岩土介质在冻融过程中的温度场研究及工程应用

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摘要基于“三区域”(已冻区、正冻区和未冻区)理论，建立岩土介质在冻融过程中的温度场数学模型，并将利用有限元数值计算方法得到的结果与V. J. Lunardini等得到的经典解析解结果进行对比，验证该数学模型的正确性和可靠性。在此基础上，探讨岩土介质在冻融过程中相变潜热和正冻区的大小对温度场分布的影响，并对西藏嘎隆拉隧道围岩温度场以及保温层保温效果进行数值仿真分析。研究结果表明：采用二衬表面附设保温材料方法对隧道衬砌及围岩温度影响效果明显，在二衬表面施作6 cm厚的福利凯保温层后，衬砌和围岩不会承受冻融破坏。该研究成果对于寒区隧道冻融圈大小的确定及防寒保温措施的选用具有重要的理论和现实意义。

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	谭贤君1
	余祥宏2
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	于洪丹1

关键词 ：土力学, 寒区隧道, 冻融, 相变, 温度场

Abstract：Basing on the “three-zone”(frozen zone，freezing zone and unfrozen zone) theory，a mathematical model considering the process of freezing-thawing is presented to calculate the temperature field in geotechnical media，the model is verified by correctly simulating the V. J. Lunardini analytical solution for ice formation in a porous medium. Based on this，the influence of heat latent and range of freezing zone on the distribution of temperature in the process of freezing-thawing is studied，and a numerical simulation about a tunnel in Tibet is done to discusses the effect of insulation material. From the numerical results，it is found that the temperature of lining and surrounding rock are greatly changed by building insulation material at the surface of tunnel lining，after constructing a 6 cm thickness poly phenolic insulation，the lining and surrounding rock will not be affected by freezing-thawing damage. The results can give some references for design and construction of tunnel in cold regions.

Key words： soil mechanics tunnel in cold region freezing-thawing phase change temperature field

引用本文:

谭贤君1，余祥宏2，陈卫忠1，3，伍国军1，于洪丹1. 岩土介质在冻融过程中的温度场研究及工程应用[J]. 岩石力学与工程学报, 2012, 31(S1): 2867-2874.
TAN Xianjun1，YU Xianghong2，CHEN Weizhong1，3，WU Guojun1，YU Hongdan1. STUDY OF TEMPERATURE FIELD IN PROCESS OF FREEZING-THAWING IN GEOTECHNICAL MEDIUM AND ITS APPLICATION. , 2012, 31(S1): 2867-2874.

链接本文:

https://rockmech.whrsm.ac.cn/CN/Y2012/V31/IS1/2867

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