不同加固技术在散粒体斜坡表层的应用对比研究

散粒体斜坡多发育于我国西部山区,由块度不一、黏粒含量较少的碎砾石土组成,由于胶结性差,遇雨水冲刷、风吹或人畜踩踏易失稳。传统坡面防护技术包括拦挡锚固和土工材料与植被构筑,新型护坡技术是结合了岩土材料加固和生态环境两方面所提出的新方法。本文中该新技术是指将浓度1.3%的改性钠羧甲基纤维素与边坡表层土拌合,后掺入植物纤维,喷洒到坡表形成加固层;加固层表面喷洒草籽,以达到边坡防护的目的。文章选择传统的护坡方法（格构和三维网）和新型土壤改良方法结合植草绿化技术对室外某散粒体斜坡进行加固处理,以天然斜坡为参照,统计降雨冲刷和径流冲刷后边坡表面侵蚀破坏、入渗和植被破坏特征,对比不同护坡方式的应用效果。试验结果表明:每个斜坡辅之相同的植草条件下,对比降雨和放水冲刷试验后各边坡的侵蚀破坏特征可以发现,材料改良植草边坡侵蚀弱,产沙量小,作用层能减缓雨水下渗,提高植被存活率和降低植被倒伏率,其效果优于三维网植草护坡和格构植草护坡。     

三维土工网垫设计指标的研究

三维土工网垫作为一种新型的坡面防护植草材料,在土木工程各领域得到广泛地应用。然而三维网垫的选择研究却远远落后于应用。不同强度、厚度、开口尺寸的网垫产品的抗冲刷与植被性能是不一样的。首先,从水力学、土力学、水文学及工程力学等方面推导了网垫强度公式,进而,从网垫厚度测量及网垫厚度对长草的影响得出网垫的较优厚度,最后,通过冲刷模型试验得到了合理的网垫开口尺寸,在一定程度上解决了三维网垫设计指标的选择问题。     

全风化花岗岩突水通道扩展的颗粒起动流速研究

突水突泥是富水全强风化花岗岩隧道施工常见的地质灾害,地层颗粒的流失是导致突水通道扩展的关键因素,其中颗粒达到起动流速是其流失的临界条件。考虑水流冲刷和土体黏结作用,对突水通道断面颗粒进行三维受力分析,导出颗粒的临界起动条件,建立了考虑颗粒粒径、颗粒坡面位置、相对暴露度三因素的颗粒起动流速函数,并利用数值方法分析了上述三因素对起动流速的影响规律。计算分析表明:起动流速随粒径增大先减小后增大,通道断面不同坡面位置颗粒起动流速呈明显的对称性,总体上起动流速随相对暴露度的增大呈增大趋势。采用正交试验法研究了三因素对颗粒起动流速的敏感性,发现粒径对起动流速影响最为显著。同时根据断面颗粒起动最小流速标准及相对暴露度的随机性,简化颗粒坡面位置和相对暴露度两因素,导出颗粒起动流速的简化公式,最后利用室内试验和工程实例验证了该公式的合理性。     

坡面流速及侵蚀产沙空间变异性试验

在野外放水试验条件下,利用染色法和侵蚀针法分别观测坡面流速和侵蚀产沙空间变异性。结果表明,坡面各横向断面的流速与距坡顶距离之间呈正相关,且相关性随流量增大逐渐变得显著,纵向断面流速的变异程度明显强于横向断面。总体上,上、下坡位侵蚀程度较重,而中坡位最轻;小流量时沉积作用明显,大流量时距坡顶0~2 m范围为净侵蚀区;各坡段侵蚀量与其距坡顶距离之间呈负相关;发生泥沙沉积部位随流量增大逐渐下移,细沟侵蚀量占坡面总侵蚀量的比例随流量增大不断增加。试验条件下流速为0.30 m/s时,细沟侵蚀产沙大于细沟间侵蚀,且坡面侵蚀量迅速增大。随流量增大,流速和侵蚀产沙量呈增大趋势;但在流量较大时,坡面各坡位侵蚀量与流速呈负相关,这可能与坡面中下部位粗颗粒泥沙沉积以及含沙水流的挟沙能力基本达到饱和有关。     

