Sage Journals: Discover world-class research

Abstract

This work presents aerodynamic results of crosswind stability obtained numerically and experimentally for the leading control unit (class 808) of Deutsche Bahn AG's high-speed train Inter-CityExpress 2. The train model is on top of a 6m high embankment in accordance with the proposed European code for interoperable trains, the so-called technical specifications for interoperability. The purpose of the study is to convey the predictive accuracy that typical steady-state computational fluid dynamics-Reynolds average Navier-Stokes methods (industry standard) return and to contribute to the understanding of the aerodynamics for the current application.

Attention is drawn to the aerodynamics around the train and embankment when subjected to a steady block profile crosswind of 30° yaw angle on the basis of the onset velocity far upstream the embankment. The Re (Reynolds number) of the embankment cases is 4.6 × 10⁶. Calculated results are obtained with the commercial code STAR-CD, with exclusively hexahedral meshes with a total cell count of 13.5 × 10⁶. Results are obtained when the train stands on the windward and leeward tracks on top of the embankment. These results are first compared with a flat ground case from a previous study.

Then experimental data are obtained in a high-pressure wind tunnel with a model scale of 1:100. Re effects are compensated by raising the ambient pressure by a factor of 60, which increases the air density and thus the Re by a similar factor. Calculated results are in fair agreement with the experiments, where both the calculations and the experiments predict the leeward case to be the more critical one.

In addition, the related consequences on the mechanical behaviour, i.e. the stability of the car, are briefly addressed by means of a quasi-static mechanical analysis. The results of the present study indicate that the 6m high embankment concerning the current train reduces the permissible crosswind speed with approximately 20 per cent.

Keywords

train aerodynamics crosswind stability train overturning computational fluid dynamics wind tunnel testing

Get full access to this article

View all access options for this article.

References

Shulte-Werning

Grégoire

Matschke

TRANSAERO - a European initiative on transient aerodynamics for railway system optimisation, 2002 (Springer-Verlag, Berlin, Heidelberg, and New York). ISBN 3–540-43316–3.

Diedrichs

On computational fluid dynamics modeling of crosswind effects for high-speed rolling stock

Proc. Instn Mech. Engrs, Part F: J. Rail and Rapid Transit, 2003, 217 (F3), 203–226.

Eisenlauer

Matschke

Meri

Heine

CFD calculation of aerodynamic forces and side wind behavior of railway vehicles. Parametric investigations and comparison with wind tunnel data. MIRA Conference, 2003, pp. 1–12.

Gautier

P.-E.

Tielkes

Sourget

Allain

Grab

Heine

Strong wind risks in railways: the DEUFRAKO crosswind program. Proceeding of WCRR'2003, 2003, pp. 463–475.

Mancini

Cheli

Roberti

Diana

Cheli

Tomasini

Corradi

Cross-wind aerodynamic forces on rail vehicles - wind tunnel experimental tests and numerical dynamic analysis (Abstract no: 11). WCRR 2003, Edinburgh; Topic: Interactive Systems and Environment, 2003.

Cléon

L. M.

Gautier

P.-E.

Sourget

Sécurité de la circulation des trains à grande vitesse vis-à-vis des vents latéraux: le programme DeuFraKo. Revue Générale des Chemins de fer - juillet-août 2004/7, 2004.

Diedrichs

Ekequist

Stichel

Tengstrand

Quasi-static modelling of wheel-rail reactions due to crosswind effects for various types of high-speed rolling stock

Proc. Instn Mech. Engrs, Part F: J. Rail and Rapid Transit, 2004, 218 (F2), 133–148.

Predictive prospects of unsteady detached-eddy simulations in industrial external aerodynamic flow simulations. Final Thesis, Lehrstuhl für Strömungslehre und Aerodynamishes Institute Aachen, Matriculation number: 219949, 2004.

Rolén

Rung

Computational modelling of cross-wind stability of high speed trains. In European Congress on

Computational methods in applied sciences and engineering (Eds Neittaanmäki

Rossi

Korotov

Oñate

Périaux

Knörzer

) 24–28 July 2004, pp. 1–20 (ECCOMAS, Jyväskylä).

