共查询到18条相似文献,搜索用时 203 毫秒
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无网格伽辽金法应用的参数选择及内部边界处理 总被引:8,自引:0,他引:8
无网格辽金法作为-种新的岩土工程数值计算方法, 该法其只需节点信息的无单元特性, 使其具有计算优势。本文结合固结EFGM刚度矩阵公式, 对不同的计算参数进行计算分析, 找出其影响规律。并采用跳跃函数处理内部边界条件, 计算结果表明, EFGM处理内部场函数不连续是准确的。 相似文献
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提出在基于小变形弹性假定的太沙基一维固结方程解答中采用非线性条件下定义的固结系数,并且进行了计算验证,结果证明在小变形弹性固结方程的解答中采用非线性条件下定义的固结系数可以使计算结果更好地接近实际沉降值。相对于传统太沙基理论,修正后的太沙基固结理论可以用来更准确地计算实际工程中的非线性固结沉降。 相似文献
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无单元Galerkin法大地电磁三维正演模拟 总被引:1,自引:0,他引:1
无单元Galerkin法(EFGM)作为一种相对成熟的无网格方法,避免了网格剖分,其精度高,适用于复杂电导率分布和复杂边界形状的计算。本文将EFGM用于大地电磁三维正演,详述了三维EFGM形函数的构造过程,从大地电磁三维变分问题出发,利用Galerkin法结合高斯积分公式推导了相应的系统矩阵离散表达式,简述了边界条件的加载技术,研究了支持域尺寸对EFGM三维正演计算精度的影响,最后通过数值计算验证了EFGM三维算法的正确性。 相似文献
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为了探究不同固结状态下的饱和软土固结系数的变化规律,在太沙基固结理论的基础上,利用渗透系数和孔隙比的关系、孔隙比和固结应力的关系,分别推导出了在正常固结和超固结状态下固结系数(Cv)随固结应力变化的关系式,将关系式代入Terzaghi方程,进而获得考虑应力历史和固结应力影响的修正Terzaghi一维固结方程;通过室内固结试验和工程应用分析对固结系数关系式和修正的Terzaghi一维固结方程的准确性进行验证.结果表明,对于正常固结的软土,当固结应力小于前期固结应力时,固结系数随应力的增大而增大;当固结应力大于前期固结应力时,固结系数随应力的增大而减小.对于超固结状态的软土,固结系数随应力的增大而增大,最后趋于平缓.当上覆荷载较小时,修正前后的Terzaghi一维固结方程计算结果相近;但当上覆荷载较大时,修正后的Terzaghi一维固结方程计算的固结度明显滞后于修正前的计算结果.前期的应力历史和后期的固结应力对软土固结系数的影响是不容忽视的,修正后的Terzaghi一维固结方程更能真实反映土体的固结性状. 相似文献
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考虑非达西流的弱透水层固结计算 总被引:13,自引:1,他引:12
由于成岩作用的影响,深部弱透水层中的黏性土较为坚硬、致密,在这种黏土层中的孔隙渗流规律有偏离达西定律的现象,而在现有的地面沉降研究中,对深部弱透水层的固结变形计算始终沿用以达西定律为基础的固结方程进行,这显然是与实际情况不相符的。鉴于此,以孔隙渗流为非达西流为基础,对太沙基一维固结方程进行了重新推导,并采用半解析法对非达西流-太沙基一维固结方程进行了求解。分别采用达西流-太沙基固结方程和非达西流-太沙基固结方程对同一固结问题进行了计算,结果表明,考虑非达西流后土层达到某一固结度所需的固结时间较之不考虑非达西流时明显增加了,而且固结时间增长的趋势与实测的增长趋势较为一致。 相似文献
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对于Biot固结方程中的连续性方程形式,不同的研究者存在分歧。在详细分析了Biot推导固结方程的过程后,发现其在推导固结方程时用到的弹性应变能密度函数存在错误。为了得到正确的连续性方程,采用两种思路进行了分析:①通过对土体单元变形的分析,得到了考虑土体颗粒和流体可压缩性的连续性方程;②按照Biot推导固结方程的思路,通过修正推导过程中用到的弹性应变能密度函数得到了连续性方程。上述两种思路得到的连续性方程是等价的,同时将上述连续性方程和其他研究者通过质量守恒得到的连续方程进行了对比,结果是一致的,从而确定了连续性方程的正确形式,并澄清了目前在Biot固结方程中的连续性方程上存在的分歧,所得结论可为固结方程的解析或数值计算提供依据。 相似文献
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层状可压缩岩基三维固结问题的状态空间解 总被引:1,自引:0,他引:1
采用状态空间法求解层状可压缩岩基的三维固结问题。首先从直角坐标系下考虑可压缩性的三维Biot固结问题的控制方程出发,通过Laplace-Fourier变换得到状态空间方程,解此方程并通过Cayley-Hamilton定理,得到单层可压缩岩基三维固结问题的传递矩阵;然后利用传递矩阵法,结合层间连续性条件和边界条件,得到了层状可压缩岩基三维固结问题在积分变换域内的解答;最后应用Laplace-Fourier逆变换技术,得到层状可压缩岩基三维固结问题在物理域内的理论解答。编制了相应的计算程序,进行了数值计算与分析,证明了压缩性对岩基固结问题的影响 相似文献
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Modelling of contaminant transport through landfill liners and natural soil deposits is an important area of research activity in geoenvironmental engineering. Conventional mesh‐based numerical methods depend on mesh/grid size and element connectivity and possess some difficulties when dealing with advection‐dominant transport problems. In the present investigation, an attempt has been made to provide a simple but sufficiently accurate methodology for numerical simulation of the two‐dimensional contaminant transport through the saturated homogeneous porous media and landfill liners using element‐free Galerkin method (EFGM). In the EFGM, an approximate solution is constructed entirely in terms of a set of nodes and no characterization of the interrelationship of the nodes is needed. The EFGM employs moving least‐square approximants to approximate the function and uses the Lagrange multiplier method for imposing essential boundary conditions. The results of the EFGM are validated using experimental results. Analytical and finite element solutions are also used to compare the results of the EFGM. In order to test the practical applicability and performance of the EFGM, three case studies of contaminant transport through the landfill liners are presented. A good agreement is obtained between the results of the EFGM and the field investigation data. Copyright © 2009 John Wiley & Sons, Ltd. 相似文献
