1. Falling Weight Deflectometer (FWD) Reference Calibration ����An Overview Demonstration
3. Falling Weight Deflectometer (FWD) �Calibration Procedures A Product of the Long-Term Pavement Performance Program
4. What is a FWD? Comprised of a tow vehicle and/or trailer
Designed to impart a dynamic load to a pavement structure
Measures deflection of the pavement surface
Simulates a moving wheel load.
5. What is it Used For? Structural capacity/remaining life estimates
Load transfer efficiency between PCC pavement joints
Void detection in PCC pavements
Network level pavement management
Project level pavement investigations
Many research applications.
6. Why Calibration? FWD is a complex system
Standards needed to ensure consistency between FWD units
High cost of obtaining bad data
(economic and political).
7. FWD Calibration Components LTPP FWD Calibration Centers
LTPP FWD Calibration Equipment
Center Equipment Calibrations
Implementation and Training
Calibration Center Certification Program
Reference Calibration Procedure
FWDREFCL Software
Relative Calibration Procedure
FWDCAL Software.
8. FWD Calibration
9. FWD Calibration Purpose - Calibration of FWD unit to known, or reference, standards
Reference standards are NIST traceable where applicable
Procedure completed in one day (assuming no problems)
Reference Calibration should be performed at certified FWD calibration center for best results.
10. Product Development Background 1987 - Strategic Highway Research Program (SHRP) selects FWDs, need for calibration established
1988 – Original FWDs procured
1989 – Calibration procedures developed
1989 – FWD testing begins
1992 - FHWA assumes leadership of LTPP.
11. Calibration Centers Four LTPP sponsored – State owned
Minneapolis, MN - North Central Region
Reno, NV - Western Region
Harrisburg, PA - North Atlantic Region
College Station, TX - Southern Region
(All LTPP Certified 1999)
Non-LTPP
Kansas State University (Kansas DOT)
Purdue University (Illinois DOT)
Dynatest (FWD manufacturer)
12. Calibration Centers
Equipment In-place - Status Unknown
South Africa
Australia
Cornell University [original developer]
Potential Areas of Interest
Brazil
Saudi Arabia
South Korea
Australia
New Zealand
China.
13. Calibration Process Reference
Calibration of FWD unit to known, or reference, standards
Relative
Comparison of FWD deflection sensors to one another
Reference and relative calibration performed at the same time
Relative can be performed on its own.
14. Frequency of Calibration Reference
Once per year
After equipment (load cell, deflection sensor, computer components, etc.) have been repaired or replaced
Whenever data is suspect.
15. Frequency of Calibration Relative
Immediately after reference calibration
AND…………..
Once per month
After deflection sensor(s) has been repaired or replaced
After a period of equipment inactivity
Prior to a major project
Whenever data is suspect.
16. Reference Calibration Equipment General Equipment List
Building to house calibration center
Isolation (test) pad
Reference load cell
LVDT (deformation measurement device)
Aluminum I-beam
Micrometer calibration stand
Data acquisition/signal conditioners
Computer/printing capabilities
Calibration software.
17. Reference Calibration Equipment
18. Reference Calibration Equipment
19. Reference Calibration Equipment
20. Reference Calibration Building Building Requirements
Indoor space
Easy access for FWD and tow vehicle
Floor large enough for FWD and tow vehicle to be level and completely indoors
Constant temperature (50-100 F)
Constant humidity (40-90 %)
Adequate security to protect investment.
21. Reference Calibration Test Pad
22. Reference Calibration Process What to Expect
Output is a set of multipliers used to adjust “raw” sensor readings
Calibration center staff run reference calibration equipment and software
FWD operator runs the FWD and responsible for updating FWD calibration parameters
FWD operator must be able to competently run the FWD.
23. Reference Calibration Process What NOT to Expect
Perfect calibration results - calibration has an allowable level of error
Calibration center to provide spare parts
Calibration center to serve as a repair shop.
24. Reference Calibration Process Preparations for FWD
FWD in good operational condition
Maintenance up to-date
Proper FWD software
Proper programmed drop sequence
Adequate supply of spare parts
Relative calibration stand.
25. Reference Calibration Process
26. Reference Calibration Pre-Calibration Preparation
Perform buffer warm-up procedures
Position FWD on test pad
Allow FWD temperature to stabilize
Move reference computer as close as possible to FWD computer
Load FWDREFCL into reference system computer
Turn off FWD filters
Disengage “peak smoothing” option.
27. Reference Calibration -Load Cell FWD Load Cell Calibration
Procedure performed at least twice and results averaged
Set FWD mass and drop heights to produce loads within 10 percent of:
28. Reference Calibration -Load Cell FWD Load Cell Calibration
Position FWD load plate near center of test pad
Position reference load cell under FWD load plate
Complete reference system zero process.
29. Reference Calibration -Load Cell FWD Load Cell Calibration
Perform following drop sequence
3 seating drops @ height 1, pause
5 drops @ height 1, pause after each drop
5 drops @ height 2, pause after each drop
5 drops @ height 3, pause after each drop
5 drops @ height 4, pause after each drop
Note: 6 drops may be used to provide a “spare” for data analysis
Load plate should not be raised at any time
Record data from FWD load cell and reference system
Repeat.