黄土坡面径流侵蚀产沙动力过程模拟与研究

通过室内模拟冲刷试验系统研究了3°~30°坡度范围内坡面径流的侵蚀动力及产沙特征,分析了坡面径流能耗与径流侵蚀产沙之间的关系。结果表明,坡面径流平均流速随坡度和流量的增加而增大,流速与坡度和流量之间存在指数函数关系,坡度对流速的影响大于流量。在3°~21°坡度范围内,坡面径流单宽能耗随坡度的增加而增加,当坡度超过21°时,径流能耗随坡度的增加而降低。坡度对侵蚀产沙的影响也有类似的现象,在3°~21°坡度范围内,坡面径流平均单宽输沙率随坡度的增加而增大,当坡度达到临界极值21°和24°后,坡面径流平均输沙率随坡度增加而减小;在整个试验坡度范围内,径流平均单宽输沙率随流量的增大而增大;流量对坡面径流平均单宽输沙率的影响大于坡度。坡面径流平均单宽输沙率和单宽径流能耗之间存在明显的线性关系,其临界单宽径流能耗随坡度的增加而增加,土壤可蚀性参数随坡度的变化在10.368~30.366的范围变化,试验的土壤可蚀性的平均值为14.61。     

降雨冲刷对黄土公路边坡植物防护影响的试验研究

通过对裸露黄土公路边坡、厚层基材植草公路边坡、三维网植草公路边坡以及平台植树公路边坡的现场降雨冲刷试验,阐述了不同防护型式的公路黄土边坡在降雨条件下的坡面径流、含泥量以及坡面冲刷情况,得出了降雨对边坡坡面的侵蚀过程,首先是从雨滴直接打击土体开始,进而引起溅蚀,分散土粒,紧接着发生超渗径流造成坡面冲刷。以及对坡面破坏最大的是坡顶上方来水等重要结论。验证了坡面植物防护以及平台植树等防护方法可以有效降低降雨冲刷对坡面的侵蚀破坏,为黄土地区公路边坡植物防护的设计施工以提供了可靠的依据。     

新型高分子材料固化黄土边坡的抗冲刷试验

在已有成果的基础上采用新型高分子材料SH固化剂固化黄土,通过改良坡面黄土的工程性质,提高坡面抗冲刷性能。利用室内试验装置人工模拟边坡顶端来流冲刷,研究采用SH固化剂和固土植草相结合的方法加固黄土边坡,以边坡坡面产流产沙特征评价抗冲刷性。结果表明:SH固化黄土坡面后,坡面径流含沙量比黄土坡面显著减小,随SH掺量增加,含沙量递减,抗冲刷性明显增强; SH固化植草坡面的产流产沙性能说明化学与生态结合防护黄土边坡坡面冲刷更为有效。 更多还原     

均质土岸坡崩塌与河床冲淤交互过程试验

在弯道水槽中展开系列试验,研究水力冲刷过程中均质土岸坡冲刷崩塌输移与河床冲淤过程及其影响因素。该过程及变化特征可描述为:水下坡面侵蚀及坡脚淘刷导致岸坡失稳崩塌;暂时堆积在凹岸坡脚处的崩塌体加剧附近水流紊动程度利于其输运与分解;分解后较粗的颗粒随弯道螺旋流以推移质形式被输移至下游凸岸落淤,较细的颗粒大部分都随水流以悬移质形式被携带至下游出口;水流结构随岸坡及河床变形而调整;如此循环往复。试验成果进一步表明:冲刷状态下,试验材料黏性越小、近岸流速越大、作用时间越长,岸坡冲刷崩塌量及河床冲刷量都越大;同条件下岸坡冲刷崩塌总量大于河床冲刷总量,且河床相对冲刷率随岸坡冲刷崩塌量的增大而减小,数值范围为0.40~0.92。     

