基于人工降雨试验的淮北地区产流产沙差异性研究

针对淮北地区水土流失问题,利用野外人工模拟降雨试验,分析了不同雨强(40mm/h、60mm/h和80mm/h)和坡度(5°、10°和15°)条件下砂姜黑土和黄潮土产流产沙差异。结果表明:砂姜黑土初始产流时间长,产流总量小。坡面出现细沟时,砂姜黑土初始含沙量随时间变化有减小趋势,最终趋于稳定,而黄潮土含沙量呈波动变化;60mm/h、80mm/h雨强10°坡砂姜黑土产沙总量大于黄潮土,其他情况黄潮土产沙总量大于砂姜黑土,黄潮土土壤侵蚀严重。砂姜黑土表面细沟发育密度大,主要在坡面中下部,为相互连通的树枝状结构,而黄潮土表面细沟发育密度小,形成沟壑。两种土壤产流总量、产沙总量与坡度、雨强分别呈多元线性函数、多元幂函数关系,雨强对坡面产流产沙总量的影响大于坡度。     

降雨作用下马兰黄土渗透规律实验研究

通过自主研制的非饱和土直渗仪,对高为15cm、直径为12.5cm的圆柱形黄土试样进行降雨强度分别为16mm/h、50mm/h、70mm/h的渗透模拟试验,分析降水入渗深度、径流、富集量等与时间的对应关系,探究降水-黄土间的作用模式。得到实验结果:①不同雨强作用下,降水入渗锋面均呈漏斗状,凹面向下,均匀推进;②试验后试样含水率均超过液限,但随雨强增大含水率相应减小;③雨强16mm/h时无径流产生,雨强50mm/h、70mm/h时径流分别在试验开始29min和14min时形成;④降水入渗具有阶段性,雨强16mm/h,可分为快速下渗、缓慢下渗和匀速下渗三个阶段;雨强50mm/h、70mm/h,水开始入渗速率与土自身吸水能力有关,待上覆土饱和,水不仅受重力还受水驱动力的作用,入渗速度加快,最后稳定。获得结论包括:(1)雨强越大,水受重力和水力梯度作用越大,水下渗速度越快,充填孔隙的水就越少;(2)在雨强大于土体吸水能力的一定范围内,雨水补给量、径流量、下渗量以及充填量之间随降雨历时、入渗深度、孔隙度变化等因素出现相互制约、相互促进的关系;(3)试样完成渗流后,土体内形成稳定流,富集量与时间呈线性关系。     

不同坡度植被边坡降雨入渗和径流侵蚀规律的试验研究

为研究不同坡度植被边坡降雨入渗和径流侵蚀的规律,开展大型边坡模型降雨试验,对边坡含水率、水土流失等参数进行实时监测,量化分析坡度对边坡雨水入渗、坡面径流和土壤侵蚀的影响。结果表明：在持时为4 h、降雨强度为60 mm/h持续降雨条件下,1:2、1:1.75、1:1.5裸土边坡累计雨水入渗量分别为同坡度植被边坡的70.6%、80.4%、92.3%,植被覆盖会加快雨水入渗速率,增大边坡累计雨水入渗量。植被边坡坡度越小,雨水入渗速率越快,累计雨水入渗量越大,而裸土边坡则相反。植被覆盖可有效降低坡面径流速率、减少累积径流量,边坡坡度越小,减流效果越显著,1:2、1:1.75、1:1.5植被边坡对比同坡度裸土边坡分别减少径流量53.11%、32.56%、17.73%。植被边坡水土流失含泥沙量均不足0.1%,植被可有效抑制坡面土壤侵蚀,而裸土边坡坡度越大坡面土壤侵蚀越严重,1:2、1:1.75、1:1.5裸土边坡单位面积侵蚀土壤质量分别为3.623、5.710、11.295 kg/m²,水土流失含泥沙量分别为3.06%、4.29%、7.34%。根据试验结果拟合得到裸土边坡产泥...     

