基于灰色理论的雪山梁隧道施工过程渗漏水水源识别研究

为了解决黄龙景区雪山梁隧道开挖过程中的涌水水源识别问题,结合黄龙景区雪山梁隧道的相关施工资料,依据已有的地质资料和涌突水预测,通过水分析化学实验,采用灰色理论计算方法研究不同水系之间的关联度;而后针对单一水源和混合水源分别进行试验和分析,得出雪山梁隧道出口段内渗漏水来源最可能为大气降水,关联度较高的还有淘金沟上游水系和隧道出口处水系;最后进行比对,得出隧道渗漏水主要来源是大气降水和淘金沟上游水体的结论,并依据现场资料及实地踏勘,验证了灰色理论分析结果的可靠性。     

隧道工程风险评估及控制措施

阐述了新建隧道工程风险评估的意义、风险评估的程序、风险评估方法的选择及具体步骤,提出了评估结论及规避该隧道工程风险的具体控制措施。     

象山特长隧道施工风险分析

在隧道宏观工程背景分析的基础上,对龙厦铁路象山隧道施工风险进行了详细的分析,指出了象山隧道施工面临突水突泥、地表失水、塌方、软岩变形、岩爆、瓦斯爆炸、高地温、有轨运输溜车等八项典型施工风险,对长大隧道施工风险控制具有指导意义。     

浅谈隧道工程塌方的预防及处理方法

在施工中要采取有效的措施来预防塌方的发生，当在施工中不可避免地出现塌方的时候，能够提出合理的处理方法和步骤。介绍了隧道工程预防塌方的施工措施及隧道发生塌方后的处理方法。     

八盘岭隧道新型防排水材料的应用

通过八盘岭隧道防排水系统与传统防排水系统的比较,介绍了新型排水材料在隧道中的应用,并分析了新型排水材料的社会和经济效益.     

大跨隧道双侧壁导坑法施工力学行为研究

结合某城市道路,对大跨隧道双侧壁导坑法施工进行了弹塑性数值模拟,探明了施工过程中国岩深部位移、围岩稳定性,以及衬砌结构的受力特性.研究表明,围岩等级较高,围岩条件差的情况下,采用双侧壁导坑法在技术上是可行的,并且能够很好的控制施工过程中围岩的稳定.     

新庄隧道冒顶处理方法探析

结合新庄隧道塌方,分析了隧道塌方的原因,介绍了隧道塌方冒顶的处理方法。     

长沙南湖路湘江隧道通风方案初探

基于我国的经济技术发展现状及趋势,借鉴公路隧道通风的相关设计理论、原则以及国内已建类似工程的经验,针对长沙市南湖路湘江隧道的工程特点,探讨并分析影响该隧道通风方案确立的因素,提出既满足隧道内的行车安全和洞外环保要求,又有利于降低工程造价和减少运营费用的通风方案。     

Mechanism of Tunnel Water Inflow Caused by Bending Failure of a Waterproof Dike Based on a Circular Thin Plate Mechanical Model北大核心CSCD

Water bursts during tunnel construction endanger construction, and it is therefore necessary to reserve a waterproof dike with the required thickness to avoid water bursts and to take reinforcement of the dike and treatment of the structure liable to trigger a water burst. Using the water burst at K5+398 of the Mingyueshan tunnel of the Shanghai-Chengdu expressway as an example, and considering the type of tunnel section and the upright mudstone of the dike, the waterproof dike at the work face is simplified as a round thin plate. A formula for the calculation of a minimum safety thickness for the critical waterproof dike is deduced by analyzing the force applied on the water-proof dike, and the minimum safety thickness for the water burst section at K5+398 of the Mingyueshan tunnel is cal-culated. The numerical simulation analysis demonstrates the critical thickness of waterproof dike at K5+398 of the Mingyueshan tunnel is 1.4-1.55 m, and the calculated water inflow and water burst basically agree with the actual condition. © 2018, Editorial Office of "Modern Tunnelling Technology". All right reserved.     

Analysis on the Characteristics and Development Trends of the Support Technology of High Ground Stress Tunnels in China北大核心CSCD

Combining the present situation and development trend of different tunnel support technologies at home and abroad, this paper analyzes the problems of rockburst in hard rock tunnels and large deformation in soft rock tunnels caused by high ground stress. It is concluded that: 1) regarding the rockburst problem, the current support technology is mainly influenced by the rock burst mechanism which is dominated by static factors, and so the used support components are generally of smaller deformation performance and "passive support" properties; 2) as the rockburst is the result of dynamic-static stress coupling, and only the anchor bolt has the "active support" attribute in the current "shotcrete+anchor bolt+wire net" support system, so the best support system should have the two functions of active support and energy release in terms of the rockburst problem, and the key focus of the research and development is anchorage members; 3) there are three main support types for large deformation in soft rock tunnels, e.g. the heavy support, layered support and yielding support. Among them, the heavy support system in underground cavern with large deformation is easy to induce excessive surrounding rock pressure, and so the applicable conditions are limited. The layered support system is still not the best choice due to its immature theoretical study, difficult determination of the thickness value and the installation time of each support layer and the interference to construction progress. With the characteristics of timely support and yielding while supporting, the yielding support system can give full play to the performance values of surrounding rocks and supporting materials, and make both of them reach the optimal state, so it is the best choice for supporting the soft rock tunnels with large deformations. © 2018, Editorial Office of "Modern Tunnelling Technology". All right reserved.