节理岩体等效流变损伤模型及其在卸载边坡中的应用

Equivalent rheological damage model of jointed rock and its application to unloading slope

重大建设项目对施工过程中岩土体稳定性提出了更高的要求,常以一种动态设计施工模式来应对工程体的各类突发状况与病害。流变损伤模型既能反映岩土体在施工过程中变形的时效发展,又能反映其力学性质的时效劣化,继而能较准确地掌握工程体动态稳定性。基于以上考虑,为体现卸载边坡工程在卸载回弹阶段的瞬时塑性特征和时效演化阶段的黏塑性特征,因此,在流变模型中引入加载塑性元件和黏塑性元件,建立了复合黏弹塑(弹-黏-黏弹-黏塑-塑)模型,室内岩石压缩(卸载)蠕变试验证明了该流变模型的合理性,并对其参数进行辨识。在此基础上,从几何研究方法出发,引入反映节理分布的初始损伤张量及一种等效的依据黏塑性偏应变推导出的损伤演化方程,最终建立了一种新型的节理岩体等效流变损伤模型。将此模型用于川东红层某软硬岩互层型路堑边坡的卸载分析,结果表明:随不同的开挖阶段,易损部位(软岩集中段、软岩深埋段、软硬交接硬岩段)在瞬时卸载回弹阶段的塑性损伤和时效演化阶段的黏塑性损伤逐渐积累,边坡浅表部逐渐出现卸载损伤(松弛)带,在损伤累积中边坡各部位蠕变速率呈不同程度的增长。计算结果较好地反映了边坡变形、损伤发展与动态稳定性特征,其研究结果对于指导支护时机及相应的信息化施工具有一定的意义。

Major engineering projects put forward higher requirements for rock stability in the process of construction, and a dynamic mode of engineering design is usually applied to deal with various kinds of emergencies and diseases. Rheological damage model can simulate both the time-dependent deformation of rock mass and the time-dependent degradation of mechanical properties, which can reflect the dynamic stability of engineering projects. In order to reflect the instantaneous plastic deformation in the unloading-rebound stage of slope as well as the viscoplastic deformation in the time-evolution stage of slope, loading-plastic and viscoplastic components are applied to the rheology model; thus a composite visco-elastoplastic model （elastic-viscous-viscoelastic-viscoplastic-plastic） is established. Results of compression（unloading） creep test proves the rationality of this model;and rheological parameters are recognized. On this basis, damage tensor describes the characteristics of joint geometry, and damage evolution equation based on the viscoplastic partial strain is established; eventually, a new type of equivalent rheological damage model of jointed rock is established. Applying this model to a soft-hard interbedded slope under the cutting（unloading） condition, the results show that instantaneous plastic damage in unloading-rebound stage and viscoplastic damage in time-evolution stage, of the damageable parts （soft rock section, buried section of soft rock, hard rock section of soft-hard handover）, gradually accumulate;the unloading damage areas gradually appear;creep rates of every part gradually increase in varying degrees of growth with the damage accumulating. The reasonable analysis results can reflect the dynamic stability in the process of slope cutting, and guide the intervention time of supporting measures.