降雨条件下滑坡排水沟排水数值模拟

地表排水沟是滑坡治理常见措施之一。在降雨入渗与坡面径流有限元耦合模型中,通过调整径流方程中的坡度参数,实现地表排水沟排水模型。模型具有易于理解、实现简单的优点。以地表排水模型为基础,对5种典型滑坡在设与不设排水沟情况下坡体渗流场、坡面径流场、坡体入渗量和入渗过程进行了数值模拟。结果表明,当降雨强度相对土体渗透性较小时,排水沟设置在坡体渗透性由小变大的位置,才能有效地截断上游径流,减小入渗量;而当降雨强度相对土体渗透性较大时,排水沟排水效果并不明显。     

微生物诱导矿化加固粉土坡面的径流与侵蚀特性

微生物诱导碳酸盐沉淀（MICP）是一种微生物矿化过程,能够胶结松散土体。将其应用于加固土体坡面提高抗降雨侵蚀能力具有潜在的发展前景。通过模拟降雨冲刷试验,对微生物诱导矿化加固前后粉土坡面的径流水动力与侵蚀特性开展研究,分析和讨论了水动力参数之间的相关性以及对土壤剥蚀率的影响规律。结果显示,加固后与加固前相比,粉土坡面径流的弗劳德数平均下降50%;在降雨前期的阻力系数平均下降66%,径流稳定后二者阻力系数接近;径流剪切力平均提高52%。径流系数与坡面入渗速率呈线性负相关（R²=0.857）,与加固层的贯入强度呈指数负相关（R²=0.824）;入渗速率与加固层的贯入强度呈二次负相关R²=0.930）;径流剪切力与坡度呈指数正相关（R²=0.964）。加固粉土坡面的剥蚀率与加固层的贯入强度呈指数负相关（R²=0.822）,与径流剪切力线性正相关（R2=0.912）,临界径流剪切力为0.5 Pa。对于坡度10~25°的粉土坡面,微生物加固能将其剥蚀率从58.2~118.4 g/m2s降至2.4~21.2 g/m2s,剥蚀率最大降幅可达95.0%。粉土坡面经微生物诱导矿化加固后,水动力参数值发生显著变化,径流特性与水动力参数、加固层特性及坡度相关,坡面的抗冲刷侵蚀性能得到有效提升。     

喀斯特裸坡土壤侵蚀模拟研究

文章通过人工模拟降雨试验,研究不同地下孔（裂）隙度、基岩裸露率和雨强对地表、地下产流、产沙的影响,其结果表明:（1）土壤侵蚀与地下孔（裂）隙度具有较高相关性,地表产流、产沙随地下孔（裂）隙度的增大而减小,而地下则相反;（2）坡面径流刚产生时,雨滴击溅和薄层水流冲刷,土壤细小颗粒堵塞其毛管空隙,渗漏率减小,而地表径流量增大,土壤团聚体被破坏、分散和迁移,降水与土壤渗漏率增大,地表径流量减小,雨滴击溅增强,如此循环,降水与土壤渗漏率呈波动性变化;总体而言,地表、地下悬移质均随降雨历时呈下降趋势,而地表推移质则相反,地表、地下产流量变幅较小,趋于平行;（3）地表产流、产沙量随基岩裸露率增大呈波动性变化,总体呈下降趋势;而地下产流、产沙量随基岩裸露率增大呈波动性变化,总体呈增大趋势;（4）在较小雨强30 mm/h时,地表只产生悬移质流失,没有产生推移质流失;地表、地下产流、产沙都是随雨强增大而增大;雨强由30 mm/h增大到150 mm/h,地表累积产流量为538.5 L,累积产沙量为2 393.81 g,地下累积产流量为207.8 L,累积产沙量为687.73 g,累积产沙量的递增速率比累积产流量的递增速率要大,地表产流、产沙的递增速率大于地下产流、产沙的递增速率;（5）各因子与土壤侵蚀间相关程度为:降雨历时>雨强>地下孔（裂）隙度>基岩裸露率。该实验有助于为喀斯特地区的水土流失研究、评价及制订石漠化治理措施提供理论依据。      

