ali-hvs evaluation of thin asphalt overlays€¦ · hvs evaluation of thin asphalt overlays on...
TRANSCRIPT
HVS Evaluation of thin AsphaltOverlays on CompositePavementsAyman Ali, Ph.D.Manager, Center for Research and Education in Advanced Transportation Engineering Systems (CREATEs) Rowan University.109 Gilbrith Pkwy,Mullica Hill, NJ 08062Tel.: (908) 283-0467E-Mail: [email protected]
NEAUPG Annual Fall Meeting – October 18-19, 2017
Acknowledgementq Dr. Yusuf Mehta (Rowan University)q Dr. Hashim Rizvi (Rowan University)q Mr. Andrae Francois (Rowan University)q Ms. Eileen Sheehy (NJDOT/NEAUPG)q Ms. Susan Gresavage (NJDOT)q Mr. Paul Hanczaryk (NJDOT)q Mr. Robert Blight (NJDOT)q Dr. Giri Venkiteela (NJDOT)q Ms. Kimbrali Davis (NJDOT)
2
In this presentation…q What is CREATEs?q Motivation for this studyq Goals & Objectivesq Research Approachq Preliminary Resultsq Other CREATEs Projectsq Questions
3
NEAUPG Annual Fall Meeting – October 18-19, 2017
Rowan CREATEs
Rowan CREATEs
Rowan University CREATEs
5
q Rowan University acquired HVS (MarkIV model) from the United States ArmyCorps of Engineers (USACE).
q Typically used to evaluate flexible(asphalt) and rigid (cement)pavements.
q Apply uni- and bi-directional loadingalong with advanced temperaturecontrol (heating and cooling systems).
CREATEs HVS
6
CREATEs APTF (Infrastructure)
7
CREATEs HVS
8
CREATEs HVS (Heating Unit)
9
CREATEs HVS (Cooling Unit)
10
CREATEs
11
NEAUPG Annual Fall Meeting – October 18-19, 2017
Why Asphalt Overlays?
q Around 50% of NJDOT’s roads arePCC pavements.
q These roads are generally in poorcondition.
q Thin overlays are typically utilized toextend the life of these pavements.
q However, these overlays have beenperforming poorly in the field.
Thin Asphalt Overlays (Need)
13
q Conduct accelerated full-scalepavement testing to predict theexpected life of four thin asphaltoverlay treatments used on PortlandCement Concrete (PCC) pavements.
Thin Asphalt Overlays (Goal)
14
NEAUPG Annual Fall Meeting – October 18-19, 2017
Research Approach
Research Approach
16
Conduct Laboratory TestingOverlay Tester, Asphalt Pavement Analyzer, & AASHTO T283
1
Construct six full-scale pavement sections at CREATEs (includes instrumentation)2
Apply accelerated loading on each section using a Heavy Vehicle Simulator (HVS)3
Monitor performance as loading progresses.4
Overlays Considered
17
A 9.5 mm. NMAS Superpave Mix (Control)
12.5 mm. NMAS Stone Matrix Asphalt (SMA)
High Performance Thin Overlay (HPTO)
Binder Rich Intermediate Course (BRIC)
B
C
D
q A total of six sections were constructed atCREATEs accelerated pavement testingfacility.
q Combinations of the four overlays withvarying thicknesses.
q The supporting PCC pavement structurewas similar for all sections.
q The sections were instrumented using:asphalt strain gauge, thermocouples,compression gauges, LVDTs, and pressurecells.
Sections Constructed
18
Sections Constructed
19
High Performance Thin Overlay (1 inches)Binder Rich Intermediate Course (1 inch)12.5 mm. NMAS SMA (2 inches)Binder Rich Intermediate Course (1 inch)9.5 mm. NMAS Superpave (2 inches)Binder Rich Intermediate Course (1 inch)High Performance Thin Overlay (2 inches)12.5 mm. NMAS SMA (3 inches)9.5 mm. NMAS Superpave (3 inches)
PCCLayer(8inches)
Subbase Layer(16inches)
CompactedNaturalSoil(12inches)
NaturalSoil
Section No. 6:q A combination of HPTO and
BRIC Mixes.
Section No. 5:q A combination of 12.5 mm.
SMA and BRIC Mixes.
Section No. 4:q A combination of 9.5 mm.
