Scanning pulse phase thermography for surface defect detection in manganese steel turnout frogs

Research output: Contribution to conferencePaperpeer-review

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Scanning pulse phase thermography for surface defect detection in manganese steel turnout frogs. / Tuschl, Christoph; Oswald-Tranta, Beata; Eck, Sven et al.
2023. Paper presented at 13th European Conference of Non-Destructive Testing, Lissabon, Portugal.

Research output: Contribution to conferencePaperpeer-review

Harvard

Tuschl, C, Oswald-Tranta, B, Eck, S & Dornig, P 2023, 'Scanning pulse phase thermography for surface defect detection in manganese steel turnout frogs', Paper presented at 13th European Conference of Non-Destructive Testing, Lissabon, Portugal, 3/07/23 - 7/07/23. https://doi.org/10.58286/28220

APA

Tuschl, C., Oswald-Tranta, B., Eck, S., & Dornig, P. (2023). Scanning pulse phase thermography for surface defect detection in manganese steel turnout frogs. Paper presented at 13th European Conference of Non-Destructive Testing, Lissabon, Portugal. https://doi.org/10.58286/28220

Vancouver

Tuschl C, Oswald-Tranta B, Eck S, Dornig P. Scanning pulse phase thermography for surface defect detection in manganese steel turnout frogs. 2023. Paper presented at 13th European Conference of Non-Destructive Testing, Lissabon, Portugal. doi: https://doi.org/10.58286/28220

Author

Tuschl, Christoph ; Oswald-Tranta, Beata ; Eck, Sven et al. / Scanning pulse phase thermography for surface defect detection in manganese steel turnout frogs. Paper presented at 13th European Conference of Non-Destructive Testing, Lissabon, Portugal.

Bibtex - Download

@conference{1a5a2dbcd33c495e90b90c0da69387e0,
title = "Scanning pulse phase thermography for surface defect detection in manganese steel turnout frogs",
abstract = "Austenitic manganese steel is a commonly used material for railway turnout frogs dueto its beneficial mechanical properties. In service, surface defects caused by rollingcontact fatigue (RCF) can occur and need to be detected and assessed duringmaintenance intervals. In this work inductive scanning pulse phase thermography isused to localize these surface defects. During scanning the surface of the frog is heated (∆T<5K) with an air-cooled inductor. The surface temperature is recorded with an infrared camera. A registration target is also recorded in each frame of the imagesequence. This method recognizes the movement in the sequence itself without external sensors. Furthermore, by using a registration target it is also possible to scan manually, as motion speed is calculated frame by frame. For the evaluation, the recorded sequence is transformed such that the turnout frog and the registration target seem to be stationary. In this new sequence the temporal changes in temperature of each pixel of the surface are evaluated by Fourier transform to a phase image. The evaluation via phase image is known to be robust to negative effects such as inhomogeneous heating and emissivity. This work aims at developing a mobile prototype, which allows service personnel to use scanning pulse phase thermography to localize and characterize surface defects on manganese steel turnout frogs during maintenance.",
author = "Christoph Tuschl and Beata Oswald-Tranta and Sven Eck and Peter Dornig",
year = "2023",
month = aug,
doi = "https://doi.org/10.58286/28220",
language = "Deutsch",
note = "13th European Conference of Non-Destructive Testing ; Conference date: 03-07-2023 Through 07-07-2023",
url = "https://ecndt2023.org/",

}

RIS (suitable for import to EndNote) - Download

TY - CONF

T1 - Scanning pulse phase thermography for surface defect detection in manganese steel turnout frogs

AU - Tuschl, Christoph

AU - Oswald-Tranta, Beata

AU - Eck, Sven

AU - Dornig, Peter

PY - 2023/8

Y1 - 2023/8

N2 - Austenitic manganese steel is a commonly used material for railway turnout frogs dueto its beneficial mechanical properties. In service, surface defects caused by rollingcontact fatigue (RCF) can occur and need to be detected and assessed duringmaintenance intervals. In this work inductive scanning pulse phase thermography isused to localize these surface defects. During scanning the surface of the frog is heated (∆T<5K) with an air-cooled inductor. The surface temperature is recorded with an infrared camera. A registration target is also recorded in each frame of the imagesequence. This method recognizes the movement in the sequence itself without external sensors. Furthermore, by using a registration target it is also possible to scan manually, as motion speed is calculated frame by frame. For the evaluation, the recorded sequence is transformed such that the turnout frog and the registration target seem to be stationary. In this new sequence the temporal changes in temperature of each pixel of the surface are evaluated by Fourier transform to a phase image. The evaluation via phase image is known to be robust to negative effects such as inhomogeneous heating and emissivity. This work aims at developing a mobile prototype, which allows service personnel to use scanning pulse phase thermography to localize and characterize surface defects on manganese steel turnout frogs during maintenance.

AB - Austenitic manganese steel is a commonly used material for railway turnout frogs dueto its beneficial mechanical properties. In service, surface defects caused by rollingcontact fatigue (RCF) can occur and need to be detected and assessed duringmaintenance intervals. In this work inductive scanning pulse phase thermography isused to localize these surface defects. During scanning the surface of the frog is heated (∆T<5K) with an air-cooled inductor. The surface temperature is recorded with an infrared camera. A registration target is also recorded in each frame of the imagesequence. This method recognizes the movement in the sequence itself without external sensors. Furthermore, by using a registration target it is also possible to scan manually, as motion speed is calculated frame by frame. For the evaluation, the recorded sequence is transformed such that the turnout frog and the registration target seem to be stationary. In this new sequence the temporal changes in temperature of each pixel of the surface are evaluated by Fourier transform to a phase image. The evaluation via phase image is known to be robust to negative effects such as inhomogeneous heating and emissivity. This work aims at developing a mobile prototype, which allows service personnel to use scanning pulse phase thermography to localize and characterize surface defects on manganese steel turnout frogs during maintenance.

U2 - https://doi.org/10.58286/28220

DO - https://doi.org/10.58286/28220

M3 - Paper

T2 - 13th European Conference of Non-Destructive Testing

Y2 - 3 July 2023 through 7 July 2023

ER -