共查询到19条相似文献,搜索用时 187 毫秒
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结构性粘土的堆砌体模型 总被引:68,自引:18,他引:50
天然粘土一般都具有结构性, 其变形过程必然伴随着结构的破坏。 提出了一种新型的堆砌体模型, 用以描述这种结构破坏现象。 这一模型把变形过程中的结构性土看作不同大小土块的集合体, 总的变形将由土块的弹性变形、土块之间滑动引起的塑性变形和土块破碎引起的损伤变形三部分组成。 塑性变形常用屈服函数描述, 损伤变形则可以引入一种类似的损伤函数加以描述。推导了相应的应力应变关系式并提出了模型参数的测定方法。 相似文献
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非饱和黏土的结构性能够显著影响其力学特性。基于非饱和土经典模型BBM(Barcelona basic model)和一种可描述循环塑性的硬化法则,引入体积破损率的作为标准土体结构破损的参数,建立了一个描述常吸力下非饱和结构性黏土静态及动态力学特性的弹塑性双面模型。模型在应力空间中包含与重塑非饱和土屈服面几何相似的结构性边界面和加载面,采用径向映射法则和可移动的记忆中心原理,通过结构性边界面和加载面在应力空间中的演化来反映循环加载过程中非饱和结构性黏土的循环塑性特征和结构损伤过程。通过与相关非饱和黏土控制吸力试验数据的比较,表明该模型能够较好地反映静态加载下非饱和结构性黏土的力学特性,而模型预测的循环荷载下的应力?应变特征也具有一定的合理性。 相似文献
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以天津海积软黏土为研究对象,对原状土及重塑土进行了不同固结压力、应力路径、加荷速率、排水条件下的三轴剪切试验,以应力比结构性参数与应变的关系来描述结构性衰减,研究了不同加荷模式下的结构损伤特性。结果表明,固结压力小于结构屈服应力时,剪切阶段的初始结构性和损伤速率基本不受固结压力影响,固结压力大于结构屈服应力时,初始结构性和损伤速率则随固结压力的增大而减小;在0相似文献
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桩-土界面间冻结力及荷载作用下界面的剪切力学行为是决定冻土区桩基础承载性能和荷载传递的关键。由于冰的显著流变性及高含冰量冻土区上限附近厚层地下冰的广泛分布特征,桩基础中上位具有的冰冻结界面剪切蠕变特性对桩基础的承载性能有显著影响。为研究桩冰冻结界面剪切变形特征及其内在机制,开展了-3℃、-5℃下冰-钢管结构分级加卸载剪切蠕变试验。通过对变形曲线的分段独立解耦,分析了冻结界面的黏弹塑性剪切变形行为。结果表明,界面剪切变形可分解为瞬弹性(Sie)、瞬塑性(Sip)、黏塑性(Svp)以及黏弹性变形(Sve)。广义弹性剪切模量随分级荷载的增加逐渐变大,表明加卸载过程中结构未加速破坏前界面存在明显的强化效应。界面剪切蠕变特征随剪应力水平的增加由衰减向非衰减过渡。其中,黏弹性变形和低剪应力水平下黏塑性变形均表现为衰减性,且荷载越大,黏弹性变形越大。高应力水平下黏塑性表现为非衰减性,且变形速率随剪应力水平增加显著提升。整体而言,冻结界面塑性变形值占总累计变形的比例先减小,后增大,其中瞬塑性变形主要存在于应力水平较... 相似文献
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考虑到天然岩石存在不同程度初始损伤以及蠕变过程中岩石受载后裂隙扩展而导致的新损伤,对具有初始损伤的岩石蠕变特性进行全面描述。根据不闭合结构面应力与法向变形之间的关系,提出裂隙岩石塑性变形体元件,描述岩石蠕变过程中的瞬时塑性变形。引入初始损伤影响因子,建立具有初始损伤的岩石损伤变量演化方程,构建模拟岩石加速蠕变的蠕变损伤体元件。将裂隙岩石塑性变形体和蠕变损伤体与描述瞬时弹性变形和黏弹性变形的广义开尔文模型进行串联组合,形成能够反映具有初始损伤的岩石瞬时弹-塑性变形、稳定蠕变和加速蠕变的蠕变全过程本构模型,提出了进行少量蠕变试验既能解析模型参数的方法,在不同应力水平下模型理论曲线与蠕变试验曲线吻合。 相似文献
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粘性土的动力特性实验及数值模拟 总被引:1,自引:1,他引:0
使用产自日本的DTC-306型多功能电液伺服动态三轴仪,对粉质粘土进行动三轴试验。在试验提供的各种参数和数据的基础上,利用有限元程序ABAQUS建立动三轴试件的三维有限元模型,模拟在循环荷载作用下粉质粘土的动力变形特性;并通过与动三轴试验相关数据的大量对比分析,验证了模型的可靠性。然后在建立的三维有限元模型的基础上,进一步用数值模拟的方法研究了土体动力变形与各影响因素间的关系,得出如下结论:初始弹性模量、阻尼系数、受荷形式对土的塑性变形影响最大,应力幅值、围压、频率、加荷周数次之,加载波形的影响最小,不同波形对塑性变形的影响取决于荷载最大值时历时的长短。有限元数值模拟方法在一定程度上可以替代动三轴实验。 相似文献
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软土一般具有结构性,试验表明,加荷比会对结构性软土压缩特性有很大的影响,加荷比增加土体剪切趋势,降低土体结构强度,使土体的结构屈服应力值和压缩指数降低。在试验的基础上,给出了考虑加荷比影响的结构性软土地基的沉降计算方法。工程算例表明,在加载终值相同的情况下,如果加荷比过大,就会增大结构性软土地基沉降产生附加沉降,为了减小对软土结构性的破坏而影响土体压缩特性,建议对结构性软土的加荷比不宜采用为1:1以上,宜采用1:0.25或1:0.5。 相似文献
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基于间断位移场的隧道围岩承载能力研究 总被引:3,自引:2,他引:1
岩体是岩石块体和分割这些块体的边界的组合体。沿边界面(结构面)的局部剪切变形使得位移场产生间断,对岩体的力学性能产生巨大的影响。采用光滑函数组合来描述滑移面上的间断,得到反映岩体沿着边界局部剪切的数学模型。利用此局部剪切模型得出了应力–滑移关系具有强化阶段时圆形坑道围岩自身承载能力的解析表达式,研究了岩体滑移面对坑道围岩自身承载能力的影响。通过分析得到,自承能力在深部坑道围岩的稳定中发挥了重要作用,应力–滑移关系的强化段对围岩承载力有着很大的影响;围岩压力与坑道的埋深、坑道的尺寸以及围岩的物理力学性质等具有直接关系;围岩出现不稳定的动力现象(岩爆)与此岩体参数m关系极大,而岩体参数与接触面的软化程度、能量转移、耗散结构的几何尺寸以及弹性模量有关。 相似文献
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Hypoplastic model for sands with loading surface 总被引:3,自引:3,他引:0
