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Assessment of ventilation noise impact from metro depot with over-track platform structure on workers and nearby inhabitants

  • Ziyu Tao
  • Yimin Wang
  • Chao ZouEmail author
  • Qi Li
  • Yue Luo
Research Article
  • 9 Downloads

Abstract

In order to alleviate the shortage of land use accompanied with urbanization, over-track building complexes above metro depots are developed rapidly in China, resulting in the larger mechanical ventilation needs in the metro depot. Excessive noise exposure caused by the huge ventilation system will bring serious impacts on the health of workers in the metro depot. This research intends to evaluate the noise annoyance in the metro depot and the noise influences on adjacent residential buildings by the ventilation system. A questionnaire survey of 100 people working in a metro depot of Guangzhou Metro Line 6 was conducted, and field measurements inside the metro depot and inside adjacent residential buildings were carried out. The environmental noise level in the metro depot and the ventilation fan–induced noise level inside adjacent residential buildings exceed the corresponding criterion limit of China. Dose-response relationship modeled by logistic function was used to assess the noise annoyance, which is found underestimating the percentage of “Annoyed” (% A) and percentage of “Little Annoyed” (% LA) of staffs in the metro depot, especially for the % LA. This may be attributed to the reducing reliability of dose-effect curves as the Ldn is higher than 65 dB(A). In order to alleviate the noise impact, noise-controlling measures need to be took. However, traditional noise-controlling measures cannot solve low-frequency noise disturbance.

Keywords

Metro depot Ventilation noise Questionnaire survey Measurement 

Notes

Acknowledgements

The authors wish to thank all co-workers helping to conduct the survey and measurements, as well as all the respondents filling out the questionnaire.

Funding information

This work is financially supported by Metro (GZMTR) projects and the science and technology project of Guangdong province, China (No. 2017A050501005).

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Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2019

Authors and Affiliations

  1. 1.School of Civil Engineering and TransportationSouth China University of TechnologyGuangzhouChina
  2. 2.School of Civil and Transportation EngineeringGuangdong University of TechnologyGuangzhouChina

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