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土石坝漫顶溃决往往在其下游产生巨大的洪水灾难,研究坝体溃决及洪水演进是防灾减灾的需要。对土石坝漫顶溃决过程现象、机理及其模拟的研究进展进行了综述。讨论了物理模型试验的尺度设计,总结了不同尺度、不同类型、不同条件溃坝试验的研究成果;按照参数模型、简化物理模型、精细物理模型,分类总结了漫顶溃坝数学模型研究进展;阐述了溃坝洪水演进方面的试验与模拟研究。在此基础上,对该研究领域今后的研究工作提出了若干展望,包括河道边界对溃坝过程及溃坝洪水传播过程的影响、非均质土石坝溃决机理、溃坝过程中挟沙水流冲蚀规律、溃坝下游河床的冲淤调整及泥沙分选、溃坝对水生态环境的冲击影响等。 相似文献
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土石坝漫顶溃决往往在其下游产生巨大的洪水灾难,研究坝体溃决及洪水演进是防灾减灾的需要。对土石坝漫顶溃决过程现象、机理及其模拟的研究进展进行了综述。讨论了物理模型试验的尺度设计,总结了不同尺度、不同类型、不同条件溃坝试验的研究成果;按照参数模型、简化物理模型、精细物理模型,分类总结了漫顶溃坝数学模型研究进展;阐述了溃坝洪水演进方面的试验与模拟研究。在此基础上,对该研究领域今后的研究工作提出了若干展望,包括河道边界对溃坝过程及溃坝洪水传播过程的影响、非均质土石坝溃决机理、溃坝过程中挟沙水流冲蚀规律、溃坝下游河床的冲淤调整及泥沙分选、溃坝对水生态环境的冲击影响等。 相似文献
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针对缺乏地形条件和工程处置措施对堰塞坝溃决过程影响研究的现状,采用4种河床坡度(0°、1°、2°、3°)和3种泄流槽横断面型式(三角形、梯形、复合型),开展了堰塞坝溃决的模型试验。通过分析堰塞坝的溃决流量、溃决历时、溃口发展和坝体纵截面演变过程,研究了不同河床坡度和泄流槽横断面对堰塞坝溃决过程的影响规律。试验结果表明:... 相似文献
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滑坡堰塞坝作为结构松散的堆积物,随着上游水位的不断上涨,其稳定性不断降低,并存在突然溃坝的风险。以唐家山滑坡堰塞坝为研究对象,基于相似原理,开展符合坝体颗粒级配的室内水槽物理模型实验,模拟了不同坝后蓄水量、不同水位和不同颗粒物质组成条件下坝体渗流、漫顶破坏的整个过程。监测结果显示:堰塞坝漫顶溃坝主要分为渗流、漫顶、冲刷和溃决4个过程;坝体堆积颗粒级配越差,坝体允许渗流坡降越小;相同材料配比的坝体,上游水位相同时,坝体底部水平位移最大,且漫顶溃坝时溃口尺寸与蓄水量正相关。该研究结果揭示了堰塞坝漫顶破坏规律,可为堰塞坝溃坝防治提供理论参考。 相似文献
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堤防溃决时溃口附近水流形态及溃决流量变化过程的正确描述是指导溃口堵复及时避险、预测溃堤洪水演进并进一步评估淹没损失的前提条件.通过弯道水槽中的概化模型试验,根据无粘性土堤防漫顶溃决的溃口变化和水流运动特征,将无粘性土堤防溃决过程分为漫流、冲槽、展宽及稳定4个阶段.试验系统研究了堤防溃决后河道以及溃口附近水位的变化过程,研究了河道洪水流量、洪水位和筑堤材料对溃口处水位的影响.基于大量的试验资料,进一步归纳总结出溃决流量与溃口口门宽度及溃口处水头变化之间的关系. 相似文献
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白什滑坡坝漫溢溃坝的水文条件预测 总被引:1,自引:0,他引:1
为防避四川省北川县白什滑坡坝溃坝酿至溃决洪水与泥石流灾害,对导致漫溢溃坝的水文条件进行了预测。在论述白什滑坡和滑坡坝的特征的基础上,通过对可能发生的溃坝类型、形成漫溢型溃决所需临界水头、溃决时水流流速和导致溃决的洪峰流量的预计,得出了一般洪水时不会溃坝、100年一遇洪水时可能溃坝的预测结论。 相似文献
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堰塞坝溃坝模型实验研究综述 总被引:1,自引:0,他引:1
堰塞坝是天然形成的坝体,结构比较松散、稳定性差、渗透作用强,发生溃决危险性大、概率高、突发性强,而且破坏可能性高及产生的洪水威胁人们的生命和财产安全,因此需要系统、全面的研究。作者从单坝溃坝、级联溃坝及堰塞坝处置的溃坝试验进行详细的回顾,总结及分析了国内外学者在堰塞坝溃坝模型实验取得的成果及局限性,进一步分析了单坝溃决的颗粒级配、密实度、含水率、沟床坡度等因素,最后讨论了溃坝因素与溃决模式、溃决特征、溃决流量、溃口演化的关系。基于模型实验相似理论及模型比尺、实验测试手段、堰塞坝处置三个方面,提出了今后的研究重点。 相似文献
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为研究粉质黏土堤防漫溢溃决破坏过程及其对水流要素和土体性质的响应规律,以河道流量、筑堤土体含水率和孔隙率为变量,在弯道水槽中开展了9组堤防漫溢溃决概化试验.通过试验发现,粉质黏土堤漫溢溃决溃口发展过程可分为垂向侵蚀和横向扩宽两个阶段,垂向侵蚀阶段以"陡坎"后退为主要形式;筑堤土体含水率与孔隙率不仅影响了溃口垂向侵蚀以及横向扩宽速度,而且决定了溃口最终形态,河道流量主要影响堤防溃口的横向扩宽速度;溃口处流速以及下游水位变化受溃口高度的制约.拟合得到土体黏聚力与土体含水率、孔隙率的相关关系式;通过试验数据提出了由土体黏聚力和水流参数表达的"陡坎"侵蚀后退速度计算公式,证明具有一定合理性. 相似文献
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为了解堰塞坝在不同沟床坡度地段的溃口展宽历程,进行了沟床坡度为7°~13°,间隔为1°的7组水槽试验。对比分析7组试验观测数据,评价不同沟床坡度对堰塞坝溃口展宽历程的影响。得到如下结果及结论:(1)漫顶破坏的堰塞坝在不同沟床坡度地段的溃口展宽历程是十分相似的,根据其溃决特征,可将其展宽历程划分为溃口贯通、突变和稳定边坡形成等3个阶段。(2)在突变阶段溃口边坡沿x轴方向会发生多次失稳,溃口顶部形态在背水坡呈“S”型,在坝顶呈“U”型,在迎水坡呈“弧”型。(3)不同沟床坡度条件会影响突变阶段的溃决特征,随沟床坡度的增加突变阶段溃口边坡单次失稳规模表现出先增大后减小的特征,溃口边坡失稳次数呈现出先减少后增加的特征。(4)溃口边坡的稳定性主要取决于溃口的侧蚀宽度和下蚀深度,其与溃口顶、底部侧蚀宽度之差呈负相关关系,与溃口下蚀深度呈正相关关系。(5)不同沟床坡度堰塞坝的溃决流量随溃决时间的延长具有相同的变化趋势,但不同沟床坡度堰塞坝的溃决峰值流量和峰值流量到达时间却不尽相同,随沟床坡度的增加峰值流量逐渐减小,峰值流量到达时间先提前后推迟。 相似文献
