高海拔隧道施工期污染物扩散规律

doi:10.3785/j.issn.1008-973X.2024.01.019

浙江大学学报(工学版)

2024, Vol. 58

Issue (1): 176-187 DOI: 10.3785/j.issn.1008-973X.2024.01.019

能源工程、环境工程

高海拔隧道施工期污染物扩散规律

陈星宇1(

),吴剑2,任松1,*(

),张平1,邓超1,孔令伟3

1. 重庆大学煤矿灾害动力学与控制国家重点实验室，重庆 400044
2. 中铁西南科学研究院有限公司，四川成都 611731
3. 昭通市昭泸高速公路投资开发有限公司，云南昭通 657000

Pollutant diffusion law during high-altitude tunnel construction

Xingyu CHEN1(

),Jian WU2,Song REN1,*(

),Ping ZHANG1,Chao DENG1,Lingwei KONG3

1. State Key Laboratory of Coal Mine Disaster Dynamics and Control, Chongqing University, Chongqing 400044, China
2. China Railway Southwest Research Institute Limited Company, Chengdu 611731, China
3. Zhaotong Zhaolu Expressway Investment and Development Limited Company, Zhaotong 657000, China

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摘要：

为了探究高海拔隧道施工通风过程中的污染物扩散规律，依托川藏铁路芒康山隧道工程，采用数值模拟和现场测试的方法，研究高海拔隧道施工通风过程中粉尘和CO的扩散规律. 研究结果表明，粉尘主要是以贴壁流动的形式向洞外扩散，在该过程中会聚集成为“粉尘团”. 粉尘扩散主要是受到重力影响发生沉降，隧道内风速过大，不利于降低粉尘质量浓度. CO以“气团”的形式从掌子面附近向洞口迁移，在迁移过程中CO气团体积逐渐扩大，质量浓度峰值不断下降，逐渐形成“U形”的分布趋势，CO质量浓度的现场测试结果与数值模拟结果基本吻合. 随着海拔高度的上升，隧道内的CO质量浓度会增大，隧道内同一位置CO质量浓度达到规范要求的时间会增加. 推导基于海拔高度的隧道通风过程中CO质量浓度修正系数计算公式，对当前规范中CO的海拔高度修正系数进行很好的补充.

关键词： 高海拔隧道; 通风; 污染物扩散; 现场测试; 修正系数

Abstract:

Numerical simulation and on-site testing methods were used to analyze the diffusion law of dust and CO during the ventilation process of high-altitude tunnel construction by relying on the Mangkang Mountain Tunnel Project of the Sichuan Tibet Railway in order to analyze the diffusion law of pollutants during the ventilation process of high-altitude tunnel construction. Results show that dust mainly diffuses towards the outside of the tunnel in the form of wall-adhering flow, and it accumulates into ‘dust clusters’ during this process. Dust diffusion is mainly influenced by gravity and causes sedimentation. Excessive wind speed in the tunnel is not conducive to reducing dust mass concentration. CO migrates in the form of ‘air masses’ from the vicinity of the palm face to the entrance of the cave. The volume of CO air masses gradually expands during the migration process, and the mass concentration peak continuously decreases, gradually forming a ‘U-shaped’ distribution trend. The on-site test results of CO mass concentration basically accorded with the numerical simulation results. The CO mass concentration in the tunnel will increase as the altitude increases, and the time it takes for the CO mass concentration at the same location in the tunnel to meet the standard requirements will increase. A formula for calculating the correction coefficient of CO mass concentration during tunnel ventilation was derived based on altitude, which is a good supplement to the altitude correction coefficient of CO in the current specifications.

Key words: high-altitude tunnel ventilation pollutant dispersion field testing correction factor

收稿日期: 2023-03-29 出版日期: 2023-11-07

CLC:

X 947

基金资助: 国家自然科学基金资助项目（52074048）

通讯作者: 任松 E-mail: CXY0018@cqu.edu.cn;rs_rwx@163.com

作者简介: 陈星宇（1997—），男，硕士生，从事隧道及岩土工程的研究. orcid. org/0009-0004-4015-1329. E-mail： CXY0018@cqu.edu.cn

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引用本文:

陈星宇,吴剑,任松,张平,邓超,孔令伟. 高海拔隧道施工期污染物扩散规律[J]. 浙江大学学报(工学版), 2024, 58(1): 176-187.

Xingyu CHEN,Jian WU,Song REN,Ping ZHANG,Chao DENG,Lingwei KONG. Pollutant diffusion law during high-altitude tunnel construction. Journal of ZheJiang University (Engineering Science), 2024, 58(1): 176-187.

链接本文:

https://www.zjujournals.com/eng/CN/10.3785/j.issn.1008-973X.2024.01.019 或 https://www.zjujournals.com/eng/CN/Y2024/V58/I1/176

图 1 隧道模型的断面图

图 2 不同网格条件下的风速变化

图 3 隧道模型及网格划分

图 4 隧道进口的网格划分情况

图 5 炮烟抛掷距离的示意图

表 1 模拟一氧化碳扩散的边界条件设置

表 2 一氧化碳扩散计算模型的设置

表 3 模拟粉尘扩散边界条件的设置

表 4 离散相模型的参数设置

表 5 粉尘扩散计算模型的设置

图 6 掌子面附近空气流场的流线分布图

图 7 距掌子面不同距离处的隧道截面风速分布云图

图 8 不同时刻的隧道粉尘扩散三维云图

图 9 与掌子面不同距离处的隧道截面粉尘分布

图 10 离掌子面不同距离处粉尘质量浓度随时间的变化图

图 11 不同时刻隧道CO质量浓度分布云图

图 12 隧道不同断面不同时刻CO质量浓度的分布云图

图 13 隧道典型断面CO分布云图

图 14 隧道内呼吸带高度CO质量浓度的分布

图 15 一氧化碳测试仪

表 6 现场测试仪器设备与功能

图 16 隧道各处CO扩散数值模拟与现场实测结果的对比

表 7 不同海拔高度下的工况参数

图 17 不同海拔高度处的CO质量浓度变化

表 8 不同海拔高度处的CO质量浓度变化

表 9 不同海拔高度处的CO质量浓度修正系数平均值

图 18 CO质量浓度海拔高度修正系数的拟合曲线

图 19 不同海拔高度处CO质量浓度降到规定的质量浓度所需的时间

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