Track Transitions and the Effects of Track Stiffness

Track Transitions and the Effects of Track Stiffness D. Plotkin, D.D. Davis, S. Gurule and S.M. Chrismer AREMA 2006 IJ presentation - 1 Transportation Technology Center, Inc., a subsidiary of the Association of American Railroads, 2006

Track Transitions Problem Description Bump at the end of the Bridge, Rough Road Crossing,, High Impact Diamond Crossing Occurs when track structure changes abruptly Can generate high dynamic loads Can result in speed restrictions May require frequent maintenance Note: problem is far from universal many locations perform well AREMA 2006 IJ presentation - 2

Track Transitions Problem Description Conventional Wisdom: Track stiffness change generates dynamic forces that cause rapid degradation of approach track Project Task: Determine the effects of track stiffness on approach performance AREMA 2006 IJ presentation - 3

Track Transition Problems AREMA 2006 IJ presentation - 4

Reduced Impact Track; Bridge Approach Problems Abrupt structure changes Different foundation types AREMA 2006 IJ presentation - 5

Track Transitions - Tribal Knowledge Commonly Known Large Stiffness change Lower Damping Low spot at end of bridge Stiffness change generates high loads How we Know Train Observation Train Observation Geometry car, Observation Observation What we Found Yes, even on ballasted deck concrete Yes, measured impact tests Sometimes, but can be differential Not by itself; ~10% from stiffness alone Data Marysville sub FAST, Marysville Surveys of approaches Load measuring wheelsets, modeling AREMA 2006 IJ presentation - 6

FRA Track Transition Study Large Stiffness Change Measured using TLV Track Modulus: Approach: 3-6,0003 Bridge: 8 12,000 Dynamic Track Modulus (lb/in./in.) 14000 12000 10000 8000 6000 4000 BRIDGE 2000 0 1200 1300 1400 1500 1600 1700 Distance (ft) AREMA 2006 IJ presentation - 7

FRA Track Transition Study Does Stiffness Change Generate High Loads? High loads always associated with surface defect Surface defect often associated with stiffness change Also, it is difficult to surface to a fixed elevation (e.g. open deck bridge) AREMA 2006 IJ presentation - 8

Track Transitions - Theoretical Modeling Parametric study of: Track Stiffness Track Damping Track Surface Used Western Coal Route as Base Case Recent construction Traffic known Surfacing records Measured track profiles Measured track stiffness, damping AREMA 2006 IJ presentation - 9

NUCARS Schematic AREMA 2006 IJ presentation - 10

NUCARS Modeling Track Stiffness change No running surface defect 60 mph 100000 90000 80000 Soft Approach Track (2000 lbs/in/in) Bridge Structure (30000 lbs/in/in) 70000 Travel 60000 LOAD (LBS) 50000 40000 30000 20000 10000 Location of Abutement 0 40 45 50 55 60 65 70 75 80 85 90 DISTANCE ALONG TRACK (FT) AREMA 2006 IJ presentation - 11

NUCARS Modeling No Stiffness Change 0.5 vertical perturbations 60 mph 100000 90000 Location of 0.5" Perturbation Bridge Abutement 80000 Maximum Vertical Load (lbs) 70000 60000 50000 40000 30000 20000 10000 0 40 45 50 55 60 65 70 75 80 85 90 Distance (ft) AREMA 2006 IJ presentation - 12

Effects of stiffness change on smooth track Effects of stiffness change on smooth track Bridge Approach Bridge Approach AREMA 2006 IJ presentation - 13

Effect of Bridge Stiffness on Tie Loads 20000 Direction of Travel 18000 Bridge Approach Maximum Vertical Force beneath each tie (lbs) 16000 14000 12000 10000 8000 6000 4000 Smooth Track Input All cases @ 50 mph Vary Track Modulus on Bridge 5,000 10,000 15,000 20,000 Endwall 2000 0 180 185 190 195 200 205 210 Tie Number (Spaced @ 20") AREMA 2006 IJ presentation - 14

Track Transitions Design Factors Factor Stiffness Surface Defect Stiffness & Surface Defect Effect ~ 6% 1.5 to 3 x static load 1.5 to 3 x static load Comments By itself, a small effect The reason why we have track standards Stiffness effect is negligible AREMA 2006 IJ presentation - 15

Track Transitions - Theoretical Modeling Summary: Small dynamic load at stiffness change ~10% for freight operations Short distance affected ~5 feet Unlikely to drive accelerated settlement on approaches AREMA 2006 IJ presentation - 16

Track Transitions - Measured Forces Wheel/Rail Forces Measured at Bridge/Approaches: Facility for Accelerated Service Testing (FAST) 315K coal hoppers and gons at 40 mph Measured: Dynamic wheel loads Track surface (loaded) Track stiffness Amtrak Northeast Corridor 160K passenger cars at 80 125 mph Measured: Dynamic wheel loads AREMA 2006 IJ presentation - 17

