-95SJN 1192 NW 39-1C 190 I-10 DE 681 TPK 1U 195 I-10 DW 681
SR80-2U 207 I-10 MW2 546 SR80-1C 221 US 301BN 558 I75-1U 558 US 301BS 558
Table F.2. Summary of Loading Stress (psi)
Section Stress Section Stress I75-1U 153 TPK 1U 116 I75-1C 152 TPK 2C 162 I75-2U 99.8 NW 39-2U 208 I75-3C 157 NW 39-1C 282
SR80-2U 175 I10-MW1 158 SR80-1C 318 I10-MW2 133
SR 16-6U 120 US301-BN 98.2 SR 16-4C 120 US301-BS 128 US 19-1U 87 I95-DN 53.9 US 19-2C 146 I95-SJN 92.1 SR 375-1U 120 I10-DW 138 SR 375-2C 120 I10-DE 120
110
111
Table F.3. Summary of Mixture Test Results Needed for Cracking Model Section m-value FE DCSE St D1
(KJ/m3) (KJ/m3) (MPa) (1/psi) I75-1U 0.42 2.0 1.81 2.01 9.89E-07 I75-1C 0.43 1.1 0.98 1.65 9.73E-07 I75-2U 0.44 1.3 1.13 1.89 9.99E-07 I75-3C 0.45 0.8 0.68 1.68 6.23E-07
SR80-2U 0.36 1.0 0.79 2.39 3.52E-07 SR80-1C 0.47 0.3 0.21 1.59 3.82E-07
SR 16-6U 0.49 0.5 0.41 1.24 6.65E-07 SR 16-4C 0.61 0.3 0.25 0.89 3.66E-07 US 19-1U 0.6 1.7 1.55 1.53 8.29E-07 US 19-2C 0.58 3.3 1.91 2.73 4.11E-07 SR 375-1U 2.12
0.68 2.15 TPK 1U 0.96
1.3 1.14 1.7 NW 39-2U 1.75 NW 39-1C 0.23
2.4 2.26 1.82 I10-MW2 0.59 1.05
US301-BN 0.37 0.3 0.27 1.13 6.32E-07 US301-BS 0.39 0.1 0.03 0.93 8.47E-07
I95-DN 0.48 1.2 1.20 1.3 9.59E-07 I95-SJN 0.51 0.8 0.53 1.94 3.60E-07 I10-DW 0.46 0.8 0.66 1.33 1.67E-06 I10-DE 0.52 1.0 0.88 1.25 2.21E-06
0.52 2.3 2.59 4.63E-07 SR 375-2C 1.7 1.53 3.80E-07
0.47 1.1 1.96 4.67E-07 TPK 2C 0.49 8.10E-07
0.45 2.0 2.65 3.14E-07 0.54 0.3 1.41 9.18E-07
I10-MW1 0.55 8.31E-07 1.1 1.18 8.67E-07
Table F.4. Number of Cycles to Propagate Crack Length of 50mm
Section Nf to Prop I75-1U 7410 I75-1C 4039 I75-2U 8311 I75-3C 3543
SR80-2U 10147 SR80-1C 704
SR 16-6U 2610 SR 16-4C 1376 US 19-1U 6530 US 19-2C 6131 SR 375-1U 12827 SR 375-2C 4314
TPK 1U 9250 TPK 2C 3328
NW 39-2U 9903 NW 39-1C 2628
1120
1
2
3
4
5
6
7
I-10 M
W1
US 19-1U
SR 375-1
UTPK 1U
NW 39
-2UI-9
5 DN
SR 16-6U
I75-1U
I75-2U
SR-80 2U
I-95S
JNI-1
0 DE
I-10 D
WSR 37
5-2C
TPK 2CI-1
0 MW
2US 30
1 BN
US 301 B
SSR 16
-4CUS 19
-2CNW
39-1C
I75-1C
I75-3C
SR-80 1C
Sections
Eff
ectiv
e A
spha
lt C
onte
nt %
Uncracked Cracked
Figure F.1. Effective Asphalt Content (%)
0
2
4
6
8
10
12
I-10 M
W1
US 19-1U
SR 375-1
UTPK 1U
NW 39
-2UI-9
5 DN
SR 16-6U
I75-1U
I75-2U
SR 80-2U
I-1
0 DE
I-10 D
WSR 37
5-2C
TPK 2CI-1
0 MW
2US 30
1 BN
US 301 B
SSR 16
-4CUS 19
-2CNW
39-1C
I-95S
JNI75
-1CI75
-3CSR 80
-1C
Section
% A
ir V
oids
WP BWP
CrackedUncracked
Figure F.2 Percent Air Voids (%)
113
0.0
2.0
4.0
6.0
8.0
10.0
12.0
I-10 M
W1
US 19-1U
SR 375-1
UTPK 1U
NW 39
-2UI-9
5 DN
SR 16-6U
I75-1U
I75-2U
SR-80 2U
I-95S
JNI-1
0 DE
I-10 D
WSR 37
5-2C
TPK 2CI-1
0 MW
2US 30
1 BN
US 301 B
SSR 16
-4CUS 19
-2CNW
39-1C
I75-1C
I75-3C
SR-80 1C
Section
Film
Thi
ckne
ss, m
icro
ns
Uncracked Cracked
Figure F.3. Theoretical Film Thickness (microns)
114
02468
101214161820
I-10 M
W1
US 19-1U
SR 375-1
UTPK 1U
NW 39
-2UI-9
5 DN
SR 16-6U
I75-1U
I75
-2U
SR 80-2U
I-9
5SJN
I-10 D
EI-1
0 DW
SR 375-2
CTPK 2C
I-10 M
W2
US 301 B
NUS 30
1 BS
SR 16-4C
US 19-2C
NW 39
-1CI75
-1C
I75-3C
SR 80
-1C
Section
VM
A (%
)
Uncracked Cracked
Figure F.4. VMA (%)
115
116
LIST OF REFERENCES
Ewalds, H.L., and R.J.H. Wanhill, Fracture Mechanics, Delftse Uitgevers Maatschappij, Delft,Netherlands, and Edward Arnold Publishers, London, 1986.
