Benign Adjusting Effects of Long Tunnel on Environment and Slope Hazards:taking Erlang Mountain Tunnel as an example

The 21st century shall be a century of accelerated development of tunnel construction in China. But until now, what have been frequently stated in reports about influence of tunnels on environment are basically negative. In fact, this is not true. Tunnels, especially those extend across sensitive areas do exert some positive functions on improving environment and preventing local slope hazards. These positive effects, being new phenomena, are found and put forward by the authors after a series of careful observations have been carried out and in-depth analysis performed the first time. Meanwhile, it is a positive evaluation that the authors made upon tunnels. Many important phenomena and data are cited as evidence and their causative factors are analyzed in this paper as well.

Analysis of the Relationship between the Number of Traffic Accidents and the Traffic Flow &Section Location in Extra Long Tunnel

In order to study the influence of the traffic characteristics on traffic accidents in extra long tunnel, the main measurement indicators of traffic flow during the time of traffic accidents are matched with the accident information to form a data set of the number of traffic accidents and the hourly traffic flow of the accident. Vehicle ratio and the number of accidents are mainly used as the characteristic indicators of traffic flow. At the same time, the longitudinal distribution law of the average speed of traffic flow and the number of traffic accidents in the extra long tunnel is studied. Based on the superposition principle, the extra long tunnel is divided into 5 traffic safety zones. This paper analyzes the distribution of time, morphology, cause of accident, and other characteristics in different traffic safety zones, finding that the shape of traffic accidents in extra long tunnel is mainly rear-end collisions. Improper operation and illegal lane changes are the main causes of accidents.

Allowance of Lateral Breakthrough Error for Super Long Tunnels from 20km to 50km

Up to now there is no specification about the allowance of lateral breakthrough error for super long tunnel from 20 km to 50 km. On the basis of the design of GPS networks located outside and inside tunnel traverse network, we propose a method for calculating the influence value caused by control surveying errors. Through a lot of simulative calculations and combination with piercing practice of super tunnels in Wan Jiazai Project, Shanxi province, we present an allowance table of lateral breakthrough error for super long tunnels from 20 km to 50 km.

LONG AND DEEP DIVERSION TUNNELS OF 1^(ST) STAGE PROJECT IN WEST ROUTE OF SOUTH-NORTH WATER TRANSFER PROJECT

West Route of South-North Water Transfer Project,situated in southeastern Qinghai-Tibet Plateau,is a giant project,which will deliver 17 billion m3 of water from the main stream and tributaries upstream of the Yangtze River to the upper reaches of the Yellow River. It is to be constructed in 3 stages, of which the 1st stage project includes delivering 4 billion m3 of water by gravity from two tributaries of Yalong River and three tributaries of Dadu River. The project consists of 5 dams,7 tunnels and a channel in series,with the dam height of 63～123 m and water transfer length of 260.3 km,of which the tunnels measure 244.1 km. The special climatic,environmental and geologic conditions make the project much more complicated in construction,especially 3 tunnels with the length longer than 50 km each create challenges to the technical requirements of engineering survey,design and construction.

Predictive analysis of stress regime and possible squeezing deformation for super-long water conveyance tunnels in Pakistan

The prediction of the stress field of deep-buried tunnels is a fundamental problem for scientists and engineers. In this study, the authors put forward a systematic solution for this problem. Databases from the World Stress Map and the Crustal Stress of China, and previous research findings can offer prediction of stress orientations in an engineering area. At the same time, the Andersonian theory can be used to analyze the possible stress orientation of a region. With limited in-situ stress measurements, the Hoek–Brown Criterion can be used to estimate the strength of rock mass in an area of interest by utilizing the geotechnical investigation data, and the modified Sheorey's model can subsequently be employed to predict the areas' stress profile, without stress data, by taking the existing in-situ stress measurements as input parameters. In this paper, a case study was used to demonstrate the application of this systematic solution. The planned Kohala hydropower plant is located on the western edge of Qinghai–Tibet Plateau.Three hydro-fracturing stress measurement campaigns indicated that the stress state of the area is SH>-Sh> SVor SH> SV> Sh. The measured orientation of SHis NEE(N70.3°–89°E), and the regional orientation of SHfrom WSM is NE, which implies that the stress orientation of shallow crust may be affected by landforms. The modified Sheorey model was utilized to predict the stress profile along the water sewage tunnel for the plant. Prediction results show that the maximum and minimum horizontal principal stresses of the points with the greatest burial depth were up to 56.70 and 40.14 MPa, respectively, and the stresses of areas with a burial depth of greater than 500 m were higher. Based on the predicted stress data, large deformations of the rock mass surrounding water conveyance tunnels were analyzed. Results showed that the large deformations will occur when the burial depth exceeds 300 m. When the burial depth is beyond 800 m, serious squeezing deformations will occur in the surrounding rock masses, thus requiring more attention in the design and construction. Based on the application efficiency in this case study, this prediction method proposed in this paper functions accurately.

