共查询到17条相似文献,搜索用时 320 毫秒
1.
不同土层结构的堤基,其管涌发生和发展的情形不同。以前的研究多集中于双层堤基的情况。事实上,含夹砂层堤基中,位于砂砾石层内的细砂层会对堤基管涌的发生产生重大影响,并且这些影响随细砂层在砂砾石层中的位置不同而不尽相同。利用室内砂槽试验,模拟当细砂层位于砂砾石层内部不同深度时含夹砂层堤基管涌的发展过程,研究细砂层埋深对 堤基管涌的影响。试验结果表明,细砂层埋深存在一个临界深度,当细砂层埋深较浅时,堤基的临界水力梯度较小,易于发生管涌,且管涌发生以后,堤基被侵蚀的速率较大,出砂较多;堤基破坏的临界水力梯度随着细砂层埋深的增加而增大,当细砂层埋深大于临界埋深时,堤基的临界水力梯度基本不变,同时堤基抵抗管涌破坏的能力较强,其破坏形式与双层堤基 相类似。 相似文献
2.
通过算例采用分时段稳定流理论模拟了基于临界水力坡降的流砂动态发展过程,建立了双层结构堤基发生流土的完整井流砂和半球形井底流砂物理模型。堤基发生渗透变形而形成的集中渗漏通道,将自涌砂口沿垂直堤轴方向发展,并在平面上自涌砂口到河床不断扩大,在深度上不断加深。通道的规模取决于涌砂口的流量大小和水位高低,尤其在较低水位时通道规模将最大。减压井在降低了井附近水头的同时也加大了水力坡降,从而更易发展渗透变形,因此应特别重视减压井的反滤层设计和施工,以使土体保持在原位而不致发生渗透变形。 相似文献
3.
管涌的发生、发展过程是土骨架相在渗流作用下侵蚀为可动细颗粒相,并随水相在孔隙通道中运移流失的过程。在该过程中,渗流与侵蚀相互耦合,相互促进,水相、土相、可动细颗粒相互作用,因此,管涌过程是一个多场、多相耦合的高度非线性的动态过程。现有的管涌试验结果表明,只有当水力梯度大于起始水力梯度时,细颗粒相才会随水相从土体中运移流失,土体才会发生管涌侵蚀,且管涌稳定后土体的孔隙率(稳定孔隙率)和水力梯度之间存在对应关系,根据该结果,提出管涌稳定孔隙率的概念,修正传统的渗流侵蚀本构方程,建立多孔介质中三相耦合的修正的渗流侵蚀管涌控制方程。最后,针对特定应力状态下的土体建立稳定孔隙率和水力梯度之间的对应关系。基于Galerkin有限元法编制有限元程序,在轴对称情况下对该土体的管涌过程进行数值模拟。结果表明,修正后的管涌控制方程能更全面地描述管涌发生、发展直至稳定状态的特性。 相似文献
4.
为了揭示发育薄弱区对管涌发展的影响机制,进行了管涌砂槽模型试验和颗粒流数值模拟,建立了3组模型,以研究孔隙通道的空间发育对颗粒运移过程的影响,分析了土体内部细颗粒运移引起管涌破坏的动态过程。根据数值模拟结果,分析了管涌发展过程中试样细观及流体的变化规律,并与砂槽模型试验结果进行了比较,模拟与模型试验结果较吻合。结果表明,薄弱区越发育,压力分布调整的趋势越强,颗粒运移的趋势相应增加,达到破坏需要的时间越短。数值模拟获得的临界水力梯度与室内试验以及理论分析结果均比较接近,证明了采用颗粒流程序研究管涌问题是合理的,对研究存在薄弱区的砂土管涌现象具有明显的优势和广阔的应用前景。所揭示的结果有益于管涌机制的更深入研究。 相似文献
5.
基料一滤层利用数码可视化跟踪技术、计算机信息实时处理技术和土体变形无标点量测技术,对宽级配基料一滤层系统进行了渗透室内模型试验。探讨了滤层准则的适用性,研究了不同滤层厚度和加压速率对管涌发生发展的影响。结果表明:传统太沙基滤层准则不适用于宽级配砂土,建议采用可移动颗粒中的d85s进行滤层准则设计;增加滤层厚度可提高系统的抗渗透破坏能力,但提高滤层厚度对提高整个系统抵抗渗透能力作用不大;水力梯度增加较快不利于系统的稳定。 相似文献
6.
