Title: LTPP Lessons Learned: National Experiment
1LTPP Lessons Learned National Experiment
- Wednesday April 9, 2014
- Dover, DE
- Jack Springer, P.E. - FHWA
- Gabe Cimini, PM LTPP - NARSC
2Lessons Learned Overview
- Program Benefits and Return on Investment
- Construction Effects on PCC Pavement Performance
- Specific SPS-2 Lessons Learned
- Pavement Performance
- Pavement Design
- Materials Testing
- Data Collection
- Future Benefits
3LTPP Benefits
- The LTPP program has generated a wide range of
benefits all across the pavement engineering and
performance spectrum.
4Return on Investment
LTPP by the Numbers
LTPP Resource Statistics
Requests for Data 48,000 Requests
Registered LTPP Website Users 3,000 Users (in 75 Countries)
Published Documents Resulting from LTPP Data 500 Publications
ASCE Paper Contest 60 Entries
Distress Manuals 20 State Agencies
FWD Calibration Centers 500 Calibrations
WIM Systems 550 Installations
SPS Traffic Pooled Fund Study Installations 21 WIM Sites Installed
MRL Materials 2,000,000 Pounds Available
MRL Shipments 17,000 Pounds Delivered
The numerous innovations that have directly
resulted from the LTPP program include
procedures, tools, manuals, and research findings
that have been implemented across the United
States and abroad.
5Return on Investment
Cost Savings
LTPP has already realized over 2 Billion in
savings, with the potential for even greater
future savings.
Savings To Date Projected Cumulative Future Savings (2015-2024) Projected Cumulative Future Savings (2015-2024)
Savings To Date No Additional Monitoring Continued Monitoring
2.1 Billion 2.28 Billion 4.56 Billion
6Construction Effects on PCC Performance
Construction Practice Classification Effect on Distress Type Effect on Distress Type Effect on Distress Type Average Ranking
Construction Practice Classification JPCP faulting JPCP cracking Roughness Average Ranking
Dowel Placement Others 3 X X 3
Dowel Placement Mechanical install 2 X X 2
Dowel Placement Preplaced in baskets 1 X X 1
Joint Forming Sawed 2 X X 2
Joint Forming Plastic Insert 1 X X 1
Coarse Agg. Content lt1800 kg/m3 X 2 X 2
Coarse Agg. Content gt1800 kg/m3 X 1 X 1
Fine Agg. Content lt1300 kg/m3 X 1 X 1
Fine Agg. Content gt1300 kg/m3 X 2 X 2
Concrete Curing Membrane X X 3 3
Concrete Curing Polythene X X 1.5 1.5
Concrete Curing Burlap X X 1.5 1.5
Concrete Texture Astroturf X X 6 6
Concrete Texture Others X X 5 5
Concrete Texture Broom X X 4 4
Concrete Texture Tine X X 3 3
Concrete Texture Burlap Drag X X 2 2
Concrete Texture Grooved Float X X 1 1
Note X denotes no effect ranking of 1-5
indicates best-worst performance
7SPS-2 Lessons LearnedPavement Performance
- Standardizing AVC and WIM data storage formats
(Card 4 and Card 7, respectively) - The initial IRI of SPS-2 sections after placement
ranged from 0.76 to 2.19 m/km with a mean of 1.30
m/km - Increased roughness, faulting and transverse
cracking are more prevalent in wet climates - Pavements located in areas of higher annual
freeze-thaw cycles experience more spalling
8SPS-2 Lessons LearnedPavement Design
- Widened slab sections show less faulting than
conventional width slabs - Sections with aggregate base show the highest
joint faulting level. Sections with LCB and PATB
have the lowest joint faulting - Thinner (203 mm) slabs show more transverse
cracks than thicker slabs. Sections with a
thinner slab and a widened slab show the highest
level of transverse cracking
9SPS-2 Lessons LearnedPavement Design (cont.)