Superpave and Binder Rich Intermediate Course (BRIC) Mixes.
q BRIC is a Specialty NJDOT Overlay mix
Section No. 3:q High Performance Thin Overlayq A Specialty NJDOT Overlay mix
Section No. 2:q 12.5 mm. NMAS SMAq A Specialty NJDOT Overlay mix
Section No. 1:q 9.5 mm. NMAS Superpaveq Control Section
Sections Constructed
20
Longitudinal Asphalt Strain Gauge (Total: 2)
Pressure Cell (Total: 1)
LVDT (Total: 2)
Soil Compression Gauge (Total: 2)
HMA Temperature Sensor (Total: 3 T-type Thermocouples)
Type T thermocouples will be used for temperature measurements.
3”
11”
26”
31”
5 ft.5 ft.5 ft.5 ft.5 ft.5 ft.
Natural Soil
Compacted Natural Soil
I-3 (Layer -2)
PCC
HMA
I-3 (Layer -1)
5 ft.5 ft.5 ft.5 ft.5 ft.5 ft.
Construction/Sensor Installation
21
Construction/Sensor Installation
22
Construction/Sensor Installation
23
Construction/Sensor Installation
24
Construction/Sensor Installation
25
Construction/Sensor Installation
26
Construction/Sensor Installation
27
Construction/Sensor Installation
28
Construction/Sensor Installation
29
Construction/Sensor Installation
30
Construction/Sensor Installation
31
Construction/Sensor Installation
32
Construction/Sensor Installation
33
Construction/Sensor Installation
34
Construction/Sensor Installation
35
NEAUPG Annual Fall Meeting – October 18-19, 2017
Full-Scale Testing Protocols
q One section, out of the six, will be subjected toloading using the HVS until failure (i.e., failing onesection at a time or a total of 300K passes).
q Air Temp. around section is controlled usingCREATEs Cooling/Heating System (25oC).
q Therefore, HVS loading will be conducted in thefollowing sequence: Section 1 loaded until failure,followed by Section 2, followed by Section 3, andso on.
HVS Full-Scale Loading
37
9.5ME SMA HPTO 95/BRIC SMA/BRIC HPTO/BRIC
Section 1 Section 2 Section 3 Section 4 Section 5 Section 6
q Loading will commence by applying, a 25 kNwheel load in a uni-directional mode at aspeed of 5 mph for 40,000 passes.
q Load magnitude will then be increased from25 kN to 40 kN while all other testparameters remain the same for another40,000 passes.
q Finally, load magnitude will be increasedfrom 40 kN to 60 kN after 80,000 passes.
q Each section will be loaded 22 hours a day;two hours for maintaining the HVS.
HVS Full-Scale Loading
38
q The CREATEs cDAQ system was utilized tocollect data from all sensors after theapplication of the following load passes:
HVS Instrumentation Sampling
39
Data Sampling Frequency1, 5, 10, 20, 30, 40, 50, 60, 70, 80, 90, 100, 125, 150, 175,200, 250, 300, 350, 400, 450, 500, 600, 700, 800, 900,1000, 1200, 1400, 1600, 1800, 2000, 2500, 3000, 3500,4000, 4500, 5000, 6000, 7000, 8000, 9000, 10000, …
Incremented by 5,000 after 10k
Incremented by 10,000 after 40kIncremented by
20,000 after 100kIncremented by 40,000 after 200k
q A field test that is typicallyconducted evaluate thestructural integrity ofpavements.
q The HWD “drops” (freefall) aweight on a particular location.
q Geophones (seven) are usedto measure deflections atvarious locations: Forming aDeflection Basin.
HWD Testing
40
q Heavy Weight Deflectometer (HWD) testingwill be conducted before loading is appliedand at “failure”.
q Six locations will be tested on each section.
HWD Testing
41
5 ft.5 ft.5 ft.5 ft.5 ft.5 ft.
12 ft
.
NEAUPG Annual Fall Meeting – October 18-19, 2017
Preliminary Results
Test Section 1 (Joint Behavior)
43
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
Join
t
Whe
el p
ath
Dire
ctio
n of
lo
adin
g
2ft.
LVD
T 2
LVD
T 1
Test Section 1 (Joint Behavior)
44
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
Join
t
Whe
el p
ath
Dire
ctio
n of
lo
adin
g
2ft.
