As more complex tunnel projects are being constructed in the mountains of southwestern China, understanding the diffusion phenomenon of carbon monoxide (CO) in high-altitude tunnels is essential. This is particularly critical for tunnels with high ground temperatures during blasting. This study employed field monitoring and computer simulations, focusing on a specific plateau tunnel. A real-time monitoring system was established, using CO as the representative gas. A computational fluid dynamics model was developed and was validated against field data. Results show that forced ventilation could create four distinct flow regions. CO concentration in the tunnel declined during outward diffusion under ventilation. Specifically, the CO concentration was increased by a factor of 1.83 with the increase in the altitude from 0 to 5000 m. Furthermore, with ground temperature rising from 300 to 320 K, the propagation speed of the CO concentration peak accelerated, arriving at the tunnel exit section 53 s earlier, and its magnitude was decreased by 224 ppm. Finally, a functional relationship was established between CO concentration, ventilation time, distance, temperature and altitude. This study provides a valuable reference for safety assurance and informs ventilation design for tunnel construction in relation to CO diffusion in such tunnels.
GongJWangWLiXHeWYuanYWangFYangCDingXHanHLiLCaoY. Statistics of China’s railway tunnels by the end of 2023 and overview of tunnels of key new projects in 2023. Tunnel Constr2025; 45(3): 636–653.
2.
FangJLiuHZhaiJ. Development and prospect of blasting technology for mountain-crossing tunnels. Tunnel Constr2021; 41(11): 1980–1991.
3.
TornoSTorañoJ. On the prediction of toxic fumes from underground blasting operations and dilution ventilation. Conventional and numerical models. Tunnel Undergr Space Technol2020; 96: 103194.
4.
WuQYuLWangFLiQWangM. Study of construction control technology for super-long high altitude highway tunnel in low pressure and low oxygen environment: technical standards for oxygen supply. Tunnel Constr2017; 37(8): 973–979.
5.
LiuNChenKDengEYangWWangY. Study on dust suppression performance of a new spray device during drilling and blasting construction in the metro tunnel. Tunnel Undergr Space Technol2023; 133: 104975.
6.
KrólMKrólAKoperPWronaP. The influence of natural draught on the air flow in a tunnel with longitudinal ventilation. Tunnel Undergr Space Techno2019; 85: 140–148.
7.
MenéndezJSanabriaMFernández-OroJMGaldo-VegaMÁlvarez de PradoLBernardo-SánchezA. Energy consumption and dilution of toxic gases in underground infrastructures: a case study in a railway tunnel under forced ventilation. Energy2024; 307: 132810.
8.
LiuNWuXDengENiYQYangWCLiGZ. Dust diffusion laws during partition excavation by boom-type roadheader in a metro tunnel. Tunnel Undergr Space Technol2023; 141: 105382.
9.
ZhouHZhangSLuP. Interfacial thermal resistance effect of ventilation cooling in high temperature mine roadway. J Basic Sci Eng2022; 30(3): 673–683.
10.
TaoYHuHZhangHZhangGHaoZWangL. A new ventilation system for extra-long railway tunnel construction by using the air cabin relay: a case study on optimization of air cabin parameters length. J Build Eng2022; 45: 103480.
11.
YangWWangJDengELiuYLuoLYangJ. A hybrid ventilation scheme applied to bidirectional excavation tunnel construction with a long inclined shaft. J Cent South Univ2024; 31(9): 3187–3205.
12.
ZhangHZhaoYZhangGTaoYGeZ. Relay ventilation system with long air-cabin for extra-long railway tunnel: a case study on pollutant transport characteristics after blasting. Tunnel Undergr Space Technol2025; 157: 106281.
13.
ZhouYYangYBuRMaFShenY. Effect of press-in ventilation technology on pollutant transport in a railway tunnel under construction. J Cleaner Prod2020; 243: 118590.
14.
XieZZhaoZLiDJiangTWangTXiaoY. Field measurements on the attenuation characteristics of PM2.5 and toxic gases in a blasting metro tunnel and evaluation of the re-entry time. Tunnel Undergr Space Technol2023; 138: 105170.
15.
BaiJWuZChenTLiWZhangPLiY. Influence of ventilation duct parameter optimization on pollutant diffusion in spiral tunnels. Sustainability2022; 14(17): 10540.
16.
TornoSTorañoJUleciaMAllendeC. Conventional and numerical models of blasting gas behaviour in auxiliary ventilation of mining headings. Tunnel Undergr Space Technol2013; 34: 73–81.
17.
ChangXChaiJLuoJQinYXuZCaoJ. Tunnel ventilation during construction and diffusion of hazardous gases studied by numerical simulations. Build Environ2020; 177: 106902.
18.
