Condition monitoring of a fixed railway...

www.voestalpine.com/vae

voestalpine VAE GmbH

Condition monitoring of a

fixed railway crossing

Uwe Oßberger1, Werner Kollment2, Sven Eck3

ESIS TC24 workshop, 24th – 25th October 2016 in Leoben

1voestalpine VAE GmbH;

2 Montanuniversität Leoben, Institut für Automation

3 Materials Center Leoben Forschung GmbH

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 2

Table of contents

Introduction

Field tests

Geometry measurements and evaluation

Vertical wheel position trajectories

Geometry change plot

Geometry assessment

Strain measurements and evaluation

Noise analysis (Kolmogorov-Smirnov test)

Load pattern analysis

Conclusion

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 3

Table of contents

Introduction

Field tests

Geometry measurements and evaluation

Vertical wheel position trajectories

Geometry change plot

Geometry assessment

Strain measurements and evaluation

Noise analysis (Kolmogorov-Smirnov test)

Load pattern analysis

Conclusion

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 4

stock rail

stock rail

check rail

check rail

wing rails

crossing nose or

“frog of a turnout”

test site Niklasdorf

track superstructure

concrete sleepers

switch rails

ballast

Introduction

Discontinuity

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 5

Introduction

Transition of a wheel over a turnout crossing

Slip, due to different rolling radii

High vertical forces as a result of vertical wheel movement

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 6

Material response to loading

Plastic deformation Wear Rolling contact fatigue

All three material responses demand for maintenance or replacement of the

crossing after some time.

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 7

Field trials

geometry measurements

Measured cross-sections

Bf. Marein/ St. Lorenzen (vmax = 150 km/h)

2x Bainite crossings

3x Mn13-casted-crossings (EDH)

Bf. Marein/ St. Lorenzen (vmax = 150 km/h)

2x Bainite crossings

3x Mn13-casted-crossings (EDH)

Bf. Niklasdorf (vmax = 140 km/h)

2x Cold work tool steel crossings

2x Hot work tool steel crossings

4x Mn13-casted-crossings (EDH)

Bf. Niklasdorf (vmax = 140 km/h)

2x Cold work tool steel crossings

2x Hot work tool steel crossings

4x Mn13-casted-crossings (EDH)

Bf. Zeltweg (vmax = 90 km/h)

4x Cr-Bainite crossings

2x Mn13-casted-crossings (EDH)

Bf. Zeltweg (vmax = 90 km/h)

4x Cr-Bainite crossings

2x Mn13-casted-crossings (EDH)

Zeltweg

∑ 20 turnouts

60E1–500m–1:12

5 different materials Graz

Villach

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 8

Table of contents

Introduction

Field tests

Geometry measurements and evaluation

Vertical wheel position trajectories

Geometry change plot

Geometry assessment

Strain measurements and evaluation

Noise analysis (Kolmogorov-Smirnov test)

Load pattern analysis

Conclusion

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 9

Geometry measurements

2d cross-section evaluation

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 10

Vertical wheel position trajectories (ORE-S1002 wheel, y=0)

Low changes of transition geometry

Transition point moves slightly to end of crossing

Geometry measurements

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Field trials

geometry measurements

Detail

positive geometry change

negative geometry change

Geometry change calculation of geometry measurements

Reference measurement

Comparative measurement

Wear & Plastic deformation Wear

+ -

Negative surface change is always related to macroscopic plastic deformation

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 12

Field trials,

Results for cold work tool steel

Cold work tool steel:

Niklasdorf

43,6 MGT

Pre: 0.0 MGT

Moderate RCF performance, low wear rate, no deformation.

Material is very sensitive concerning manufactured geometry, because it

changes its geometry very slow.

Surface change

through wear at

very low values

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 13

Geometry assessment:

Methodology Geometry measurements

crossing:

Wheel profiles

Contact calculation

Simple MBS-model Simple assessment model

co

nta

ct p

ressu

re

load cycles

𝑘 = 3,3

S/N curve:

Hertzian pressure

𝐷 = 𝑑𝑖

Material loading

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 14

Geometry assessment:

Evolution of loading for cold work tool steel

Geometry adaption process leads to lower material loading while contact forces

stay almost constant.