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The breach of landslide dam often causes significant disaster in the inundated area; the prediction of breach hydrograph is in high demand for the dam breach risk evaluation. In this study, according to the model tests and Tangjiashan landslide dam breach case, the surface erosion accompanied by intermittent mass failure is known as the key breaching mechanism for landslide dam due to overtopping failure. The downstream slope angle would gradually decrease during the dam-breaching process, whereas a planar wedge failure occurs when the breach slopes at the dam crest and downstream breach channel fail. Based on the breach mechanism, a numerical model for landslide dam breach due to overtopping is developed to simulate the coupling process of water and soil. The model focuses on the breach morphology evolution during the breaching for the sake of the improvement of breach hydrograph prediction. Furthermore, the model can handle one- and two-sided breach, as well as incomplete and base erosion at the vertical direction. The case study of Tangjiashan landslide dam-breaching feedback analysis testifies the rationality of the present model with the relative errors less than 10% for peak discharge, final breach widths, and time to peak. The sensitivity analysis indicates that the final breach depth and soil erodibility affect the breach flow prediction of the landslide dam significantly, whereas the one- or two-sided breach mode is less sensitive. 相似文献
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Landslide dam failure can trigger catastrophic flooding in the downstream. However, field observation of such flooding is
rarely available, while laboratory experimental studies are sparse. The mechanism of landslide dam failure and the flood has
so far remained insufficiently understood. Here, we present an experimental investigation of landslide dam failure and the
flood. A total of 28 runs of experiments are carried out in a flume of 80 m × 1.2 m × 0.8 m, with differing inflow discharge,
dam composition, dam geometry, and initial breach dimension. An array of twelve automatic water-level probes is deployed to
measure the stage hydrographs along the flume, and the video recording of the dam failure processes facilitates an estimation
of the widening of initial breach. Under the present experimental conditions with dams composed of homogeneous materials,
landslide dam failure is primarily caused by erosion of overtopping flow, and lateral mass collapse is also considerable during
the cause of breach widening. Cohesive clay may act to mitigate the seepage through the dam and thus its subsidence and appreciably
modulate the dam failure process and the flood. However, the impacts of clay may be readily overwhelmed by a large inflow
discharge and initial breach. Gravels in the dam may appreciably depress the rate of the dam failure process and thus modify
the flood. The present work provides new experimental data set for testing mathematical models of the flood flow due to landslide
dam failure. 相似文献
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A coupled 2D mathematical modelling study of landslide dam failure and flood is presented, complementing our experimental
investigation presented in the companion paper. The model is built upon the shallow water hydrodynamic equations. The governing
equations are numerically solved using the total-variation-diminishing version of the second-order weighted-average-flux method
along with the HLLC (Harten, Lax and van Leer with Contact wave restored) approximate Riemann solver. Two parameters related
to bed-load sediment transport and critical slope stability are calibrated using the measured stage hydrographs from two runs
