Litcius/Paper detail

Research on the drag reduction of high-speed train based on bottom two-multistage wing deflector

Chen Jiang, Y Li, Jin-lan Long, Xin Tang, Guangjun Gao, Franklin Chinemelem Eze

2024Physics of Fluids10 citationsDOI

Abstract

To address the challenge of reducing aerodynamic drag while further enhancing the speed of high-speed trains, this research employs the concept of flow control for the bottom parts and draws inspiration from the front wings of Formula 1 (F1) race cars. Three kinds of two-multistage wing deflectors are designed and systematically analyzed by unsteady Reynolds-averaged Navier–Stokes (URANS) turbulent model. The most suitable design is determined by the single bogie model with a simplified train body. Using the improved delayed detached eddy simulation method, the aerodynamic drag of 1:8 three-car train models with or without two-multistage wing deflector is studied at different operational speeds. The results present the total drag reduction is higher at higher speeds. The reductions of 4.26%, 3.92%, 3.63%, and 3.49% are obtained at the operating speeds of 400, 350, 300, and 200 km/h, respectively. The two-multistage wing deflector desirably improves the flow structure at the bottom of the train, which leads to the reduction of aerodynamic drag and a corresponding reduction in the positive pressure zones within the bogie area. Furthermore, the deflector restricts shedding vortices, effectively narrowing the interference range of airflow under the train, which will provide a potential drag reduction method for the next generation high-speed train.

Topics & Concepts

DragBogieAerodynamic dragAerodynamicsReduction (mathematics)PhysicsTurbulenceWingMarine engineeringVortexDetached eddy simulationMechanicsAerospace engineeringLift-induced dragReynolds-averaged Navier–Stokes equationsEngineeringMechanical engineeringGeometryMathematicsAerodynamics and Fluid Dynamics ResearchWind and Air Flow StudiesFluid Dynamics and Vibration Analysis