截至2023年底中国10km以上特长公路隧道统计与分析

在隧道行业相关单位的大力支持及既有统计数据的基础上,对截至2023年底中国已建成运营、正在建设、规划设计的共计74座长度10 km以上的特长公路隧道进行统计,其中,已建成运营特长公路隧道25座,正在建设特长公路隧道31座,规划设计特长公路隧道18座。从隧道长度、所在省份、公路等级、地理位置、技术标准、施工工法、设计与施工单位等方面,对中国已建成运营、正在建设、规划设计的长度10 km以上的特长公路隧道建设情况进行分析,其中:长度在10~14.9 km的隧道共62座,长度在15~19.9 km的隧道共10座,长度大于20 km的隧道共2座;隧道主要集中在中国西南部,约占63%,四川省最多,其次是云南省;高速公路隧道达65座,占比约为88%;山岭公路隧道68座,水下隧道6座;隧道技术标准以双向4车道为主;隧道施工工法以钻爆法为主,近些年出现了TBM+钻爆组合工法;隧道设计单位主要有31家;隧道施工单位主要有52家。

特长水下公路盾构隧道结构防火保护策略及关键参数研究

特长水下公路盾构隧道普遍设置独立排烟道进行顶部集中排烟。现有隧道工程防火技术“护顶不护墙”,顶部设有排烟道时,顶部防火保护施加在烟道板上,而烟道层拱顶管片及车道层两侧管片不施加防火保护,存在安全隐患。根据隧道结构实际可能受到的火灾高温作用,结合管片、烟道板结构相对重要性,提出了新的车道层侧墙管片、烟道层拱顶管片、烟道板结构防火保护策略,即车道层所有结构表面采用RABT火灾升温曲线,烟道层所有结构表面采用基于CFD模拟的火灾升温曲线,耐火极限均不小于2.0h,管片耐火极限由管片混凝土表面及距表面25mm处温度判定,烟道板耐火极限由烟道板的极限弯曲变形量和极限弯曲变形速率判定。基于所提出的防火保护策略,开展数值模拟及耐火试验研究,确定了防火保护技术参数。结果表明:车道层侧墙管片防火保护层等效热阻应不小于0.10℃·m~2/W;烟道层拱顶管片防火保护层等效热阻在排烟口处不小于0.10℃·m~2/W,且随距排烟口距离的增大逐渐减小,距离排烟口16m处减小为零;隧道侧墙常用装饰材料搪瓷钢板在火灾过程中易发生变形而脱落;无防火保护烟道板耐火极限大于2.0h,掺加PP纤维、钢纤维可提升烟道板的耐火性能。

截至2023年底中国铁路隧道情况统计及2023年新开通重点项目隧道情况介绍

对截至2023年底中国铁路隧道、高速铁路隧道、特长铁路隧道情况进行统计。结果显示,截至2023年底,中国铁路营业里程达到15.9万km,其中,投入运营的铁路隧道18 573座,总长23 508 km;中国已投入运营的高速铁路总长超过4.5万km,共建成高速铁路隧道4 561座,总长7 735 km,其中,长度大于10 km的特长隧道115座,长约1 471 km;中国投入运营的特长铁路隧道共286座,长约3 869 km,其中,长度20 km以上特长铁路隧道13座,长约312 km。最后,对2023年新开通的重点项目贵南铁路隧道、成兰铁路成都至川主寺段隧道的概况及特点进行介绍,并总结其技术经验;同时对广汕铁路隧道、金甬铁路隧道、南崇铁路留村大直径盾构隧道、和邢铁路隧道的技术应用进行总结。贵南铁路通过空间选线、创新岩溶处理手段,以及加强运营期间的排水措施,有效降低了岩溶发育地区高速铁路运营的安全风险;成兰铁路设计充分贯彻“减灾选线”的理念,大规模减小了运营期间的安全风险,另外创新了隧道通过活动断裂带的处理技术。随着铁路建设向西部地区转移,隧道建设将面临埋深更大、地应力更高、地质构造更加复杂、高海拔地区缺氧等系列建设问题,仍需要各位同仁共同攻坚克难,不断创新隧道修建技术。

