法向应力和水压力作用下岩石单裂隙水力耦合模型

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摘要为突出孔隙水压力对裂隙变形及其水力传导性能的影响，以经典的Biot孔隙弹性模型为基础，通过把裂隙视为一系列空隙的联合体，将广义的Biot有效应力系数扩展到岩石裂隙上。模型通过有效应力系数的引进，建立饱和裂隙在法向应力和孔隙水压力共同作用下的非线性本构方程，同时通过裂隙渗流的“立方定理”得到渗流流速与裂隙变形的关系以及裂隙法向应力作用下的水力耦合模型。模型中包含的4个参数均有其物理意义，并且可以通过裂隙力学压缩试验和渗流试验结果确定。与经典的太沙基有效应力原理不同，该模型中Biot有效应力系数是裂隙位移的函数，强调了不同位移状态下水压力作用效果的不同，突出了孔隙水压力与裂隙变形之间的相互影响。最后，针对不同孔隙水压力下裂隙渗流流速随法向应力变化的试验数据，用该模型对试验结果进行预测，初步证实该模型的准确性和适用性。

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关键词 ：岩石力学, 水力耦合, 水压力, 广义Biot系数, 裂隙变形

Abstract：A coupled mechanical-hydraulic model for a single saturated fracture under both normal stress and fluid pressure is proposed based on the classic Biot poroelasticity theory. By taking the fracture as assembling of a set of voids in rock mass，a generalized Biot coefficient is introduced to describe the interaction effect between pore fluid pressure and fracture deformation. Compared with the classic concept of effective stress proposed by Terzaghi，the generalized Biot coefficient in this model is not a constant but a function of fracture deformation，so that the dependency of the effect of fluid pressure on fracture deformation is emphasized. With the help of the generalized Biot coefficient，a nonlinear constitutive equation for a single fracture under both normal stress and fluid pressure is developed. Later，the mechanical deformation of the fracture is related to the fracture hydraulic conductivity through “cubic law”，so that a coupled mechanical-hydraulic model is developed. All the four parameters involved in this model have their physical significances and can be determined through mechanical compression tests and permeability tests. A first validity of the model is made by predicting the variation curve of fracture flowrates versus normal stress under different fluid pressure. Comparison between model prediction and tests data verifies the applicability of the proposed model.

Key words： rock mechanics hydro-mechanical coupling fluid pressure generalized Biot coefficient fracture deformation

收稿日期: 2010-12-30

引用本文:

谢妮1，2，徐礼华1，邵建富2，冯夏庭3. 法向应力和水压力作用下岩石单裂隙水力耦合模型[J]. 岩石力学与工程学报, 2011, 30(S2): 3796-3803.
XIE Ni1，2，XU Lihua1，SHAO Jianfu2，FENG Xiating3. COUPLED HYDRO-MECHANICAL MODELING OF ROCK FRACTURES SUBJECT TO BOTH NORMAL STRESS AND FLUID PRESSURE. , 2011, 30(S2): 3796-3803.

链接本文:

http://www.rockmech.org/CN/Y2011/V30/IS2/3796

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