A novel vented tunnel hood with decreasing open ratio to mitigate micro-pressure wave emitted at high-speed maglev tunnel exit
Artikel i vetenskaplig tidskrift, 2023

The significant increase in train speed contributes to stronger vehicle/tunnel coupling aerodynamic effect, especially on the intensity of the micro-pressure wave (MPW) emitted at high-speed maglev tunnel exit. Hence when the train speed reaches 600 km/h and more, how to effectively mitigate the MPW becomes a challenge for aerodynamic researchers. In this study, a novel vented tunnel hood with the decreasing open ratio along the enlarged cross-section wall was proposed, while one consistent and two inconsistent layouts of the hoods applied at the tunnel portals were attempted to obtain a better hood combination for the mitigation of MPW. In addition, the sliding mesh technique was used to simulate the train passing through the single-track high-speed maglev tunnel. The validation of the methodology has been carried out to compare with the previous moving model test results. The peak variations of pressure wave and MPW were analysed in combination with the grid-independence study and numerical validation. The new hoods installed consistently at the tunnel portals (entrance and exit), can reduce the maximums of MPWs at required locations, i.e., 20m and 50m from the tunnel exit, by 66.9% and 40.9% respectively, when compared to the existing unvented tunnel hood; however, when the new hood at the tunnel exit is replaced by the existing tunnel hood without vents, the maximums of MPWs at the corresponding 20m and 50m are significantly increased by 79.1% and 71.0%. After changing the set-up of the inconsistent hoods, i.e., the tunnel entrance hood is unvented and this novel hood is installed at the tunnel exit, the corresponding MPW peaks can be reduced by 84.0% and 71.1%. Therefore, the hoods at both of tunnel entrance and exit can affect the variations of MPWs, and a reasonable arrangement of the hood openings at tunnel portals can effectively mitigate the MPW emitted at the high-speed maglev tunnel exit.

Novel vented and enlarged cross-section tunnel hood

Micro-pressure wave

Initial compression wave

High-speed maglev train

Decreasing open ratio

Författare

Jie Zhang

Central South University

Bingjun Guo

Central South University

Yuge Wang

Central South University

Shuai Han

Central South University

Xiaohui Xiong

Central South University

Sinisa Krajnovic

Chalmers, Mekanik och maritima vetenskaper

Guangjun Gao

Central South University

Journal of Wind Engineering and Industrial Aerodynamics

0167-6105 (ISSN)

Vol. 240 105459

Styrkeområden

Transport

Ämneskategorier

Farkostteknik

Strömningsmekanik och akustik

DOI

10.1016/j.jweia.2023.105459

Mer information

Senast uppdaterat

2023-07-04