LVD
T 2
LVD
T 1
Test Section 1 (Joint Behavior)
45
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
Join
t
Whe
el p
ath
Dire
ctio
n of
lo
adin
g
2ft.
LVD
T 2
LVD
T 1
Test Section 1 (Joint Behavior)
46
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
Join
t
Whe
el p
ath
Dire
ctio
n of
lo
adin
g
2ft.
LVD
T 2
LVD
T 1
Test Section 1 (Slab Movement)
47
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
Join
t
Whe
el p
ath
Dire
ctio
n of
lo
adin
g
2ft.
LVD
T 2
LVD
T 1
Test Section 1 (Slab Movement)
48
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
Join
t
Whe
el p
ath
Dire
ctio
n of
lo
adin
g
2ft.
LVD
T 2
LVD
T 1
Test Section 1 (Slab Movement)
49
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
Join
t
Whe
el p
ath
Dire
ctio
n of
lo
adin
g
2ft.
LVD
T 2
LVD
T 1
Test Section 1 (Slab Movement)
50
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
Join
t
Whe
el p
ath
Dire
ctio
n of
lo
adin
g
2ft.
LVD
T 2
LVD
T 1
Test Section 1 (Slab Movement)
51
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
Join
t
Whe
el p
ath
Dire
ctio
n of
lo
adin
g
2ft.
LVD
T 2
LVD
T 1
Test Section 1 (Slab Movement)
52
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
5 ft.
Join
t
Whe
el p
ath
Dire
ctio
n of
lo
adin
g
2ft.
LVD
T 2
LVD
T 1
Test Section 2 (Strains)
53
Test Section 2 (Strains)
54
Test Section 2 (Strains)
55
Test Section 2 (Strains)
56
Test Section 2 (Strains)
57
Test Section 2 (Strains)
58
Test Section 2 (Strains)
59
Test Section 2 (Strains)
60
Test Section 2 (Strains)
61
Test Section 2 (Strains)
62
63
Heavy Weight Deflectometer Testing Results (Initial)
Conduct Accelerated Pavement Testing
0.00
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
9.00
10.00
8 18 28 38 48 58 68
Pave
men
t Def
lect
ion
(mil)
Distance from applied Load (in)
TS1-2 TS1-1 TS1-6
TS1-4 TS1-5 TS1-3
TS-
2T
S-6
TS-
4
TS-
1T
S-3
TS-
5
TS-3
and
TS-
4 lo
cate
d 1.
5 ft.
from
jo
int
q The joint between the two concrete slabs isprogressively opening with the increase innumber of loading passes applied on top ofsection.
q Joint opening in section 1 after 260,000 loadingpasses was around 0.022 inches (about 0.0175in. for section 2)
q A similar trend has been observed for the tensilestrains at the bottom of the HMA overlay layer.
q Section 2 is currently experiencing approximately400 µe (tensile) at the bottom of the HMA overlay.
Summary of Observations
64
NEAUPG Annual Fall Meeting – October 18-19, 2017
Other CREATEs Projects
q Project Sponsor: United States Departmentof Defense-United States Army Corps ofEngineers (USDoD-USACE).
q Goals:q Comprehensive laboratory evaluation of the
potential benefits for using Geogrids as astabilizing element in airfield pavements.
q Numerical modeling (FEM) of geogrid-reinforcedairfield pavement.
q Status: In-Progress
Geogrid Reinforced Airfield Pavements
66
q Project Sponsor: United States Departmentof Defense-United States Army Corps ofEngineers (USDoD-USACE).
q Goals:q Comprehensive laboratory and full-scale testing
of Cold In-Place Recycling (CIPR) technologiesimplemented by various State DOTs in thenortheast.
q Status: In-Progress
Evaluation of Cold In-Place Recycling
67
q Project Sponsor: The New JerseyDepartment of Transportation (NJDOT)
q Goals:q Full-scale evaluation of precast and Cast In-
Place (CIP) concrete pavement rapid repairtechnologies.
q Recommending a list of systems for inclusion inNJDOT’s Approved Materials List.
q Status: Project Awarded/Under Contract
Evaluation Rapid Precast and CIP Systems
68
E-mail: [email protected]/creates
Thank you from the CREATEs team