长隧道路段货车限道措施的数值模拟——以甬莞高速角洞岙隧道路段为例

基于实际交通录像分析得出的边界条件和货车影响距离,提出了含有长隧道的双车道元胞自动机交通流模型.模拟结果与实际交通数据对比,吻合较好,表明模型能够准确反映实际交通流的特性.数值模拟显示,货车的存在增加了隧道路段交通拥堵的发生概率,且这种影响随货车比增加而增强.为降低货车对隧道交通的影响,提出了货车限道措施,并开展数值模拟,结果表明,货车限道措施能显著提升左车道的车速,在大进车率时也能提升右车道的车速,在高货车比时流量提升效果显著.

双洞双弯长陡坡导流隧洞明满交替流水力特性研究

双洞双弯长陡坡导流隧洞内,由于弯道螺旋流的影响,引起明满交替流流量区间增大,加之明满交替流的水力特性为非恒定流,导致洞内明满交替流的界定与导流设计流量的确定难度大幅增加。针对此问题,基于三维数学模型模拟,阐述洞内流态由明流经明满交替流转变为有压流的过程;提出携气有压流归为有压流范畴且作为明满交替流与有压流的分界流态;明确明满交替流的水力特征:上游相对作用水头为1.61~2.40;流态为自由面不连续且随时空变化;同一流量下库水位波动较大,内侧隧洞分流比随之呈正向变化,而外侧隧洞分流比则呈反向变化;沿程压力特性呈现有压流特性与明流特性交替变化,作用压力紊动性强。

椿木山特长隧道施工风险评估及精细化施工方案研究

为提高特长隧道的施工效率,降低施工成本,本文依托椿木山特长隧道开展风险评估及精细化施工技术研究。分析了该隧道施工的重难点,结合各种风险源对隧道风险进行评估。基于隧道施工工艺,从人力安排和施工工时多角度分析了“七台套”大机作业的实施成效。并根据多种因素对比各种竖井布置方案的经济效益。结果表明:(1)隧道风险评估仅考虑单一风险忽视作业风险会使得风险出现不可控现象,应从地层、水文及技术水平等多角度分析;(2)与传统钻爆法施工相比,大机作业施工在降低人力成本和提高施工效率方面都具有明显优势;(3)竖井布置方案应在满足正常运营通风条件下选择埋深短、施工方便、经济效益好的方案。本文的研究成果为椿木山隧道施工提供了技术支持,也可为类似隧道提供技术参考,有助于大机作业推广。

棠棣岭隧道通风系统设计及施工设备选型优化

良好的通风设计是保证长大隧道施工安全的前提,需要做好隧道通风方案的设计和优化以及施工设备选择。依托棠棣岭隧道实际施工通风设计情况,介绍了工程概况和通风方案的确定;根据隧道施工中的通风特点计算出各工作面的所需风压和风量,并考虑了风管摩擦阻力作用和弯道处的风压损失;根据计算结果研究了隧道通风合理的设备选型以及相应的优化改进措施。结果表明:配置的压入式轴流风机和射流风机可以满足棠棣岭隧道施工通风的需要,合适的风机和风管选型可以达到需风量要求并有效降低风阻损失。

测量网形对特长隧道贯通误差的影响

控制测量精度直接影响隧道工程建设质量,是决定隧道工程能否精确贯通的关键因素。控制测量精度受多种因素影响,其中测量网形则是其精度影响的关键因素之一。以某特长铁路隧道工程为例,根据现阶段隧道工程测量技术与经验,分别设计若干种洞内、外控制测量网形方案,采用数据模拟的方法,分别计算各方案的隧道横向贯通误差影响值,结合实际工作量与隧道工程贯通限差要求,分析各控制网在特长隧道工程控制测量中的应用情况,为特长隧道控制测量工作的开展提供参考。

长距离地铁隧道自动化监测技术工程实践与应用

随着地铁保护工程的监测范围越来越长,工况越来越复杂,难度越来越高。长距离(>400 m)的监测范围,多台(>3)仪器串联的项目也屡见不鲜,对自动化监测技术的要求也越来越高。通过某项目涉及杭州地铁1号线保护监测的工程实践,阐述了5+2台测量机器人串联系统的监测技术实施及数据分析,证明了多台测量机器人串联自动化监测技术的准确性及可靠性,为后续同类型项目提供借鉴。

