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隧道建设(中英文) ›› 2024, Vol. 44 ›› Issue (9): 1771-1782.DOI: 10.3973/j.issn.2096-4498.2024.09.006

• 极端环境(寒区等)隧道专题 • 上一篇    下一篇

川西高海拔隧道洞内气温特征及抗防冻理念探讨

郑波1, 吴剑1, 袁明2, 郑金龙3, 郭瑞1   

  1. 1. 中铁西南科学研究院有限公司, 四川 成都 611731; 2. 中铁投资集团有限公司, 北京 100055;3. 四川省公路规划勘察设计研究院有限公司, 四川 成都 610041)

  • 出版日期:2024-09-20 发布日期:2024-10-12
  • 作者简介:郑波(1980—),男,湖南邵阳人,2010年毕业于中国铁道科学研究院,桥梁与隧道工程专业,博士,教授级高级工程师,现从事隧道及地下工程科研和技术咨询工作。E-mail: my1390@126.com。

Temperature Characteristics and Anti-Freezing Concepts of High-Altitude Tunnels in Western Sichuan Plateau, China

ZHENG Bo1, WU Jian1, YUAN Ming2, ZHENG Jinlong3, GUO Rui1   

  1. (1. China Railway Southwest Research Institute Co., Ltd., Chengdu 611731, Sichuan, China; 2. China Railway Investment Group Co., Ltd., Beijing 100055, China; 3. Sichuan Highway Planning, Survey, Design and Research Institute Ltd., Chengdu 610041, Sichuan, China)

  • Online:2024-09-20 Published:2024-10-12

摘要: 针对川西高海拔隧道抗防冻设计问题,对运营期公路隧道洞内气温采用实测和数值模拟等方法,对隧道洞内纵向温度特征及抗防冻设计方法进行研究。结果表明: 1)川西高原较短隧道冬季洞内纵向温度呈负温贯通状态,长隧道、特长隧道的洞内纵向温度呈现出弱对称或非对称分布特征。2)冬季隧道洞口温度及洞身负温分布状态与隧道自身所处环境有关,尤其是隧道两端地形特征及高差程度。3)洞口负温段冻结指数和年冻结天数均随进洞距离的增大呈减小趋势,但单向自然风占主导的隧道下降趋势较缓。4)川西高原隧道衬砌防冻设计宜结合围岩冻胀敏感性,考虑以冻结指数180 ℃·d为临界值较为合理,两侧水沟保温设防长度可按月平均气温0 ℃考虑;考虑到冻结指数大于180 ℃·d且月平均气温低于0 ℃的衬砌段落会经受短时频繁冻融循环作用的影响,建议采取必要措施改善混凝土耐久性指标,确保隧道衬砌结构的长期稳定性。

关键词: 高海拔隧道, 纵向温度场, 抗防冻设计, 现场监测, 数值模拟, 冻结指数, 冻结深度

Abstract:

The authors investigate the longitudinal temperature characteristics and anti-freezing design methods for a highway tunnel in the western Sichuan plateau, China, through field temperature measurements and numerical simulations conducted during the operational period. The findings are as follows: (1) The longitudinal temperature in short tunnels in the western Sichuan plateau shows negative temperature penetration in winter, while long and extra-long tunnels exhibit weakly symmetric and asymmetric temperature distributions. (2) The temperature distribution at the tunnel portal and the occurrence of negative temperatures inside the tunnel are influenced by the surrounding environment in winter, particularly the terrain features and the height differences at both tunnel ends. (3) The freezing index and the annual number of freezing days at the tunnel portal decrease with increasing distance from the portal. This decrease is slower in tunnels where one-way natural wind prevails. (4) The antifreezing design of tunnel lining structures in the western Sichuan plateau should be based on the frost-heave sensitivity of the surrounding rock. A freezing index of 180 ℃·d is recommended as the critical value. The insulation length for the ditches on both sides of the tunnel can be determined by the monthly average zero-degree temperature. For lining sections with a freezing index exceeding 180 ℃·d and a monthly average temperature below 0 , short-term freeze-thaw cycles frequently occur. Thus, the concrete durability index should be enhanced to ensure the long-term stability of the tunnel lining structure.

Key words:  , high-altitude tunnel, longitudinal temperature field, anti-freezing design, on-site monitoring, numerical simulation, freezing index, freezing depth