Track Transitions - Measured Forces Minimum and Maximum Vertical Wheel Load and Space Curve Surface West Approach SOA Bridge, CCW, 40 MPH 80 0.40 70 0.30 Vertical Wheel Load (Kips) 60 50 40 30 20 0.20 0.10 0.00-0.10-0.20 Surface (in) 10 West End SOA Bridge -0.30 0 0 10 20 30 40 50 60 70 Distance (ft) -0.40 AREMA 2006 IJ presentation - 18 MIN V MAX V ALD Left Surface Right Surface

Track Transitions - Measured Forces FAST Track Track Stiffness Soft side: 2,500-6,000 Stiff side: 4,000-9,000 Track Surface No class 4 exceptions Dynamic Loads ~10% > open track VERTICAL WHEEL FORCES (KIPS 70 60 50 40 30 20 10 0 MEAN 95TH 99.5TH MAX OPEN TRACK TRANSITIONS AREMA 2006 IJ presentation - 19

Track Transitions - Measured Forces Amtrak Bridges Conventional track on bridges and approaches Stiffness not measured Track Surface No class 7 exceptions Train Speeds 80 125 mph Dynamic Loads Indistinguishable from open track AREMA 2006 IJ presentation - 20

Track Transitions - Measured Forces MP 56.51 AP Perryville, MD AREMA 2006 IJ presentation - 21

Track Transitions - Measured Forces MP 40.71 AP Newark, DE AREMA 2006 IJ presentation - 22

Track Transitions - Measured Forces MP 13.36 AN Elizabeth, NJ AREMA 2006 IJ presentation - 23

Track Transitions - Measured Settlement Revenue Service Measurements of Bridge and Approach Track Surface: Time series of top of rail surveys conducted on coal line bridges Before and after maintenance Differential settlement determined AREMA 2006 IJ presentation - 24

FRA Track Transition Study Low Spot at end of Bridge Case 1 truly a low spot at approach Case 2 approach no lower than rest of track AREMA 2006 IJ presentation - 25

Track Transitions - Measured Settlement Track profiles were measured at Revenue Service bridge approaches: Profiles showed low spot to be wide and flat Track around bridges has settled (i.e. Case 2) 102 TOP OF RAIL ELEVATION (FEET 101.5 101 100.5 100 99.5 99 0 100 200 300 400 500 DISTANCE (FEET) GRADE CORRECTED BRIDGE ENDS RAW ELEVATIONS AREMA 2006 IJ presentation - 26

Track Transitions - Measured Settlement Effect of Increasing Dynamic Load on Approaches: Measured dynamic loading not likely to create low spot 35% 30% Change in Diff Settlement 25% 20% 15% 10% 5% 0% -5% AREMA 2006 IJ presentation - 27-10% -20% -10% 0% 10% 20% 30% 40% 50% Change in Wheel Load

FRA Track Transition Study Track Settlement Study Conclusions Differential track settlement at bridge approaches due to change in track structure Approaches often no worse than track away from bridge Effect of track stiffness change Small dynamic load increase Somewhat higher stresses on tie/ballast interface at abutment only Approaches can be worse than track away from bridge in some cases: Drainage Surfacing to fixed elevation AREMA 2006 IJ presentation - 28

Pencil and Paper Analysis Track stiffness difference is said to cause dynamic loads by creating a bump in the track at the point where stiffness changes as the deflection under load will change at this point. How big a bump is this? AREMA 2006 IJ presentation - 29

Track Stiffness Difference 2,000-10,000 10,000 2,000 0.15 inches AREMA 2006 IJ presentation - 30

Track Stiffness Difference 2,000-10,000 10,000 2,000 0.15 inches? AREMA 2006 IJ presentation - 31

Track Stiffness Difference 2,000-10,000 10,000 2,000 0.15 inches 5 Feet AREMA 2006 IJ presentation - 32

Track Stiffness Difference 2,000-10,000 A track stiffness difference of 2,000 to 10,000 produces an effect roughly equivalent to a ramp of 1 in 400. The surface runoff criteria for one large railroad shows a runoff of 1 in 331 as sufficient to create a "smooth ride" at 60 mph. Design of flange bearing frog ramps: 1:240 ramps used for maximum vertical loads of 1.5 x static wheel load at 60 mph AREMA 2006 IJ presentation - 33

Train Ride Test Riding a train soon after the track has been surfaced. What vertical effect is felt crossing over bridges? You can hear it, but can you feel it? Would this suggest that there are dynamic forces large enough to cause accelerated track settlement on bridge approaches? AREMA 2006 IJ presentation - 34

FRA Track Transition Study Conclusions Dynamic loads on bridge approaches due to stiffness changes are small Stiffness changes do not cause higher settlement on bridge approaches AREMA 2006 IJ presentation - 35

Acknowledgements Union Pacific Bill GeMeiner,, Ed Kohake BNSF Steve Millsap, Elwood Starner TTCI Charity Duran, Rachel Anaya, Ding Li, Duane Otter Ensco Brian Whitten, Brent Selby AREMA 2006 IJ presentation - 36