Authors: Alexander Buhr, Klaus Ehrenfried

Abstract:

Trackside induced airflow velocities, also known as slipstream velocities, are an important criterion for the design of high-speed trains. The maximum permitted values are given by the Technical Specifications for Interoperability (TSI) and have to be checked in the approval process. For train manufactures it is of great interest to know in advance, how new train geometries would perform in TSI tests. The Reynolds number in moving model experiments is lower compared to full-scale. Especially the limited model length leads to a thinner boundary layer at the rear end. The hypothesis is that the boundary layer rolls up to characteristic flow structures in the train wake, in which the maximum flow velocities can be observed. The idea is to enlarge the boundary layer using roughness elements at the train model head so that the ratio between the boundary layer thickness and the car width at the rear end is comparable to a full-scale train. This may lead to similar flow structures in the wake and better prediction accuracy for TSI tests. In this case, the design of the roughness elements is limited by the moving model rig. Small rectangular roughness shapes are used to get a sufficient effect on the boundary layer, while the elements are robust enough to withstand the high accelerating and decelerating forces during the test runs. For this investigation, High-Speed Particle Image Velocimetry (HS-PIV) measurements on an ICE3 train model have been realized in the moving model rig of the DLR in Göttingen, the so called tunnel simulation facility Göttingen (TSG). The flow velocities within the boundary layer are analysed in a plain parallel to the ground. The height of the plane corresponds to a test position in the EN standard (TSI). Three different shapes of roughness elements are tested. The boundary layer thickness and displacement thickness as well as the momentum thickness and the form factor are calculated along the train model. Conditional sampling is used to analyse the size and dynamics of the flow structures at the time of maximum velocity in the train wake behind the train. As expected, larger roughness elements increase the boundary layer thickness and lead to larger flow velocities in the boundary layer and in the wake flow structures. The boundary layer thickness, displacement thickness and momentum thickness are increased by using larger roughness especially when applied in the height close to the measuring plane. The roughness elements also cause high fluctuations in the form factors of the boundary layer. Behind the roughness elements, the form factors rapidly are approaching toward constant values. This indicates that the boundary layer, while growing slowly along the second half of the train model, has reached a state of equilibrium.

Keywords: Boundary layer, high-speed PIV, ICE3, moving train model, roughness elements.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1129573

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1483

References:

[1] 2008/232/EG, Entscheidung der Kommission vom 21. Februar 2008 über die technische Spezifikation für die Interoperabilität des Teilsystems ’Fahrzeuge’ des transeuropäischen Hochgeschwindigkeitsbahnsystems, Amtsblatt der Europäischen Union, 2008.
[2] C.J. Baker, A. Quinn, M. Sima, L. Hoefener, R. Licciardello, Full-scale measurement and analysis of train slipstreams and wakes. Part 1: Ensemble averages, Proceedings of the Institution of Mechanical Engineers, Part F: Journal of Rail and Rapid Transit, Vol 228, Issue 5, pp. 451 – 467, 2014 doi:10.1177/0954409713485944.
[3] T.W. Muld, Slipstream and Flow Structures in the Near Wake of High-Speed Trains, Royal Institute of Technology Stockholm, 2012.
[4] T.W. Muld, G. Efraimsson, D.S. Henningson, Wake characteristics of high-speed trains with different lengths, Proceedings of the Institution of Mechanical Engineers, Part F: Journal of Rail and Rapid Transit, Vol 228, Issue 4, pp. 333–342, 2013.
[5] A. Herbst, T. Muld, G. Efraimsson, Front Shape and Slipstream for Wide Body Trains at Higher Speeds, KTH Railway Group, Publication 1402, 2012.
[6] A. Buhr, Experimentelle Untersuchung der instationären Strömungsstrukturen im Nachlauf eines in Wandnähe bewegten stumpfen Körpers, master thesis, German Aerospace Center (DLR), Göttingen, Germany, 2015.
[7] J. Nikuradse, Strömungsgesetze in rauhen Rohren, VDI-Verlag, Berlin, Germany, 1933.
[8] H. Schlichting, Grenzschicht-Theorie, 5th edition, Verlag G. Braun, 1965.
[9] M. Raffel, C. Willert, S. Wereley, J. Kompenhans, Particle Image Velocimetry, second edition, Springer, 2007.
[10] PivTec, PIVview2C/3C Version 3.0 - User Manual, PivTec GmbH, Stauffenbergring 21, Göttingen, Germany, 2010.
[11] A. Buhr, A. Henning, K. Ehrenfried, An Experimental Study of Unsteady Flow Structures in the Wake of a Train Model, in J. Pombo, (Editor), Proceedings of the Third International Conference on Railway Technology: Research, Development and Maintenance, Civil-Comp Press, Stirlingshire, UK, Paper 41, 2016. doi:10.4203/ccp.110.41.
[12] D.W. Weyburne, New thickness and shape parameters for the boundary layer velocity profile, in Experimental Thermal and Fluid Science, Vol 54, pp. 22 – 28, 2014 issn:0894-1777.