具有不同转折角度的复杂单裂隙水头损失试验研究

裂隙是岩溶含水系统的重要组成部分,裂隙水流运动对岩溶含水系统水流运动起到重要的控制作用。利用自行设计研制的具有不同转折角度、不同裂隙开度的复杂单裂隙物理模型,通过室内物理试验得到有、无裂隙条件下,水头差变化曲线,并基于能量方程推导得出水流流经裂隙时产生的总水头损失计算式,计算得到不同裂隙开度(1～2.6 mm)、不同流速(0～40 cm/s)条件下,裂隙总水头损失对不同转折角度(0°～165°)的变化曲线,利用修正立方定律和达西-魏斯巴赫公式计算裂隙平行部分的沿程水头损失,总水头损失与之相减得到转折角处的局部水头损失。结果表明:随裂隙开度增大,流速增大,裂隙总水头损失、转折处局部水头损失均呈增大趋势,且流速越大,趋势越明显;对水头损失与平均流速之间的关系曲线进行拟合分析,发现裂隙总水头损失、转折处局部水头损失与平均流速之间均呈二次函数关系,可用Forchheimer方程描述,且总水头损失、局部水头损失与平均流速之间函数关系的二次项系数随裂隙开度增大基本呈增大趋势,最终得到二次项系数分布的上包线与下包线,而一次项系数分布比较集中,总水头损失的一次项系数分布于-0.1～0.5之间,转折处局部水头损失的一次项系数分布于-0.1～0.25之间。     

地形地貌对地震波放大效应数值模拟研究

采用FLAC3D 软件进行大量数值模拟,研究了地形地貌对地震波放大效应规律。结果表明:对于单面坡模型,斜坡较低时,坡体对天然地震波和简谐波的峰值加速度在竖直向和顺坡面向产生线性放大效应。斜坡较高时,若坡角低,两种波形的加速度等值线近似平行于坡面,天然地震波坡顶正下方极值性不明显,但随坡角增大而明显,坡面正下方可见若干条与坡面相平行具节律性的极小值条带,随坡角增大向一条极值带转化,简谐波在高低坡脚时坡顶面正下方区域内都出现等间距相间分布具节律性的极值条带,坡面正下方的极值带状性不如天然地震波明显,随坡角增大而消失; 若坡角高,两波形加速度放大系数顺坡面呈相间的极值圈分布。双面坡坡顶宽度越小,山脊越单薄,加速度放大效应越强烈,随坡顶宽度增大,坡肩加速度放大系数趋于稳定,双面坡对加速度放大效应强于单面坡。对加速度放大效应,多峰形双峰形单峰形,坡顶越不规则,加速度放大效应越强烈。V形河谷坡面上半部分加速度放大效应要强于U形河谷,U形河谷的谷底中部对地震波动力响应要强于V形谷。坡面局部不规则性只影响到坡面局部范围内的峰值加速度分布,坡高、坡角、坡顶几何特征为整个峰值加速度分布的控制因素。     

水流拖曳力对斜坡浅层土稳定性的影响分析

为研究强降雨条件下地表径流和裂隙水流的拖曳力作用对斜坡稳定性的影响,建立斜坡地表径流和地下水渗流耦合分析模型。采用Navier-Stokes方程描述地表径流和裂隙水流,Brinkman-extended Darcy方程描述土体和岩石中的渗流,并根据不同介质交界面处流速相等及剪应力连续的边界条件,推求各介质中的流速分布。应用Newton内摩擦定律求得水流对斜坡产生的拖曳力,进而将拖曳力嵌入刚体极限平衡理论对斜坡稳定性进行分析。典型斜坡实例计算结果表明,当未考虑拖曳力效应时,斜坡的安全系数为1.164,考虑水流对斜坡土体产生拖曳力效应时,斜坡的安全系数为1.089,斜坡安全系数降低了6.44%。这表明拖曳力作用对斜坡的稳定性存在不利影响,斜坡土体在近乎临界稳定状态下拖曳力将对斜坡失稳起到决定性作用。最后分别讨论了考虑拖曳力和不考虑拖曳力情况下斜坡的安全系数与径流水深、斜坡倾角、土层厚度之间的关系。分析表明,在其他条件相似的条件下,斜坡越陡,斜坡土体的安全系数下降越明显;斜坡安全系数随着斜坡倾角增加而不断降低,随着土层厚度的增加而不断降低。     

黄土丘陵区堆积体边坡对上方来水的侵蚀响应

为探明上方来水类型对工程堆积体高陡边坡下部冲刷侵蚀的定量影响,以神府高速公路沿线典型工程堆积体陡坡坡面(36°)为例,设计4种上方来水类型,通过野外放水冲刷试验分析了不同上方来水类型下堆积体坡面的径流侵蚀输沙过程.结果表明:①上方来水类型对堆积体坡面下部的产流影响较小,却干扰了坡面侵蚀产沙过程,造成土壤流失量增加;②径流深、单宽径流侵蚀力和水流功率均可以较好地预测堆积体边坡下部输沙模数的变化;③单宽径流侵蚀功率可以作为表征坡面尺度次径流事件中径流侵蚀力变化的指标.研究结果可为工程堆积体土壤侵蚀强度评价、侵蚀模型建立及新增水土流失防治提供参考.     