Although the hypoplastic models for sands have exhibited good predictive capability in monotonic loading, they are not able to reproduce memory effects and predict excessive plastic accumulation under cyclic loading. To overcome these issues, a loading surface has been incorporated into a hypoplastic model. This surface is capped and has two hardening variables. Notions from the bounding surface plasticity were borrowed in order to formulate the hardening functions. With this novel model, some salient features can be described: the model can account for the accumulation of plastic deformation, a memory effect is provided by the new surface, and stress-induced anisotropy effects observed in sands are successfully simulated. A short calibration guide of the parameters is given, and some simulations for Hostun RF loose sand and Toyoura sand are presented. 相似文献
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循环荷载作用下接触面的边界面模型研究 总被引:1,自引:0,他引:1
基于边界面的概念,建立了循环荷载作用下砂与结构物接触面的边界面塑性模型,以描述其剪切应力与剪应变的滞回特性。该模型考虑了初始相对密度和法向应力的影响,同时在弹性模量中引入损伤因子,反映了接触面在循环荷载下逐渐硬化的性质。通过比较理论计算与试验结果,显示了该模型的合理性。 相似文献
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考虑循环载荷下饱和黏土软化的损伤边界面模型研究 总被引:1,自引:0,他引:1
研究表明,循环载荷作用下饱和黏土将发生软化,其机制主要有两个:一是孔压的积累;二是土体原有结构的不断损伤和新结构的不断重塑。针对上述机制,基于广义各向同性硬化准则建立了考虑饱和黏土循环软化的损伤单面模型。该模型在有效应力空间中引入损伤变量,表征土体结构的损伤和重塑程度,在连续的循环加载下,损伤不断累积,边界面则随着损伤的累积不断收缩,以模拟饱和黏土刚度和强度的软化;以应力反向点作为边界面的广义各向同性硬化中心和映射法则的映射中心,灵活地选择塑性模量的插值公式以模拟塑性变形和孔压的累积以及应力-应变的滞回特性。应用该模型对不排水循环三轴试验进行模拟,并且考查了循环周次、循环应力水平和固结历史对饱和黏土循环软化特性的影响,并与相关试验比较,验证了模型的有效性。 相似文献
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A three-dimensional (3D) soil–structure interface model is proposed within the two-mechanism constitutive theory and bounding surface theory originally established for soils. The proposed model has two main characteristics: first, the model is formulated based on two different and superposed deformation mechanisms. The first mechanism is due to the stress ratio increment, and the second is due to the normal stress increment. Each mechanism induces a shear strain component and a normal strain component. The proposed model can be reduced to the conventional single-mechanism interface model. Second, the plastic modulus and stress dilatancy are defined using the bounding surface theory. The plastic flow rule under cyclic loading is modified and assumed to be dependent on both the stress state of the mapping point and the stress reversal loading direction. The proposed model was validated against the available 3D interface tests and was found to satisfactorily reflect the salient features of the interfaces under monotonic and cyclic loading paths with different normal boundaries. The problem in which the elastic normal stiffness in conventional single-mechanism interface models is often underestimated to enhance the simulation performance under varying normal stress conditions is solved by incorporating the second mechanism. And the effect of the second mechanism on the modeling behavior is discussed. The modified plastic flow direction accurately simulates the 3D cyclic shear response, and the difference between the model simulation and test result increases with the number of cycles by use of the plastic flow direction defined in conventional bounding surface theory. 相似文献
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This paper presents a kinematic hardening model for describing some important features of natural stiff clays under cyclic loading conditions, such as closed hysteretic loops, smooth transition from the elastic behavior to the elastoplastic one and changes of the compression slope with loading/unloading loops. The model includes two yield surfaces, an inner surface and a bounding surface. A non-associated flow rule and a kinematic hardening law are proposed for the inner