双洞八车道特大跨度隧道Ⅴ级石质围岩开挖工法

为减小双洞八车道特大跨度隧道洞口Ⅴ级石质围岩后行导坑爆破对已完成支护结构的不利影响,该文以平潭牛寨山隧道工程为例,针对原设计双侧壁导坑法在后行的临近导坑爆破时,易将原先已施工完成的临时钢支撑震塌,提出取消临时横向支撑的变更方案1,以及带竖向支撑的上下台阶法(变更方案2),再利用有限元法计算,模拟3种不同开挖工法对隧道变形及受力的影响。计算结果表明:3种方案引起的拱顶沉降相差较小,最大相差约11.8%;变更方案2引起的围岩应力最大,但变更方案2同时取消了左右侧壁导坑的横向支撑以及左右侧壁导坑下台阶的竖向支撑,大大简化了施工工序。最后,结合监测数据进行分析,隧道结构安全稳定,变更方案2不仅合理可靠,而且加快了施工进度,节约了造价。

长锚杆/锚索改善深埋大跨度隧道初支结构受力试验研究

针对深埋大跨度软岩隧道拱脚及拱顶处初支开裂、钢架变形过大问题,提出了局部增设长锚杆或锚索的支护技术,以实现对该类隧道初支结构受力的调节改善。基于课题组自主研发的隧道结构性能测试平台,对比分析了同等围岩荷载作用下系统锚杆支护与多类长锚杆/锚索支护方案的初期支护结构受力变形特征,研究了不同环向间距与布设范围的长锚杆/锚索支护效果。研究结果表明:(1)常规支护时,大跨度隧道初期支护整体呈压扁趋势,拱顶内侧与拱脚外侧承受结构最大弯矩而最先开裂,仰拱内侧拉裂后模型加速变形进而引起结构整体失稳破坏;(2)4种增设长锚杆或锚索支护方案下,初支拱顶处结构安全系数分别为常规支护体系的4.59,2.12,1.96,1.80倍,拱脚处结构安全系数分别为常规支护的5.23,2.80,2.34,2.37倍;(3)在拱部120°范围以2 m环向间距布设长锚杆对初支结构内力改善效果最佳,支护点轴向强拉力产生的局部负弯矩组合效应抵消了拱顶处较大正弯矩;(4)不同位置长锚杆/锚索支护力整体呈从拱顶处至拱肩侧先减小后增大的规律。

长距离大埋深盾构隧道施工高效出渣施工技术

长距离、大埋深盾构隧道施工过程中,高效的出渣方式可以提高隧道施工效率,保障施工进度。以珠三角水资源配置工程为背景,提出了与盾构机配套的连续皮带机+垂直提升皮带机组成的出渣方式,并对其工艺流程、技术原理和操作要点进行了详细阐述。应用实践表明:相较于常规出渣方式,该技术可以有效提高盾构掘进效率,由平均6环/d提高至平均12环/d,掘进效率提高1倍左右,通过“水平+垂直”皮带机与盾构机联机的智能化控制及管理系统,可以及时预警,保障设备运行安全,具有较高的经济效益与安全效益,可为类似工程的出渣施工提供一定的参考。

高瓦斯特长高铁隧道通风方案设计及监测分析

成都至自贡高铁白云山隧道全长13340 m,为特长高瓦斯隧道,多工区、多阶段施工通风问题严重制约着隧道运营施工与人员安全。通过工作面最大通风量、最大供风量及沿程风压损失对不同工区施工阶段进行通风计算,设计单工区通风方案及隧道总体贯通顺序,并采用水气分离方法处理地下水及自动安全监控系统实时监测隧道瓦斯浓度。分析表明:施工的大部分时间内,2#~6#斜井的瓦斯浓度均偏低,说明合理的通风方案及工区贯通顺序可以有效降低隧道瓦斯浓度;采用水气分离方法对地下水进行处理,将地下水和瓦斯分别排出,可进一步降低隧道内瓦斯浓度;监控系统对2#、3#和6#斜井出现的瓦斯排放异常情况及时报警提示并断电保护,保证了隧道施工进度及人员安全。针对特长高瓦斯隧道多工区、多阶段施工通风,基于隧道通风方案、贯通顺序、水气分离处理及瓦斯监测等方面建立一套完整的通风监测设计方法,为类似工程提供指导。