- JPCP constructed on PATB were smoother than
sections constructed on LCB or untreated
aggregate base - Sections with PATB show the lowest total
longitudinal cracking levels, while the sections
with LCB show the highest longitudinal cracking - Sections with PATB show the lowest percentage of
slabs cracked transversely, while the sections
with an LCB show the highest transverse cracking
10SPS-2 Lessons LearnedPavement Design (cont.)
- In general, LCB provided the worst performance
and PATB over DGAB provided the best performance - Longitudinal cracking was influenced by base type
and slab thickness - Widened lanes contributed to lower transverse
joint faulting
11SPS-2 Lessons LearnedPavement Design (cont.)
- Thicker slabs were found to have more initial
roughness as compared to thinner slabs - The presence of drainage was the driving factor
of change in roughness with time. Sections with
drainage showed a slower increase in roughness
than those without drainage - 900 PSI sections typically show map cracking and
550 PSI sections typically show polished
aggregate - 14 lane 1 of thickness
12SPS-2 Lessons LearnedPavement Design (cont.)
Rigid Pavement Design
13SPS-2 Lessons LearnedMaterials Testing
- JPCP constructed on coarse-grained soil were
smoother (lower initial IRI) than those
constructed on fine-grained soils - PCC slabs placed on LCB displayed the largest
amounts of curling and slabs placed on ATB
displayed the smallest amounts of curling - Concrete performed the worst with a lean concrete
base (LCB) and the best with an asphalt treated
base (ATB)
14SPS-2 Lessons LearnedMaterials Testing (cont.)
- Six inches of LCB has approximately the same
stiffness as 8 inches of ATB, both of which are
less stiff than 8 inches of dense graded
aggregate base (DGAB) - Creating the Materials Reference Librarywhich
allows researchers to obtain and test materials
used in constructing specific LTPP sections
15SPS-2 Lessons LearnedMaterials Testing (cont.)
- Collecting periodic non-destructive testing
measurements to allow the backcalculation of
in-situ moduli - Developing standardized laboratory and field
testing protocols - Providing materials data for calibrating M-E PDG
damage functions and performing M-E PDG pavement
designs
16SPS-2 Lessons LearnedData Collection
- The IRI trend over time depends heavily on the
initial IRI, the traffic loadings, and the extent
of joint faulting - Loads below design table (2 million)
- Standardizing data collection and quality control
practices - Pavement distress
- Automated profile
- FWD
17SPS-2 Lessons LearnedData Collection
- Indiana Department of Transportation found that
an FWD that was only 1 mil out of calibration
resulted in additional construction and
maintenance costs of 17,000 per mile
18Future Benefits
- Looking forward, there are many potential
benefits LTPP can provide. A partial listing
includes - Increasing service lives for new and
rehabilitated pavements, - Comparison of new vs. existing material
performance
We see the LTPP database serving into the
indefinite future as a key component of the
agencys pavement research activities, and those
activities will benefit substantially from the
many LTPP data collection and analysis activities
in FY 2010 -FY 2015 that are mentioned in the
FHWA document. Victor Mendez, Chairman Twenty-thi
rd letter report of the Transportation Research
Board Long-Term Pavement Performance Committee
19Future Benefits (continued)
- Effects of specific design features
- SHRP 2 support
- Determining the impact of environment on
performance - Baseline data sets for agencies to evaluate
performance - Year-to-year checks against agency pavement
management system/pavement condition index data
LTPP is a major contributor toward assuring
that we will have good pavements into the 21st
Century. Charlie Churilla, An Investment in
the Future Roads Bridges, August 2001
20Future Benefits (continued)
- MEPDG local calibration and model refinement
- Top-down vs. bottom-up cracking
- Improved rutting prediction
- Improved curing procedures to reduce built-in
temperature gradients - Next design procedure (and state-specific design
procedures) - Optimizing treatment selection
- Constructing new sections to expand inference
set - Calibration of new field data equipment
- Refining concrete coefficient of thermal
expansion (CTE) test protocol - Understanding/properly addressing curl and warp
21Curl and Warp Study040215
22Curl and Warp Study040213
23- For more information
- www.fhwa.dot.gov/research/tfhrc/infrastructure/
pavement/ltpp
More products and information at http//ltpp-pro
ducts.com
Thank You !