Numerical investigation on thermal insulation layer of a tunnel in seasonally frozen regions

• Published in: Applied thermal engineering Vol. 138; pp. 280 - 291
• Main Authors: Ma, Qinguo, Luo, Xiaoxiao, Lai, Yuanming, Niu, Fujun, Gao, Jianqiang
• Format: Journal Article
• Language: English
• Published: Oxford Elsevier Ltd 25.06.2018; Elsevier BV
• Subjects: Conduction heating; Conductive heat transfer; Frost damage; Frost heaving; Heat conductivity; Heat-moisture coupled model; Insulation; Mathematical models; Migration; Moisture; Numerical analysis; Phase transitions; Seasonally frozen region; Thermal conductivity; Thermal insulation; Thickness; Tunnel; Tunnels; Heat-moisture coupled model; Tunnel; Seasonally frozen region; Thermal insulation
• ISSN: 1359-4311; 1873-5606
• DOI: 10.1016/j.applthermaleng.2018.04.063

•A heat-moisture coupled model including heat convection of water and phase change is developed.•The unfavorable freezing position and time are determined.•The effect of location of insulation layer on thermal state is analyzed.•The relationship between thermal conductivity and thickness is given for heat insulation. As an effective engineering measure, thermal insulation layer is used to prevent tunnel from frost heave damage in seasonally frozen regions. Two different methods are generally adopted to lay insulation layer. One is to lay the insulation layer between the preliminary lining and the secondary lining. The other is to lay the insulation layer on the surface of the secondary lining. But, there is no evidence to show which method is more useful. Meantime, the relationship between the insulation effect and thermal conductivity as well as thickness of insulation layer should be identified. To solve these problems, a numerical heat-moisture coupled model for the tunnel in a seasonally frozen region is established, which involves heat conduction, water migration and phase transition. And then, a representative tunnel in the Northwest of China is taken as an example to explore the heat-moisture state of the tunnel. Afterwards, the thermal insulation effect and the effect of location of thermal insulation layer on thermal state are analyzed. Subsequently, the methods on thermal conductivity and thickness of thermal insulation layer are constructed and the relationship among the insulation effect, thermal conductivity and thickness is obtained for heat insulation effect.