降雨侵蚀力对露天矿排土场边坡水土流失的影响研究

降雨侵蚀力反应降雨引起的土壤侵蚀潜在能力,是水土保持研究中的主要指标之一。以露天煤矿排土场不同覆盖类型边坡为研究对象,分析了日降雨侵蚀力与边坡侵蚀的关系。结果表明,从控制坡面径流深来看,降雨侵蚀力的作用受到了乔灌草和灌草配置的显著影响,其产生的坡面径流仅为对照区的42.9%和52.6%。从控制坡面侵蚀量来看,三种植物配置措施都具有显著减少功能,土壤侵蚀量仅为对照区的2.3%~6.7%。降雨侵蚀力与边坡水土流失量存在线性正相关,其中坡面径流深对降雨侵蚀力的响应快于土壤侵蚀量。     

裂隙黄土边坡三维稳定性极限分析

黄土边坡中竖直裂隙的发育往往会对边坡稳定产生影响。相对于平面应变机制,建立三维破坏机制下边坡稳定性分析方法更能接近实际边坡失稳情况。基于塑性极限分析上限法,考虑预先存在竖直裂隙的三维黄土边坡不同破坏机制（坡面破坏、坡脚破坏和坡底破坏）,建立能量平衡方程及其无量纲临界高度值γH/c表达式,采用随机搜索法得到了临界高度的上限解。分析了约束宽度、边坡坡度、内摩擦角以及裂隙深度对三维竖直裂隙黄土边坡临界高度值的影响。结果表明：对于坡脚破坏机制,临界高度值随着裂隙深度的增加而减小,减小至临界裂隙深度 (δ /H)_min后,裂隙深度的增加不再影响临界高度值;临界裂隙深度随着坡度β 的增大而增大,随着内摩擦角φ 的增大而减小。当约束宽度B/H<0.8时,大多数破坏机制为坡面破坏。当约束宽度B/H=0.8、内摩擦角φ =10° 及约束宽度B/H=0.6、内摩擦角φ =15° 时,边坡的破坏从坡面破坏机制逐渐过渡到坡脚破坏机制。存在竖直裂隙的黄土边坡比完整边坡具有更小的临界高度,约束宽度及内摩擦角会对三维黄土边坡破坏机制产生影响。     

The relative importance of soil crust and slope angle in runoff and soil loss: a case study in the hilly areas of the Loess Plateau, North China

Soil crust and slope angle are of important factors affecting runoff production and sediment yield. In the hilly areas of the Loess Plateau, North China, slope lands are distributed extensively and subjected to soil crusting; therefore, the research on the responses of runoff and soil loss to soil crust and slope angle is essential to soil and water conservation. In the study, five pairs of 1 m × 5 m plots with slope angles of 5°, 10°, 15°, 20° and 25° respectively, were established in Wangjiagou watershed, which was located at the Loess Plateau, China. Based on the two simulated rainfall events, uncrusted surface prior to the first simulated rainfall event, and crusted surface prior to the second rainfall event were distinguished. The runoff production and soil loss were measured at intervals of 5 min during the simulated events. It indicated that both soil crust and slope angle played an important role in runoff production and soil loss. With the reference slope angle of 5°, the relative importance of soil crust and slope angle in runoff production was calculated. It showed that soil crust effect on the total runoff volume decreased from 100 to ～40%, while slope angle effect increased from 0 to ～60% with increasing slope angle because soil crust less developed on the steeper slopes. Furthermore, soil crust effect was associated with rainfall duration. At the same slope angle, the relative importance of soil crust decreased with rainfall duration because new crust was formed on the uncrusted surface. The critical slope of erosion was also discussed. Soil loss increased with slope angle when the slope angle was less than 20°. Generally speaking, soil crust effect decreased with slope angle and/or rainfall duration.     

