[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/was.2014.19.2.145

Wind loads on a moving vehicle-bridge deck system by wind-tunnel model test

Li, Yongle (Department of Bridge Engineering, Southwest Jiaotong University)
Hu, Peng (Department of Bridge Engineering, Southwest Jiaotong University)
Xu, You-Lin (Department of Civil and Environmental Engineering, The Hong Kong Polytechnic University)
Zhang, Mingjin (Department of Bridge Engineering, Southwest Jiaotong University)
Liao, Haili (Department of Bridge Engineering, Southwest Jiaotong University)

Publication Information

Wind and Structures / v.19, no.2, 2014 , pp. 145-167 More about this Journal

Abstract

Wind-vehicle-bridge (WVB) interaction can be regarded as a coupled vibration system. Aerodynamic forces and moment on vehicles and bridge decks play an important role in the vibration analysis of the coupled WVB system. High-speed vehicle motion has certain effects on the aerodynamic characteristics of a vehicle-bridge system under crosswinds, but it is not taken into account in most previous studies. In this study, a new testing system with a moving vehicle model was developed to directly measure the aerodynamic forces and moment on the vehicle and bridge deck when the vehicle model moved on the bridge deck under crosswinds in a large wind tunnel. The testing system, with a total length of 18.0 m, consisted of three main parts: vehicle-bridge model system, motion system and signal measuring system. The wind speed, vehicle speed, test objects and relative position of the vehicle to the bridge deck could be easily altered for different test cases. The aerodynamic forces and moment on the moving vehicle and bridge deck were measured utilizing the new testing system. The effects of the vehicle speed, wind yaw angle, rail track position and vehicle type on the aerodynamic characteristics of the vehicle and bridge deck were investigated. In addition, a data processing method was proposed according to the characteristics of the dynamic testing signals to determine the variations of aerodynamic forces and moment on the moving vehicle and bridge deck. Three-car and single-car models were employed as the moving rail vehicle model and road vehicle model, respectively. The results indicate that the drag and lift coefficients of the vehicle tend to increase with the increase of the vehicle speed and the decrease of the resultant wind yaw angle and that the vehicle speed has more significant effect on the aerodynamic coefficients of the single-car model than on those of the three-car model. This study also reveals that the aerodynamic coefficients of the vehicle and bridge deck are strongly influenced by the rail track positions, while the aerodynamic coefficients of the bridge deck are insensitive to the vehicle speed or resultant wind yaw angle.

Keywords

crosswinds; moving-vehicle model; wind loads; wind-tunnel test; wind-vehicle-bridge system;

Citations & Related Records

Reference

1	Zhang, J. and Chen, N.Y. (1998), "Experimental investigations in to the effect of cross-winds on the aerodynamics of EMU vehicles", Electric Drive for Locomotive, 2, 4-6 (in Chinese).
2	Zhou, L. and Ge, Y.J. (2008), "Aerodynamic coefficient of vehicle-bridge system by wind tunnel test", J. Harbin Inst. Technol. (New Series), 15(6), 871-877.
3	Zhu, Z.W. and Chen, Z.Q. (2001), "Investigation on wind loads for YZ22 vehicle and railway freebeam bridge", J. Hunan University, 28(1), 93-97 (in Chinese).
4	Chiu, T.W. and Squire, L.C. (1992), "An experimental study of the flow over a train in a cross-wind at large yaw angles up to 90", J. Wind Eng. Ind. Aerod., 45(1), 47-74. DOI
5	Hemida, H. and Krajnovic, S. (2010), "LES study of the influence of the nose shape and yaw angles on flow structures around trains", J. Wind Eng. Ind. Aerod., 98(1), 34-46. DOI
6	Huang, L., Liao, H.L. and Li, Y.L. (2006), "Analysis of flow characteristics around train-bridge system under cross wind and train induced wind", J. Railway Sci. Eng., 3(6), 61-65. (in Chinese).
7	Li, Y.L., Hu, P., Cai, C.S., Zhang, M.J. and Qiang, S.Z. (2013), "Wind tunnel study of a sudden change of train wind loads due to the wind shielding effects of bridge towers and passing trains", J. Eng. Mech. - ASCE, 139(9), 1249-1259. DOI
8	Li, Y.L., Liao, H.L. and Qiang, S.Z. (2004), "Study on aerodynamic characteristics of the vehicle-bridge system by the section model wind tunnel test", J. China Railway Soc., 26(3), 71-75. (in Chinese).
9	Li, Y.L., Qiang, S.Z., Liao, H.L. and Xu, Y.L. (2005), "Dynamics of wind-rail vehicle-bridge system", J. Wind Eng. Ind. Aerod., 93(6), 483-507. DOI ScienceOn
10	Xu, Y.L. and Guo, W.H. (2003), "Dynamic analysis of coupled road vehicle and cable-stayed bridge systems under turbulent wind", Eng. Struct., 25(4), 473-486. DOI ScienceOn
11	Yang, M.Z., Yuan, X.X., Lu, Z.J. and Huang, H.J. (2008), "Experimental study on aerodynamic characteristics of train running on Qinghai-Tibet railway under cross winds", J. Exper. Fluid Mech., 22(1), 76-79. (in Chinese).
12	Baker, C.J. (1986), "Train aerodynamic forces and moments from moving model experiments", J. Wind Eng. Ind. Aerod., 24(3), 227-251. DOI
13	MathWorks Inc. (2005), MATLAB 7.1.0.246 (R14), The MathWorks Inc, Natick, Massachusetts, USA.
14	Pope, C.W. (1991), Aerodynamics and ventilation of vehicle tunnels, Elsevier, New York, USA.
15	Suzuki, M., Tanemoto, K. and Maeda, T. (2003), "Aerodynamic characteristics of train/vehicles under cross winds", J. Wind Eng. Ind. Aerod., 91(1-2), 209-218. DOI ScienceOn
16	Cai, C.S. and Chen, S.R. (2004), "Framework of vehicle-bridge-wind dynamic analysis", J. Wind Eng. Ind. Aerod., 92(8), 579-607. DOI
17	Charuvisit, S., Kimura, K. and Fujino Y. (2004), "Experimental and semi-analytical studies on the aerodynamic forces acting on a vehicle passing through the wake of a bridge tower in cross wind", J. Wind Eng. Ind. Aerod., 92(9), 749-780. DOI
18	Li, Y.L., Wang, B., Xu, Y.L. and Liao, H.L. (2011), "Numerical simulation of aerodynamic characteristics for static and dynamic vehicle-bridge system under crosswinds", China Civil Eng. J., 44, 87-94, (in Chinese).
19	Chiu, T.W. (1995), "Prediction of the aerodynamic loads on a railway train in a cross-wind at large yaw angles using an integrated two-and three-dimensional source/vortex panel method", J. Wind Eng. Ind. Aerod., 57(1), 19-39. DOI