黄土丘陵沟壑区坡面尺度撂荒草地入渗特征影响因素试验研究

为研究黄土丘陵沟壑区多种因素对撂荒草地入渗特征的影响,采用野外自然降雨观测法,研究不同降雨特征（降雨量、平均雨强、降雨历时和最大30 min雨强（I₃₀））、土壤前期含水量、坡长（10 m、20 m、30 m、40 m和50 m）和植被盖度条件下土壤入渗特征差异,通过灰色关联度法判断影响撂荒草地入渗特征的主导因子。结果表明:①入渗量随降雨量、降雨历时和I₃₀增加而增大（R2>0.55,P < 0.01）;入渗补给系数随降雨量、I₃₀和平均雨强增大而减小（R2>0.12,P < 0.05）;平均入渗率随降雨强度、I₃₀增加而递增（R2>0.53,P < 0.01）。②入渗量和平均入渗率随前期含水量增加而减少,入渗补给系数随之增加而增大（R2>0.13,P < 0.05）。③入渗量、入渗补给系数和平均入渗率总体随坡长增加而增大（R2>0.56,P < 0.01）,但在坡长30 m和40 m之间存在临界坡长。④在入渗效率较高的情况下,植被对土壤入渗的影响并不显著,降雨特征和坡长成为主导因子。     

黄土丘陵沟壑区坡面尺度撂荒草地入渗特征影响因素试验研究

为研究黄土丘陵沟壑区多种因素对撂荒草地入渗特征的影响,采用野外自然降雨观测法,研究不同降雨特征（降雨量、平均雨强、降雨历时和最大30 min雨强（I₃₀））、土壤前期含水量、坡长（10 m、20 m、30 m、40 m和50 m）和植被盖度条件下土壤入渗特征差异,通过灰色关联度法判断影响撂荒草地入渗特征的主导因子。结果表明：①入渗量随降雨量、降雨历时和I₃₀增加而增大（R²>0.55,P<0.01）;入渗补给系数随降雨量、I₃₀和平均雨强增大而减小（R²>0.12,P<0.05）;平均入渗率随降雨强度、I₃₀增加而递增（R²>0.53,P<0.01）。②入渗量和平均入渗率随前期含水量增加而减少,入渗补给系数随之增加而增大（R²>0.13,P<0.05）。③入渗量、入渗补给系数和平均入渗率总体随坡长增加而增大（R²>0.56,P<0.01）,但在坡长30 m和40 m之间存在临界坡长。④在入渗效率较高的情况下,植被对土壤入渗的影响并不显著,降雨特征和坡长成为主导因子。     

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。     

陕北风沙区含砾石工程堆积体坡面产流产沙试验

采用室内人工模拟降雨方法,研究了陕北风沙区含砾石工程堆积体边坡的产流产沙过程。结果表明:①砾石存在改变了坡面入渗速率,径流系数受入渗速率的影响,随砾石含量的增加先线性递减后线性递增,并在10%砾石含量处存在阈值;径流系数随降雨强度的增加线性递增。②含砾石堆积体坡面流速较纯土堆积体降低,且随雨强增大,砾石延缓径流流动的作用越显著;雨强对径流流速的影响随砾石含量增加持续减弱。③土壤剥蚀率在产流24~33 min后显著增加,砾石主要对显著增加后的平均剥蚀率产生影响。④雨强1.0 mm/min时,砾石存在促进降雨侵蚀,产沙量增大;雨强大于1.0 mm/min时,砾石具有显著的减沙效应。     