Water infiltration characteristics of unsaturated soil slope and its effect on suction and stability

Rainfall has been considered the cause of the majority of slope failures and landslides that happened in regions experiencing high seasonal rainfalls. The mechanism of the failures was mainly due to the lost of matric suction of soils by rainwater. This paper presents the results of a laboratory model study on the effect of slope angle and surface cover on water infiltration into soil and soil matric suction. A field infiltration test is carried out for comparison. A parametric study is also done to examine the effect of permeability ratio, development of perched water table and rainfall intensity on the factor of safety against instability of a soil slope. Results of the model study show that different surface covers on slopes have an effect on the water infiltration. Generally the covered surface (grass or geosynthetic net) has a lower infiltration rate compared with the bare (no cover) surface. On the effect of slope angle, it was observed that water infiltration decrease with increase in the slope steepness. With regards to the movement of the wetting front, it appears that water infiltration is more at the toe compared with the top of the model slope. Based on the parametric study, it is found factor of safety of the slope against instability drops for slope with higher ratio of permeability for the permeable and impermeable stratum. As the perched water table is formed, the factor of safety decreased. The rainfall intensity also has a marked effect on the slope factor of safety. The higher the intensity of the rainfall, the higher is the infiltration rate into the soil, hence the lower is the factor of safety against slope instability.     

Failure mechanism of a slope with a thin soft band triggered by intensive rainfall

Rainfall is considered as one of the paramount factors for slope failures in many regions around the world, particularly in tropical and subtropical regions. To study the effect of rainfall storm and its duration on the stability of slopes with a thin soft band layer, a 2D seepage numerical analysis and experimental investigation were implemented on an unsaturated model, consisting of clayey sand soils with a thin soft layer inclined to the horizontal level by 30° at a slope angle of 50°. It was subjected to intensive rainfall 20 mm/h for 8 h. Positive pore water pressures and horizontal earth pressures were monitored during the rainstorm using sensors distributed inside the experimental model. Both the experimental and numerical simulation results showed that the stability of the slope decreased during the time of the rainfall storm. Infiltration of rainwater resulted in reduction of soil shear strength, due to the loss occurring in soil suction after 1 h of rainstorm; the tension cracks appeared at the top of the slope and a certain displacement was observed in the sliding blocks. During the time of rainstorm, the infiltrated water flowed out from the slope through the weak interlayer near to the toe causing piping and local failure, so the formed cracks at the top of slope grew and expanded due to sliding of the failed soil blocks. Moreover, the ground water table rose and the positive pore water pressures increased, resulting in a reduction of effective stress, which is considered as a main factor in soil shear strength. A surface runoff was also present following the full saturation of the slope, leading to dragging the fine particles with water flow causing erosion. The combination of piping and erosion effects led to a quick local failure at the toe, as well as sliding of the failed blocks and spreading of the cracks.     

细沟形态演变对坡面水沙过程的影响

为探明细沟形态演变对坡面产流产沙的互反馈作用,采用室内模拟降雨和三维地形扫描等手段对细沟形态演变中的水沙变化过程进行了研究。试验分析了黄土在不同雨强（66 mm/h、94 mm/h和127 mm/h）条件下,不同细沟发育阶段的水沙过程变化规律。结果表明,黄土细沟形态演变过程对产沙的影响较大,而对产流的影响较弱。径流量的变化过程主要取决于土体透水性、土壤的结皮作用以及产流方式,坡面产流量有先增大后减小最后趋于平稳的趋势;产沙量的变化过程与细沟发育进程有明显的对应关系,尤其是坡面地貌信息熵与产沙量和侵蚀速率的相关系数分别达到0.954和0.916,细沟的出现会加剧侵蚀,使含沙量明显增加;不同雨强下坡面产沙的变化规律基本相同,细沟沟网稳定后的产沙量与降雨强度呈正相关关系。     

陕西旬阳县210国道6号边坡变形特征初步研究

通过现场工程地质勘探、室内物理力学实验并利用FLAC2D数值分析软件对陕西旬阳县某堆积层边坡进行变形特征的实例分析,考查了坡体岩土体的粘聚力、内摩擦角数值与坡脚开挖深度的变化后,得出浅层岩土体较深层岩土体的滑动趋势与滑动位移均较大,并且浅层岩土体滑移变形对深层岩土体具有牵引力作用。最后对该类型堆积层坡体滑动的防治措施提出了一些看法。