All different crossing nose materials show this self-optimization process

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 15

Table of contents

Introduction

Field tests

Geometry measurements and evaluation

Vertical wheel position trajectories

Geometry change plot

Geometry assessment

Strain measurements and evaluation

Noise analysis (Kolmogorov-Smirnov test)

Load pattern analysis

Conclusion

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 16

Measurement equipment

Strain gauge application before turnout installation

4 channels, measure bending strain of crossing nose structure

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Strain measurements

The 4 strain channels show a typical pattern

that is commonly known as “Winkler foundation”

Different trains (with diff. axle distances & axle

loads) show a different characteristic pattern.

Figure: 4 DMS channels, two axles

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Strain measurements

Trains with invariant configurations, like Bombardier „Talent“ are evaluated:

Resource: wikipedia.org

Noise evaluation:

Kolmogorov-Smirnov-

Test to detect good

wheels / bad wheels

Pattern evaluation:

Dynamic-time-warping

and resampling to

visualize changes in the

load pattern.

Offset evaluation:

Residual strain

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 19

Noise evaluation:

Kolmogorov-Smirnov-Test

Calculation of probability distribution and cumulative probability distribution:

The test is based on the fact that random noise usually follows Gaussian

distribution => Spectral analysis follows

Good

wheel

Bad

wheel

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 20

Pattern evaluation

For pattern comparison, as train speeds are not exactly equal every time,

dynamic-time-warping is used:

After dynamic-time-warping the signals are resampled to guarantee a uniform

sampling interval and equal number of samples.

𝐸 = 𝑟 𝑡 − 𝑠 𝑔 𝑡 ∙ 𝑑𝑡 Minimize: 𝑔 𝑡 = 𝑐2 ∙ 𝑡2 + 𝑐1 ∙ 𝑡 + 𝑐0

Reference

signal

Measurement

signal

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 21

Pattern evaluation

Strain pattern normalisation and subtraction (to visualize the change):

A characteristic change of load patterns was observed which can be, e.g. a result

of ballast or impact change.

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 22

Table of contents

Introduction

Field tests

Geometry measurements and evaluation

Vertical wheel position trajectories

Geometry change plot

Geometry assessment

Strain measurements and evaluation

Noise analysis (Kolmogorov-Smirnov test)

Load pattern analysis

Conclusion

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 23

Conclusion

Numerical methods to evaluate geometry measurements and strain

measurements were developed and presented.

Geometry changes due to deformation, wear or breakouts change the material

loading of a fixed crossing.

Strain measurements can give an information how the loading changes over time

and we can detect “bad” wheels.

Our target: In the future we want to create forecast models based on the gained

data to predict damage and initiate maintenance actions dynamically.

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 24

Uwe Oßberger

T. +43/50304/28 - 585

uwe.ossberger@voestalpine.com

Thank you!

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ESIS TC24: Condition monitoring of a fixed railway crossing 07.11.2016 25

Preceding publications

U. Oßberger, M. Pletz, S. Eck, W. Daves, H. Oßberger:

Validation of a finite element crossing model using measurements at an instrumented turnout,

Proceeding of the 23rd International Symposium on Dynamics of Vehicels on Roads and Tracks, 19-23.

August 2013, Qingdao, China, paper No. 32.2

S. Eck, H. Oßberger, U. Oßberger, S. Marsoner, R. Ebner:

Comparison of the fatigue and impact fracture behaviour of 5 different steel grades used in the frog

of a turnout,

Int. J. Rail and Rapid Transit 228 (6) 2014, pp 603-610

U. Oßberger, S. Eck and E. Stocker:

Performance of different materials in a frog of a turnout,

Proceedings of the 11th International Heavy Haul Conference, 21-24 June, 2015, Perth, Australia, 329-336.

W. Kollment, P. O’Leary, M.Harker, U. Oßberger and S. Eck:

Towards Condition Monitoring of Railway Points: Instrumentation, Measurement and Signal

Processing,

Proceedings of IEEE International Instrumentation and Measurement Technology Conference (I2MTC), 23-

26 May 2016, Taipei, Taiwan, pp. 612-617

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Acknowledgement

The presented work was performed as part of the COMET MPPE projects

A6.16 “High performance railway crossings – Materials, manufacturing and in service performance” and

A5.21 “Tool health monitoring”.

Financial support by the Austrian Federal Government (in particular from Bundesministerium für Verkehr,

Innovation und Technologie and Bundesministerium für Wissenschaft, Forschung und Wirtschaft)

represented by Österreichische Forschungsförderungsgesellschaft mbH and the Styrian and the Tyrolean

Provincial Government, represented by Steirische Wirtschaftsförderungsgesellschaft mbH and

Standortagentur Tirol, within the framework of the COMET Funding Programme is gratefully

acknowledged.