SongYSunMYangJTaoC. Numerical study on the vehicle exhaust dispersion in a curved tunnel: effects of the tunnel radius and tilt angle of jet fan. Indoor Built Environ2025; 34(3): 569–585.
19.
ZhaoYShiSTianSLiGTaoWGuoW. Technical difficulties and countermeasure suggestions in tunnel construction of Yaan-Linzhi Section of Sichuan-Tibet Railway. Tunnel Constr2021; 41(7): 1079–1090.
20.
LiCLiXLiuJFanXYouGZhaoLZhaoHLiJLeiH. Investigation of the differences between the Tibetan and Han populations in the haemoglobin–oxygen affinity of red blood cells and in the adaptation to high-altitude environments. Hematology2018; 23(5): 309–313.
21.
FeinbergM. Constitutive equations for ideal gas mixtures and ideal solutions as consequences of simple postulates. Chem Eng Sci1977; 32(1): 75–78.
22.
GouHLiYLuoZ. Study on air volume calculation and fan selection for tunneling ventilation in plateau area. Tunnel Constr2012; 32(1): 53–56.
23.
XieZZhuYChenSLaiDZhaoDHanX. Research on environmental health standard of tunnel construction in plateau. J Xi’an Univ ArchitTechnol (Natural Science Edition)2011; 43(2): 247–252.
24.
YanTWangMGuoCChaoFChenH. Altitude coefficient considering CO and smoke emission in high altitude highway tunnels. J Cent South Univ (Science and Technology)2014; 45(11): 4012–4017.
25.
GuoZSunTZhangCDengMZhangA. Suggestions on discount rate of CO and smoke baseline emission of high altitude and super long tunnel ventilation. Chinese J Undergr Space Eng2020; 16(S1): 341–345.
26.
HuangRShenXWangBLiaoX. Migration characteristics of CO under forced ventilation after excavation roadway blasting: a case study in a plateau mine. J Cleaner Prod2020; 267: 122094.
27.
ChenXWuJSongRZhangPDengCKongL. Pollutant diffusion law during high-altitude tunnel construction. J Zhejiang Univ (Eng Sci)2025; 58(1): 176–187.
28.
LiZWangJZhaoSXuY. The effect of oxygen supply and oxygen distribution on single-head tunnel with different altitudes under mixed ventilation. Indoor Built Environ2022; 31(4): 972–987.
29.
TanZZhaoKWangJXuYYuanY. Optimization for diffusion-type oxygen supply nearby working face of railway tunnel in plateau. Indoor Built Environ2024; 33(6): 985–1002.
30.
ZhouX. Study on Coupling Interaction between Thermal Conduction of Surrounding Rock and Wind Convection in Cold Area Tunnel and Its Application. PhD Dissertation. Chengdu: Southwest Jiaotong University; 2018.
31.
ZhaoZXuHWeiSZhangWWangG. Preliminary prediction of temperature field and thermal damage in Zheduoshan region along Sichuan-Tibet railway. Geoscience2021; 35(1): 180–187.
32.
WangMTangXWuQTongJDongC. Temperature field variation rules of rock and support structure in high rock temperature tunnel. J China Railway Soc2016; 38(11): 126–131.
33.
SongDZhouXBaiGLiA. Study on temperature field distribution law of surrounding rock in active thermal insulated roadway of high temperature mine. Coal Sci Technol2017; 45(12): 107–113.
34.
TB 10204-2002. Numerical study on ventilation cooling in a high geothermal tunnel of the Sichuan-Tibet Railway considering the tunnel drilling process. Beijing: China Railway Publishing House, 2002.
35.
JTG/T 3660-2020. Technical Specifications for Construction of Highway Tunnel. Beijing: China Communication Press, 2020.
36.
GB16423-2020. Safety Regulation for Metal and Nonmetal Mines. Beijing: Emergency Management Press, 2020.
37.
DiegoITornoSTorañoJMenéndezMGentM. A practical use of CFD for ventilation of underground works. Tunnel Undergr Space Technol2011; 26(1): 189–200.
38.
CaiPNieWHuaYWeiWJinH. Diffusion and pollution of multi-source dusts in a fully mechanized coal face. Process Saf Environ Prot2018; 118: 93–105.
39.
WangYXuZLiuJZhangAXuZMengDZhaoJ. Study on flow field of electrochemical machining for large size blade. Int J Mech Sci2021; 190: 106018.
40.
JiangZYangBZhangGZengFWangY. Analysis of dust pollution effect of cutting dust and ventilation control parameters at the heading face in plateau mines. J China Coal Soc2021; 46(7): 2146–2157.
41.
HuYWangMWangQLiuDTongJ. Field test of thermal environment and thermal adaptation of workers in high geothermal tunnel. Build Environ2019; 160: 106174.