surface. The adopted hardening law enables the plastic modulus to vary smoothly when the kinematic yield surface approaches the bounding surface and ensures at the same time the non-intersection of the two yield surfaces. Furthermore, the first loading, unloading, and reloading stages are treated differently by applying distinct hardening parameters. The main feature of the model is that its constitutive equations can be simply formulated based on the consistency condition for the inner yield surface based on the proposed kinematic hardening law; thereby, this model can be easily implemented in a finite element code using a classic stress integration scheme as for the modified Cam Clay model. The simulation results on the Boom Clay, natural stiff clay, have revealed the relevance of the model: a good agreement has been obtained between simulations and the experimental results from the tests with different stress paths under cyclic loading conditions. In particular, the model can satisfactorily describe the complex case of oedometric conditions where the deviator stress is positive upon loading (compression) but can become negative upon unloading (extension). 相似文献
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This paper presents a constitutive model for describing the stress-strain response of sands under cyclic loading. The model, formulated using the critical state theory within the bounding surface plasticity framework, is an upgraded version of an existing model developed for monotonic behaviour of cohesionless sands. With modification of the hardening law, plastic volumetric strain increment and unloading plastic modulus, the original model was modified to simulate cyclic loading. The proposed model was validated against triaxial cyclic loading tests for Fuji River sand, Toyoura sand and Nigata sand. Comparison between the measured and predicted results suggests that the proposed modified model can capture the main features of cohesionless sands under drained and undrained cyclic loading. 相似文献
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适用于砂土循环加载分析的边界面塑性模型 总被引:1,自引:0,他引:1
基于临界状态土力学框架,建立了一个适用于砂土排水循环加载的边界面塑性模型。采用了考虑虚拟峰值应力比的偏应变硬化准则,初始加载阶段应力点位于边界面上,反向加载阶段以历史最大屈服面作为边界面,同时实现了对密砂软化现象的模拟和对历史所受最大应力的记忆。边界面采用修正的椭圆形,引入考虑密度与应力水平的状态相关剪胀函数,采用非相关联流动法则和以应力反向点作为映射中心的径向映射准则。模型仅有10个参数,通过常规三轴试验即可确定,并且使用一套参数可以模拟不同围压、密度的单调和循环加载情况。分别对饱和砂土的单调、循环排水三轴试验进行模拟,结果表明,该模型能够合理地反映饱和砂土排水条件下的应力-应变特性。 相似文献
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In this paper, we propose an anisotropic plastic damage model for semi-brittle geomaterials based on a discrete thermodynamic approach. The macroscopic plastic deformation is generated by frictional sliding of weakness planes. The evolution of damage is related to growth of such weakness planes. The local frictional sliding in each family of weakness planes is described by a non-associated plastic model taking into account material softening and volumetric dilatancy. The damage evolution is coupled with plastic deformation and modelled by an isotropic damage criterion. The proposed model is applied to modelling mechanical responses of typical sandstone under different loading paths. There is good agreement between numerical predictions and experimental data. Further, the anisotropic distributions of plastic deformation and induced damage are analysed and discussed. 相似文献
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