Numerical study on aerodynamic noises and characteristics of the high-speed train in the open air and tunnel environment

Li, Xin; Tao, Shang; Liu, Han; Wang, Lihua

doi:10.21595/jve.2017.18499

Cited by 3 publications

(1 citation statement)

References 21 publications

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“…However, most of the research focuses on the internal noise of the train, while relatively few studies address external noise and aerodynamic noise sources. Li et al [23] systematically studied aerodynamic characteristics of a high-speed train in three situations, comprising open air, entering a tunnel and completely in a tunnel. The results show that the internal noise of the high-speed train in the tunnel is the largest.…”

Section: Introductionmentioning

confidence: 99%

A Fast Approach for Predicting Aerodynamic Noise Sources of High-Speed Train Running in Tunnel

Qin¹,

Li²,

Wang³

et al. 2022

Computer Modeling in Engineering &Amp; Sciences

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The aerodynamic noise of high-speed trains passing through a tunnel has gradually become an important issue. Numerical approaches for predicting the aerodynamic noise sources of high-speed trains running in tunnels are the key to alleviating aerodynamic noise issues. In this paper, two typical numerical methods are used to calculate the aerodynamic noise of high-speed trains. These are the static method combined with non-reflective boundary conditions and the dynamic mesh method combined with adaptive mesh. The fluctuating pressure, flow field and aerodynamic noise source are numerically simulated using the above methods. The results show that the fluctuating pressure, flow field structure and noise source characteristics obtained using different methods, are basically consistent. Compared to the dynamic mesh method, the pressure, vortex size and noise source radiation intensity, obtained by the static method, are larger. The differences are in the tail car and its wake. The two calculation methods show that the spectral characteristics of the surface noise source are consistent. The maximum difference in the sound pressure level is 1.9 dBA. The static method is more efficient and more suitable for engineering applications.

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Section: Introductionmentioning

confidence: 99%

A Fast Approach for Predicting Aerodynamic Noise Sources of High-Speed Train Running in Tunnel

Qin¹,

Li²,

Wang³

et al. 2022

Computer Modeling in Engineering &Amp; Sciences

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Flow and sound fields of scaled high-speed trains with different coach numbers running in long tunnel

Li,

Sun,

Ouyang

et al. 2024

Railw. Eng. Sci.

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Segregated incompressible large eddy simulation and acoustic perturbation equations were used to obtain the flow field and sound field of 1:25 scale trains with three, six and eight coaches in a long tunnel, and the aerodynamic results were verified by wind tunnel test with the same scale two-coach train model. Time-averaged drag coefficients of the head coach of three trains are similar, but at the tail coach of the multi-group trains it is much larger than that of the three-coach train. The eight-coach train presents the largest increment from the head coach to the tail coach in the standard deviation (STD) of aerodynamic force coefficients: 0.0110 for drag coefficient (Cd), 0.0198 for lift coefficient (Cl) and 0.0371 for side coefficient (Cs). Total sound pressure level at the bottom of multi-group trains presents a significant streamwise increase, which is different from the three-coach train. Tunnel walls affect the acoustic distribution at the bottom, only after the coach number reaches a certain value, and the streamwise increase in the sound pressure fluctuation of multi-group trains is strengthened by coach number. Fourier transform of the turbulent and sound pressures presents that coach number has little influence on the peak frequencies, but increases the sound pressure level values at the tail bogie cavities. Furthermore, different from the turbulent pressure, the first two sound pressure proper orthogonal decomposition (POD) modes in the bogie cavities contain 90% of the total energy, and the spatial distributions indicate that the acoustic distributions in the head and tail bogies are not related to coach number.

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Analysis of unsteady flow field and near-field aerodynamic noise of scale high-speed trains in long tunnel

Ouyang

Chen

2023

Applied Acoustics

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Numerical study on aerodynamic noises and characteristics of the high-speed train in the open air and tunnel environment

Cited by 3 publications

References 21 publications

A Fast Approach for Predicting Aerodynamic Noise Sources of High-Speed Train Running in Tunnel

A Fast Approach for Predicting Aerodynamic Noise Sources of High-Speed Train Running in Tunnel

Flow and sound fields of scaled high-speed trains with different coach numbers running in long tunnel

Analysis of unsteady flow field and near-field aerodynamic noise of scale high-speed trains in long tunnel

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