管涌对堤防工程的危害极为严重,人类对管涌的认识也逐渐加深。目前,对管涌破坏开始的条件及其破坏后通道贯通的后果了解较多,然而,因其破坏及发展机制的复杂性,对于管涌发生后涌砂及流量的研究并不深入。通过自行设计的室内模型,改变上覆黏土的厚度对3组土性相同的无黏性土试样进行试验。对测压管水头、通道范围、涌砂量和流量等进行对比分析,研究孔隙率、渗透系数以及流量的变化规律,发现涌砂随时间变化满足非线性关系--Boltzmann模型。最后,利用渗透系数与孔隙率以及孔隙率与累计涌砂量的关系,推导并验证了流量随时间变化的理论公式。这对于认识管涌和有效控制管涌发展以及减灾避难有着非常重要的意义。 相似文献
7.
在对渗流评估方法进行一定探讨的基础上,对某水利枢纽工程坝址区厂房基坑开挖进行了渗透变形评估。结果表明,在坝轴线方向上,无防渗墙时坡面土体在渗透力的作用下是不稳定的,有防渗墙时坡面水力坡降降到0.05以下。在砂卵砾石层与基岩的交界处仍存在略大的水力坡降(值为0.56),如有水在细砂层、砾质中粗砂层渗出,则有可能出现渗流失稳,但总的说来由于防渗墙使水力坡降已降到很小,出现流土和管涌失稳的可能性不大。 相似文献
8.
邕江防洪水堤是南宁市唯一抵御洪水侵害的防线,其堤基为河床和河漫滩相冲洪积物。下部中、粗砂层和圆砾层属管涌层;中部粉砂层、粉土层属流土层;上部粘性土层;底部为第三系泥岩层。本文通过对场地管涌县、流土层判别、水文地质条件概化、地下水回水位预测、盖层变形破坏预测和地下水水力坡降计算,来预测场地发生管涌地质灾害的可能性。 相似文献
9.
利用显微摄像可视化跟踪技术、数字信息计算机实时处理技术,结合数字图像识别分析手段,对砂土管涌的整个过程进行跟踪记录,从细观角度揭示渗流过程中系统几何特性和水力特性的复杂变化。得到水头,水力梯度,颗粒位移场和孔隙率等量的动态变化过程,并对整个渗流过程中加压速率对管涌发展的影响,颗粒的运动特点,颗粒流失的分布特点以及渗漏通道的贯穿进行分析,揭示水土相互作用贯穿于管涌发展的全过程。 相似文献
10.
研究了波动水流对海堤织物滤层的水力要素及过滤机理。粒径小于0.6 mm颗粒间存在粘着力;同时,由于滤层和堤体的渗透流速不一致,则堤体界面的土颗粒将受水流剪应力的作用。在分析了使土颗粒发生变形的水流剪应力、变形土体周壁的屈服应力和波浪压力等后,根据平衡原理,建立了织物滤层的保土性准则。 相似文献
11.
悬挂式防渗墙-强透水地基所处的应力状态,对其管涌等渗透变形发展过程影响明显。利用自行研制的新型土与结构物接触剪切渗透仪,开展不同应力状态下悬挂式防渗墙--缺乏中间级配的管涌型砂砾石地基的渗流-应力耦合管涌试验研究。结果表明,应力状态对悬挂式防渗墙-砂砾石地基的管涌临界渗透坡降影响巨大,围压越大,管涌临界渗透坡降越大,基于试验结果,建立了由围压表示的管涌临界渗透坡降线性经验公式。研究成果体现了渗流-应力耦合效应对防渗墙-砂砾石地基渗透稳定性的影响,可为确定深厚覆盖层中悬挂式防渗墙的合理贯入深度提供重要的理论依据。 相似文献
13.
双层堤基是应用较多的双面层的堤基构造类型,上层为弱透水层,下层为强透水深厚砂层。堤内弱透水层在汛期高水位时面临较高的水头承压,出现管涌的危险性极大。以实验室模拟分析的方式,专题探究双层堤管涌的悬挂型防渗控制规律,结果可知:悬挂型防渗墙在有效截断管涌迁移路径方面具有独特功能和阻滞效果,管涌没有出现之前,悬挂式防渗墙消解水头冲刷的作用一般不很明显,而一旦有管涌发生,防渗墙对透水堤基深入越深,防渗作用将越好,如果保持贯入度相同,则下游布置防渗墙比上游布置防渗墙效果要好。研究结果为同类工程应用提供研究和技术参考。 相似文献
14.
