浅覆盾构隧道环向挤出破坏上限有限元分析

针对软弱地层浅覆盾构隧道未支护段地层挤出破坏问题,基于极限分析上限有限元法,结合节点可动的刚体平动运动单元,建立了隧道环向开挖面挤出破坏的非线性规划模型并编程求解。通过参数敏感性分析,研究了地层参数、隧道埋深等因素与临界加载系数间的曲线关系,并探讨了刚性块体体系破坏模式的演化特征。结果表明,临界加载系数σT/c随φ、γD/c和C/D的增加而增加;φ对地层破坏模式影响显著,φ值越大,滑动面与竖向夹角越大;刚体平动运动单元法能使单元间的速度间断线自动调整至最佳方位,利用较少的单元可获得较好的上限解,并清晰的反映出土层破坏形态。

考虑纵坡的隧道掌子面稳定性上限有限元分析

针对存在纵坡条件下的隧道掌子面稳定性和失稳破坏问题,采用高阶塑性变形单元上限有限元法开展多参数影响正交计算分析,获得临界加载系数Ncr上限解图表与拟合公式及以耗散能密度表征的破坏模式规律。研究表明:①纵向坡度对掌子面稳定性有不可忽视的影响,上坡(坡度角θ=10°)方向对应Ncr值小于平坡条件下4.5%~23.1%,内摩擦角φ越大相对降低量越大;②Ncr随φ增加而逐渐增大,φ较大时需考虑剪胀效应对稳定性的影响;③失稳临界状态发生时隧道掌子面由两条主要剪切带、三角形刚性运动楔形区和前方塑性区组成,上坡条件下(θ=10°)剪切带和塑性区旋转,剪切带与塑性区路径、范围减小,从而掌子面稳定性变差。

Analytical and experimental bearing capacities of system scaffolds

We investigated the structural behavior and bearing capacity of system scaffolds.The research showed that the critical load of a system scaffold structure without diagonal braces is similar to that of a door-shaped steel scaffold structure.Joint stiffness between vertical props in system scaffolds can be defined based on a comparison between analytical and experimental results.When the number of scaffold stories increases,the critical loads of system scaffolds decrease.Diagonal braces markedly enhance the critical load of system scaffolds.The coupling joint position between vertical props should be kept away from story-to-story joints to prevent a reduction in critical loads.The critical load of a system scaffold decreases as the quantity of extended vertical props at the bottom of the structure increases.A large Christmas tree set up by system scaffolds under various loads was used as an example for analysis and to check the design of system scaffolds.