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详细介绍了无网格伽辽金法(EFGM)基本原理,并将其应用于非均质多孔介质中的稳定地下水流问题,用具体算例将无网格伽辽金法计算结果与传统有限元法(LFEM)计算结果作比较,计算表明无网格伽辽金法具有较高的精度。 相似文献
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接触摩擦问题的数值模拟 总被引:3,自引:1,他引:2
无网格伽辽金法(EFGM)可脱离单元的概念,特别适合岩体裂纹面的接触摩擦分析。基于EFGM,在裂纹面引入罚参数,通过迭代计算,得到裂纹面真实的应力状态,从而模拟闭合裂纹的粘接、滑移和张开行为,数值结果表明该方法是合理可行的。 相似文献
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This paper presents a coupling technique for integrating the element-free Galerkin method (EFGM) with the fractal finite element method (FFEM) to analyze unbounded problems in the half-space. FFEM is adopted to model the far field of an unbounded domain and EFGM is used in the near field. In the transition region interface elements are employed. The shape functions of interface elements which comprise both the element-free Galerkin and the finite element shape functions, satisfy the consistency condition thus ensuring convergence of the proposed coupled EFGM–FFEM. The proposed method combines the best features of EFGM and FFEM, in the sense that no structured mesh or special enriched basis functions are necessary. The numerical results show that the proposed method performs extremely well converging rapidly to the analytical solution. Also a parametric study is carried out to examine the effects of the integration order, the similarity ratio, the weight function, the scaling parameter and the number of transformation terms, on the quality of the numerical solutions. 相似文献
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This paper presents a finite element procedure for the analysis of consolidation of layered soils with vertical drain using general one‐dimensional (1‐D) constitutive models. In formulating the finite element procedure, a Newton–Cotes‐type integration formula is used to avoid the unsymmetry of the stiffness matrix for a Newton (Modified Newton) iteration scheme. The proposed procedure is then applied for the consolidation analysis of a number of typical problems using both linear and non‐linear soil models. Results from this simplified method are compared with those from a fully coupled consolidation analysis using a well‐known finite element package. The average degree of consolidation, excess porewater pressure and average vertical effective stress are almost the same as those from the fully coupled analysis for both the linear and non‐linear cases studied. The differences in vertical effective stresses are tolerable except for the values near the vertical drain boundaries. The consolidation behaviour of soils below a certain depth of the bottom of vertical drain is actually one‐dimensional for the partially penetrating case. Therefore, there are not much differences in whether one uses a one‐dimensional model or a three‐dimensional model in this region. The average degree of consolidation has good normalized feature with respect to the ratio of well radius to external drainage boundary for the cases of fully penetrating vertical drain using a normalized time even in the non‐linear case. Numerical results clearly demonstrate that the proposed simplified finite element procedure is efficient for the consolidation analysis of soils with vertical drain and it has better numerical stability characteristics. This simplified method can easily account for layered systems, time‐dependent loading, well‐resistance, smear effects and inelastic stress–strain behaviour. This method is also very suitable for the design of vertical drain, since it greatly reduces the unknown variables in the calculation and the 1‐D soil model parameters can be more easily determined. Copyright © 2000 John Wiley & Sons, Ltd. 相似文献