of the flume experiments. The calibrated model is then applied to other independent runs of the experiments featuring different
inflow discharges, dam geometry, dam composition and initial breach dimensions. It is found to be able to satisfactorily reproduce
the measured stage hydrographs and the widening of initial breach. The experimental observation of the prime role of the inflow
discharge and initial breach in dictating the dam failure process and flood is unequivocally resolved, along with the impacts
of dam geometry as well the content of cohesive clay and gravel in the dam. Interestingly, the downstream peak discharge and
stage of the flood are substantially reduced by initial breach, which clearly exemplifies its role in modulating the flooding. 相似文献
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终碛坝广泛分布于世界各地的高山和极高山区。为了探究终碛坝的溃决过程,了解溃口的演变特征,文章以嘉龙错终碛坝的原位实验,模拟了终碛湖漫顶溃决过程。通过分析实验结果发现:(1)根据观察,将终碛坝溃决过程划分为坝体下游坡面冲刷、“溯源侵蚀”、出水口下切和溃口拓宽四个阶段。(2)上游湖区崩塌体激发的涌浪会造成溃口内的瞬时流量增加数倍,从而使得在有涌浪和无涌浪的条件下,“溯源侵蚀”过程出现陡坎和斜坡两种下切型。(3)通过分析溃口下切侵蚀过程,发现溃口的下切侵蚀发展过程主要受到坝体孔隙比和细粒含量的影响,并且溃口中点侵蚀率与水流剪应力存在一定的线性关系,符合线性侵蚀模型。通过分析发现,嘉龙错终碛坝的侵蚀系数为0.051,临界启动应力为237.64 Pa。与堰塞坝相比,可侵蚀系数比更小,而临界启动应力更大。 相似文献
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For over three decades, emergency planners have used numerical models to predict breaching in earthfill dams due to extreme
events such as overtopping. However, current models neglect the role of the unsaturated zone present within the downstream
face of an earthfill dam. This leads to an incorrect estimation of the time and space evolution of the breaching process,
as such models often oversimplify governing geotechnical aspects such as the presence of the unsaturated soil medium in the
vicinity of the breach channel. The stress state in the soil due to matric suction acts as a stabilizing force for the breaching
mechanism and influences the erosion of the breach channel, especially during the initial phases of the breaching. The side-slope
failure mechanism observed along the breach channel is also influenced by the negative pore-water-pressures in the soil. Based
on a comprehensive experimental research program carried out in the Hydraulics Laboratory at the University of Ottawa, Canada,
several new concepts are proposed to incorporate geotechnical factors and techniques which must be considered during the construction
of earthfill dam models for laboratory testing. Two main findings emerged from this experimental work. First, the installation
of a drainage mattress at the downstream toe of the dam depressed the phreatic surface through the earthfill dam body, which
caused a lag in the breaching process due to the infiltration and reduced erosion occurring in the breach channel. Second,
it is essential to control compaction during the construction of the earthfill dam model, since this significantly influences
the erosion, as well as the side-slope failures which occur in the breach channel. Future studies are under way by the authors
with the purpose of scaling of parameters such as the matric suction and soil erodibility. 相似文献
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Physically based modeling approach has been widely developed in recent years for simulation of dam failure process resulting
from overtopping flow. Due to the lack of field data, there exist few applications to natural quake dams with complex erosion