Reference

2	Wanming Zhai. (2015) Wind and Structures Dynamics of high-speed train in crosswinds based on an air-train-track interaction model / 20 (2) , 143
4	Hai Zhao. (2015) Wind and Structures Effect of noise barrier on aerodynamic performance of high-speed train in crosswind / 20 (4) , 509
3	Huoyue Xiang. (2015) International Journal of Rail Transportation Numerical simulation of the protective effect of railway wind barriers under crosswinds / 3 (3) , 151
6	Shengli Li. (2017) Journal of Vibroengineering Influence of catwalk design parameters on the galloping of constructing main cables in long-span suspension bridges / 19 (6) , 4671
4	Nan Zhang. (2016) Engineering A Train-Bridge Dynamic Interaction Analysis Method and Its Experimental Validation / 2 (4) , 528
2	C.S. Cai. (2015) Wind and Structures A coupled wind-vehicle-bridge system and its applications: a review / 20 (2) , 117
2	Weiwei Guo. (2015) Wind and Structures Aerodynamic effect of wind barriers and running safety of trains on high-speed railway bridges under cross winds / 20 (2) , 213
2	Mengxue Wu. (2015) Wind and Structures The impact of artificial discrete simulation of wind field on vehicle running performance / 20 (2) , 169
3	Nan Zhang. (2015) Wind and Structures Dynamic analysis of coupled wind-train-bridge system considering tower shielding and triangular wind barriers / 21 (3) , 311
	Huoyue Xiang. (2017) Journal of Wind Engineering and Industrial Aerodynamics A wind tunnel test method on aerodynamic characteristics of moving vehicles under crosswinds / 163 , 15
1662-7482	(2014) Applied Mechanics and Materials The Aerodynamic Characteristics of Bus in Different Lateral Locations of Steel Box-Girder Bridge / 587-589 (1662-7482) , 1693
3	(2019) Journal of Computational and Nonlinear Dynamics Cross Wind Effects on Vehicle–Track Interactions: A Methodology for Dynamic Model Construction / 14 (3) , 031003
1	(2014) Engineering applications of computational fluid mechanics The effect of moving train on the aerodynamic performances of train-bridge system with a crosswind / 14 (1) , 222
1	(2014) Wind & structures Numerical analysis of wind field induced by moving train on HSR bridge subjected to crosswind / 27 (1) , 29
7	(2014) Vehicle system dynamics Train-track-bridge dynamic interaction: a state-of-the-art review / 57 (7) , 984
None	(2020) Advances in civil engineering The Aerodynamic Characteristics of Road Vehicles Overtaking on Bridge Deck under Crosswinds / 2020 (None) , 1
13	(2014) Advances in structural engineering Effect of unsteady aerodynamic loads on driving safety and comfort of trains running on bridges / 23 (13) , 2898
None	(2021) Engineering structures Assessment of train running safety on bridges: A literature review / 241 (None) , 112425
6	(2014) Proceedings of the Institution of Mechanical Engineers. Part F, Journal of rail and rapid transit Effects of infrastructure on the aerodynamic performance of a high-speed train / 235 (6) , 679
1	(2021) Wind & structures Numerical simulation on aerodynamic characteristics of moving van under the train-induced wind / 33 (1) , 41