30. Reference Calibration -Load Cell FWD Load Cell Calibration
If the two calibration factors agree within 0.0030, average the results
If not, perform third calibration
If SD of three results < 0.0030, average the three results
If SD > 0.0030, repeat entire procedure.
31. Validity of Test Results -Load Cell
32. Reference Calibration - Sensors FWD Deflection Sensor Calibration
Initialize data acquisition system
Clean reference LVDT
Ensure smooth operation of LVDT
Calibrate reference LVDT
Enter calibration results into computer
Secure LVDT in holder on aluminum beam.
33. Reference Calibration - Sensors FWD Deflection Sensor Calibration
Perform drop sequence as per load cell calibration procedure
3 seating drops @ height 1, pause
5 drops @ height 1, pause after each drop
5 drops @ height 2, pause after each drop
5 drops @ height 3, pause after each drop
5 drops @ height 4, pause after each drop
Note: 6 drops may be used to provide a “spare” for data analysis.
34. Reference Calibration - Sensors FWD Deflection Sensor Calibration
Valid test results
No movement in calibration beam (view time history plots)
No excessive noise messages for drop heights 2, 3 or 4
Standard deviations for five readings at any drop height that differ by more than a factor of three
Standard error of adjustment factor < 0.0020
Average peak deflection at highest drop height < 16 mils (0.016)
If any violated, repeat test.
35. Validity of Test Results - Sensors
36. Reference Calibration Data Analysis
Calculations performed automatically by FWDREFCL software
Perform least squares regression for all data for each measurement device
Repeat any tests that did not meet the acceptance criteria outlined previously.
37. Reference Calibration Post-calibration Procedures
Enter new calibration factors into FWD software
FWD load cell calibration is a “final” calibration factor
FWD deflection sensor are “interim” factors
Final factors to be determined during relative calibration.
38. Relative Calibration
39. Relative Calibration Procedure
Remove deflection sensors from FWD holders
Label sensors 1 to n
n = number of sensors
Sensor in load plate = 1, furthest sensor from the load plate = n
Label top-most sensor stand position “A”.
Label lower positions in increasing alphabetical order (e.g. A, B, C, D, E, F …).
40. Relative Calibration Position sensors in stand
A = sensor 1
B = sensor 2, etc.
Support sensor stand in vertical position close to load plate
Mark position of stand on floor
Tip 1: Glue washer on the floor
Tip 2: Chisel out divot.
41. Relative Calibration Select FWD drop height
Goal: deflections = 16 – 24 mils
Test pad can usually be used
Warm up FWD buffers/condition test point
Repeat series of 10 drops
Load and deflection nearly uniform
No increasing or decreasing trend in load or deflection.
42. Relative Calibration Lower FWD load plate
Do not raise plate or move FWD during calibration
Perform two seating drops
Perform five replicate drops
Rotate sensors
Repeat until all sensors have been in every position in stand.
43. Relative Calibration Data Analysis
Performed by FWDCAL3 software
Three-way analysis of variance
Determines source of error
sensor number
position in calibration stand
data set.
44. Relative Calibration Valid Test Results
Repeat of procedure yields calibration factors within 0.003 for each sensor
In this case, average results
If not perform third calibration
If third calibration performed
Standard deviation < 0.003, average results
Standard deviation > 0.003, repeat relative calibration procedure.
45. Relative Calibration
46. Relative Calibration Select FWD drop height
Goal: deflections = 16 – 24 mils
Test pad can usually be used
Warm up FWD buffers/condition test point
Repeat series of 10 drops
Load and deflection nearly uniform
No increasing or decreasing trend in load or deflection.
47. Relative Calibration Post-calibration Procedures
Enter new calibration factors into FWD software
FWD deflection sensor are “final” factors.
48. Relative Calibration Relative Calibration Performed on Monthly Basis
Find pavement to produce suitable deflections
Perform as per procedure
Adjustment to sensor calibrations only performed when adjustment ratios indicate need
When sensors changed, perform relative calibration process.
49. FWD Calibration Reports
FWD unit information (serial #, id)
Transducer calibration information
Load cell calibration information
Printouts from FWDREFCL
Printouts from FWDCAL3
Final calibration computation worksheet
Diskettes with cal. data kept in FWD
Backups kept at the office.
50. Who Should Use the Product? Organizations performing FWD testing
State DOT’s
Other Government entities
Consultants
Academia
Organizations contracting for FWD services
Should be a part of contract to have FWD reference calibrated within 1 year, relative calibrated prior to job.
51. When Do You Use the Product? General
Reference – once per year
Relative – After reference and once per month thereafter
After a period of inactivity
Other recommendations
When equipment is replaced
When equipment is suspect
Whenever a major malfunction occurs.
52. Benefits of Use Provides guidelines for calibration of testing equipment
Provides a benchmark performance standard for equipment
Minimizes equipment variability
Promotes greater confidence in FWD testing and resulting pavement design
Minimizes risk of errant pavement rehabilitation designs.
53. What’s Ahead Calibration software to be updated to Windows-NT format
Calibration software upgraded to accept PDDX format
Continue to promote FWD calibration procedures.