10.

Hemida

Large-eddy simulation of the flow around simplified high-speed trains under side wind conditions. Thesis for licentiate of engineering no. 2006:06, Chalmers University, Sweden, 2006 (ISSN 1652–8565).

11.

Diedrichs

Computational methods for crosswind stability of railway trains. A literature survey, 2005 (Royal Institute of Technology (KTH), Stockholm, Sweden), TRITA AVE 2005:27. ISSN 1651–7660, ISRN KTH/AVE/RTR-05/27-SE.

12.

Cooper

R. K.

The probability of trains overturning in high winds. In Proceedings of the 5th International Conference on

Wind engineering, Fort Collins, CO, USA, Pergamon, 1979, pp. 1185–1194.

13.

Gawthorpe

R. G.

Wind effects on ground transportation

J. Wind Eng. Ind. Aerodyn., 1994, 52, 73–92.

14.

Fauchier

Le Dévéhat

Grégoire

Numerical study of the turbulent flow around the reduced-scale model of an Inter-Regio. TRANSAERO-a European initiative on transient aerodynamics for railway system optimization, 2002, pp. 61–74 (Springer-Verlag, Berlin, Heidelberg, and New York). ISBN 3–540-43316–3.

15.

Khier

Breuer

Durst

Numerical computation of 3-D turbulent flow around high-speed trains under side wind conditions. TRANSAERO-a European initiative on transient aerodynamics for railway system optimization, 2002, pp. 75–84 (Springer-Verlag, Berlin, Heidelberg, and New York). ISBN 3–540-43316–3.

16.

prEN 14067–1. Railway Applications - Aerodynamics - Part 1: Symbols and units. European standard, 2002.

17.

Railtrack plc Resistance of railway vehicles to roll-over in gales. GM/RT2142, 2000.

18.

Kunieda

Railway technical research report of Tokyo (in Japanese). No. 793, 1972.

19.

Matschke

Sicherheitsnachweis bei Seitenwind. Konzernrichtlinie 401, version 03.2001, 2001 (Deutsche Bahn AG).

20.

Heine

Sicherheitsnachweis bei Seitenwind. Konzernrichtlinie 807, version 01.01.2005, 2005, (Deutsche Bahn AG).

21.

Jackson

P. S.

Hunt

C. R.

Turbulent wind flow over a low hill

Q. J. R. Meteorol. Soc., 1975, 101, 929–955.

22.

Belcher

S. E.

Hunt

J. C. R.

Turbulent flow over hills and waves

Annu. Rev. Fluid Mech., 1998, 30, 507–533.

23.

ENV 1991–2-4.

Eurocode 1: basis of design and actions on structures - Part 2–4: actions on structures - wind actions, 1995 (European Committee for Standardization(CEN), Brussels).

24.

Baker

C. J.

The determination of topographical exposure factors for railway embankments

J. Wind Eng. Ind. Aerodyn., 1985, 21, 89–99.

25.

26.

Rhie

C. M.

Chow

W. L.

Numerical study of the turbulent flow past an airfoil with trailing edge separation

AIAA J., 1983, 21 (11), 1525–1532.

27.

Launder

B. E.

Spalding

D. B.

The numerical computation of turbulent flows

Comput. Methods. Appl. Mech. Eng., 1974, 3, 269–289.

28.

Shih

T.-H.

Zhu

Lumley

J. L.

A realizable Reynolds stress algebraic equation model. 9th Symposium on

Turbulence shear flows, Kyoto, Japan, 10–18 August, 1993, pp. 1–34.

29.

Hucho

W. H.

Aerodynamics of road vehicles, 4th edition, 1998. ISBN 0–7680-0029–7.

30.

Schlicting

Boundary-layer theory, 1968. (McGraw-Hill, Inc.).

Crosswind stability of a high-speed train on a high embankment

Abstract

Abstract

Keywords

Get full access to this article

References