Numerical Simulation Study on the Effective Distance of Pressurized Ventilation in Gas Tunnel Construction_Vol. 2 No. 2 (JES 2024)_Journal of Engineering System (ISSN: 2959-0604)

Home > Journal of Engineering System (ISSN: 2959-0604) > Vol. 2 No. 2 (JES 2024) >

Numerical Simulation Study on the Effective Distance of Pressurized Ventilation in Gas Tunnel Construction

DOI: https://doi.org/10.62517/jes.202402201

Author(s)

Zongbo Diao1, Liang Suo2, Jun Guo2

Affiliation(s)

1Sichuan Road and Bridge East China Construction Co., Ltd., Chengdu, Sichuan, China 2Sichuan Vocational and Technical College of Communications, Chengdu, Sichuan, China

Abstract

The ventilation of gas tunnel construction has always been a difficult point in the construction of gas tunnels, and the construction risk is high, and the ventilation cost is large. How to efficiently and quickly analyze the gas emission of different sections and take corresponding ventilation measures can improve the safety of gas tunnel construction and reduce the consumption of funds. Therefore, in this paper, the source term of gas emission is used to deal with it, and the actual pollution source is regarded as the source term in the air at a small distance from the wall of the tunnel face, and its emission is the actual emission of the tunnel gas source, and the source term S of these units is equal to the amount of gas generated per unit volume and unit time. Numerical simulation analysis can be carried out more vividly for the improvement of the construction safety of gas tunnels. In recent years, with the proposal of China's "double carbon" goal, the requirements for green construction have also been raised to a new height, and the ventilation standards for gas tunnel construction are getting higher and higher.

Keywords

Fluent; Gas Concentration Pressure Ventilation; Numerical Simulation

References

[1] Chen Huihao. Analysis of ventilation and flow field characteristics and parameter optimization of gas tunnel construction. Nanning: Guangxi University, 2022:1- -2. [2] He Cong. Study on ventilation scheme for construction of high gas tunnel of Dailipan Railway. Modern Tunnel Technology, 2019, 56 (S2): 478--484. [3] Yang Dezhi. Analysis and study of gas occurrence and migration and gas-solid coupling in highway tunnel. Chengdu: Southwest Jiaotong University, 2014. [4] Zeng Chang, Yao Zhigang, Fan Jianguo, et al. Study on ventilation and gas distribution of highway tunnel roadway construction. Tunnel construction, 2016, 36 (7): 837- -843. [5] Editorial Department of Chinese Highway Journal. Review of Academic Research on Tunnel Engineering in China 2015. Highway Journal of China, 2015, 28 (5): 1- -65. [6] Guan Baoshu, Essentials of Tunnel Engineering Construction. Beijing: China Communications Press, 2003. [7] Liao Zhaohua. Guo Xiaohua. The Highway Tunnel Design Manual. People's Communications Press, 2012. [8] Li Bing, Ye Aijun, Cui Pengjie, et al. Research on ventilation field of special gas tunnel. Modern Tunnel Technology, 2022, 59 (5): 118- -124. [9] Cui Pengjie, Li Bing, Ye Aijun, et al. Analysis of the safety problems and control measures of highway gas tunnel construction. Modern Tunnel Technology, 2022, 59 (S1): 660- -665. [10] Gao Jianliang, Xu Kunlun, Wu Yan. Numerical experiment study on the distribution of tunneling roadway. Chinese Journal of Security Science, 2009, 19 (1): 18- -24. [11] Liu Yanbao. Study on the deformation and failure law of gas-bearing coal body based on fine mechanical test. Chongqing: Chongqing University, 2009. [12] Yi Jun, Jiang Yongdong, Xian Xuefu, et al. Flow-solid dynamic coupling model of stress-temperature-to-seepage pressure field. Rock and Soil Mechanics, 2009, 30 (10): 2945- -2949.