Garcia, O.F., “Asphalt Mixture and Loading Effects on Surface-Cracking of Pavements,” Master’s Thesis, University of Florida, Gainesville, 2002.
Honeycutt, K.E., “Effect of Gradation and other Mixture Properties on the Cracking Resistance of Asphalt Mixtures,” Master’s Thesis, University of Florida, Gainesville, 2000.
Huang, Y.H., Pavement Analysis and Design, Prentice Hall, Englewood Cliffs NJ, 1993.
Jacobs, M.M.J., “Crack Growth in Asphaltic Mixes,” Ph.D. Dissertation, Delft, The Netherlands, Nelft University of Technology, 1995.
Kandhal P.S. and S. Chakraborty, “Evaluation of Voids in the Mineral Aggregates,” NCAT Report No. 96-4, National Center for Asphalt Technology, March 1996.
Malan, G.W., P.J. Strauss and F. Hugo, “A Field Study of Premature Surface Cracking in Asphalt,” Proceedings of the Association of Asphalt Paving Technologists, Vol. 58, pp. 142-162, 1989.
Monismith, C.L., “Fatigue Characteristics of Asphalt Paving Mixtures and Their Use in Pavement Design,” Proceedings of the Eighteen Paving Conference, Vol. 54, pp,124-132, 1981.
Monismith, C.L., J.A. Epps, and F.N. Finn, “Improved Asphalt Mix Design,” Proceedings of the Association of Asphalt Paving Technologists, Vol. 55, pp. 124-132, 1985.
Myers, L.A., “Mechanism of Wheel Path Cracking That Initiates at the Surface of Asphalt Pavements,” Master’s Thesis, University of Florida, Gainesville, 1997.
Myers, L.A., “Development and Propagation of Surface-Initiated Longitudinal Wheel Path Cracks in Flexible Highway Pavements,” Ph.D. Dissertation, University of Florida, Gainesville, 2000.
Nukunya, B. “Evaluation of Aggregate Type, Gradation and Volumetric Properties for Design and Acceptance of Durable Superpave Mixtures,” Ph.D. Dissertation, University of Florida, Gainesville, 2001.
117
Pell, P. and F. Taylor, “Asphaltic Road Materials in Fatigue,” Proceedings of the Association of Asphalt Paving Technologists, Vol. 38, pp. 371-421, 1969.
Roque, R., W.G. Buttlar, B.E. Ruth, M. Tia, S.W. Dickison, and B. Reid, “Evaluation of SHRP Indirect Tension Tester to Mitigate Cracking in Asphalt Pavements and Overlays,” Final Report to the Florida Department of Transportation, University of Florida, Gainesville, 1997.
Sedwick, S.C., “Effect of Asphalt Mixture Properties and Characteristics on Surface-Initiated Longitudinal Wheel Path Cracking,” Master’s Thesis, University of Florida, Gainesville, 1998.
Sousa, J.B., G. Way and J. Harvey, “Performance Based Mix Design and Field Quality Control for Asphalt-Aggregate Overlays,” Transportation Research Board, Record No. 1543, pp. 46-62, 1996.
Valkering C.P. and G. Van Gooswilligen, “The Role of the Binder Content in the Performance-Related Properties of Asphaltic Mixes for Surface Layers,” Proceedings of the Association of Asphalt Paving Technologists, Vol. 58, pp.238-255, 1989.
Zhang, Z., “Identification of Suitable Crack Growth Law for Asphalt Mixtures Using the Superpave Indirect Tensile Test (IDT),” Ph.D. Dissertation, University of Florida, Gainesville, 2000.
BIOGRAPHICAL SKETCH
Adam Jajliardo was born in Manchester, Connecticut on November 21, 1978. He
graduated from High School from Woodstock Academy in 1997. Adam attended The
University of Connecticut and received a Bachelor of Science in Civil Engineering
degree in 2001.
Adam gained admission to the University of Florida in 2001 and began his studies
for his Master of Engineering degree.
118