- ISSN 0258-2724
- CN 51-1277/U
- EI Compendex
- Scopus
- Indexed by Core Journals of China, Chinese S&T Journal Citation Reports
- Chinese S&T Journal Citation Reports
- Chinese Science Citation Database
| Citation: | LI Tian, QIN Deng, ZHANG Jiye, ZHANG Weihua. Numerical Approach for Far-Field Aerodynamic Noise of High-Speed Trains Based on Half Model[J]. Journal of Southwest Jiaotong University, 2023, 58(2): 272-279, 286. doi: 10.3969/j.issn.0258-2724.20210678
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With the increasing running speeds of high-speed trains, the problem of aerodynamic noise is gradually becoming more prominent. Determination of a method to predict the far-field aerodynamic noise of high-speed trains accurately and quickly has therefore become an important aim. The far-field acoustic integral formula for a half-model train is obtained in this work by solving the Ffowcs Williams and Hawkings (FW-H) equation using the Green’s function for semi-free space. A method is proposed to predict the far-field aerodynamic noise of a full-model high-speed train using the numerical calculation results for the half-model high-speed train’s aerodynamic noise. Numerical calculation models for the aerodynamic noise characteristics of high-speed trains are established with both the full model and the half model, and the aerodynamic noise sources on the surfaces of high-speed trains for the different models are solved using an improved delayed detached eddy simulation method. The numerical simulation calculation method used for the full-model high-speed train is verified using wind tunnel tests. The flow field, aerodynamic noise source, and far-field aerodynamic noise characteristics of the full-model and half-model high-speed trains are compared and analyzed. The results show that the flow field, aerodynamic noise source, and far-field aerodynamic noise characteristics obtained from the numerical calculations of the half-model high-speed train are consistent with those of the full model. Using the half-model calculations, the degree of fluctuation of the surface pressure in the streamlined area of the tail car and the noise source radiation intensity will both be overestimated. The far-field noise average sound pressure level error of the full model predicted using the half model is less than 1 dBA. When compared with the full-model high-speed train, the number of grid calculations performed for the half model is halved.
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