砾石覆盖紫色土坡耕地水文过程

紫色土中砾石分布广泛,地表常为砾石覆盖,砾石覆盖对土壤水文过程有着重要影响。试验小区(2 m×1 m)为坡度23°的坡耕地, 试验降雨强度为(53.9±2.8)mm/h、 (90.8±6.1)mm/h和(134.3±14.9)mm/h, 砾石覆盖度为0%,11%,20%,33%和42%。通过原位人工模拟降雨试验,定量研究了不同降雨强度下砾石覆盖对降雨入渗、地表产流及壤中流产流的影响。结果表明:砾石覆盖对入渗过程影响显著,稳定入渗速率及稳定入渗系数与砾石覆盖度呈正相关关系,3种降雨强度下,稳定入渗系数分别为47.70%~86.59%,30.61%~82.83%、17.76%~77.44%,42%砾石覆盖度小区的稳定入渗速率分别是裸露小区的1.95~4.94倍;地表砾石覆盖延迟地表产流、减少地表径流量,地表产流时间随着砾石覆盖度的提高呈增加趋势,地表径流速率及地表径流系数随砾石覆盖度的增加而降低,相对地表径流系数与地表砾石覆盖度呈指数负相关关系;地表砾石覆盖促进壤中流的发生、增加壤中流量,壤中流产流时间随着砾石覆盖度的增加逐渐缩短,壤中流径流速率及壤中流径流系数随地表砾石覆盖度的增加而提高,相对壤中流径流系数与地表砾石覆盖度呈指数正相关关系。     

强降雨条件下基岩型层状边坡入渗模型及稳定性研究

强降雨作用下基岩型层状边坡易发生失稳破坏,给人们生命财产造成重大损失。为探索基岩型层状边坡的降雨入渗过程,以Green-Ampt入渗模型为基础,考虑了边坡几何特征及饱和带渗流作用,得到了边坡不同入渗阶段入渗率和湿润峰深度的计算式,建立了适用于基岩型层状边坡的降雨入渗计算模型;在分析基岩型层状边坡稳定性时,考虑了饱和带的渗流作用,联合降雨入渗模型与极限平衡法,分析了基岩面与湿润峰面稳定性的变化规律,得到了计算基岩型层状边坡安全系数的解析表达式;结果表明,该模型的计算与试验结果具有一致性。利用该计算模型与传统计算方法对张家湾滑坡进行了强度为30 mm/h的降雨入渗与稳定性分析,得到了不同计算方法下张家湾滑坡湿润峰深度及安全系数随降雨历时增加而发生的变化规律,结果表明该计算模型在分析基岩型层状边坡稳定性时优于传统分析方法。     

An improved approach for evaluating the time-dependent stability of colluvial landslides during intense rainfall

The paper presents an improved analytical approach for evaluating the time-dependent stability of colluvial landslides during intense rainfall infiltration. The approach comprises two steps: first to simulate rainfall infiltration and then to compute the safety factor. In terms of the irregularity of the natural landslide surface in implementation of the method, the landslide is divided into several soil slices with approximately straight sides. Each single slice is regarded as a finite slope so that the infiltration formula and safety factor can be deduced. The infiltration formula is derived with combination of the Green–Ampt model and mass conservation law considering seepage perpendicular and parallel to slope surface simultaneously. In the modified infiltration model, both size effect and angle effect are vividly observed in the process of rainfall infiltration into the finite slope, while the former of which is not presented in the original Green–Ampt model. The safety factor is computed using the limit equilibrium method, with the influence of infiltrating water on the shear strength, gravity and seepage force of soil slices considered. By case study of the Shuping landslide in Three Gorges, decline in the safety factor and the decrease in the tendency are definite. Specifically under the rainfall intensity of 50 mm/h, the failure of Shuping landslide is most likely to occur at the time of 102 h. In addition, the results highlight shallow failure along the wetting front under intense rainfall.     

强降雨作用下强风化泥岩降雨入渗特性试验研究

土体降雨入渗特性是实施坡面泥石流和土体滑坡发育过程研究的重要因素。研制了人工降雨土柱入渗试验装置,实施了10、20、30、40、50、60 mm/h共6种降雨强度下强风化泥岩的入渗试验,最长降雨历时105 min。试验结果表明：可将土体入渗过程可分为无压入渗、有压入渗和饱和入渗3阶段,其中土体的入渗率在无压入渗阶段和饱和入渗阶段均随降雨历时增长近似为常数,在有压入渗阶段则快速降低;通过定义降雨作用下土体入渗锋,包括初始入渗锋和终止入渗锋,分析了入渗锋所处位置随降雨强度的变化关系,初始入渗锋和终止入渗锋之间的幅值随降雨强度的增大而变宽;提出了可表征重庆地区侏罗系强风化泥岩入渗过程的土体降雨入渗公式。研究成果对于构建重庆地区降雨诱发型滑坡及坡面泥石流的预测预报模型有积极意义。     

