分形截距对应力波能耗影响规律的试验研究

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摘要分别进行粗糙断裂面的扫描试验和节理花岗岩的冲击动力学试验，探讨节理面的几何构型特征及其对应力波能耗的影响规律，建立当分形维数满足条件2.0≤D≤2.2时分形截距与应力波穿越节理时截距贡献能耗比之间的定量关系。研究结果表明，当分形维数在区间2.0≤D≤2.2时，分形维数对总能耗比的贡献仍然占绝对的主导地位，但此区间内分形维数对总能耗比贡献是一常量，总能耗比的增量由分形截距决定。节理岩石的截距贡献能耗比随分形截距的增大而减小，两者间呈非线性关系；机制分析显示，分形截距大，则对应剪切刚度大，在相同的冲击荷载条件下，剪切位移则相应较小，冲击过程所做功则较小，耗散的应力波能量也相应越小。从微观角度看，节理岩石的分形截距大，冲击加载工程中，发生微小塑性变形、断键、分子间撞击的几率将大大降低，因而耗散的应力波能量也越小。

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关键词 ：岩石力学, 应力波, 截距贡献能耗比, 分形截距, 节理岩石

Abstract：Scanning experiment of rough fracture and impacting dynamics test of jointed granite is respectively conducted in order to investigate influential rule of geometrical characteristic of joint surface on energy dissipation of stress wave and establish quantitative relationship between fractal intercept and energy dissipation ratio contributed by intercept of stress wave across joint on the condition of fractal dimension 2.0≤D≤2.2. It is shown that contribution towards total energy dissipation ratio from fractal dimension is still primary；but in the interval，its contribution towards total energy dissipation ratio is constant and increment of total energy dissipation ratio is decided by fractal intercept. Energy dissipation ratio which is contributed by intercept of jointed rock decreases nonlinearly with the increasing of fractal intercept. By mechanism analysis，it is indicated that on the condition of similar impact loading，smaller shear displacement leads to less work and corresponding lower energy dissipation of stress wave because larger fractal intercept corresponds to higher shear stiffness. From microscopic view，during impacting loading，sample with larger fractal intercept brings lower probability of tiny plastic strain，crystal cracking，mutual impingement among molecule，so energy of stress wave is less dissipated.

Key words： rock mechanics stress wave energy dissipation ratio contributed by intercept fractal intercept jointed rock

收稿日期: 2010-08-03

引用本文:

李业学1，2，彭琦3，朱建波3，刘建锋2. 分形截距对应力波能耗影响规律的试验研究[J]. 岩石力学与工程学报, 2011, 30(S2): 3982-3988.
LI Yexue1，2，PENG Qi 3，ZHU Jianbo3，LIU Jianfeng2. EXPERIMENTAL STUDY OF INFLUENTIAL RULE OF FRACTAL INTERCEPT ON ENERGY DISSIPATION OF STRESS WAVE. , 2011, 30(S2): 3982-3988.

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http://www.rockmech.org/CN/Y2011/V30/IS2/3982

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