Backward erosion piping (BEP) poses a threat to the stability of water-retaining structures. This can lead to severe erosion and collapse of embankments. A novel economically appealing measure against BEP is the coarse sand barrier (CSB). The CSB is a trench filled with coarse sand that is placed below the blanket layer on the landward side of the embankment, which prevents the pipe from developing upstream when it encounters the CSB. Inclusion of a CSB creates a vertically layered sand, which is the situation that can also exist in practice but is different from traditional BEP tests with one homogeneous sand. This paper presents new observations and measurements in medium-scale laboratory tests. 3D measurements of the pipe depth and dimensions are presented and analysed. This analysis indicates how the pipe dimensions evolve during the piping process and shows the erosion mechanism for BEP in vertically layered sands. The findings demonstrate the significance of three-dimensional study of the pipe rather than two dimensions. The pipe depth, width and depth-to-width ratios at the pipe tip in critical erosion stages are measured and presented. In the presented tests, two different erosion behaviours (stepwise pipe progression until failure and straight failure) are found and analysed with respect to possible influential parameters. Higher head drops and flow rates are found in tests with straight failure at the stage before progression. A linear relationship between the hydraulic conductivity contrast (kc) and the critical head drops (hc) is found and observations are used to investigate deviations from the line. 相似文献
15.
Piping, as one of the critical patterns of internal erosion, has been reported as a major cause for failures of embankment dams and levees. The fundamental mechanism of piping was traditionally investigated through experimental trials and simplified theoretical methods in macroscale. Nevertheless, the initiation and progressive evolution of piping is a microscale phenomenon in its essence. The current understanding of the micro-mechanism of piping erosion is limited due to a lack of quantitative analysis and visualized evidence. And in fact, seepage flows can affect the soil fabrics and the development of contact forces between particles. But how these fabrics and contact forces evolve under a critical hydraulic gradient is still not fully understood. In this paper, the detailed process of piping erosion is investigated by using a coupled computational fluid dynamics and discrete element method (CFD–DEM) approach. The treatment of soil–flow interactions in CFD–DEM is explained by exchanging the momentum between the two phases. During the simulation, the piping erosion process is initiated by incrementally ascending differential water head across the soil samples. The three main stages of piping erosion (initial movement, continuation of erosion and total heave) can be identified from monitoring the particle velocity and positions. In addition, the evolution of contact force, hydraulic force, coordination number and void fraction is inspected to provide insight into the micro-mechanism of piping erosion. Two cases are simulated, one with a uniform particle size and a relatively uniform porosity distribution and the other with specific particle size and porosity distributions. An interesting finding from this study is that piping does not always initiate from the free surface and the evolution of piping depends heavily on the particle size and porosity distribution. 相似文献
16.
External suffusion, as selective erosion of fine particles through the contact with a coarser layer and moving away, is an
important phenomenon in dams which may lead to their failure. To study the initiation of external suffusion, caused by water
level increase upstream the dam, a series of experimental investigations were conducted on laboratory-scale model, in the
hydrodynamic laboratory of école polytechnique de Montreal. On the built model, clay/moraine formed the core, sand was used
as a filter and gravel performed the role of the pervious layer. Several different models (in geometry and constituent materials)
were built and subjected to the water level increase upstream, which resulted in changes in the hydraulic gradient. The results
showed no evidence of considerable suffusion on the clay/moraine and sand interface, while the visual and quantitative data
show the presence of suffusion on the sand and gravel interface. The results of the experiments show that, when focusing on
the critical hydraulic gradient that initiates the movement of the clay/moraine particles, it can be concluded that despite
the differences in test conditions, the critical hydraulic gradient has approximately the same value in all cases. It was
also shown that increasing the length of the filter layer or applying stair-like slopes does not have great impacts on the
initiation of suffusion, whereas the gravel-size distribution has a great impact on the erosion rate. 相似文献
17.
The study of particle migration in porous media under cyclic loading is the key to understand the mechanism of mud pumping hazard in railway embankments. This paper presents a series of particle migration tests, in which soil particles migrate into an overlying gravel layer under cyclic loading. The results show that the increase in loading frequency and load magnitude leads to more particle migration upwards at a greater rate, implying that the train speed and axle loads affect the extent of mud pumping. The slurry turbidity in the gravel layer increases to a steady state value with time. Soil particles smaller than 5 μm have the potential to diffuse into the entire gravel layer, and larger particles tend to aggregate in the bottom layer of the gravel. The backward erosion gradually develops deeper into the soil layer, and there is a maximum erosion depth associated with each load frequency and load magnitude. As for the mechanism, the pore water pressure oscillates because of liquid sloshing. Its amplitude is much larger in the gravel layer than that in the soil layer due to their difference in permeability. The axial hydraulic gradient acts as a pumping effect to stimulate the migration of soil particles. Increasing load frequency is conducive to the generation of a stronger pumping effect at the gravel–soil interface. Increasing load magnitude does impact not only the extent of pumping effect, but also the development of an interlayer which plays an important role in promoting particle migration. 相似文献
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