近年日本的隧道施工与抗震设计

根据日本国家TC28委员会提交的一份当前日本地下工程施工技术报告,介绍了当前盾构工法、NATM工法在日本城市隧道施工中的应用。同时还介绍1995年阪神大地震以后,在日本隧道结构中的抗震设计。     

利用ABAQUS模拟NATM隧道施工过程

在分析了NATM(新奥法)施工理念的基础上,详细地说明了隧道施工中的2个关键问题：隧道开挖后洞周应力的计算和隧道的开挖施工过程。然后在此基础上,利用大型非线性有限元软件ABAQUS对隧道的施工过程进行显示模拟,从计算得到的结果可以看出,利用有限元方法可以非常清晰直观地模拟隧道的施工过程,并能计算得到相应的应力、位移等计算结果,为设计隧道和施工提供了比较合理的理论支持。     

Layout design of rockbolts for natural ground reinforcement

The present study addresses a layout design of rockbolts for reinforcing natural ground structures applying a special optimization method, called multiphase layout optimization. Rockbolts are used to tighten loosed natural ground, and the layout of rockbolts are determined without sufficient information about the physical properties of the ground materials. Because of this uncertainty, unexpected deformation often occurs at the excavation surface of natural ground. In that case, it is requested to determine an effective layout of the additional rockbolts promptly with respect to the actual deformation at the construction site. However, it is not easy to determine the optimal layout because of its complexity, and consequently, it has no choice but to determine the layout in an empirical way. This study introduces a numerical approach to determine an optimal layout of rockbolts with respect to arbitrarily possible deformation of natural ground. The objective is to maximize the stiffness of the overall ground structure reinforced with rockbolts. For optimization, a gradient‐based optimization scheme is applied because of its numerical efficiency. It was verified from a series of numerical examples that this method has great potential to improve the stiffness of the overall ground structure and shows a certain applicability to a practical design. Copyright © 2013 John Wiley & Sons, Ltd.     

大跨度洞室开挖施工方案研究

针对某工程隧洞进口闸室段开挖跨度大,上覆岩体薄,围岩为V类的具体情况,本文以减小开挖断面跨度以及新奥法施工方法的基本原理为出发点,对该隧洞进口闸室段的两种开挖方案进行了分析研究。用有限元方法得到了洞室外围岩的位移场、应力场分布。比较这两种方案,最终得出了在围岩稳定以及支护结构稳定情况下较为理想的开挖与支护方案。      

高应力破裂岩体条件下锚网支护研究

通过研究传统新奥法充分利用和调动巷道围岩强度及其自身承载能力,依靠围岩支护共同作用原理来维护围岩的稳定性。对锚网支护作用机理进行研究,建立预应力锚杆的力学模型,发现高强预应力锚杆的锚固力与围岩性质、锚固方式、锚杆杆体和围岩应力等因素有关;同时分析了锚网支护与围岩共同作用机理,并应用FLAC对锚网支护机理进行研究,发现锚网支护与围岩形成压缩拱,依靠压缩拱来抵抗围岩应力,进而维护巷道围岩的稳定。通过在小官庄铁矿进行试验,在小官庄铁矿41联巷采用高强预应力锚网支护,取消喷射混凝土,巷道围岩变形量比较小,锚网支护能够维护高应力破裂岩体围岩的稳定,在同类矿山中具有推广应用价值。     

偏压小间距公路隧道施工的三维数值模拟

以云南平年隧道为工程背景,采用MARC三维非线性有限元法程序,对新奥法修建的偏压、错台、浅埋小间距隧道模拟了先行隧道不同超前距离情况下的动态施工过程。掌子面距离的变化对洞室的横向位移的影响大于竖向位移,且对于左洞更为显著;随着左右洞掌子面距离的增大,洞周位移、中间岩柱位移均减小,但部分范围内地表沉降值有所增大,局部区域受力、变形恶化。     

Unsupported advance length in tunnels constructed using New Austrian Tunnelling Method and ground surface settlement

Tunnels constructed using New Austrian Tunnelling Method (NATM) are always based on certain round (unsupported) advance lengths, after which, the temporary lining is placed. The settlement of the ground surface resulting from such construction is of high significance in design and practice. The existing data in this respect, however, is scarce. It is the aim of this paper to propose a semi‐analytical procedure based on three‐dimensional finite element analyses to predict the maximum surface settlement of the ground in NATM tunnels under different combinations of tunnel diameter, overburden depth, round length and soil and lining properties. The comparison of the results with three case histories of real tunnels reveals reasonable accuracy of the present solution. Copyright © 2012 John Wiley & Sons, Ltd.     

西安南五台隧道新奥法设计施工

结合西安南五台隧道(第五标段)的开挖、初期支护、现场量测及二次衬砌施工的工程实例，介绍了新奥法在隧道设计施工中的应用。     

我国隧道及地下工程的新进展

简述了我国隧道及地下工程的发展,介绍了当前隧道及地下工程的施工方法、辅助工法,并提出了施工中应注意的有关重要问题。     

Influence of shotcrete composition on load‐level estimation in NATM‐tunnel shells: Micromechanics‐based sensitivity analyses

Displacement measurement‐based estimations of loads and utilization degrees in shotcrete tunnel shells as part of the New Austrian Tunneling Method (NATM), have become standard tools in tunnel practice; their quality, however, may crucially depend on the knowledge of the actual shotcrete composition after spraying. To shed light on this issue, we here determine, based on experimentally validated micromechanical representations of shotcrete, the hydration degree‐dependent elastic, creep, and strength properties of different shotcretes, characterized by water cement ratios (w/c) between 0.4 and 0.6, aggregate cement ratios (a/c) between 3.5 and 5, and Young's modulus of aggregates (E_agg) between 40 and 80 GPa. These properties are fed into a structural shell model of the Sieberg tunnel, and this model is subjected to displacement fields approximated from daily displacement measurements at five selected points along the shell's inner surface. Resulting stresses and forces in the tunnel shell allow for analyzing the influence of shotcrete composition on load‐level estimation in NATM tunnel shells: The magnitudes of circumferential and longitudinal normal forces increase significantly with decreasing w/c, while a/c and E_agg have the inverse and relatively minor effect. The utilization degree is virtually insensitive to changes in w/c(especially at early ages), and only slightly decreases with decreasing a/c and E_agg. The location of maximum loading is unaffected by the shotcrete composition underlying the analysis. Conclusively, location and magnitude of maximum utilization degrees are very robust estimates (not affected by limited knowledge on the shotcrete composition), whereas realistic estimation of stresses and forces does require more accurate consideration of shotcrete composition. Copyright © 2011 John Wiley & Sons, Ltd.