Hydrologic conditions responsible for triggering the Sto e landslide, Slovenia

In two events, on November 15 and 17, 2000, near the Mangart Mountain (2679 m a.s.l.), NW Slovenia, two translational landslides (debris flow slides) with a total volume of more than 1.5 million m³ occurred on the Sto e slope composed of morainic material filled with silt fraction. The first landslide was associated with a dry and the second landslide with a wet debris-flow, respectively. The rain gauging station in the village of Log pod Mangartom recorded 1638.4 mm of rainfall (more than 60% of the average annual precipitation) in the 48 days before the events (rainfall intensity of 1.42 mm/h in 1152 h). The recorded rainfall depth has a recurrence interval of more than 100 years. Other recorded rainfall depths of shorter duration (481.6 mm in 7 days, 174.0 mm in 24 h, 70 mm in 1 h) have recurrence intervals of much less than 100 years. A hydrological analysis of the event showed that the increase in runoff coefficients during the wet period in autumn 2000 before the landslide was as high as two- to threefold. An analysis using natural isotopes of δ¹⁸O and tritium of water samples from the Sto e landslide area has shown permanent but slow exfiltration of underground waters from a reservoir in the slope. In the case of low-intensity and long-duration rainfall in autumn 2000, relatively low permeable (10⁻⁷ m/s) morainic material was nearly saturated but remained stable (average porosity 21%, water content 20%, liquid limit 25%) until high artesian pressures up to 100 m developed in the slope by slow exfiltration from the relatively high permeable (10⁻⁵ m/s) massive dolomite. The Sto e landslide (two debris flow slides) was triggered by high artesian pressures built in the slope after long-duration rainfall. The devastating debris-flows formed from the landslide masses by infiltration of rainfall and surface runoff into the landslide masses and by their liquefaction.     

台风暴雨型土质滑坡演化过程研究

台风暴雨型滑坡是我国东南丘陵山地主要的滑坡类型,揭示其失稳演化规律对东南丘陵山地台风暴雨型土质滑坡监测预警具有重要的理论及实际意义。本文以福建泉州德化石山滑坡为研究对象,结合现场地质勘察资料,建立滑坡物理与数值模型对其变形演化过程进行模拟,探究边坡失稳涉及的渗流和变形位移等规律。研究结果表明:(1)初期雨水以垂直入渗坡体为主,且入渗速率较大;后期入渗速率随坡体饱和度增加而减小。有前期小降雨的情况下,坡脚位置更易出现积水饱和现象;(2)雨水入渗是导致坡体稳定性下降的主要原因:在暴雨工况中E3(模拟全程降雨为暴雨雨强100 mm·d-1)中,稳定系数保持下降,从1.197降至1.125;在双峰暴雨工况E4(前期30 mm·d-1小雨强降雨,后期100 mm·d-1暴雨雨强降雨)中,小雨强降雨过程中稳定系数基本保持不变,从1.197降至1.188,当暴雨一开始,稳定系数骤降至1.060;(3)台风暴雨型滑坡位移演化过程具有阶段性特征:压缩沉降微变形阶段,该阶段位移曲线变化平缓,基本不发生位移;匀速变形阶段,该阶段位移匀速增长,位移速率不变;加速变形阶段,加速变形直至失稳阶段,破坏迅速,具有突发性,曲线呈非线性;(4)当前期发生小雨强降雨(降雨强度≤30 mm·d-1),后期突发大暴雨雨强降雨(降雨强度≥100 mm·d-1)情况下滑坡的发生具有突变性,在试验中暴雨初期位移骤增20 mm,而后快速发展到90 mm左右。     

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.