mechanisms. This paper presents a physically based simulation of the failure process of the Tangjiashan Quake Dam formed as
a result of the “May 12, 2008” Wenchuan earthquake in China. The one-dimensional model adopted features as cost saving but
enables capturing the main characteristics of the failure process, where selective sediment transport and gravitational slope
collapse are accounted for. The simulated flow hydrograph and breach progression process are generally in good agreement with
the observed data. Unsteadiness and non-uniformity are found to be substantial characteristics of breach progression during
the failure process of natural quake dams. Sensitivity analysis showed that the Manning resistance coefficient and the erodibility
coefficient in Osman and Thorne’s (J Hydraul Eng 114(2):134–150, 1988) model significantly influences the flow peak discharge but has less influence on its occurrence time, while the velocity
lag coefficient associated with bed-load transport may affect the two breaching parameters substantially. 相似文献
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Breaking tests on homogeneous earth-rock-fill dams destroyed by overtopping flow are presented. Two types of shear erosion are found: wetting shear erosion and quick shear erosion; the water level-discharge process is divided into “sharp rise and drop of flow” and “slow change of flow” types. Furthermore, overtopping break modes are divided into head-cut erosion and scour breaching mode (Mode 1), shear erosion and collapse breaching mode (Mode 2), and wetting shear erosion mode (Mode 3) based on the main failure types and their coupled mode during dam break. In Mode 1, the downstream slope encounters head-cut erosion at the onset of the breach and expands and undercuts gradually at the development stage; in Mode 2, the dam slope encounters rapid shear erosion and the downstream edge of the crest erodes quickly towards the upstream face at the onset of breach: the breach expands suddenly due to instability and collapse at both sides of the breach in its development stage; in Mode 3, the strength of the dam’s materials continuously decreases by wetting and erosion happens is localised at positions where wetting caused the most strength loss, no obvious breach was developed. Dam breaking time, dam-break flow process, and the maximum discharge flow varied for each breaking mode. Overtopping flow size, materials, height, and initial breach size of dam are important factors influencing breaking mode, by virtue of their changing the relative strength of the relationship between the critical shear stress of dam materials at the edge of the dam crest and the lower parts of its slope, and the given flow’s destruction capacity. Overtopping will cause different manifestations of damage to be exhibited, so modal classification is favourable for safety assessment and preparation of relevant protective measures for protection of earth-rock-fill dam against overtopping. 相似文献
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溃坝风险后果分析是水库大坝风险评估的重要内容。影响溃坝风险后果的因素多,作用机理复杂,导致不同研究方法的分析结果与实际后果之间均存在较大差异。从风险后果的内涵出发,建议风险后果可分为生命损失、经济损失和环境影响3个基础类别;分析国外研究成果与应用情况,明确从基于历史资料构建经验模型到基于致灾机理构建物理模型的发展趋势;分析中国溃坝风险后果评估现状,明确结合致灾机理的经验模型分析、半定量评价和区域损失叠加计算三类研究方法在准确性和实用性方面的优点与不足;提出应从加强致灾机理分析、注重准确性与实用性的结合、重视非工程措施的重要作用和在应用中不断改进等4个方面采取措施,提高风险后果研究水平和实际应用效果。 相似文献